numam-dpdk/drivers/net/mlx5/mlx5.c

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/* SPDX-License-Identifier: BSD-3-Clause
* Copyright 2015 6WIND S.A.
* Copyright 2015 Mellanox Technologies, Ltd
*/
#include <stddef.h>
#include <unistd.h>
#include <string.h>
#include <stdint.h>
#include <stdlib.h>
#include <errno.h>
#include <fcntl.h>
#include <rte_malloc.h>
#include <ethdev_driver.h>
#include <rte_pci.h>
#include <bus_pci_driver.h>
#include <rte_common.h>
#include <rte_kvargs.h>
#include <rte_rwlock.h>
#include <rte_spinlock.h>
#include <rte_string_fns.h>
common/mlx5: fix post doorbell barrier The rdma-core library can map doorbell register in two ways, depending on the environment variable "MLX5_SHUT_UP_BF": - as regular cached memory, the variable is either missing or set to zero. This type of mapping may cause the significant doorbell register writing latency and requires an explicit memory write barrier to mitigate this issue and prevent write combining. - as non-cached memory, the variable is present and set to not "0" value. This type of mapping may cause performance impact under heavy loading conditions but the explicit write memory barrier is not required and it may improve core performance. The UAR creation function maps a doorbell in one of the above ways according to the system. In run time, it always adds an explicit memory barrier after writing to. In cases where the doorbell was mapped as non-cached memory, the explicit memory barrier is unnecessary and may impair performance. The commit [1] solved this problem for a Tx queue. In run time, it checks the mapping type and provides the memory barrier after writing to a Tx doorbell register if it is needed. The mapping type is extracted directly from the uar_mmap_offset field in the queue properties. This patch shares this code between the drivers and extends the above solution for each of them. [1] commit 8409a28573d3 ("net/mlx5: control transmit doorbell register mapping") Fixes: f8c97babc9f4 ("compress/mlx5: add data-path functions") Fixes: 8e196c08ab53 ("crypto/mlx5: support enqueue/dequeue operations") Fixes: 4d4e245ad637 ("regex/mlx5: support enqueue") Cc: stable@dpdk.org Signed-off-by: Michael Baum <michaelba@nvidia.com> Reviewed-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com> Acked-by: Matan Azrad <matan@nvidia.com>
2021-11-03 18:35:13 +00:00
#include <rte_eal_paging.h>
#include <rte_alarm.h>
#include <rte_cycles.h>
#include <rte_interrupts.h>
#include <mlx5_glue.h>
#include <mlx5_devx_cmds.h>
#include <mlx5_common.h>
#include <mlx5_common_os.h>
#include <mlx5_common_mp.h>
#include <mlx5_malloc.h>
#include "mlx5_defs.h"
#include "mlx5.h"
#include "mlx5_utils.h"
#include "mlx5_rxtx.h"
#include "mlx5_rx.h"
#include "mlx5_tx.h"
#include "mlx5_autoconf.h"
#include "mlx5_flow.h"
#include "mlx5_flow_os.h"
#include "rte_pmd_mlx5.h"
#define MLX5_ETH_DRIVER_NAME mlx5_eth
net/mlx5: handle Rx CQE compression Mini (compressed) completion queue entries (CQEs) are returned by the NIC when PCI back pressure is detected, in which case the first CQE64 contains common packet information followed by a number of CQE8 providing the rest, followed by a matching number of empty CQE64 entries to be used by software for decompression. Before decompression: 0 1 2 6 7 8 +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | |-------| |---------| |-------| |-------| |-------| |-------| | ..... | | cqe8[0] | | | . | | | | | ..... | | ..... | | cqe8[1] | | | . | | | | | ..... | | ..... | | ....... | | | . | | | | | ..... | | ..... | | cqe8[7] | | | | | | | | ..... | +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ After decompression: 0 1 ... 8 +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | |-------| |-------| |-------| | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | | ..... | +-------+ +-------+ +-------+ This patch does not perform the entire decompression step as it would be really expensive, instead the first CQE64 is consumed and an internal context is maintained to interpret the following CQE8 entries directly. Intermediate empty CQE64 entries are handed back to HW without further processing. Signed-off-by: Nelio Laranjeiro <nelio.laranjeiro@6wind.com> Signed-off-by: Adrien Mazarguil <adrien.mazarguil@6wind.com> Signed-off-by: Olga Shern <olgas@mellanox.com> Signed-off-by: Vasily Philipov <vasilyf@mellanox.com>
2016-06-24 13:17:54 +00:00
/* Device parameter to enable RX completion queue compression. */
#define MLX5_RXQ_CQE_COMP_EN "rxq_cqe_comp_en"
/* Device parameter to enable padding Rx packet to cacheline size. */
#define MLX5_RXQ_PKT_PAD_EN "rxq_pkt_pad_en"
/* Device parameter to enable Multi-Packet Rx queue. */
#define MLX5_RX_MPRQ_EN "mprq_en"
/* Device parameter to configure log 2 of the number of strides for MPRQ. */
#define MLX5_RX_MPRQ_LOG_STRIDE_NUM "mprq_log_stride_num"
/* Device parameter to configure log 2 of the stride size for MPRQ. */
#define MLX5_RX_MPRQ_LOG_STRIDE_SIZE "mprq_log_stride_size"
/* Device parameter to limit the size of memcpy'd packet for MPRQ. */
#define MLX5_RX_MPRQ_MAX_MEMCPY_LEN "mprq_max_memcpy_len"
/* Device parameter to set the minimum number of Rx queues to enable MPRQ. */
#define MLX5_RXQS_MIN_MPRQ "rxqs_min_mprq"
/* Device parameter to configure inline send. Deprecated, ignored.*/
#define MLX5_TXQ_INLINE "txq_inline"
/* Device parameter to limit packet size to inline with ordinary SEND. */
#define MLX5_TXQ_INLINE_MAX "txq_inline_max"
/* Device parameter to configure minimal data size to inline. */
#define MLX5_TXQ_INLINE_MIN "txq_inline_min"
/* Device parameter to limit packet size to inline with Enhanced MPW. */
#define MLX5_TXQ_INLINE_MPW "txq_inline_mpw"
/*
* Device parameter to configure the number of TX queues threshold for
* enabling inline send.
*/
#define MLX5_TXQS_MIN_INLINE "txqs_min_inline"
/*
* Device parameter to configure the number of TX queues threshold for
* enabling vectorized Tx, deprecated, ignored (no vectorized Tx routines).
*/
#define MLX5_TXQS_MAX_VEC "txqs_max_vec"
/* Device parameter to enable multi-packet send WQEs. */
#define MLX5_TXQ_MPW_EN "txq_mpw_en"
/*
* Device parameter to include 2 dsegs in the title WQEBB.
* Deprecated, ignored.
*/
#define MLX5_TXQ_MPW_HDR_DSEG_EN "txq_mpw_hdr_dseg_en"
/*
* Device parameter to limit the size of inlining packet.
* Deprecated, ignored.
*/
#define MLX5_TXQ_MAX_INLINE_LEN "txq_max_inline_len"
/*
* Device parameter to enable Tx scheduling on timestamps
* and specify the packet pacing granularity in nanoseconds.
*/
#define MLX5_TX_PP "tx_pp"
/*
* Device parameter to specify skew in nanoseconds on Tx datapath,
* it represents the time between SQ start WQE processing and
* appearing actual packet data on the wire.
*/
#define MLX5_TX_SKEW "tx_skew"
/*
* Device parameter to enable hardware Tx vector.
* Deprecated, ignored (no vectorized Tx routines anymore).
*/
#define MLX5_TX_VEC_EN "tx_vec_en"
/* Device parameter to enable hardware Rx vector. */
#define MLX5_RX_VEC_EN "rx_vec_en"
/* Allow L3 VXLAN flow creation. */
#define MLX5_L3_VXLAN_EN "l3_vxlan_en"
/* Activate DV E-Switch flow steering. */
#define MLX5_DV_ESW_EN "dv_esw_en"
/* Activate DV flow steering. */
#define MLX5_DV_FLOW_EN "dv_flow_en"
net/mlx5: add devarg for extensive metadata support The PMD parameter dv_xmeta_en is added to control extensive metadata support. A nonzero value enables extensive flow metadata support if device is capable and driver supports it. This can enable extensive support of MARK and META item of rte_flow. The newly introduced SET_TAG and SET_META actions do not depend on dv_xmeta_en parameter, because there is no compatibility issue for new entities. The dv_xmeta_en is disabled by default. There are some possible configurations, depending on parameter value: - 0, this is default value, defines the legacy mode, the MARK and META related actions and items operate only within NIC Tx and NIC Rx steering domains, no MARK and META information crosses the domain boundaries. The MARK item is 24 bits wide, the META item is 32 bits wide. - 1, this engages extensive metadata mode, the MARK and META related actions and items operate within all supported steering domains, including FDB, MARK and META information may cross the domain boundaries. The ``MARK`` item is 24 bits wide, the META item width depends on kernel and firmware configurations and might be 0, 16 or 32 bits. Within NIC Tx domain META data width is 32 bits for compatibility, the actual width of data transferred to the FDB domain depends on kernel configuration and may be vary. The actual supported width can be retrieved in runtime by series of rte_flow_validate() trials. - 2, this engages extensive metadata mode, the MARK and META related actions and items operate within all supported steering domains, including FDB, MARK and META information may cross the domain boundaries. The META item is 32 bits wide, the MARK item width depends on kernel and firmware configurations and might be 0, 16 or 24 bits. The actual supported width can be retrieved in runtime by series of rte_flow_validate() trials. If there is no E-Switch configuration the ``dv_xmeta_en`` parameter is ignored and the device is configured to operate in legacy mode (0). Signed-off-by: Yongseok Koh <yskoh@mellanox.com> Signed-off-by: Viacheslav Ovsiienko <viacheslavo@mellanox.com> Acked-by: Matan Azrad <matan@mellanox.com>
2019-11-07 17:09:54 +00:00
/* Enable extensive flow metadata support. */
#define MLX5_DV_XMETA_EN "dv_xmeta_en"
/* Device parameter to let the user manage the lacp traffic of bonded device */
#define MLX5_LACP_BY_USER "lacp_by_user"
/* Activate Netlink support in VF mode. */
#define MLX5_VF_NL_EN "vf_nl_en"
/* Select port representors to instantiate. */
#define MLX5_REPRESENTOR "representor"
/* Device parameter to configure the maximum number of dump files per queue. */
#define MLX5_MAX_DUMP_FILES_NUM "max_dump_files_num"
/* Configure timeout of LRO session (in microseconds). */
#define MLX5_LRO_TIMEOUT_USEC "lro_timeout_usec"
/*
* Device parameter to configure the total data buffer size for a single
* hairpin queue (logarithm value).
*/
#define MLX5_HP_BUF_SIZE "hp_buf_log_sz"
net/mlx5: add reclaim memory mode Currently, when flow destroyed, some memory resources may still be kept as cached to help next time create flow more efficiently. Some system may need the resources to be more flexible with flow create and destroy. After peak time, with millions of flows destroyed, the system would prefer the resources to be reclaimed completely, no cache is needed. Then the resources can be allocated and used by other components. The system is not so sensitive about the flow insertion rate, but more care about the resources. Both DPDK mlx5 PMD driver and the low level component rdma-core have provided the flow resources to be configured cached or not, but there is no APIs or parameters exposed to user to configure the flow resources cache mode. In this case, introduce a new PMD devarg to let user configure the flow resources cache mode will be helpful. This commit is to add a new "reclaim_mem_mode" to help user configure if the destroyed flows' cache resources should be kept or not. Their will be three mode can be chosen: 1. 0(none). It means the flow resources will be cached as usual. The resources will be cached, helpful with flow insertion rate. 2. 1(light). It will only enable the DPDK PMD level resources reclaim. 3. 2(aggressive). Both DPDK PMD level and rdma-core low level will be configured as reclaimed mode. With these three mode, user can configure the resources cache mode with different levels. Signed-off-by: Suanming Mou <suanmingm@mellanox.com> Acked-by: Viacheslav Ovsiienko <viacheslavo@mellanox.com>
2020-06-01 06:09:43 +00:00
/* Flow memory reclaim mode. */
#define MLX5_RECLAIM_MEM "reclaim_mem_mode"
/* Decap will be used or not. */
#define MLX5_DECAP_EN "decap_en"
net/mlx5: add option to allocate memory from system Currently, for MLX5 PMD, once millions of flows created, the memory consumption of the flows are also very huge. For the system with limited memory, it means the system need to reserve most of the memory as huge page memory to serve the flows in advance. And other normal applications will have no chance to use this reserved memory any more. While most of the time, the system will not have lots of flows, the reserved huge page memory becomes a bit waste of memory at most of the time. By the new sys_mem_en devarg, once set it to be true, it allows the PMD allocate the memory from system by default with the new add mlx5 memory management functions. Only once the MLX5_MEM_RTE flag is set, the memory will be allocate from rte, otherwise, it allocates memory from system. So in this case, the system with limited memory no need to reserve most of the memory for hugepage. Only some needed memory for datapath objects will be enough to allocated with explicitly flag. Other memory will be allocated from system. For system with enough memory, no need to care about the devarg, the memory will always be from rte hugepage. One restriction is that for DPDK application with multiple PCI devices, if the sys_mem_en devargs are different between the devices, the sys_mem_en only gets the value from the first device devargs, and print out a message to warn that. Signed-off-by: Suanming Mou <suanmingm@mellanox.com> Acked-by: Matan Azrad <matan@mellanox.com>
2020-06-28 03:41:57 +00:00
/* Device parameter to configure allow or prevent duplicate rules pattern. */
#define MLX5_ALLOW_DUPLICATE_PATTERN "allow_duplicate_pattern"
/* Device parameter to configure the delay drop when creating Rxqs. */
#define MLX5_DELAY_DROP "delay_drop"
/* Device parameter to create the fdb default rule in PMD */
#define MLX5_FDB_DEFAULT_RULE_EN "fdb_def_rule_en"
net/mlx5: add new memory region support This is the new design of Memory Region (MR) for mlx PMD, in order to: - Accommodate the new memory hotplug model. - Support non-contiguous Mempool. There are multiple layers for MR search. L0 is to look up the last-hit entry which is pointed by mr_ctrl->mru (Most Recently Used). If L0 misses, L1 is to look up the address in a fixed-sized array by linear search. L0/L1 is in an inline function - mlx5_mr_lookup_cache(). If L1 misses, the bottom-half function is called to look up the address from the bigger local cache of the queue. This is L2 - mlx5_mr_addr2mr_bh() and it is not an inline function. Data structure for L2 is the Binary Tree. If L2 misses, the search falls into the slowest path which takes locks in order to access global device cache (priv->mr.cache) which is also a B-tree and caches the original MR list (priv->mr.mr_list) of the device. Unless the global cache is overflowed, it is all-inclusive of the MR list. This is L3 - mlx5_mr_lookup_dev(). The size of the L3 cache table is limited and can't be expanded on the fly due to deadlock. Refer to the comments in the code for the details - mr_lookup_dev(). If L3 is overflowed, the list will have to be searched directly bypassing the cache although it is slower. If L3 misses, a new MR for the address should be created - mlx5_mr_create(). When it creates a new MR, it tries to register adjacent memsegs as much as possible which are virtually contiguous around the address. This must take two locks - memory_hotplug_lock and priv->mr.rwlock. Due to memory_hotplug_lock, there can't be any allocation/free of memory inside. In the free callback of the memory hotplug event, freed space is searched from the MR list and corresponding bits are cleared from the bitmap of MRs. This can fragment a MR and the MR will have multiple search entries in the caches. Once there's a change by the event, the global cache must be rebuilt and all the per-queue caches will be flushed as well. If memory is frequently freed in run-time, that may cause jitter on dataplane processing in the worst case by incurring MR cache flush and rebuild. But, it would be the least probable scenario. To guarantee the most optimal performance, it is highly recommended to use an EAL option - '--socket-mem'. Then, the reserved memory will be pinned and won't be freed dynamically. And it is also recommended to configure per-lcore cache of Mempool. Even though there're many MRs for a device or MRs are highly fragmented, the cache of Mempool will be much helpful to reduce misses on per-queue caches anyway. '--legacy-mem' is also supported. Signed-off-by: Yongseok Koh <yskoh@mellanox.com>
2018-05-09 11:09:04 +00:00
/* Shared memory between primary and secondary processes. */
struct mlx5_shared_data *mlx5_shared_data;
/** Driver-specific log messages type. */
int mlx5_logtype;
static LIST_HEAD(, mlx5_dev_ctx_shared) mlx5_dev_ctx_list =
LIST_HEAD_INITIALIZER();
static pthread_mutex_t mlx5_dev_ctx_list_mutex;
static const struct mlx5_indexed_pool_config mlx5_ipool_cfg[] = {
#if defined(HAVE_IBV_FLOW_DV_SUPPORT) || !defined(HAVE_INFINIBAND_VERBS_H)
[MLX5_IPOOL_DECAP_ENCAP] = {
.size = sizeof(struct mlx5_flow_dv_encap_decap_resource),
.trunk_size = 64,
.grow_trunk = 3,
.grow_shift = 2,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_encap_decap_ipool",
},
[MLX5_IPOOL_PUSH_VLAN] = {
.size = sizeof(struct mlx5_flow_dv_push_vlan_action_resource),
.trunk_size = 64,
.grow_trunk = 3,
.grow_shift = 2,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_push_vlan_ipool",
},
[MLX5_IPOOL_TAG] = {
.size = sizeof(struct mlx5_flow_dv_tag_resource),
.trunk_size = 64,
.grow_trunk = 3,
.grow_shift = 2,
.need_lock = 1,
.release_mem_en = 0,
.per_core_cache = (1 << 16),
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_tag_ipool",
},
[MLX5_IPOOL_PORT_ID] = {
.size = sizeof(struct mlx5_flow_dv_port_id_action_resource),
.trunk_size = 64,
.grow_trunk = 3,
.grow_shift = 2,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_port_id_ipool",
},
[MLX5_IPOOL_JUMP] = {
.size = sizeof(struct mlx5_flow_tbl_data_entry),
.trunk_size = 64,
.grow_trunk = 3,
.grow_shift = 2,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_jump_ipool",
},
[MLX5_IPOOL_SAMPLE] = {
.size = sizeof(struct mlx5_flow_dv_sample_resource),
.trunk_size = 64,
.grow_trunk = 3,
.grow_shift = 2,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_sample_ipool",
},
[MLX5_IPOOL_DEST_ARRAY] = {
.size = sizeof(struct mlx5_flow_dv_dest_array_resource),
.trunk_size = 64,
.grow_trunk = 3,
.grow_shift = 2,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_dest_array_ipool",
},
[MLX5_IPOOL_TUNNEL_ID] = {
.size = sizeof(struct mlx5_flow_tunnel),
.trunk_size = MLX5_MAX_TUNNELS,
.need_lock = 1,
.release_mem_en = 1,
.type = "mlx5_tunnel_offload",
},
[MLX5_IPOOL_TNL_TBL_ID] = {
.size = 0,
.need_lock = 1,
.type = "mlx5_flow_tnl_tbl_ipool",
},
#endif
[MLX5_IPOOL_MTR] = {
/**
* The ipool index should grow continually from small to big,
* for meter idx, so not set grow_trunk to avoid meter index
* not jump continually.
*/
.size = sizeof(struct mlx5_legacy_flow_meter),
.trunk_size = 64,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_meter_ipool",
},
[MLX5_IPOOL_MCP] = {
.size = sizeof(struct mlx5_flow_mreg_copy_resource),
.trunk_size = 64,
.grow_trunk = 3,
.grow_shift = 2,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_mcp_ipool",
},
[MLX5_IPOOL_HRXQ] = {
.size = (sizeof(struct mlx5_hrxq) + MLX5_RSS_HASH_KEY_LEN),
.trunk_size = 64,
.grow_trunk = 3,
.grow_shift = 2,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_hrxq_ipool",
},
[MLX5_IPOOL_MLX5_FLOW] = {
/*
* MLX5_IPOOL_MLX5_FLOW size varies for DV and VERBS flows.
* It set in run time according to PCI function configuration.
*/
.size = 0,
.trunk_size = 64,
.grow_trunk = 3,
.grow_shift = 2,
.need_lock = 1,
.release_mem_en = 0,
.per_core_cache = 1 << 19,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_flow_handle_ipool",
},
[MLX5_IPOOL_RTE_FLOW] = {
.size = sizeof(struct rte_flow),
.trunk_size = 4096,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "rte_flow_ipool",
},
[MLX5_IPOOL_RSS_EXPANTION_FLOW_ID] = {
.size = 0,
.need_lock = 1,
.type = "mlx5_flow_rss_id_ipool",
},
[MLX5_IPOOL_RSS_SHARED_ACTIONS] = {
.size = sizeof(struct mlx5_shared_action_rss),
.trunk_size = 64,
.grow_trunk = 3,
.grow_shift = 2,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_shared_action_rss",
},
[MLX5_IPOOL_MTR_POLICY] = {
/**
* The ipool index should grow continually from small to big,
* for policy idx, so not set grow_trunk to avoid policy index
* not jump continually.
*/
.size = sizeof(struct mlx5_flow_meter_sub_policy),
.trunk_size = 64,
.need_lock = 1,
.release_mem_en = 1,
.malloc = mlx5_malloc,
.free = mlx5_free,
.type = "mlx5_meter_policy_ipool",
},
};
#define MLX5_FLOW_MIN_ID_POOL_SIZE 512
#define MLX5_ID_GENERATION_ARRAY_FACTOR 16
#define MLX5_FLOW_TABLE_HLIST_ARRAY_SIZE 1024
/**
* Decide whether representor ID is a HPF(host PF) port on BF2.
*
* @param dev
* Pointer to Ethernet device structure.
*
* @return
* Non-zero if HPF, otherwise 0.
*/
bool
mlx5_is_hpf(struct rte_eth_dev *dev)
{
struct mlx5_priv *priv = dev->data->dev_private;
uint16_t repr = MLX5_REPRESENTOR_REPR(priv->representor_id);
int type = MLX5_REPRESENTOR_TYPE(priv->representor_id);
return priv->representor != 0 && type == RTE_ETH_REPRESENTOR_VF &&
MLX5_REPRESENTOR_REPR(-1) == repr;
}
/**
* Decide whether representor ID is a SF port representor.
*
* @param dev
* Pointer to Ethernet device structure.
*
* @return
* Non-zero if HPF, otherwise 0.
*/
bool
mlx5_is_sf_repr(struct rte_eth_dev *dev)
{
struct mlx5_priv *priv = dev->data->dev_private;
int type = MLX5_REPRESENTOR_TYPE(priv->representor_id);
return priv->representor != 0 && type == RTE_ETH_REPRESENTOR_SF;
}
/**
* Initialize the ASO aging management structure.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object to free
*
* @return
* 0 on success, a negative errno value otherwise and rte_errno is set.
*/
int
mlx5_flow_aso_age_mng_init(struct mlx5_dev_ctx_shared *sh)
{
int err;
if (sh->aso_age_mng)
return 0;
sh->aso_age_mng = mlx5_malloc(MLX5_MEM_ZERO, sizeof(*sh->aso_age_mng),
RTE_CACHE_LINE_SIZE, SOCKET_ID_ANY);
if (!sh->aso_age_mng) {
DRV_LOG(ERR, "aso_age_mng allocation was failed.");
rte_errno = ENOMEM;
return -ENOMEM;
}
err = mlx5_aso_queue_init(sh, ASO_OPC_MOD_FLOW_HIT);
if (err) {
mlx5_free(sh->aso_age_mng);
return -1;
}
rte_rwlock_init(&sh->aso_age_mng->resize_rwl);
rte_spinlock_init(&sh->aso_age_mng->free_sl);
LIST_INIT(&sh->aso_age_mng->free);
return 0;
}
/**
* Close and release all the resources of the ASO aging management structure.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object to free.
*/
static void
mlx5_flow_aso_age_mng_close(struct mlx5_dev_ctx_shared *sh)
{
int i, j;
mlx5_aso_flow_hit_queue_poll_stop(sh);
mlx5_aso_queue_uninit(sh, ASO_OPC_MOD_FLOW_HIT);
if (sh->aso_age_mng->pools) {
struct mlx5_aso_age_pool *pool;
for (i = 0; i < sh->aso_age_mng->next; ++i) {
pool = sh->aso_age_mng->pools[i];
claim_zero(mlx5_devx_cmd_destroy
(pool->flow_hit_aso_obj));
for (j = 0; j < MLX5_COUNTERS_PER_POOL; ++j)
if (pool->actions[j].dr_action)
claim_zero
(mlx5_flow_os_destroy_flow_action
(pool->actions[j].dr_action));
mlx5_free(pool);
}
mlx5_free(sh->aso_age_mng->pools);
}
mlx5_free(sh->aso_age_mng);
}
/**
* Initialize the shared aging list information per port.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object.
*/
static void
mlx5_flow_aging_init(struct mlx5_dev_ctx_shared *sh)
{
uint32_t i;
struct mlx5_age_info *age_info;
for (i = 0; i < sh->max_port; i++) {
age_info = &sh->port[i].age_info;
age_info->flags = 0;
TAILQ_INIT(&age_info->aged_counters);
LIST_INIT(&age_info->aged_aso);
rte_spinlock_init(&age_info->aged_sl);
MLX5_AGE_SET(age_info, MLX5_AGE_TRIGGER);
}
}
/**
* DV flow counter mode detect and config.
*
* @param dev
* Pointer to rte_eth_dev structure.
*
*/
void
mlx5_flow_counter_mode_config(struct rte_eth_dev *dev __rte_unused)
{
#ifdef HAVE_IBV_FLOW_DV_SUPPORT
struct mlx5_priv *priv = dev->data->dev_private;
struct mlx5_dev_ctx_shared *sh = priv->sh;
struct mlx5_hca_attr *hca_attr = &sh->cdev->config.hca_attr;
bool fallback;
#ifndef HAVE_IBV_DEVX_ASYNC
fallback = true;
#else
fallback = false;
if (!sh->cdev->config.devx || !sh->config.dv_flow_en ||
!hca_attr->flow_counters_dump ||
!(hca_attr->flow_counter_bulk_alloc_bitmap & 0x4) ||
(mlx5_flow_dv_discover_counter_offset_support(dev) == -ENOTSUP))
fallback = true;
#endif
if (fallback)
DRV_LOG(INFO, "Use fall-back DV counter management. Flow "
"counter dump:%d, bulk_alloc_bitmap:0x%hhx.",
hca_attr->flow_counters_dump,
hca_attr->flow_counter_bulk_alloc_bitmap);
/* Initialize fallback mode only on the port initializes sh. */
if (sh->refcnt == 1)
sh->cmng.counter_fallback = fallback;
else if (fallback != sh->cmng.counter_fallback)
DRV_LOG(WARNING, "Port %d in sh has different fallback mode "
"with others:%d.", PORT_ID(priv), fallback);
#endif
}
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
/**
* Initialize the counters management structure.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object to free
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
*/
static void
mlx5_flow_counters_mng_init(struct mlx5_dev_ctx_shared *sh)
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
{
int i;
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
memset(&sh->cmng, 0, sizeof(sh->cmng));
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
TAILQ_INIT(&sh->cmng.flow_counters);
sh->cmng.min_id = MLX5_CNT_BATCH_OFFSET;
sh->cmng.max_id = -1;
sh->cmng.last_pool_idx = POOL_IDX_INVALID;
rte_spinlock_init(&sh->cmng.pool_update_sl);
for (i = 0; i < MLX5_COUNTER_TYPE_MAX; i++) {
TAILQ_INIT(&sh->cmng.counters[i]);
rte_spinlock_init(&sh->cmng.csl[i]);
}
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
}
/**
* Destroy all the resources allocated for a counter memory management.
*
* @param[in] mng
* Pointer to the memory management structure.
*/
static void
mlx5_flow_destroy_counter_stat_mem_mng(struct mlx5_counter_stats_mem_mng *mng)
{
uint8_t *mem = (uint8_t *)(uintptr_t)mng->raws[0].data;
LIST_REMOVE(mng, next);
mlx5_os_wrapped_mkey_destroy(&mng->wm);
mlx5_free(mem);
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
}
/**
* Close and release all the resources of the counters management.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object to free.
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
*/
static void
mlx5_flow_counters_mng_close(struct mlx5_dev_ctx_shared *sh)
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
{
struct mlx5_counter_stats_mem_mng *mng;
int i, j;
int retries = 1024;
rte_errno = 0;
while (--retries) {
rte_eal_alarm_cancel(mlx5_flow_query_alarm, sh);
if (rte_errno != EINPROGRESS)
break;
rte_pause();
}
if (sh->cmng.pools) {
struct mlx5_flow_counter_pool *pool;
uint16_t n_valid = sh->cmng.n_valid;
bool fallback = sh->cmng.counter_fallback;
for (i = 0; i < n_valid; ++i) {
pool = sh->cmng.pools[i];
if (!fallback && pool->min_dcs)
claim_zero(mlx5_devx_cmd_destroy
(pool->min_dcs));
for (j = 0; j < MLX5_COUNTERS_PER_POOL; ++j) {
struct mlx5_flow_counter *cnt =
MLX5_POOL_GET_CNT(pool, j);
if (cnt->action)
claim_zero
(mlx5_flow_os_destroy_flow_action
(cnt->action));
if (fallback && MLX5_POOL_GET_CNT
(pool, j)->dcs_when_free)
claim_zero(mlx5_devx_cmd_destroy
(cnt->dcs_when_free));
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
}
mlx5_free(pool);
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
}
mlx5_free(sh->cmng.pools);
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
}
mng = LIST_FIRST(&sh->cmng.mem_mngs);
while (mng) {
mlx5_flow_destroy_counter_stat_mem_mng(mng);
mng = LIST_FIRST(&sh->cmng.mem_mngs);
}
memset(&sh->cmng, 0, sizeof(sh->cmng));
}
/**
* Initialize the aso flow meters management structure.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object to free
*/
int
mlx5_aso_flow_mtrs_mng_init(struct mlx5_dev_ctx_shared *sh)
{
if (!sh->mtrmng) {
sh->mtrmng = mlx5_malloc(MLX5_MEM_ZERO,
sizeof(*sh->mtrmng),
RTE_CACHE_LINE_SIZE, SOCKET_ID_ANY);
if (!sh->mtrmng) {
DRV_LOG(ERR,
"meter management allocation was failed.");
rte_errno = ENOMEM;
return -ENOMEM;
}
if (sh->meter_aso_en) {
rte_spinlock_init(&sh->mtrmng->pools_mng.mtrsl);
rte_rwlock_init(&sh->mtrmng->pools_mng.resize_mtrwl);
LIST_INIT(&sh->mtrmng->pools_mng.meters);
}
sh->mtrmng->def_policy_id = MLX5_INVALID_POLICY_ID;
}
return 0;
}
/**
* Close and release all the resources of
* the ASO flow meter management structure.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object to free.
*/
static void
mlx5_aso_flow_mtrs_mng_close(struct mlx5_dev_ctx_shared *sh)
{
struct mlx5_aso_mtr_pool *mtr_pool;
struct mlx5_flow_mtr_mng *mtrmng = sh->mtrmng;
uint32_t idx;
#ifdef HAVE_MLX5_DR_CREATE_ACTION_ASO
struct mlx5_aso_mtr *aso_mtr;
int i;
#endif /* HAVE_MLX5_DR_CREATE_ACTION_ASO */
if (sh->meter_aso_en) {
mlx5_aso_queue_uninit(sh, ASO_OPC_MOD_POLICER);
idx = mtrmng->pools_mng.n_valid;
while (idx--) {
mtr_pool = mtrmng->pools_mng.pools[idx];
#ifdef HAVE_MLX5_DR_CREATE_ACTION_ASO
for (i = 0; i < MLX5_ASO_MTRS_PER_POOL; i++) {
aso_mtr = &mtr_pool->mtrs[i];
if (aso_mtr->fm.meter_action_g)
claim_zero
(mlx5_glue->destroy_flow_action
(aso_mtr->fm.meter_action_g));
if (aso_mtr->fm.meter_action_y)
claim_zero
(mlx5_glue->destroy_flow_action
(aso_mtr->fm.meter_action_y));
}
#endif /* HAVE_MLX5_DR_CREATE_ACTION_ASO */
claim_zero(mlx5_devx_cmd_destroy
(mtr_pool->devx_obj));
mtrmng->pools_mng.n_valid--;
mlx5_free(mtr_pool);
}
mlx5_free(sh->mtrmng->pools_mng.pools);
}
mlx5_free(sh->mtrmng);
sh->mtrmng = NULL;
}
/* Send FLOW_AGED event if needed. */
void
mlx5_age_event_prepare(struct mlx5_dev_ctx_shared *sh)
{
struct mlx5_age_info *age_info;
uint32_t i;
for (i = 0; i < sh->max_port; i++) {
age_info = &sh->port[i].age_info;
if (!MLX5_AGE_GET(age_info, MLX5_AGE_EVENT_NEW))
continue;
MLX5_AGE_UNSET(age_info, MLX5_AGE_EVENT_NEW);
if (MLX5_AGE_GET(age_info, MLX5_AGE_TRIGGER)) {
MLX5_AGE_UNSET(age_info, MLX5_AGE_TRIGGER);
rte_eth_dev_callback_process
(&rte_eth_devices[sh->port[i].devx_ih_port_id],
RTE_ETH_EVENT_FLOW_AGED, NULL);
}
}
}
/*
* Initialize the ASO connection tracking structure.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object.
*
* @return
* 0 on success, a negative errno value otherwise and rte_errno is set.
*/
int
mlx5_flow_aso_ct_mng_init(struct mlx5_dev_ctx_shared *sh)
{
int err;
if (sh->ct_mng)
return 0;
sh->ct_mng = mlx5_malloc(MLX5_MEM_ZERO, sizeof(*sh->ct_mng),
RTE_CACHE_LINE_SIZE, SOCKET_ID_ANY);
if (!sh->ct_mng) {
DRV_LOG(ERR, "ASO CT management allocation failed.");
rte_errno = ENOMEM;
return -rte_errno;
}
err = mlx5_aso_queue_init(sh, ASO_OPC_MOD_CONNECTION_TRACKING);
if (err) {
mlx5_free(sh->ct_mng);
/* rte_errno should be extracted from the failure. */
rte_errno = EINVAL;
return -rte_errno;
}
rte_spinlock_init(&sh->ct_mng->ct_sl);
rte_rwlock_init(&sh->ct_mng->resize_rwl);
LIST_INIT(&sh->ct_mng->free_cts);
return 0;
}
/*
* Close and release all the resources of the
* ASO connection tracking management structure.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object to free.
*/
static void
mlx5_flow_aso_ct_mng_close(struct mlx5_dev_ctx_shared *sh)
{
struct mlx5_aso_ct_pools_mng *mng = sh->ct_mng;
struct mlx5_aso_ct_pool *ct_pool;
struct mlx5_aso_ct_action *ct;
uint32_t idx;
uint32_t val;
uint32_t cnt;
int i;
mlx5_aso_queue_uninit(sh, ASO_OPC_MOD_CONNECTION_TRACKING);
idx = mng->next;
while (idx--) {
cnt = 0;
ct_pool = mng->pools[idx];
for (i = 0; i < MLX5_ASO_CT_ACTIONS_PER_POOL; i++) {
ct = &ct_pool->actions[i];
val = __atomic_fetch_sub(&ct->refcnt, 1,
__ATOMIC_RELAXED);
MLX5_ASSERT(val == 1);
if (val > 1)
cnt++;
#ifdef HAVE_MLX5_DR_ACTION_ASO_CT
if (ct->dr_action_orig)
claim_zero(mlx5_glue->destroy_flow_action
(ct->dr_action_orig));
if (ct->dr_action_rply)
claim_zero(mlx5_glue->destroy_flow_action
(ct->dr_action_rply));
#endif
}
claim_zero(mlx5_devx_cmd_destroy(ct_pool->devx_obj));
if (cnt) {
DRV_LOG(DEBUG, "%u ASO CT objects are being used in the pool %u",
cnt, i);
}
mlx5_free(ct_pool);
/* in case of failure. */
mng->next--;
}
mlx5_free(mng->pools);
mlx5_free(mng);
/* Management structure must be cleared to 0s during allocation. */
sh->ct_mng = NULL;
}
/**
* Initialize the flow resources' indexed mempool.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object.
*/
static void
mlx5_flow_ipool_create(struct mlx5_dev_ctx_shared *sh)
{
uint8_t i;
struct mlx5_indexed_pool_config cfg;
net/mlx5: add reclaim memory mode Currently, when flow destroyed, some memory resources may still be kept as cached to help next time create flow more efficiently. Some system may need the resources to be more flexible with flow create and destroy. After peak time, with millions of flows destroyed, the system would prefer the resources to be reclaimed completely, no cache is needed. Then the resources can be allocated and used by other components. The system is not so sensitive about the flow insertion rate, but more care about the resources. Both DPDK mlx5 PMD driver and the low level component rdma-core have provided the flow resources to be configured cached or not, but there is no APIs or parameters exposed to user to configure the flow resources cache mode. In this case, introduce a new PMD devarg to let user configure the flow resources cache mode will be helpful. This commit is to add a new "reclaim_mem_mode" to help user configure if the destroyed flows' cache resources should be kept or not. Their will be three mode can be chosen: 1. 0(none). It means the flow resources will be cached as usual. The resources will be cached, helpful with flow insertion rate. 2. 1(light). It will only enable the DPDK PMD level resources reclaim. 3. 2(aggressive). Both DPDK PMD level and rdma-core low level will be configured as reclaimed mode. With these three mode, user can configure the resources cache mode with different levels. Signed-off-by: Suanming Mou <suanmingm@mellanox.com> Acked-by: Viacheslav Ovsiienko <viacheslavo@mellanox.com>
2020-06-01 06:09:43 +00:00
for (i = 0; i < MLX5_IPOOL_MAX; ++i) {
cfg = mlx5_ipool_cfg[i];
switch (i) {
default:
break;
/*
* Set MLX5_IPOOL_MLX5_FLOW ipool size
* according to PCI function flow configuration.
*/
case MLX5_IPOOL_MLX5_FLOW:
cfg.size = sh->config.dv_flow_en ?
sizeof(struct mlx5_flow_handle) :
MLX5_FLOW_HANDLE_VERBS_SIZE;
break;
}
if (sh->config.reclaim_mode) {
cfg.release_mem_en = 1;
cfg.per_core_cache = 0;
} else {
cfg.release_mem_en = 0;
}
sh->ipool[i] = mlx5_ipool_create(&cfg);
net/mlx5: add reclaim memory mode Currently, when flow destroyed, some memory resources may still be kept as cached to help next time create flow more efficiently. Some system may need the resources to be more flexible with flow create and destroy. After peak time, with millions of flows destroyed, the system would prefer the resources to be reclaimed completely, no cache is needed. Then the resources can be allocated and used by other components. The system is not so sensitive about the flow insertion rate, but more care about the resources. Both DPDK mlx5 PMD driver and the low level component rdma-core have provided the flow resources to be configured cached or not, but there is no APIs or parameters exposed to user to configure the flow resources cache mode. In this case, introduce a new PMD devarg to let user configure the flow resources cache mode will be helpful. This commit is to add a new "reclaim_mem_mode" to help user configure if the destroyed flows' cache resources should be kept or not. Their will be three mode can be chosen: 1. 0(none). It means the flow resources will be cached as usual. The resources will be cached, helpful with flow insertion rate. 2. 1(light). It will only enable the DPDK PMD level resources reclaim. 3. 2(aggressive). Both DPDK PMD level and rdma-core low level will be configured as reclaimed mode. With these three mode, user can configure the resources cache mode with different levels. Signed-off-by: Suanming Mou <suanmingm@mellanox.com> Acked-by: Viacheslav Ovsiienko <viacheslavo@mellanox.com>
2020-06-01 06:09:43 +00:00
}
}
/**
* Release the flow resources' indexed mempool.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object.
*/
static void
mlx5_flow_ipool_destroy(struct mlx5_dev_ctx_shared *sh)
{
uint8_t i;
for (i = 0; i < MLX5_IPOOL_MAX; ++i)
mlx5_ipool_destroy(sh->ipool[i]);
for (i = 0; i < MLX5_MAX_MODIFY_NUM; ++i)
if (sh->mdh_ipools[i])
mlx5_ipool_destroy(sh->mdh_ipools[i]);
}
/*
* Check if dynamic flex parser for eCPRI already exists.
*
* @param dev
* Pointer to Ethernet device structure.
*
* @return
* true on exists, false on not.
*/
bool
mlx5_flex_parser_ecpri_exist(struct rte_eth_dev *dev)
{
struct mlx5_priv *priv = dev->data->dev_private;
struct mlx5_ecpri_parser_profile *prf = &priv->sh->ecpri_parser;
return !!prf->obj;
}
/*
* Allocation of a flex parser for eCPRI. Once created, this parser related
* resources will be held until the device is closed.
*
* @param dev
* Pointer to Ethernet device structure.
*
* @return
* 0 on success, a negative errno value otherwise and rte_errno is set.
*/
int
mlx5_flex_parser_ecpri_alloc(struct rte_eth_dev *dev)
{
struct mlx5_priv *priv = dev->data->dev_private;
struct mlx5_ecpri_parser_profile *prf = &priv->sh->ecpri_parser;
struct mlx5_devx_graph_node_attr node = {
.modify_field_select = 0,
};
uint32_t ids[8];
int ret;
if (!priv->sh->cdev->config.hca_attr.parse_graph_flex_node) {
DRV_LOG(ERR, "Dynamic flex parser is not supported "
"for device %s.", priv->dev_data->name);
return -ENOTSUP;
}
node.header_length_mode = MLX5_GRAPH_NODE_LEN_FIXED;
/* 8 bytes now: 4B common header + 4B message body header. */
node.header_length_base_value = 0x8;
/* After MAC layer: Ether / VLAN. */
node.in[0].arc_parse_graph_node = MLX5_GRAPH_ARC_NODE_MAC;
/* Type of compared condition should be 0xAEFE in the L2 layer. */
node.in[0].compare_condition_value = RTE_ETHER_TYPE_ECPRI;
/* Sample #0: type in common header. */
node.sample[0].flow_match_sample_en = 1;
/* Fixed offset. */
node.sample[0].flow_match_sample_offset_mode = 0x0;
/* Only the 2nd byte will be used. */
node.sample[0].flow_match_sample_field_base_offset = 0x0;
/* Sample #1: message payload. */
node.sample[1].flow_match_sample_en = 1;
/* Fixed offset. */
node.sample[1].flow_match_sample_offset_mode = 0x0;
/*
* Only the first two bytes will be used right now, and its offset will
* start after the common header that with the length of a DW(u32).
*/
node.sample[1].flow_match_sample_field_base_offset = sizeof(uint32_t);
prf->obj = mlx5_devx_cmd_create_flex_parser(priv->sh->cdev->ctx, &node);
if (!prf->obj) {
DRV_LOG(ERR, "Failed to create flex parser node object.");
return (rte_errno == 0) ? -ENODEV : -rte_errno;
}
prf->num = 2;
ret = mlx5_devx_cmd_query_parse_samples(prf->obj, ids, prf->num);
if (ret) {
DRV_LOG(ERR, "Failed to query sample IDs.");
return (rte_errno == 0) ? -ENODEV : -rte_errno;
}
prf->offset[0] = 0x0;
prf->offset[1] = sizeof(uint32_t);
prf->ids[0] = ids[0];
prf->ids[1] = ids[1];
return 0;
}
/*
* Destroy the flex parser node, including the parser itself, input / output
* arcs and DW samples. Resources could be reused then.
*
* @param dev
* Pointer to Ethernet device structure.
*/
static void
mlx5_flex_parser_ecpri_release(struct rte_eth_dev *dev)
{
struct mlx5_priv *priv = dev->data->dev_private;
struct mlx5_ecpri_parser_profile *prf = &priv->sh->ecpri_parser;
if (prf->obj)
mlx5_devx_cmd_destroy(prf->obj);
prf->obj = NULL;
}
uint32_t
mlx5_get_supported_sw_parsing_offloads(const struct mlx5_hca_attr *attr)
{
uint32_t sw_parsing_offloads = 0;
if (attr->swp) {
sw_parsing_offloads |= MLX5_SW_PARSING_CAP;
if (attr->swp_csum)
sw_parsing_offloads |= MLX5_SW_PARSING_CSUM_CAP;
if (attr->swp_lso)
sw_parsing_offloads |= MLX5_SW_PARSING_TSO_CAP;
}
return sw_parsing_offloads;
}
uint32_t
mlx5_get_supported_tunneling_offloads(const struct mlx5_hca_attr *attr)
{
uint32_t tn_offloads = 0;
if (attr->tunnel_stateless_vxlan)
tn_offloads |= MLX5_TUNNELED_OFFLOADS_VXLAN_CAP;
if (attr->tunnel_stateless_gre)
tn_offloads |= MLX5_TUNNELED_OFFLOADS_GRE_CAP;
if (attr->tunnel_stateless_geneve_rx)
tn_offloads |= MLX5_TUNNELED_OFFLOADS_GENEVE_CAP;
return tn_offloads;
}
common/mlx5: fix post doorbell barrier The rdma-core library can map doorbell register in two ways, depending on the environment variable "MLX5_SHUT_UP_BF": - as regular cached memory, the variable is either missing or set to zero. This type of mapping may cause the significant doorbell register writing latency and requires an explicit memory write barrier to mitigate this issue and prevent write combining. - as non-cached memory, the variable is present and set to not "0" value. This type of mapping may cause performance impact under heavy loading conditions but the explicit write memory barrier is not required and it may improve core performance. The UAR creation function maps a doorbell in one of the above ways according to the system. In run time, it always adds an explicit memory barrier after writing to. In cases where the doorbell was mapped as non-cached memory, the explicit memory barrier is unnecessary and may impair performance. The commit [1] solved this problem for a Tx queue. In run time, it checks the mapping type and provides the memory barrier after writing to a Tx doorbell register if it is needed. The mapping type is extracted directly from the uar_mmap_offset field in the queue properties. This patch shares this code between the drivers and extends the above solution for each of them. [1] commit 8409a28573d3 ("net/mlx5: control transmit doorbell register mapping") Fixes: f8c97babc9f4 ("compress/mlx5: add data-path functions") Fixes: 8e196c08ab53 ("crypto/mlx5: support enqueue/dequeue operations") Fixes: 4d4e245ad637 ("regex/mlx5: support enqueue") Cc: stable@dpdk.org Signed-off-by: Michael Baum <michaelba@nvidia.com> Reviewed-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com> Acked-by: Matan Azrad <matan@nvidia.com>
2021-11-03 18:35:13 +00:00
/* Fill all fields of UAR structure. */
static int
common/mlx5: fix post doorbell barrier The rdma-core library can map doorbell register in two ways, depending on the environment variable "MLX5_SHUT_UP_BF": - as regular cached memory, the variable is either missing or set to zero. This type of mapping may cause the significant doorbell register writing latency and requires an explicit memory write barrier to mitigate this issue and prevent write combining. - as non-cached memory, the variable is present and set to not "0" value. This type of mapping may cause performance impact under heavy loading conditions but the explicit write memory barrier is not required and it may improve core performance. The UAR creation function maps a doorbell in one of the above ways according to the system. In run time, it always adds an explicit memory barrier after writing to. In cases where the doorbell was mapped as non-cached memory, the explicit memory barrier is unnecessary and may impair performance. The commit [1] solved this problem for a Tx queue. In run time, it checks the mapping type and provides the memory barrier after writing to a Tx doorbell register if it is needed. The mapping type is extracted directly from the uar_mmap_offset field in the queue properties. This patch shares this code between the drivers and extends the above solution for each of them. [1] commit 8409a28573d3 ("net/mlx5: control transmit doorbell register mapping") Fixes: f8c97babc9f4 ("compress/mlx5: add data-path functions") Fixes: 8e196c08ab53 ("crypto/mlx5: support enqueue/dequeue operations") Fixes: 4d4e245ad637 ("regex/mlx5: support enqueue") Cc: stable@dpdk.org Signed-off-by: Michael Baum <michaelba@nvidia.com> Reviewed-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com> Acked-by: Matan Azrad <matan@nvidia.com>
2021-11-03 18:35:13 +00:00
mlx5_rxtx_uars_prepare(struct mlx5_dev_ctx_shared *sh)
{
common/mlx5: fix post doorbell barrier The rdma-core library can map doorbell register in two ways, depending on the environment variable "MLX5_SHUT_UP_BF": - as regular cached memory, the variable is either missing or set to zero. This type of mapping may cause the significant doorbell register writing latency and requires an explicit memory write barrier to mitigate this issue and prevent write combining. - as non-cached memory, the variable is present and set to not "0" value. This type of mapping may cause performance impact under heavy loading conditions but the explicit write memory barrier is not required and it may improve core performance. The UAR creation function maps a doorbell in one of the above ways according to the system. In run time, it always adds an explicit memory barrier after writing to. In cases where the doorbell was mapped as non-cached memory, the explicit memory barrier is unnecessary and may impair performance. The commit [1] solved this problem for a Tx queue. In run time, it checks the mapping type and provides the memory barrier after writing to a Tx doorbell register if it is needed. The mapping type is extracted directly from the uar_mmap_offset field in the queue properties. This patch shares this code between the drivers and extends the above solution for each of them. [1] commit 8409a28573d3 ("net/mlx5: control transmit doorbell register mapping") Fixes: f8c97babc9f4 ("compress/mlx5: add data-path functions") Fixes: 8e196c08ab53 ("crypto/mlx5: support enqueue/dequeue operations") Fixes: 4d4e245ad637 ("regex/mlx5: support enqueue") Cc: stable@dpdk.org Signed-off-by: Michael Baum <michaelba@nvidia.com> Reviewed-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com> Acked-by: Matan Azrad <matan@nvidia.com>
2021-11-03 18:35:13 +00:00
int ret;
ret = mlx5_devx_uar_prepare(sh->cdev, &sh->tx_uar);
if (ret) {
DRV_LOG(ERR, "Failed to prepare Tx DevX UAR.");
return -rte_errno;
}
common/mlx5: fix post doorbell barrier The rdma-core library can map doorbell register in two ways, depending on the environment variable "MLX5_SHUT_UP_BF": - as regular cached memory, the variable is either missing or set to zero. This type of mapping may cause the significant doorbell register writing latency and requires an explicit memory write barrier to mitigate this issue and prevent write combining. - as non-cached memory, the variable is present and set to not "0" value. This type of mapping may cause performance impact under heavy loading conditions but the explicit write memory barrier is not required and it may improve core performance. The UAR creation function maps a doorbell in one of the above ways according to the system. In run time, it always adds an explicit memory barrier after writing to. In cases where the doorbell was mapped as non-cached memory, the explicit memory barrier is unnecessary and may impair performance. The commit [1] solved this problem for a Tx queue. In run time, it checks the mapping type and provides the memory barrier after writing to a Tx doorbell register if it is needed. The mapping type is extracted directly from the uar_mmap_offset field in the queue properties. This patch shares this code between the drivers and extends the above solution for each of them. [1] commit 8409a28573d3 ("net/mlx5: control transmit doorbell register mapping") Fixes: f8c97babc9f4 ("compress/mlx5: add data-path functions") Fixes: 8e196c08ab53 ("crypto/mlx5: support enqueue/dequeue operations") Fixes: 4d4e245ad637 ("regex/mlx5: support enqueue") Cc: stable@dpdk.org Signed-off-by: Michael Baum <michaelba@nvidia.com> Reviewed-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com> Acked-by: Matan Azrad <matan@nvidia.com>
2021-11-03 18:35:13 +00:00
MLX5_ASSERT(sh->tx_uar.obj);
MLX5_ASSERT(mlx5_os_get_devx_uar_base_addr(sh->tx_uar.obj));
ret = mlx5_devx_uar_prepare(sh->cdev, &sh->rx_uar);
if (ret) {
DRV_LOG(ERR, "Failed to prepare Rx DevX UAR.");
mlx5_devx_uar_release(&sh->tx_uar);
return -rte_errno;
}
common/mlx5: fix post doorbell barrier The rdma-core library can map doorbell register in two ways, depending on the environment variable "MLX5_SHUT_UP_BF": - as regular cached memory, the variable is either missing or set to zero. This type of mapping may cause the significant doorbell register writing latency and requires an explicit memory write barrier to mitigate this issue and prevent write combining. - as non-cached memory, the variable is present and set to not "0" value. This type of mapping may cause performance impact under heavy loading conditions but the explicit write memory barrier is not required and it may improve core performance. The UAR creation function maps a doorbell in one of the above ways according to the system. In run time, it always adds an explicit memory barrier after writing to. In cases where the doorbell was mapped as non-cached memory, the explicit memory barrier is unnecessary and may impair performance. The commit [1] solved this problem for a Tx queue. In run time, it checks the mapping type and provides the memory barrier after writing to a Tx doorbell register if it is needed. The mapping type is extracted directly from the uar_mmap_offset field in the queue properties. This patch shares this code between the drivers and extends the above solution for each of them. [1] commit 8409a28573d3 ("net/mlx5: control transmit doorbell register mapping") Fixes: f8c97babc9f4 ("compress/mlx5: add data-path functions") Fixes: 8e196c08ab53 ("crypto/mlx5: support enqueue/dequeue operations") Fixes: 4d4e245ad637 ("regex/mlx5: support enqueue") Cc: stable@dpdk.org Signed-off-by: Michael Baum <michaelba@nvidia.com> Reviewed-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com> Acked-by: Matan Azrad <matan@nvidia.com>
2021-11-03 18:35:13 +00:00
MLX5_ASSERT(sh->rx_uar.obj);
MLX5_ASSERT(mlx5_os_get_devx_uar_base_addr(sh->rx_uar.obj));
return 0;
}
static void
mlx5_rxtx_uars_release(struct mlx5_dev_ctx_shared *sh)
{
mlx5_devx_uar_release(&sh->rx_uar);
mlx5_devx_uar_release(&sh->tx_uar);
}
/**
* rte_mempool_walk() callback to unregister Rx mempools.
* It used when implicit mempool registration is disabled.
*
* @param mp
* The mempool being walked.
* @param arg
* Pointer to the device shared context.
*/
static void
mlx5_dev_ctx_shared_rx_mempool_unregister_cb(struct rte_mempool *mp, void *arg)
{
struct mlx5_dev_ctx_shared *sh = arg;
mlx5_dev_mempool_unregister(sh->cdev, mp);
}
/**
* Callback used when implicit mempool registration is disabled
* in order to track Rx mempool destruction.
*
* @param event
* Mempool life cycle event.
* @param mp
* An Rx mempool registered explicitly when the port is started.
* @param arg
* Pointer to a device shared context.
*/
static void
mlx5_dev_ctx_shared_rx_mempool_event_cb(enum rte_mempool_event event,
struct rte_mempool *mp, void *arg)
{
struct mlx5_dev_ctx_shared *sh = arg;
if (event == RTE_MEMPOOL_EVENT_DESTROY)
mlx5_dev_mempool_unregister(sh->cdev, mp);
}
int
mlx5_dev_ctx_shared_mempool_subscribe(struct rte_eth_dev *dev)
{
struct mlx5_priv *priv = dev->data->dev_private;
struct mlx5_dev_ctx_shared *sh = priv->sh;
int ret;
/* Check if we only need to track Rx mempool destruction. */
if (!sh->cdev->config.mr_mempool_reg_en) {
ret = rte_mempool_event_callback_register
(mlx5_dev_ctx_shared_rx_mempool_event_cb, sh);
return ret == 0 || rte_errno == EEXIST ? 0 : ret;
}
return mlx5_dev_mempool_subscribe(sh->cdev);
}
/**
* Set up multiple TISs with different affinities according to
* number of bonding ports
*
* @param priv
* Pointer of shared context.
*
* @return
* Zero on success, -1 otherwise.
*/
static int
mlx5_setup_tis(struct mlx5_dev_ctx_shared *sh)
{
int i;
struct mlx5_devx_lag_context lag_ctx = { 0 };
struct mlx5_devx_tis_attr tis_attr = { 0 };
tis_attr.transport_domain = sh->td->id;
if (sh->bond.n_port) {
if (!mlx5_devx_cmd_query_lag(sh->cdev->ctx, &lag_ctx)) {
sh->lag.tx_remap_affinity[0] =
lag_ctx.tx_remap_affinity_1;
sh->lag.tx_remap_affinity[1] =
lag_ctx.tx_remap_affinity_2;
sh->lag.affinity_mode = lag_ctx.port_select_mode;
} else {
DRV_LOG(ERR, "Failed to query lag affinity.");
return -1;
}
if (sh->lag.affinity_mode == MLX5_LAG_MODE_TIS) {
for (i = 0; i < sh->bond.n_port; i++) {
tis_attr.lag_tx_port_affinity =
MLX5_IFC_LAG_MAP_TIS_AFFINITY(i,
sh->bond.n_port);
sh->tis[i] = mlx5_devx_cmd_create_tis(sh->cdev->ctx,
&tis_attr);
if (!sh->tis[i]) {
DRV_LOG(ERR, "Failed to TIS %d/%d for bonding device"
" %s.", i, sh->bond.n_port,
sh->ibdev_name);
return -1;
}
}
DRV_LOG(DEBUG, "LAG number of ports : %d, affinity_1 & 2 : pf%d & %d.\n",
sh->bond.n_port, lag_ctx.tx_remap_affinity_1,
lag_ctx.tx_remap_affinity_2);
return 0;
}
if (sh->lag.affinity_mode == MLX5_LAG_MODE_HASH)
DRV_LOG(INFO, "Device %s enabled HW hash based LAG.",
sh->ibdev_name);
}
tis_attr.lag_tx_port_affinity = 0;
sh->tis[0] = mlx5_devx_cmd_create_tis(sh->cdev->ctx, &tis_attr);
if (!sh->tis[0]) {
DRV_LOG(ERR, "Failed to TIS 0 for bonding device"
" %s.", sh->ibdev_name);
return -1;
}
return 0;
}
/**
* Verify and store value for share device argument.
*
* @param[in] key
* Key argument to verify.
* @param[in] val
* Value associated with key.
* @param opaque
* User data.
*
* @return
* 0 on success, a negative errno value otherwise and rte_errno is set.
*/
static int
mlx5_dev_args_check_handler(const char *key, const char *val, void *opaque)
{
struct mlx5_sh_config *config = opaque;
signed long tmp;
errno = 0;
tmp = strtol(val, NULL, 0);
if (errno) {
rte_errno = errno;
DRV_LOG(WARNING, "%s: \"%s\" is not a valid integer", key, val);
return -rte_errno;
}
if (tmp < 0 && strcmp(MLX5_TX_PP, key) && strcmp(MLX5_TX_SKEW, key)) {
/* Negative values are acceptable for some keys only. */
rte_errno = EINVAL;
DRV_LOG(WARNING, "%s: invalid negative value \"%s\"", key, val);
return -rte_errno;
}
if (strcmp(MLX5_TX_PP, key) == 0) {
unsigned long mod = tmp >= 0 ? tmp : -tmp;
if (!mod) {
DRV_LOG(ERR, "Zero Tx packet pacing parameter.");
rte_errno = EINVAL;
return -rte_errno;
}
config->tx_pp = tmp;
} else if (strcmp(MLX5_TX_SKEW, key) == 0) {
config->tx_skew = tmp;
} else if (strcmp(MLX5_L3_VXLAN_EN, key) == 0) {
config->l3_vxlan_en = !!tmp;
} else if (strcmp(MLX5_VF_NL_EN, key) == 0) {
config->vf_nl_en = !!tmp;
} else if (strcmp(MLX5_DV_ESW_EN, key) == 0) {
config->dv_esw_en = !!tmp;
} else if (strcmp(MLX5_DV_FLOW_EN, key) == 0) {
if (tmp > 2) {
DRV_LOG(ERR, "Invalid %s parameter.", key);
rte_errno = EINVAL;
return -rte_errno;
}
config->dv_flow_en = tmp;
} else if (strcmp(MLX5_DV_XMETA_EN, key) == 0) {
if (tmp != MLX5_XMETA_MODE_LEGACY &&
tmp != MLX5_XMETA_MODE_META16 &&
tmp != MLX5_XMETA_MODE_META32 &&
tmp != MLX5_XMETA_MODE_MISS_INFO) {
DRV_LOG(ERR, "Invalid extensive metadata parameter.");
rte_errno = EINVAL;
return -rte_errno;
}
if (tmp != MLX5_XMETA_MODE_MISS_INFO)
config->dv_xmeta_en = tmp;
else
config->dv_miss_info = 1;
} else if (strcmp(MLX5_LACP_BY_USER, key) == 0) {
config->lacp_by_user = !!tmp;
} else if (strcmp(MLX5_RECLAIM_MEM, key) == 0) {
if (tmp != MLX5_RCM_NONE &&
tmp != MLX5_RCM_LIGHT &&
tmp != MLX5_RCM_AGGR) {
DRV_LOG(ERR, "Unrecognize %s: \"%s\"", key, val);
rte_errno = EINVAL;
return -rte_errno;
}
config->reclaim_mode = tmp;
} else if (strcmp(MLX5_DECAP_EN, key) == 0) {
config->decap_en = !!tmp;
} else if (strcmp(MLX5_ALLOW_DUPLICATE_PATTERN, key) == 0) {
config->allow_duplicate_pattern = !!tmp;
} else if (strcmp(MLX5_FDB_DEFAULT_RULE_EN, key) == 0) {
config->fdb_def_rule = !!tmp;
}
return 0;
}
/**
* Parse user device parameters and adjust them according to device
* capabilities.
*
* @param sh
* Pointer to shared device context.
* @param mkvlist
* Pointer to mlx5 kvargs control, can be NULL if there is no devargs.
* @param config
* Pointer to shared device configuration structure.
*
* @return
* 0 on success, a negative errno value otherwise and rte_errno is set.
*/
static int
mlx5_shared_dev_ctx_args_config(struct mlx5_dev_ctx_shared *sh,
struct mlx5_kvargs_ctrl *mkvlist,
struct mlx5_sh_config *config)
{
const char **params = (const char *[]){
MLX5_TX_PP,
MLX5_TX_SKEW,
MLX5_L3_VXLAN_EN,
MLX5_VF_NL_EN,
MLX5_DV_ESW_EN,
MLX5_DV_FLOW_EN,
MLX5_DV_XMETA_EN,
MLX5_LACP_BY_USER,
MLX5_RECLAIM_MEM,
MLX5_DECAP_EN,
MLX5_ALLOW_DUPLICATE_PATTERN,
MLX5_FDB_DEFAULT_RULE_EN,
NULL,
};
int ret = 0;
/* Default configuration. */
memset(config, 0, sizeof(*config));
config->vf_nl_en = 1;
config->dv_esw_en = 1;
config->dv_flow_en = 1;
config->decap_en = 1;
config->allow_duplicate_pattern = 1;
config->fdb_def_rule = 1;
if (mkvlist != NULL) {
/* Process parameters. */
ret = mlx5_kvargs_process(mkvlist, params,
mlx5_dev_args_check_handler, config);
if (ret) {
DRV_LOG(ERR, "Failed to process device arguments: %s",
strerror(rte_errno));
return -rte_errno;
}
}
/* Adjust parameters according to device capabilities. */
if (config->dv_flow_en && !sh->dev_cap.dv_flow_en) {
DRV_LOG(WARNING, "DV flow is not supported.");
config->dv_flow_en = 0;
}
if (config->dv_esw_en && !sh->dev_cap.dv_esw_en) {
DRV_LOG(DEBUG, "E-Switch DV flow is not supported.");
config->dv_esw_en = 0;
}
if (config->dv_esw_en && !config->dv_flow_en) {
DRV_LOG(DEBUG,
"E-Switch DV flow is supported only when DV flow is enabled.");
config->dv_esw_en = 0;
}
if (config->dv_miss_info && config->dv_esw_en)
config->dv_xmeta_en = MLX5_XMETA_MODE_META16;
if (!config->dv_esw_en &&
config->dv_xmeta_en != MLX5_XMETA_MODE_LEGACY) {
DRV_LOG(WARNING,
"Metadata mode %u is not supported (no E-Switch).",
config->dv_xmeta_en);
config->dv_xmeta_en = MLX5_XMETA_MODE_LEGACY;
}
if (config->tx_pp && !sh->dev_cap.txpp_en) {
DRV_LOG(ERR, "Packet pacing is not supported.");
rte_errno = ENODEV;
return -rte_errno;
}
if (!config->tx_pp && config->tx_skew) {
DRV_LOG(WARNING,
"\"tx_skew\" doesn't affect without \"tx_pp\".");
}
/* Check for LRO support. */
if (mlx5_devx_obj_ops_en(sh) && sh->cdev->config.hca_attr.lro_cap) {
/* TBD check tunnel lro caps. */
config->lro_allowed = 1;
DRV_LOG(DEBUG, "LRO is allowed.");
DRV_LOG(DEBUG,
"LRO minimal size of TCP segment required for coalescing is %d bytes.",
sh->cdev->config.hca_attr.lro_min_mss_size);
}
/*
* If HW has bug working with tunnel packet decapsulation and scatter
* FCS, and decapsulation is needed, clear the hw_fcs_strip bit.
* Then RTE_ETH_RX_OFFLOAD_KEEP_CRC bit will not be set anymore.
*/
if (sh->dev_cap.scatter_fcs_w_decap_disable && sh->config.decap_en)
config->hw_fcs_strip = 0;
else
config->hw_fcs_strip = sh->dev_cap.hw_fcs_strip;
DRV_LOG(DEBUG, "FCS stripping configuration is %ssupported",
(config->hw_fcs_strip ? "" : "not "));
DRV_LOG(DEBUG, "\"tx_pp\" is %d.", config->tx_pp);
DRV_LOG(DEBUG, "\"tx_skew\" is %d.", config->tx_skew);
DRV_LOG(DEBUG, "\"reclaim_mode\" is %u.", config->reclaim_mode);
DRV_LOG(DEBUG, "\"dv_esw_en\" is %u.", config->dv_esw_en);
DRV_LOG(DEBUG, "\"dv_flow_en\" is %u.", config->dv_flow_en);
DRV_LOG(DEBUG, "\"dv_xmeta_en\" is %u.", config->dv_xmeta_en);
DRV_LOG(DEBUG, "\"dv_miss_info\" is %u.", config->dv_miss_info);
DRV_LOG(DEBUG, "\"l3_vxlan_en\" is %u.", config->l3_vxlan_en);
DRV_LOG(DEBUG, "\"vf_nl_en\" is %u.", config->vf_nl_en);
DRV_LOG(DEBUG, "\"lacp_by_user\" is %u.", config->lacp_by_user);
DRV_LOG(DEBUG, "\"decap_en\" is %u.", config->decap_en);
DRV_LOG(DEBUG, "\"allow_duplicate_pattern\" is %u.",
config->allow_duplicate_pattern);
DRV_LOG(DEBUG, "\"fdb_def_rule_en\" is %u.", config->fdb_def_rule);
return 0;
}
/**
* Configure realtime timestamp format.
*
* @param sh
* Pointer to mlx5_dev_ctx_shared object.
* @param hca_attr
* Pointer to DevX HCA capabilities structure.
*/
void
mlx5_rt_timestamp_config(struct mlx5_dev_ctx_shared *sh,
struct mlx5_hca_attr *hca_attr)
{
uint32_t dw_cnt = MLX5_ST_SZ_DW(register_mtutc);
uint32_t reg[dw_cnt];
int ret = ENOTSUP;
if (hca_attr->access_register_user)
ret = mlx5_devx_cmd_register_read(sh->cdev->ctx,
MLX5_REGISTER_ID_MTUTC, 0,
reg, dw_cnt);
if (!ret) {
uint32_t ts_mode;
/* MTUTC register is read successfully. */
ts_mode = MLX5_GET(register_mtutc, reg, time_stamp_mode);
if (ts_mode == MLX5_MTUTC_TIMESTAMP_MODE_REAL_TIME)
sh->dev_cap.rt_timestamp = 1;
} else {
/* Kernel does not support register reading. */
if (hca_attr->dev_freq_khz == (NS_PER_S / MS_PER_S))
sh->dev_cap.rt_timestamp = 1;
}
}
/**
* Allocate shared device context. If there is multiport device the
* master and representors will share this context, if there is single
* port dedicated device, the context will be used by only given
* port due to unification.
*
* Routine first searches the context for the specified device name,
* if found the shared context assumed and reference counter is incremented.
* If no context found the new one is created and initialized with specified
* device context and parameters.
*
* @param[in] spawn
* Pointer to the device attributes (name, port, etc).
* @param mkvlist
* Pointer to mlx5 kvargs control, can be NULL if there is no devargs.
*
* @return
* Pointer to mlx5_dev_ctx_shared object on success,
* otherwise NULL and rte_errno is set.
*/
struct mlx5_dev_ctx_shared *
mlx5_alloc_shared_dev_ctx(const struct mlx5_dev_spawn_data *spawn,
struct mlx5_kvargs_ctrl *mkvlist)
{
struct mlx5_dev_ctx_shared *sh;
int err = 0;
uint32_t i;
MLX5_ASSERT(spawn);
/* Secondary process should not create the shared context. */
MLX5_ASSERT(rte_eal_process_type() == RTE_PROC_PRIMARY);
pthread_mutex_lock(&mlx5_dev_ctx_list_mutex);
/* Search for IB context by device name. */
LIST_FOREACH(sh, &mlx5_dev_ctx_list, next) {
if (!strcmp(sh->ibdev_name, spawn->phys_dev_name)) {
sh->refcnt++;
goto exit;
}
}
/* No device found, we have to create new shared context. */
MLX5_ASSERT(spawn->max_port);
sh = mlx5_malloc(MLX5_MEM_ZERO | MLX5_MEM_RTE,
sizeof(struct mlx5_dev_ctx_shared) +
spawn->max_port * sizeof(struct mlx5_dev_shared_port),
RTE_CACHE_LINE_SIZE, SOCKET_ID_ANY);
if (!sh) {
DRV_LOG(ERR, "Shared context allocation failure.");
rte_errno = ENOMEM;
goto exit;
}
pthread_mutex_init(&sh->txpp.mutex, NULL);
sh->numa_node = spawn->cdev->dev->numa_node;
sh->cdev = spawn->cdev;
sh->esw_mode = !!(spawn->info.master || spawn->info.representor);
if (spawn->bond_info)
sh->bond = *spawn->bond_info;
err = mlx5_os_capabilities_prepare(sh);
if (err) {
DRV_LOG(ERR, "Fail to configure device capabilities.");
goto error;
}
err = mlx5_shared_dev_ctx_args_config(sh, mkvlist, &sh->config);
if (err) {
DRV_LOG(ERR, "Failed to process device configure: %s",
strerror(rte_errno));
goto error;
}
sh->refcnt = 1;
sh->max_port = spawn->max_port;
strncpy(sh->ibdev_name, mlx5_os_get_ctx_device_name(sh->cdev->ctx),
sizeof(sh->ibdev_name) - 1);
strncpy(sh->ibdev_path, mlx5_os_get_ctx_device_path(sh->cdev->ctx),
sizeof(sh->ibdev_path) - 1);
/*
* Setting port_id to max unallowed value means there is no interrupt
* subhandler installed for the given port index i.
*/
for (i = 0; i < sh->max_port; i++) {
sh->port[i].ih_port_id = RTE_MAX_ETHPORTS;
sh->port[i].devx_ih_port_id = RTE_MAX_ETHPORTS;
sh->port[i].nl_ih_port_id = RTE_MAX_ETHPORTS;
}
if (sh->cdev->config.devx) {
sh->td = mlx5_devx_cmd_create_td(sh->cdev->ctx);
if (!sh->td) {
DRV_LOG(ERR, "TD allocation failure");
rte_errno = ENOMEM;
goto error;
}
if (mlx5_setup_tis(sh)) {
DRV_LOG(ERR, "TIS allocation failure");
rte_errno = ENOMEM;
goto error;
}
common/mlx5: fix post doorbell barrier The rdma-core library can map doorbell register in two ways, depending on the environment variable "MLX5_SHUT_UP_BF": - as regular cached memory, the variable is either missing or set to zero. This type of mapping may cause the significant doorbell register writing latency and requires an explicit memory write barrier to mitigate this issue and prevent write combining. - as non-cached memory, the variable is present and set to not "0" value. This type of mapping may cause performance impact under heavy loading conditions but the explicit write memory barrier is not required and it may improve core performance. The UAR creation function maps a doorbell in one of the above ways according to the system. In run time, it always adds an explicit memory barrier after writing to. In cases where the doorbell was mapped as non-cached memory, the explicit memory barrier is unnecessary and may impair performance. The commit [1] solved this problem for a Tx queue. In run time, it checks the mapping type and provides the memory barrier after writing to a Tx doorbell register if it is needed. The mapping type is extracted directly from the uar_mmap_offset field in the queue properties. This patch shares this code between the drivers and extends the above solution for each of them. [1] commit 8409a28573d3 ("net/mlx5: control transmit doorbell register mapping") Fixes: f8c97babc9f4 ("compress/mlx5: add data-path functions") Fixes: 8e196c08ab53 ("crypto/mlx5: support enqueue/dequeue operations") Fixes: 4d4e245ad637 ("regex/mlx5: support enqueue") Cc: stable@dpdk.org Signed-off-by: Michael Baum <michaelba@nvidia.com> Reviewed-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com> Acked-by: Matan Azrad <matan@nvidia.com>
2021-11-03 18:35:13 +00:00
err = mlx5_rxtx_uars_prepare(sh);
if (err)
goto error;
#ifndef RTE_ARCH_64
common/mlx5: fix post doorbell barrier The rdma-core library can map doorbell register in two ways, depending on the environment variable "MLX5_SHUT_UP_BF": - as regular cached memory, the variable is either missing or set to zero. This type of mapping may cause the significant doorbell register writing latency and requires an explicit memory write barrier to mitigate this issue and prevent write combining. - as non-cached memory, the variable is present and set to not "0" value. This type of mapping may cause performance impact under heavy loading conditions but the explicit write memory barrier is not required and it may improve core performance. The UAR creation function maps a doorbell in one of the above ways according to the system. In run time, it always adds an explicit memory barrier after writing to. In cases where the doorbell was mapped as non-cached memory, the explicit memory barrier is unnecessary and may impair performance. The commit [1] solved this problem for a Tx queue. In run time, it checks the mapping type and provides the memory barrier after writing to a Tx doorbell register if it is needed. The mapping type is extracted directly from the uar_mmap_offset field in the queue properties. This patch shares this code between the drivers and extends the above solution for each of them. [1] commit 8409a28573d3 ("net/mlx5: control transmit doorbell register mapping") Fixes: f8c97babc9f4 ("compress/mlx5: add data-path functions") Fixes: 8e196c08ab53 ("crypto/mlx5: support enqueue/dequeue operations") Fixes: 4d4e245ad637 ("regex/mlx5: support enqueue") Cc: stable@dpdk.org Signed-off-by: Michael Baum <michaelba@nvidia.com> Reviewed-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com> Acked-by: Matan Azrad <matan@nvidia.com>
2021-11-03 18:35:13 +00:00
} else {
/* Initialize UAR access locks for 32bit implementations. */
rte_spinlock_init(&sh->uar_lock_cq);
for (i = 0; i < MLX5_UAR_PAGE_NUM_MAX; i++)
rte_spinlock_init(&sh->uar_lock[i]);
#endif
common/mlx5: fix post doorbell barrier The rdma-core library can map doorbell register in two ways, depending on the environment variable "MLX5_SHUT_UP_BF": - as regular cached memory, the variable is either missing or set to zero. This type of mapping may cause the significant doorbell register writing latency and requires an explicit memory write barrier to mitigate this issue and prevent write combining. - as non-cached memory, the variable is present and set to not "0" value. This type of mapping may cause performance impact under heavy loading conditions but the explicit write memory barrier is not required and it may improve core performance. The UAR creation function maps a doorbell in one of the above ways according to the system. In run time, it always adds an explicit memory barrier after writing to. In cases where the doorbell was mapped as non-cached memory, the explicit memory barrier is unnecessary and may impair performance. The commit [1] solved this problem for a Tx queue. In run time, it checks the mapping type and provides the memory barrier after writing to a Tx doorbell register if it is needed. The mapping type is extracted directly from the uar_mmap_offset field in the queue properties. This patch shares this code between the drivers and extends the above solution for each of them. [1] commit 8409a28573d3 ("net/mlx5: control transmit doorbell register mapping") Fixes: f8c97babc9f4 ("compress/mlx5: add data-path functions") Fixes: 8e196c08ab53 ("crypto/mlx5: support enqueue/dequeue operations") Fixes: 4d4e245ad637 ("regex/mlx5: support enqueue") Cc: stable@dpdk.org Signed-off-by: Michael Baum <michaelba@nvidia.com> Reviewed-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com> Acked-by: Matan Azrad <matan@nvidia.com>
2021-11-03 18:35:13 +00:00
}
mlx5_os_dev_shared_handler_install(sh);
if (LIST_EMPTY(&mlx5_dev_ctx_list)) {
err = mlx5_flow_os_init_workspace_once();
if (err)
goto error;
}
mlx5_flow_aging_init(sh);
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
mlx5_flow_counters_mng_init(sh);
mlx5_flow_ipool_create(sh);
/* Add context to the global device list. */
LIST_INSERT_HEAD(&mlx5_dev_ctx_list, sh, next);
rte_spinlock_init(&sh->geneve_tlv_opt_sl);
exit:
pthread_mutex_unlock(&mlx5_dev_ctx_list_mutex);
return sh;
error:
err = rte_errno;
pthread_mutex_destroy(&sh->txpp.mutex);
pthread_mutex_unlock(&mlx5_dev_ctx_list_mutex);
MLX5_ASSERT(sh);
mlx5_rxtx_uars_release(sh);
i = 0;
do {
if (sh->tis[i])
claim_zero(mlx5_devx_cmd_destroy(sh->tis[i]));
} while (++i < (uint32_t)sh->bond.n_port);
if (sh->td)
claim_zero(mlx5_devx_cmd_destroy(sh->td));
mlx5_free(sh);
rte_errno = err;
return NULL;
}
/**
* Create LWM event_channel and interrupt handle for shared device
* context. All rxqs sharing the device context share the event_channel.
* A callback is registered in interrupt thread to receive the LWM event.
*
* @param[in] priv
* Pointer to mlx5_priv instance.
*
* @return
* 0 on success, negative with rte_errno set.
*/
int
mlx5_lwm_setup(struct mlx5_priv *priv)
{
int fd_lwm;
pthread_mutex_init(&priv->sh->lwm_config_lock, NULL);
priv->sh->devx_channel_lwm = mlx5_os_devx_create_event_channel
(priv->sh->cdev->ctx,
MLX5DV_DEVX_CREATE_EVENT_CHANNEL_FLAGS_OMIT_EV_DATA);
if (!priv->sh->devx_channel_lwm)
goto err;
fd_lwm = mlx5_os_get_devx_channel_fd(priv->sh->devx_channel_lwm);
priv->sh->intr_handle_lwm = mlx5_os_interrupt_handler_create
(RTE_INTR_INSTANCE_F_SHARED, true,
fd_lwm, mlx5_dev_interrupt_handler_lwm, priv);
if (!priv->sh->intr_handle_lwm)
goto err;
return 0;
err:
if (priv->sh->devx_channel_lwm) {
mlx5_os_devx_destroy_event_channel
(priv->sh->devx_channel_lwm);
priv->sh->devx_channel_lwm = NULL;
}
pthread_mutex_destroy(&priv->sh->lwm_config_lock);
return -rte_errno;
}
/**
* Destroy LWM event_channel and interrupt handle for shared device
* context before free this context. The interrupt handler is also
* unregistered.
*
* @param[in] sh
* Pointer to shared device context.
*/
void
mlx5_lwm_unset(struct mlx5_dev_ctx_shared *sh)
{
if (sh->intr_handle_lwm) {
mlx5_os_interrupt_handler_destroy(sh->intr_handle_lwm,
mlx5_dev_interrupt_handler_lwm, (void *)-1);
sh->intr_handle_lwm = NULL;
}
if (sh->devx_channel_lwm) {
mlx5_os_devx_destroy_event_channel
(sh->devx_channel_lwm);
sh->devx_channel_lwm = NULL;
}
pthread_mutex_destroy(&sh->lwm_config_lock);
}
/**
* Free shared IB device context. Decrement counter and if zero free
* all allocated resources and close handles.
*
* @param[in] sh
* Pointer to mlx5_dev_ctx_shared object to free
*/
void
mlx5_free_shared_dev_ctx(struct mlx5_dev_ctx_shared *sh)
{
int ret;
int i = 0;
pthread_mutex_lock(&mlx5_dev_ctx_list_mutex);
#ifdef RTE_LIBRTE_MLX5_DEBUG
/* Check the object presence in the list. */
struct mlx5_dev_ctx_shared *lctx;
LIST_FOREACH(lctx, &mlx5_dev_ctx_list, next)
if (lctx == sh)
break;
MLX5_ASSERT(lctx);
if (lctx != sh) {
DRV_LOG(ERR, "Freeing non-existing shared IB context");
goto exit;
}
#endif
MLX5_ASSERT(sh);
MLX5_ASSERT(sh->refcnt);
/* Secondary process should not free the shared context. */
MLX5_ASSERT(rte_eal_process_type() == RTE_PROC_PRIMARY);
if (--sh->refcnt)
goto exit;
/* Stop watching for mempool events and unregister all mempools. */
if (!sh->cdev->config.mr_mempool_reg_en) {
ret = rte_mempool_event_callback_unregister
(mlx5_dev_ctx_shared_rx_mempool_event_cb, sh);
if (ret == 0)
rte_mempool_walk
(mlx5_dev_ctx_shared_rx_mempool_unregister_cb, sh);
}
/* Remove context from the global device list. */
LIST_REMOVE(sh, next);
/* Release resources on the last device removal. */
if (LIST_EMPTY(&mlx5_dev_ctx_list)) {
mlx5_os_net_cleanup();
mlx5_flow_os_release_workspace();
}
pthread_mutex_unlock(&mlx5_dev_ctx_list_mutex);
if (sh->flex_parsers_dv) {
mlx5_list_destroy(sh->flex_parsers_dv);
sh->flex_parsers_dv = NULL;
}
/*
* Ensure there is no async event handler installed.
* Only primary process handles async device events.
**/
net/mlx5: accelerate DV flow counter transactions The DevX interface exposes a new feature to the PMD that can allocate a batch of counters by one FW command. It can improve the flow transaction rate (with count action). Add a new counter pools mechanism to manage HW counters in the PMD. So, for each flow with counter creation the PMD will try to find a free counter in the PMD pools container and only if there is no a free counter, it will allocate a new DevX batch counters. Currently we cannot support batch counter for a group 0 flow, so create a 2 container types, one which allocates counters one by one and one which allocates X counters by the batch feature. The allocated counters objects are never released back to the HW assuming the flows maximum number will be close to the actual value of the flows number. Later, it can be updated, and dynamic release mechanism can be added. The counters are contained in pools, each pool with 512 counters. The pools are contained in counter containers according to the allocation resolution type - single or batch. The cache memory of the counters statistics is saved as raw data per pool. All the raw data memory is allocated for all the container in one memory allocation and is managed by counter_stats_mem_mng structure which registers all the raw memory to the HW. Each pool points to one raw data structure. The query operation is in pool resolution which updates all the pool counter raw data by one operation. Signed-off-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-16 14:34:53 +00:00
mlx5_flow_counters_mng_close(sh);
if (sh->ct_mng)
mlx5_flow_aso_ct_mng_close(sh);
if (sh->aso_age_mng) {
mlx5_flow_aso_age_mng_close(sh);
sh->aso_age_mng = NULL;
}
if (sh->mtrmng)
mlx5_aso_flow_mtrs_mng_close(sh);
mlx5_flow_ipool_destroy(sh);
mlx5_os_dev_shared_handler_uninstall(sh);
common/mlx5: fix post doorbell barrier The rdma-core library can map doorbell register in two ways, depending on the environment variable "MLX5_SHUT_UP_BF": - as regular cached memory, the variable is either missing or set to zero. This type of mapping may cause the significant doorbell register writing latency and requires an explicit memory write barrier to mitigate this issue and prevent write combining. - as non-cached memory, the variable is present and set to not "0" value. This type of mapping may cause performance impact under heavy loading conditions but the explicit write memory barrier is not required and it may improve core performance. The UAR creation function maps a doorbell in one of the above ways according to the system. In run time, it always adds an explicit memory barrier after writing to. In cases where the doorbell was mapped as non-cached memory, the explicit memory barrier is unnecessary and may impair performance. The commit [1] solved this problem for a Tx queue. In run time, it checks the mapping type and provides the memory barrier after writing to a Tx doorbell register if it is needed. The mapping type is extracted directly from the uar_mmap_offset field in the queue properties. This patch shares this code between the drivers and extends the above solution for each of them. [1] commit 8409a28573d3 ("net/mlx5: control transmit doorbell register mapping") Fixes: f8c97babc9f4 ("compress/mlx5: add data-path functions") Fixes: 8e196c08ab53 ("crypto/mlx5: support enqueue/dequeue operations") Fixes: 4d4e245ad637 ("regex/mlx5: support enqueue") Cc: stable@dpdk.org Signed-off-by: Michael Baum <michaelba@nvidia.com> Reviewed-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com> Acked-by: Matan Azrad <matan@nvidia.com>
2021-11-03 18:35:13 +00:00
mlx5_rxtx_uars_release(sh);
do {
if (sh->tis[i])
claim_zero(mlx5_devx_cmd_destroy(sh->tis[i]));
} while (++i < sh->bond.n_port);
if (sh->td)
claim_zero(mlx5_devx_cmd_destroy(sh->td));
MLX5_ASSERT(sh->geneve_tlv_option_resource == NULL);
pthread_mutex_destroy(&sh->txpp.mutex);
mlx5_lwm_unset(sh);
mlx5_free(sh);
return;
exit:
pthread_mutex_unlock(&mlx5_dev_ctx_list_mutex);
}
/**
* Destroy table hash list.
*
* @param[in] priv
* Pointer to the private device data structure.
*/
void
mlx5_free_table_hash_list(struct mlx5_priv *priv)
{
struct mlx5_dev_ctx_shared *sh = priv->sh;
struct mlx5_hlist **tbls = (priv->sh->config.dv_flow_en == 2) ?
&sh->groups : &sh->flow_tbls;
if (*tbls == NULL)
return;
mlx5_hlist_destroy(*tbls);
*tbls = NULL;
}
#ifdef HAVE_MLX5_HWS_SUPPORT
/**
* Allocate HW steering group hash list.
*
* @param[in] priv
* Pointer to the private device data structure.
*/
static int
mlx5_alloc_hw_group_hash_list(struct mlx5_priv *priv)
{
int err = 0;
struct mlx5_dev_ctx_shared *sh = priv->sh;
char s[MLX5_NAME_SIZE];
MLX5_ASSERT(sh);
snprintf(s, sizeof(s), "%s_flow_groups", priv->sh->ibdev_name);
sh->groups = mlx5_hlist_create
(s, MLX5_FLOW_TABLE_HLIST_ARRAY_SIZE,
false, true, sh,
flow_hw_grp_create_cb,
flow_hw_grp_match_cb,
flow_hw_grp_remove_cb,
flow_hw_grp_clone_cb,
flow_hw_grp_clone_free_cb);
if (!sh->groups) {
DRV_LOG(ERR, "flow groups with hash creation failed.");
err = ENOMEM;
}
return err;
}
#endif
/**
* Initialize flow table hash list and create the root tables entry
* for each domain.
*
* @param[in] priv
* Pointer to the private device data structure.
*
* @return
* Zero on success, positive error code otherwise.
*/
int
mlx5_alloc_table_hash_list(struct mlx5_priv *priv __rte_unused)
{
int err = 0;
/* Tables are only used in DV and DR modes. */
#ifdef HAVE_MLX5_HWS_SUPPORT
struct mlx5_dev_ctx_shared *sh = priv->sh;
char s[MLX5_NAME_SIZE];
if (priv->sh->config.dv_flow_en == 2)
return mlx5_alloc_hw_group_hash_list(priv);
MLX5_ASSERT(sh);
snprintf(s, sizeof(s), "%s_flow_table", priv->sh->ibdev_name);
sh->flow_tbls = mlx5_hlist_create(s, MLX5_FLOW_TABLE_HLIST_ARRAY_SIZE,
false, true, sh,
flow_dv_tbl_create_cb,
flow_dv_tbl_match_cb,
flow_dv_tbl_remove_cb,
flow_dv_tbl_clone_cb,
flow_dv_tbl_clone_free_cb);
if (!sh->flow_tbls) {
DRV_LOG(ERR, "flow tables with hash creation failed.");
err = ENOMEM;
return err;
}
#ifndef HAVE_MLX5DV_DR
struct rte_flow_error error;
struct rte_eth_dev *dev = &rte_eth_devices[priv->dev_data->port_id];
/*
* In case we have not DR support, the zero tables should be created
* because DV expect to see them even if they cannot be created by
* RDMA-CORE.
*/
if (!flow_dv_tbl_resource_get(dev, 0, 0, 0, 0,
NULL, 0, 1, 0, &error) ||
!flow_dv_tbl_resource_get(dev, 0, 1, 0, 0,
NULL, 0, 1, 0, &error) ||
!flow_dv_tbl_resource_get(dev, 0, 0, 1, 0,
NULL, 0, 1, 0, &error)) {
err = ENOMEM;
goto error;
}
return err;
error:
mlx5_free_table_hash_list(priv);
#endif /* HAVE_MLX5DV_DR */
#endif
return err;
}
/**
* Retrieve integer value from environment variable.
*
* @param[in] name
* Environment variable name.
*
* @return
* Integer value, 0 if the variable is not set.
*/
int
mlx5_getenv_int(const char *name)
{
const char *val = getenv(name);
if (val == NULL)
return 0;
return atoi(val);
}
/**
* DPDK callback to add udp tunnel port
*
* @param[in] dev
* A pointer to eth_dev
* @param[in] udp_tunnel
* A pointer to udp tunnel
*
* @return
* 0 on valid udp ports and tunnels, -ENOTSUP otherwise.
*/
int
mlx5_udp_tunnel_port_add(struct rte_eth_dev *dev __rte_unused,
struct rte_eth_udp_tunnel *udp_tunnel)
{
MLX5_ASSERT(udp_tunnel != NULL);
if (udp_tunnel->prot_type == RTE_ETH_TUNNEL_TYPE_VXLAN &&
udp_tunnel->udp_port == 4789)
return 0;
if (udp_tunnel->prot_type == RTE_ETH_TUNNEL_TYPE_VXLAN_GPE &&
udp_tunnel->udp_port == 4790)
return 0;
return -ENOTSUP;
}
/**
* Initialize process private data structure.
*
* @param dev
* Pointer to Ethernet device structure.
*
* @return
* 0 on success, a negative errno value otherwise and rte_errno is set.
*/
int
mlx5_proc_priv_init(struct rte_eth_dev *dev)
{
struct mlx5_priv *priv = dev->data->dev_private;
struct mlx5_proc_priv *ppriv;
size_t ppriv_size;
mlx5_proc_priv_uninit(dev);
/*
* UAR register table follows the process private structure. BlueFlame
* registers for Tx queues are stored in the table.
*/
common/mlx5: fix post doorbell barrier The rdma-core library can map doorbell register in two ways, depending on the environment variable "MLX5_SHUT_UP_BF": - as regular cached memory, the variable is either missing or set to zero. This type of mapping may cause the significant doorbell register writing latency and requires an explicit memory write barrier to mitigate this issue and prevent write combining. - as non-cached memory, the variable is present and set to not "0" value. This type of mapping may cause performance impact under heavy loading conditions but the explicit write memory barrier is not required and it may improve core performance. The UAR creation function maps a doorbell in one of the above ways according to the system. In run time, it always adds an explicit memory barrier after writing to. In cases where the doorbell was mapped as non-cached memory, the explicit memory barrier is unnecessary and may impair performance. The commit [1] solved this problem for a Tx queue. In run time, it checks the mapping type and provides the memory barrier after writing to a Tx doorbell register if it is needed. The mapping type is extracted directly from the uar_mmap_offset field in the queue properties. This patch shares this code between the drivers and extends the above solution for each of them. [1] commit 8409a28573d3 ("net/mlx5: control transmit doorbell register mapping") Fixes: f8c97babc9f4 ("compress/mlx5: add data-path functions") Fixes: 8e196c08ab53 ("crypto/mlx5: support enqueue/dequeue operations") Fixes: 4d4e245ad637 ("regex/mlx5: support enqueue") Cc: stable@dpdk.org Signed-off-by: Michael Baum <michaelba@nvidia.com> Reviewed-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com> Acked-by: Matan Azrad <matan@nvidia.com>
2021-11-03 18:35:13 +00:00
ppriv_size = sizeof(struct mlx5_proc_priv) +
priv->txqs_n * sizeof(struct mlx5_uar_data);
ppriv = mlx5_malloc(MLX5_MEM_RTE | MLX5_MEM_ZERO, ppriv_size,
RTE_CACHE_LINE_SIZE, dev->device->numa_node);
if (!ppriv) {
rte_errno = ENOMEM;
return -rte_errno;
}
ppriv->uar_table_sz = priv->txqs_n;
dev->process_private = ppriv;
if (rte_eal_process_type() == RTE_PROC_PRIMARY)
priv->sh->pppriv = ppriv;
return 0;
}
/**
* Un-initialize process private data structure.
*
* @param dev
* Pointer to Ethernet device structure.
*/
void
mlx5_proc_priv_uninit(struct rte_eth_dev *dev)
{
if (!dev->process_private)
return;
mlx5_free(dev->process_private);
dev->process_private = NULL;
}
/**
* DPDK callback to close the device.
*
* Destroy all queues and objects, free memory.
*
* @param dev
* Pointer to Ethernet device structure.
*/
int
mlx5_dev_close(struct rte_eth_dev *dev)
{
struct mlx5_priv *priv = dev->data->dev_private;
unsigned int i;
int ret;
if (rte_eal_process_type() == RTE_PROC_SECONDARY) {
/* Check if process_private released. */
if (!dev->process_private)
return 0;
mlx5_tx_uar_uninit_secondary(dev);
mlx5_proc_priv_uninit(dev);
rte_eth_dev_release_port(dev);
return 0;
}
if (!priv->sh)
return 0;
DRV_LOG(DEBUG, "port %u closing device \"%s\"",
dev->data->port_id,
((priv->sh->cdev->ctx != NULL) ?
mlx5_os_get_ctx_device_name(priv->sh->cdev->ctx) : ""));
/*
* If default mreg copy action is removed at the stop stage,
* the search will return none and nothing will be done anymore.
*/
mlx5_flow_stop_default(dev);
mlx5_traffic_disable(dev);
/*
* If all the flows are already flushed in the device stop stage,
* then this will return directly without any action.
*/
mlx5_flow_list_flush(dev, MLX5_FLOW_TYPE_GEN, true);
ethdev: introduce indirect flow action Right now, rte_flow_shared_action_* APIs are used for some shared actions, like RSS, count. The shared action should be created before using it inside a flow. These shared actions sometimes are not really shared but just some indirect actions decoupled from a flow. The new functions rte_flow_action_handle_* are added to replace the current shared functions rte_flow_shared_action_*. There are two types of flow actions: 1. the direct (normal) actions that could be created and stored within a flow rule. Such action is tied to its flow rule and cannot be reused. 2. the indirect action, in the past, named shared_action. It is created from a direct actioni, like count or rss, and then used in the flow rules with an object handle. The PMD will take care of the retrieve from indirect action to the direct action when it is referenced. The indirect action is accessed (update / query) w/o any flow rule, just via the action object handle. For example, when querying or resetting a counter, it could be done out of any flow using this counter, but only the handle of the counter action object is required. The indirect action object could be shared by different flows or used by a single flow, depending on the direct action type and the real-life requirements. The handle of an indirect action object is opaque and defined in each driver and possibly different per direct action type. The old name "shared" is improper in a sense and should be replaced. Since the APIs are changed from "rte_flow_shared_action*" to the new "rte_flow_action_handle*", the testpmd application code and command line interfaces also need to be updated to do the adaption. The testpmd application user guide is also updated. All the "shared action" related parts are replaced with "indirect action" to have a correct explanation. The parameter of "update" interface is also changed. A general pointer will replace the rte_flow_action struct pointer due to the facts: 1. Some action may not support fields updating. In the example of a counter, the only "update" supported should be the reset. So passing a rte_flow_action struct pointer is meaningless and there is even no such corresponding action struct. What's more, if more than one operations should be supported, for some other action, such pointer parameter may not meet the need. 2. Some action may need conditional or partial update, the current parameter will not provide the ability to indicate which part(s) to update. For different types of indirect action objects, the pointer could either be the same of rte_flow_action* struct - in order not to break the current driver implementation, or some wrapper structures with bits as masks to indicate which part to be updated, depending on real needs of the corresponding direct action. For different direct actions, the structures of indirect action objects updating will be different. All the underlayer PMD callbacks will be moved to these new APIs. The RTE_FLOW_ACTION_TYPE_SHARED is kept for now in order not to break the ABI. All the implementations are changed by using RTE_FLOW_ACTION_TYPE_INDIRECT. Since the APIs are changed from "rte_flow_shared_action*" to the new "rte_flow_action_handle*" and the "update" interface's 3rd input parameter is changed to generic pointer, the mlx5 PMD that uses these APIs needs to do the adaption to the new APIs as well. Signed-off-by: Bing Zhao <bingz@nvidia.com> Acked-by: Andrey Vesnovaty <andreyv@nvidia.com> Acked-by: Ori Kam <orika@nvidia.com> Acked-by: Ajit Khaparde <ajit.khaparde@broadcom.com> Acked-by: Thomas Monjalon <thomas@monjalon.net>
2021-04-19 14:38:29 +00:00
mlx5_action_handle_flush(dev);
mlx5_flow_meter_flush(dev, NULL);
/* Prevent crashes when queues are still in use. */
dev->rx_pkt_burst = rte_eth_pkt_burst_dummy;
dev->tx_pkt_burst = rte_eth_pkt_burst_dummy;
rte_wmb();
/* Disable datapath on secondary process. */
mlx5_mp_os_req_stop_rxtx(dev);
/* Free the eCPRI flex parser resource. */
mlx5_flex_parser_ecpri_release(dev);
mlx5_flex_item_port_cleanup(dev);
#ifdef HAVE_MLX5_HWS_SUPPORT
flow_hw_destroy_vport_action(dev);
flow_hw_resource_release(dev);
flow_hw_clear_port_info(dev);
if (priv->sh->config.dv_flow_en == 2)
flow_hw_clear_tags_set(dev);
#endif
if (priv->rxq_privs != NULL) {
/* XXX race condition if mlx5_rx_burst() is still running. */
rte_delay_us_sleep(1000);
for (i = 0; (i != priv->rxqs_n); ++i)
mlx5_rxq_release(dev, i);
priv->rxqs_n = 0;
mlx5_free(priv->rxq_privs);
priv->rxq_privs = NULL;
}
if (priv->txqs != NULL) {
/* XXX race condition if mlx5_tx_burst() is still running. */
rte_delay_us_sleep(1000);
for (i = 0; (i != priv->txqs_n); ++i)
mlx5_txq_release(dev, i);
priv->txqs_n = 0;
priv->txqs = NULL;
}
mlx5_proc_priv_uninit(dev);
if (priv->q_counters) {
mlx5_devx_cmd_destroy(priv->q_counters);
priv->q_counters = NULL;
}
if (priv->drop_queue.hrxq)
mlx5_drop_action_destroy(dev);
if (priv->mreg_cp_tbl)
mlx5_hlist_destroy(priv->mreg_cp_tbl);
mlx5_mprq_free_mp(dev);
mlx5_os_free_shared_dr(priv);
if (priv->rss_conf.rss_key != NULL)
mlx5_free(priv->rss_conf.rss_key);
if (priv->reta_idx != NULL)
mlx5_free(priv->reta_idx);
if (priv->sh->dev_cap.vf)
mlx5_os_mac_addr_flush(dev);
if (priv->nl_socket_route >= 0)
close(priv->nl_socket_route);
if (priv->nl_socket_rdma >= 0)
close(priv->nl_socket_rdma);
net/mlx5: add workaround for VLAN in virtual machine On some virtual setups (particularly on ESXi) when we have SR-IOV and E-Switch enabled there is the problem to receive VLAN traffic on VF interfaces. The NIC driver in ESXi hypervisor does not setup E-Switch vport setting correctly and VLAN traffic targeted to VF is dropped. The patch provides the temporary workaround - if the rule containing the VLAN pattern is being installed for VF the VLAN network interface over VF is created, like the command does: ip link add link vf.if name mlx5.wa.1.100 type vlan id 100 The PMD in DPDK maintains the database of created VLAN interfaces for each existing VF and requested VLAN tags. When all of the RTE Flows using the given VLAN tag are removed the created VLAN interface with this VLAN tag is deleted. The name of created VLAN interface follows the format: evmlx.d1.d2, where d1 is VF interface ifindex, d2 - VLAN ifindex Implementation limitations: - mask in rules is ignored, rule must specify VLAN tags exactly, no wildcards (which are implemented by the masks) are allowed - virtual environment is detected via rte_hypervisor() call, and the type of hypervisor is checked. Currently we engage the workaround for ESXi and unrecognized hypervisors (which always happen on platforms other than x86 - it means workaround applied for the Flow over PCI VF). There are no confirmed data the other hypervisors (HyperV, Qemu) need this workaround, we are trying to reduce the list of configurations on those workaround should be applied. Signed-off-by: Viacheslav Ovsiienko <viacheslavo@mellanox.com> Acked-by: Matan Azrad <matan@mellanox.com> Acked-by: Shahaf Shuler <shahafs@mellanox.com>
2019-07-30 09:20:24 +00:00
if (priv->vmwa_context)
mlx5_vlan_vmwa_exit(priv->vmwa_context);
ret = mlx5_hrxq_verify(dev);
if (ret)
DRV_LOG(WARNING, "port %u some hash Rx queue still remain",
dev->data->port_id);
ret = mlx5_ind_table_obj_verify(dev);
if (ret)
DRV_LOG(WARNING, "port %u some indirection table still remain",
dev->data->port_id);
ret = mlx5_rxq_obj_verify(dev);
if (ret)
DRV_LOG(WARNING, "port %u some Rx queue objects still remain",
dev->data->port_id);
ret = mlx5_ext_rxq_verify(dev);
if (ret)
DRV_LOG(WARNING, "Port %u some external RxQ still remain.",
dev->data->port_id);
ret = mlx5_rxq_verify(dev);
if (ret)
DRV_LOG(WARNING, "port %u some Rx queues still remain",
dev->data->port_id);
ret = mlx5_txq_obj_verify(dev);
if (ret)
DRV_LOG(WARNING, "port %u some Verbs Tx queue still remain",
dev->data->port_id);
ret = mlx5_txq_verify(dev);
if (ret)
DRV_LOG(WARNING, "port %u some Tx queues still remain",
dev->data->port_id);
ret = mlx5_flow_verify(dev);
if (ret)
DRV_LOG(WARNING, "port %u some flows still remain",
dev->data->port_id);
if (priv->hrxqs)
mlx5_list_destroy(priv->hrxqs);
mlx5_free(priv->ext_rxqs);
/*
* Free the shared context in last turn, because the cleanup
* routines above may use some shared fields, like
* mlx5_os_mac_addr_flush() uses ibdev_path for retrieving
* ifindex if Netlink fails.
*/
mlx5_free_shared_dev_ctx(priv->sh);
if (priv->domain_id != RTE_ETH_DEV_SWITCH_DOMAIN_ID_INVALID) {
unsigned int c = 0;
uint16_t port_id;
MLX5_ETH_FOREACH_DEV(port_id, dev->device) {
struct mlx5_priv *opriv =
rte_eth_devices[port_id].data->dev_private;
if (!opriv ||
opriv->domain_id != priv->domain_id ||
&rte_eth_devices[port_id] == dev)
continue;
++c;
break;
}
if (!c)
claim_zero(rte_eth_switch_domain_free(priv->domain_id));
}
memset(priv, 0, sizeof(*priv));
priv->domain_id = RTE_ETH_DEV_SWITCH_DOMAIN_ID_INVALID;
/*
* Reset mac_addrs to NULL such that it is not freed as part of
* rte_eth_dev_release_port(). mac_addrs is part of dev_private so
* it is freed when dev_private is freed.
*/
dev->data->mac_addrs = NULL;
return 0;
}
const struct eth_dev_ops mlx5_dev_ops = {
.dev_configure = mlx5_dev_configure,
.dev_start = mlx5_dev_start,
.dev_stop = mlx5_dev_stop,
.dev_set_link_down = mlx5_set_link_down,
.dev_set_link_up = mlx5_set_link_up,
.dev_close = mlx5_dev_close,
.promiscuous_enable = mlx5_promiscuous_enable,
.promiscuous_disable = mlx5_promiscuous_disable,
.allmulticast_enable = mlx5_allmulticast_enable,
.allmulticast_disable = mlx5_allmulticast_disable,
.link_update = mlx5_link_update,
.stats_get = mlx5_stats_get,
.stats_reset = mlx5_stats_reset,
.xstats_get = mlx5_xstats_get,
.xstats_reset = mlx5_xstats_reset,
.xstats_get_names = mlx5_xstats_get_names,
.fw_version_get = mlx5_fw_version_get,
.dev_infos_get = mlx5_dev_infos_get,
.representor_info_get = mlx5_representor_info_get,
.read_clock = mlx5_txpp_read_clock,
.dev_supported_ptypes_get = mlx5_dev_supported_ptypes_get,
.vlan_filter_set = mlx5_vlan_filter_set,
.rx_queue_setup = mlx5_rx_queue_setup,
.rx_queue_avail_thresh_set = mlx5_rx_queue_lwm_set,
.rx_queue_avail_thresh_query = mlx5_rx_queue_lwm_query,
.rx_hairpin_queue_setup = mlx5_rx_hairpin_queue_setup,
.tx_queue_setup = mlx5_tx_queue_setup,
.tx_hairpin_queue_setup = mlx5_tx_hairpin_queue_setup,
.rx_queue_release = mlx5_rx_queue_release,
.tx_queue_release = mlx5_tx_queue_release,
.rx_queue_start = mlx5_rx_queue_start,
.rx_queue_stop = mlx5_rx_queue_stop,
.tx_queue_start = mlx5_tx_queue_start,
.tx_queue_stop = mlx5_tx_queue_stop,
.flow_ctrl_get = mlx5_dev_get_flow_ctrl,
.flow_ctrl_set = mlx5_dev_set_flow_ctrl,
.mac_addr_remove = mlx5_mac_addr_remove,
.mac_addr_add = mlx5_mac_addr_add,
.mac_addr_set = mlx5_mac_addr_set,
.set_mc_addr_list = mlx5_set_mc_addr_list,
.mtu_set = mlx5_dev_set_mtu,
.vlan_strip_queue_set = mlx5_vlan_strip_queue_set,
.vlan_offload_set = mlx5_vlan_offload_set,
.reta_update = mlx5_dev_rss_reta_update,
.reta_query = mlx5_dev_rss_reta_query,
.rss_hash_update = mlx5_rss_hash_update,
.rss_hash_conf_get = mlx5_rss_hash_conf_get,
.flow_ops_get = mlx5_flow_ops_get,
.rxq_info_get = mlx5_rxq_info_get,
.txq_info_get = mlx5_txq_info_get,
.rx_burst_mode_get = mlx5_rx_burst_mode_get,
.tx_burst_mode_get = mlx5_tx_burst_mode_get,
.rx_queue_intr_enable = mlx5_rx_intr_enable,
.rx_queue_intr_disable = mlx5_rx_intr_disable,
.is_removed = mlx5_is_removed,
.udp_tunnel_port_add = mlx5_udp_tunnel_port_add,
.get_module_info = mlx5_get_module_info,
.get_module_eeprom = mlx5_get_module_eeprom,
.hairpin_cap_get = mlx5_hairpin_cap_get,
.mtr_ops_get = mlx5_flow_meter_ops_get,
.hairpin_bind = mlx5_hairpin_bind,
.hairpin_unbind = mlx5_hairpin_unbind,
.hairpin_get_peer_ports = mlx5_hairpin_get_peer_ports,
.hairpin_queue_peer_update = mlx5_hairpin_queue_peer_update,
.hairpin_queue_peer_bind = mlx5_hairpin_queue_peer_bind,
.hairpin_queue_peer_unbind = mlx5_hairpin_queue_peer_unbind,
.get_monitor_addr = mlx5_get_monitor_addr,
};
/* Available operations from secondary process. */
const struct eth_dev_ops mlx5_dev_sec_ops = {
.stats_get = mlx5_stats_get,
.stats_reset = mlx5_stats_reset,
.xstats_get = mlx5_xstats_get,
.xstats_reset = mlx5_xstats_reset,
.xstats_get_names = mlx5_xstats_get_names,
.fw_version_get = mlx5_fw_version_get,
.dev_infos_get = mlx5_dev_infos_get,
.representor_info_get = mlx5_representor_info_get,
.read_clock = mlx5_txpp_read_clock,
.rx_queue_start = mlx5_rx_queue_start,
.rx_queue_stop = mlx5_rx_queue_stop,
.tx_queue_start = mlx5_tx_queue_start,
.tx_queue_stop = mlx5_tx_queue_stop,
.rxq_info_get = mlx5_rxq_info_get,
.txq_info_get = mlx5_txq_info_get,
.rx_burst_mode_get = mlx5_rx_burst_mode_get,
.tx_burst_mode_get = mlx5_tx_burst_mode_get,
.get_module_info = mlx5_get_module_info,
.get_module_eeprom = mlx5_get_module_eeprom,
};
/* Available operations in flow isolated mode. */
const struct eth_dev_ops mlx5_dev_ops_isolate = {
.dev_configure = mlx5_dev_configure,
.dev_start = mlx5_dev_start,
.dev_stop = mlx5_dev_stop,
.dev_set_link_down = mlx5_set_link_down,
.dev_set_link_up = mlx5_set_link_up,
.dev_close = mlx5_dev_close,
.promiscuous_enable = mlx5_promiscuous_enable,
.promiscuous_disable = mlx5_promiscuous_disable,
.allmulticast_enable = mlx5_allmulticast_enable,
.allmulticast_disable = mlx5_allmulticast_disable,
.link_update = mlx5_link_update,
.stats_get = mlx5_stats_get,
.stats_reset = mlx5_stats_reset,
.xstats_get = mlx5_xstats_get,
.xstats_reset = mlx5_xstats_reset,
.xstats_get_names = mlx5_xstats_get_names,
.fw_version_get = mlx5_fw_version_get,
.dev_infos_get = mlx5_dev_infos_get,
.representor_info_get = mlx5_representor_info_get,
.read_clock = mlx5_txpp_read_clock,
.dev_supported_ptypes_get = mlx5_dev_supported_ptypes_get,
.vlan_filter_set = mlx5_vlan_filter_set,
.rx_queue_setup = mlx5_rx_queue_setup,
.rx_hairpin_queue_setup = mlx5_rx_hairpin_queue_setup,
.tx_queue_setup = mlx5_tx_queue_setup,
.tx_hairpin_queue_setup = mlx5_tx_hairpin_queue_setup,
.rx_queue_release = mlx5_rx_queue_release,
.tx_queue_release = mlx5_tx_queue_release,
.rx_queue_start = mlx5_rx_queue_start,
.rx_queue_stop = mlx5_rx_queue_stop,
.tx_queue_start = mlx5_tx_queue_start,
.tx_queue_stop = mlx5_tx_queue_stop,
.flow_ctrl_get = mlx5_dev_get_flow_ctrl,
.flow_ctrl_set = mlx5_dev_set_flow_ctrl,
.mac_addr_remove = mlx5_mac_addr_remove,
.mac_addr_add = mlx5_mac_addr_add,
.mac_addr_set = mlx5_mac_addr_set,
.set_mc_addr_list = mlx5_set_mc_addr_list,
.mtu_set = mlx5_dev_set_mtu,
.vlan_strip_queue_set = mlx5_vlan_strip_queue_set,
.vlan_offload_set = mlx5_vlan_offload_set,
.flow_ops_get = mlx5_flow_ops_get,
.rxq_info_get = mlx5_rxq_info_get,
.txq_info_get = mlx5_txq_info_get,
.rx_burst_mode_get = mlx5_rx_burst_mode_get,
.tx_burst_mode_get = mlx5_tx_burst_mode_get,
.rx_queue_intr_enable = mlx5_rx_intr_enable,
.rx_queue_intr_disable = mlx5_rx_intr_disable,
.is_removed = mlx5_is_removed,
.get_module_info = mlx5_get_module_info,
.get_module_eeprom = mlx5_get_module_eeprom,
.hairpin_cap_get = mlx5_hairpin_cap_get,
.mtr_ops_get = mlx5_flow_meter_ops_get,
.hairpin_bind = mlx5_hairpin_bind,
.hairpin_unbind = mlx5_hairpin_unbind,
.hairpin_get_peer_ports = mlx5_hairpin_get_peer_ports,
.hairpin_queue_peer_update = mlx5_hairpin_queue_peer_update,
.hairpin_queue_peer_bind = mlx5_hairpin_queue_peer_bind,
.hairpin_queue_peer_unbind = mlx5_hairpin_queue_peer_unbind,
.get_monitor_addr = mlx5_get_monitor_addr,
};
/**
* Verify and store value for device argument.
*
* @param[in] key
* Key argument to verify.
* @param[in] val
* Value associated with key.
* @param opaque
* User data.
*
* @return
* 0 on success, a negative errno value otherwise and rte_errno is set.
*/
static int
mlx5_port_args_check_handler(const char *key, const char *val, void *opaque)
{
struct mlx5_port_config *config = opaque;
signed long tmp;
/* No-op, port representors are processed in mlx5_dev_spawn(). */
if (!strcmp(MLX5_REPRESENTOR, key))
return 0;
net/mlx5: handle Rx CQE compression Mini (compressed) completion queue entries (CQEs) are returned by the NIC when PCI back pressure is detected, in which case the first CQE64 contains common packet information followed by a number of CQE8 providing the rest, followed by a matching number of empty CQE64 entries to be used by software for decompression. Before decompression: 0 1 2 6 7 8 +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | |-------| |---------| |-------| |-------| |-------| |-------| | ..... | | cqe8[0] | | | . | | | | | ..... | | ..... | | cqe8[1] | | | . | | | | | ..... | | ..... | | ....... | | | . | | | | | ..... | | ..... | | cqe8[7] | | | | | | | | ..... | +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ After decompression: 0 1 ... 8 +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | |-------| |-------| |-------| | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | | ..... | +-------+ +-------+ +-------+ This patch does not perform the entire decompression step as it would be really expensive, instead the first CQE64 is consumed and an internal context is maintained to interpret the following CQE8 entries directly. Intermediate empty CQE64 entries are handed back to HW without further processing. Signed-off-by: Nelio Laranjeiro <nelio.laranjeiro@6wind.com> Signed-off-by: Adrien Mazarguil <adrien.mazarguil@6wind.com> Signed-off-by: Olga Shern <olgas@mellanox.com> Signed-off-by: Vasily Philipov <vasilyf@mellanox.com>
2016-06-24 13:17:54 +00:00
errno = 0;
tmp = strtol(val, NULL, 0);
net/mlx5: handle Rx CQE compression Mini (compressed) completion queue entries (CQEs) are returned by the NIC when PCI back pressure is detected, in which case the first CQE64 contains common packet information followed by a number of CQE8 providing the rest, followed by a matching number of empty CQE64 entries to be used by software for decompression. Before decompression: 0 1 2 6 7 8 +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | |-------| |---------| |-------| |-------| |-------| |-------| | ..... | | cqe8[0] | | | . | | | | | ..... | | ..... | | cqe8[1] | | | . | | | | | ..... | | ..... | | ....... | | | . | | | | | ..... | | ..... | | cqe8[7] | | | | | | | | ..... | +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ After decompression: 0 1 ... 8 +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | |-------| |-------| |-------| | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | | ..... | +-------+ +-------+ +-------+ This patch does not perform the entire decompression step as it would be really expensive, instead the first CQE64 is consumed and an internal context is maintained to interpret the following CQE8 entries directly. Intermediate empty CQE64 entries are handed back to HW without further processing. Signed-off-by: Nelio Laranjeiro <nelio.laranjeiro@6wind.com> Signed-off-by: Adrien Mazarguil <adrien.mazarguil@6wind.com> Signed-off-by: Olga Shern <olgas@mellanox.com> Signed-off-by: Vasily Philipov <vasilyf@mellanox.com>
2016-06-24 13:17:54 +00:00
if (errno) {
rte_errno = errno;
DRV_LOG(WARNING, "%s: \"%s\" is not a valid integer", key, val);
return -rte_errno;
net/mlx5: handle Rx CQE compression Mini (compressed) completion queue entries (CQEs) are returned by the NIC when PCI back pressure is detected, in which case the first CQE64 contains common packet information followed by a number of CQE8 providing the rest, followed by a matching number of empty CQE64 entries to be used by software for decompression. Before decompression: 0 1 2 6 7 8 +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | |-------| |---------| |-------| |-------| |-------| |-------| | ..... | | cqe8[0] | | | . | | | | | ..... | | ..... | | cqe8[1] | | | . | | | | | ..... | | ..... | | ....... | | | . | | | | | ..... | | ..... | | cqe8[7] | | | | | | | | ..... | +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ After decompression: 0 1 ... 8 +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | |-------| |-------| |-------| | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | | ..... | +-------+ +-------+ +-------+ This patch does not perform the entire decompression step as it would be really expensive, instead the first CQE64 is consumed and an internal context is maintained to interpret the following CQE8 entries directly. Intermediate empty CQE64 entries are handed back to HW without further processing. Signed-off-by: Nelio Laranjeiro <nelio.laranjeiro@6wind.com> Signed-off-by: Adrien Mazarguil <adrien.mazarguil@6wind.com> Signed-off-by: Olga Shern <olgas@mellanox.com> Signed-off-by: Vasily Philipov <vasilyf@mellanox.com>
2016-06-24 13:17:54 +00:00
}
if (tmp < 0) {
/* Negative values are acceptable for some keys only. */
rte_errno = EINVAL;
DRV_LOG(WARNING, "%s: invalid negative value \"%s\"", key, val);
return -rte_errno;
}
net/mlx5: handle Rx CQE compression Mini (compressed) completion queue entries (CQEs) are returned by the NIC when PCI back pressure is detected, in which case the first CQE64 contains common packet information followed by a number of CQE8 providing the rest, followed by a matching number of empty CQE64 entries to be used by software for decompression. Before decompression: 0 1 2 6 7 8 +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | |-------| |---------| |-------| |-------| |-------| |-------| | ..... | | cqe8[0] | | | . | | | | | ..... | | ..... | | cqe8[1] | | | . | | | | | ..... | | ..... | | ....... | | | . | | | | | ..... | | ..... | | cqe8[7] | | | | | | | | ..... | +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ After decompression: 0 1 ... 8 +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | |-------| |-------| |-------| | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | | ..... | +-------+ +-------+ +-------+ This patch does not perform the entire decompression step as it would be really expensive, instead the first CQE64 is consumed and an internal context is maintained to interpret the following CQE8 entries directly. Intermediate empty CQE64 entries are handed back to HW without further processing. Signed-off-by: Nelio Laranjeiro <nelio.laranjeiro@6wind.com> Signed-off-by: Adrien Mazarguil <adrien.mazarguil@6wind.com> Signed-off-by: Olga Shern <olgas@mellanox.com> Signed-off-by: Vasily Philipov <vasilyf@mellanox.com>
2016-06-24 13:17:54 +00:00
if (strcmp(MLX5_RXQ_CQE_COMP_EN, key) == 0) {
if (tmp > MLX5_CQE_RESP_FORMAT_L34H_STRIDX) {
DRV_LOG(ERR, "invalid CQE compression "
"format parameter");
rte_errno = EINVAL;
return -rte_errno;
}
config->cqe_comp = !!tmp;
config->cqe_comp_fmt = tmp;
} else if (strcmp(MLX5_RXQ_PKT_PAD_EN, key) == 0) {
config->hw_padding = !!tmp;
} else if (strcmp(MLX5_RX_MPRQ_EN, key) == 0) {
config->mprq.enabled = !!tmp;
} else if (strcmp(MLX5_RX_MPRQ_LOG_STRIDE_NUM, key) == 0) {
config->mprq.log_stride_num = tmp;
} else if (strcmp(MLX5_RX_MPRQ_LOG_STRIDE_SIZE, key) == 0) {
config->mprq.log_stride_size = tmp;
} else if (strcmp(MLX5_RX_MPRQ_MAX_MEMCPY_LEN, key) == 0) {
config->mprq.max_memcpy_len = tmp;
} else if (strcmp(MLX5_RXQS_MIN_MPRQ, key) == 0) {
config->mprq.min_rxqs_num = tmp;
} else if (strcmp(MLX5_TXQ_INLINE, key) == 0) {
DRV_LOG(WARNING, "%s: deprecated parameter,"
" converted to txq_inline_max", key);
config->txq_inline_max = tmp;
} else if (strcmp(MLX5_TXQ_INLINE_MAX, key) == 0) {
config->txq_inline_max = tmp;
} else if (strcmp(MLX5_TXQ_INLINE_MIN, key) == 0) {
config->txq_inline_min = tmp;
} else if (strcmp(MLX5_TXQ_INLINE_MPW, key) == 0) {
config->txq_inline_mpw = tmp;
} else if (strcmp(MLX5_TXQS_MIN_INLINE, key) == 0) {
config->txqs_inline = tmp;
} else if (strcmp(MLX5_TXQS_MAX_VEC, key) == 0) {
DRV_LOG(WARNING, "%s: deprecated parameter, ignored", key);
} else if (strcmp(MLX5_TXQ_MPW_EN, key) == 0) {
config->mps = !!tmp;
} else if (strcmp(MLX5_TXQ_MPW_HDR_DSEG_EN, key) == 0) {
DRV_LOG(WARNING, "%s: deprecated parameter, ignored", key);
} else if (strcmp(MLX5_TXQ_MAX_INLINE_LEN, key) == 0) {
DRV_LOG(WARNING, "%s: deprecated parameter,"
" converted to txq_inline_mpw", key);
config->txq_inline_mpw = tmp;
} else if (strcmp(MLX5_TX_VEC_EN, key) == 0) {
DRV_LOG(WARNING, "%s: deprecated parameter, ignored", key);
} else if (strcmp(MLX5_RX_VEC_EN, key) == 0) {
config->rx_vec_en = !!tmp;
} else if (strcmp(MLX5_MAX_DUMP_FILES_NUM, key) == 0) {
config->max_dump_files_num = tmp;
} else if (strcmp(MLX5_LRO_TIMEOUT_USEC, key) == 0) {
config->lro_timeout = tmp;
} else if (strcmp(MLX5_HP_BUF_SIZE, key) == 0) {
config->log_hp_size = tmp;
} else if (strcmp(MLX5_DELAY_DROP, key) == 0) {
config->std_delay_drop = !!(tmp & MLX5_DELAY_DROP_STANDARD);
config->hp_delay_drop = !!(tmp & MLX5_DELAY_DROP_HAIRPIN);
net/mlx5: handle Rx CQE compression Mini (compressed) completion queue entries (CQEs) are returned by the NIC when PCI back pressure is detected, in which case the first CQE64 contains common packet information followed by a number of CQE8 providing the rest, followed by a matching number of empty CQE64 entries to be used by software for decompression. Before decompression: 0 1 2 6 7 8 +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | | CQE64 | |-------| |---------| |-------| |-------| |-------| |-------| | ..... | | cqe8[0] | | | . | | | | | ..... | | ..... | | cqe8[1] | | | . | | | | | ..... | | ..... | | ....... | | | . | | | | | ..... | | ..... | | cqe8[7] | | | | | | | | ..... | +-------+ +---------+ +-------+ +-------+ +-------+ +-------+ After decompression: 0 1 ... 8 +-------+ +-------+ +-------+ | CQE64 | | CQE64 | | CQE64 | |-------| |-------| |-------| | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | . | ..... | | ..... | | ..... | | ..... | +-------+ +-------+ +-------+ This patch does not perform the entire decompression step as it would be really expensive, instead the first CQE64 is consumed and an internal context is maintained to interpret the following CQE8 entries directly. Intermediate empty CQE64 entries are handed back to HW without further processing. Signed-off-by: Nelio Laranjeiro <nelio.laranjeiro@6wind.com> Signed-off-by: Adrien Mazarguil <adrien.mazarguil@6wind.com> Signed-off-by: Olga Shern <olgas@mellanox.com> Signed-off-by: Vasily Philipov <vasilyf@mellanox.com>
2016-06-24 13:17:54 +00:00
}
return 0;
}
/**
* Parse user port parameters and adjust them according to device capabilities.
*
* @param priv
* Pointer to shared device context.
* @param mkvlist
* Pointer to mlx5 kvargs control, can be NULL if there is no devargs.
* @param config
* Pointer to port configuration structure.
*
* @return
* 0 on success, a negative errno value otherwise and rte_errno is set.
*/
int
mlx5_port_args_config(struct mlx5_priv *priv, struct mlx5_kvargs_ctrl *mkvlist,
struct mlx5_port_config *config)
{
struct mlx5_hca_attr *hca_attr = &priv->sh->cdev->config.hca_attr;
struct mlx5_dev_cap *dev_cap = &priv->sh->dev_cap;
bool devx = priv->sh->cdev->config.devx;
const char **params = (const char *[]){
MLX5_RXQ_CQE_COMP_EN,
MLX5_RXQ_PKT_PAD_EN,
MLX5_RX_MPRQ_EN,
MLX5_RX_MPRQ_LOG_STRIDE_NUM,
MLX5_RX_MPRQ_LOG_STRIDE_SIZE,
MLX5_RX_MPRQ_MAX_MEMCPY_LEN,
MLX5_RXQS_MIN_MPRQ,
MLX5_TXQ_INLINE,
MLX5_TXQ_INLINE_MIN,
MLX5_TXQ_INLINE_MAX,
MLX5_TXQ_INLINE_MPW,
MLX5_TXQS_MIN_INLINE,
MLX5_TXQS_MAX_VEC,
MLX5_TXQ_MPW_EN,
MLX5_TXQ_MPW_HDR_DSEG_EN,
MLX5_TXQ_MAX_INLINE_LEN,
MLX5_TX_VEC_EN,
MLX5_RX_VEC_EN,
MLX5_REPRESENTOR,
MLX5_MAX_DUMP_FILES_NUM,
MLX5_LRO_TIMEOUT_USEC,
MLX5_HP_BUF_SIZE,
MLX5_DELAY_DROP,
NULL,
};
int ret = 0;
/* Default configuration. */
memset(config, 0, sizeof(*config));
config->mps = MLX5_ARG_UNSET;
config->cqe_comp = 1;
config->rx_vec_en = 1;
config->txq_inline_max = MLX5_ARG_UNSET;
config->txq_inline_min = MLX5_ARG_UNSET;
config->txq_inline_mpw = MLX5_ARG_UNSET;
config->txqs_inline = MLX5_ARG_UNSET;
config->mprq.max_memcpy_len = MLX5_MPRQ_MEMCPY_DEFAULT_LEN;
config->mprq.min_rxqs_num = MLX5_MPRQ_MIN_RXQS;
config->mprq.log_stride_num = MLX5_MPRQ_DEFAULT_LOG_STRIDE_NUM;
config->log_hp_size = MLX5_ARG_UNSET;
config->std_delay_drop = 0;
config->hp_delay_drop = 0;
if (mkvlist != NULL) {
/* Process parameters. */
ret = mlx5_kvargs_process(mkvlist, params,
mlx5_port_args_check_handler, config);
if (ret) {
DRV_LOG(ERR, "Failed to process port arguments: %s",
strerror(rte_errno));
return -rte_errno;
}
}
/* Adjust parameters according to device capabilities. */
if (config->hw_padding && !dev_cap->hw_padding) {
DRV_LOG(DEBUG, "Rx end alignment padding isn't supported.");
config->hw_padding = 0;
} else if (config->hw_padding) {
DRV_LOG(DEBUG, "Rx end alignment padding is enabled.");
}
/*
* MPW is disabled by default, while the Enhanced MPW is enabled
* by default.
*/
if (config->mps == MLX5_ARG_UNSET)
config->mps = (dev_cap->mps == MLX5_MPW_ENHANCED) ?
MLX5_MPW_ENHANCED : MLX5_MPW_DISABLED;
else
config->mps = config->mps ? dev_cap->mps : MLX5_MPW_DISABLED;
DRV_LOG(INFO, "%sMPS is %s",
config->mps == MLX5_MPW_ENHANCED ? "enhanced " :
config->mps == MLX5_MPW ? "legacy " : "",
config->mps != MLX5_MPW_DISABLED ? "enabled" : "disabled");
if (priv->sh->config.lro_allowed) {
/*
* If LRO timeout is not configured by application,
* use the minimal supported value.
*/
if (!config->lro_timeout)
config->lro_timeout =
hca_attr->lro_timer_supported_periods[0];
DRV_LOG(DEBUG, "LRO session timeout set to %d usec.",
config->lro_timeout);
}
if (config->cqe_comp && !dev_cap->cqe_comp) {
DRV_LOG(WARNING, "Rx CQE 128B compression is not supported.");
config->cqe_comp = 0;
}
if (config->cqe_comp_fmt == MLX5_CQE_RESP_FORMAT_FTAG_STRIDX &&
(!devx || !hca_attr->mini_cqe_resp_flow_tag)) {
DRV_LOG(WARNING,
"Flow Tag CQE compression format isn't supported.");
config->cqe_comp = 0;
}
if (config->cqe_comp_fmt == MLX5_CQE_RESP_FORMAT_L34H_STRIDX &&
(!devx || !hca_attr->mini_cqe_resp_l3_l4_tag)) {
DRV_LOG(WARNING,
"L3/L4 Header CQE compression format isn't supported.");
config->cqe_comp = 0;
}
DRV_LOG(DEBUG, "Rx CQE compression is %ssupported.",
config->cqe_comp ? "" : "not ");
if ((config->std_delay_drop || config->hp_delay_drop) &&
!dev_cap->rq_delay_drop_en) {
config->std_delay_drop = 0;
config->hp_delay_drop = 0;
DRV_LOG(WARNING, "dev_port-%u: Rxq delay drop isn't supported.",
priv->dev_port);
}
if (config->mprq.enabled && !priv->sh->dev_cap.mprq.enabled) {
DRV_LOG(WARNING, "Multi-Packet RQ isn't supported.");
config->mprq.enabled = 0;
}
if (config->max_dump_files_num == 0)
config->max_dump_files_num = 128;
/* Detect minimal data bytes to inline. */
mlx5_set_min_inline(priv);
DRV_LOG(DEBUG, "VLAN insertion in WQE is %ssupported.",
config->hw_vlan_insert ? "" : "not ");
DRV_LOG(DEBUG, "\"rxq_pkt_pad_en\" is %u.", config->hw_padding);
DRV_LOG(DEBUG, "\"rxq_cqe_comp_en\" is %u.", config->cqe_comp);
DRV_LOG(DEBUG, "\"cqe_comp_fmt\" is %u.", config->cqe_comp_fmt);
DRV_LOG(DEBUG, "\"rx_vec_en\" is %u.", config->rx_vec_en);
DRV_LOG(DEBUG, "Standard \"delay_drop\" is %u.",
config->std_delay_drop);
DRV_LOG(DEBUG, "Hairpin \"delay_drop\" is %u.", config->hp_delay_drop);
DRV_LOG(DEBUG, "\"max_dump_files_num\" is %u.",
config->max_dump_files_num);
DRV_LOG(DEBUG, "\"log_hp_size\" is %u.", config->log_hp_size);
DRV_LOG(DEBUG, "\"mprq_en\" is %u.", config->mprq.enabled);
DRV_LOG(DEBUG, "\"mprq_log_stride_num\" is %u.",
config->mprq.log_stride_num);
DRV_LOG(DEBUG, "\"mprq_log_stride_size\" is %u.",
config->mprq.log_stride_size);
DRV_LOG(DEBUG, "\"mprq_max_memcpy_len\" is %u.",
config->mprq.max_memcpy_len);
DRV_LOG(DEBUG, "\"rxqs_min_mprq\" is %u.", config->mprq.min_rxqs_num);
DRV_LOG(DEBUG, "\"lro_timeout_usec\" is %u.", config->lro_timeout);
DRV_LOG(DEBUG, "\"txq_mpw_en\" is %d.", config->mps);
DRV_LOG(DEBUG, "\"txqs_min_inline\" is %d.", config->txqs_inline);
DRV_LOG(DEBUG, "\"txq_inline_min\" is %d.", config->txq_inline_min);
DRV_LOG(DEBUG, "\"txq_inline_max\" is %d.", config->txq_inline_max);
DRV_LOG(DEBUG, "\"txq_inline_mpw\" is %d.", config->txq_inline_mpw);
return 0;
}
/**
* Print the key for device argument.
*
* It is "dummy" handler whose whole purpose is to enable using
* mlx5_kvargs_process() function which set devargs as used.
*
* @param key
* Key argument.
* @param val
* Value associated with key, unused.
* @param opaque
* Unused, can be NULL.
*
* @return
* 0 on success, function cannot fail.
*/
static int
mlx5_dummy_handler(const char *key, const char *val, void *opaque)
{
DRV_LOG(DEBUG, "\tKey: \"%s\" is set as used.", key);
RTE_SET_USED(opaque);
RTE_SET_USED(val);
return 0;
}
/**
* Set requested devargs as used when device is already spawned.
*
* It is necessary since it is valid to ask probe again for existing device,
* if its devargs don't assign as used, mlx5_kvargs_validate() will fail.
*
* @param name
* Name of the existing device.
* @param port_id
* Port identifier of the device.
* @param mkvlist
* Pointer to mlx5 kvargs control to sign as used.
*/
void
mlx5_port_args_set_used(const char *name, uint16_t port_id,
struct mlx5_kvargs_ctrl *mkvlist)
{
const char **params = (const char *[]){
MLX5_RXQ_CQE_COMP_EN,
MLX5_RXQ_PKT_PAD_EN,
MLX5_RX_MPRQ_EN,
MLX5_RX_MPRQ_LOG_STRIDE_NUM,
MLX5_RX_MPRQ_LOG_STRIDE_SIZE,
MLX5_RX_MPRQ_MAX_MEMCPY_LEN,
MLX5_RXQS_MIN_MPRQ,
MLX5_TXQ_INLINE,
MLX5_TXQ_INLINE_MIN,
MLX5_TXQ_INLINE_MAX,
MLX5_TXQ_INLINE_MPW,
MLX5_TXQS_MIN_INLINE,
MLX5_TXQS_MAX_VEC,
MLX5_TXQ_MPW_EN,
MLX5_TXQ_MPW_HDR_DSEG_EN,
MLX5_TXQ_MAX_INLINE_LEN,
MLX5_TX_VEC_EN,
MLX5_RX_VEC_EN,
MLX5_REPRESENTOR,
MLX5_MAX_DUMP_FILES_NUM,
MLX5_LRO_TIMEOUT_USEC,
MLX5_HP_BUF_SIZE,
MLX5_DELAY_DROP,
NULL,
};
/* Secondary process should not handle devargs. */
if (rte_eal_process_type() != RTE_PROC_PRIMARY)
return;
MLX5_ASSERT(mkvlist != NULL);
DRV_LOG(DEBUG, "Ethernet device \"%s\" for port %u "
"already exists, set devargs as used:", name, port_id);
/* This function cannot fail with this handler. */
mlx5_kvargs_process(mkvlist, params, mlx5_dummy_handler, NULL);
}
/**
* Check sibling device configurations when probing again.
*
* Sibling devices sharing infiniband device context should have compatible
* configurations. This regards representors and bonding device.
*
* @param cdev
* Pointer to mlx5 device structure.
* @param mkvlist
* Pointer to mlx5 kvargs control, can be NULL if there is no devargs.
*
* @return
* 0 on success, a negative errno value otherwise and rte_errno is set.
*/
int
mlx5_probe_again_args_validate(struct mlx5_common_device *cdev,
struct mlx5_kvargs_ctrl *mkvlist)
{
struct mlx5_dev_ctx_shared *sh = NULL;
struct mlx5_sh_config *config;
int ret;
/* Secondary process should not handle devargs. */
if (rte_eal_process_type() != RTE_PROC_PRIMARY)
return 0;
pthread_mutex_lock(&mlx5_dev_ctx_list_mutex);
/* Search for IB context by common device pointer. */
LIST_FOREACH(sh, &mlx5_dev_ctx_list, next)
if (sh->cdev == cdev)
break;
pthread_mutex_unlock(&mlx5_dev_ctx_list_mutex);
/* There is sh for this device -> it isn't probe again. */
if (sh == NULL)
return 0;
config = mlx5_malloc(MLX5_MEM_ZERO | MLX5_MEM_RTE,
sizeof(struct mlx5_sh_config),
RTE_CACHE_LINE_SIZE, SOCKET_ID_ANY);
if (config == NULL) {
rte_errno = -ENOMEM;
return -rte_errno;
}
/*
* Creates a temporary IB context configure structure according to new
* devargs attached in probing again.
*/
ret = mlx5_shared_dev_ctx_args_config(sh, mkvlist, config);
if (ret) {
DRV_LOG(ERR, "Failed to process device configure: %s",
strerror(rte_errno));
mlx5_free(config);
return ret;
}
/*
* Checks the match between the temporary structure and the existing
* IB context structure.
*/
if (sh->config.dv_flow_en ^ config->dv_flow_en) {
DRV_LOG(ERR, "\"dv_flow_en\" "
"configuration mismatch for shared %s context.",
sh->ibdev_name);
goto error;
}
if ((sh->config.dv_xmeta_en ^ config->dv_xmeta_en) ||
(sh->config.dv_miss_info ^ config->dv_miss_info)) {
DRV_LOG(ERR, "\"dv_xmeta_en\" "
"configuration mismatch for shared %s context.",
sh->ibdev_name);
goto error;
}
if (sh->config.dv_esw_en ^ config->dv_esw_en) {
DRV_LOG(ERR, "\"dv_esw_en\" "
"configuration mismatch for shared %s context.",
sh->ibdev_name);
goto error;
}
if (sh->config.reclaim_mode ^ config->reclaim_mode) {
DRV_LOG(ERR, "\"reclaim_mode\" "
"configuration mismatch for shared %s context.",
sh->ibdev_name);
goto error;
}
if (sh->config.allow_duplicate_pattern ^
config->allow_duplicate_pattern) {
DRV_LOG(ERR, "\"allow_duplicate_pattern\" "
"configuration mismatch for shared %s context.",
sh->ibdev_name);
goto error;
}
if (sh->config.fdb_def_rule ^ config->fdb_def_rule) {
DRV_LOG(ERR, "\"fdb_def_rule_en\" configuration mismatch for shared %s context.",
sh->ibdev_name);
goto error;
}
if (sh->config.l3_vxlan_en ^ config->l3_vxlan_en) {
DRV_LOG(ERR, "\"l3_vxlan_en\" "
"configuration mismatch for shared %s context.",
sh->ibdev_name);
goto error;
}
if (sh->config.decap_en ^ config->decap_en) {
DRV_LOG(ERR, "\"decap_en\" "
"configuration mismatch for shared %s context.",
sh->ibdev_name);
goto error;
}
if (sh->config.lacp_by_user ^ config->lacp_by_user) {
DRV_LOG(ERR, "\"lacp_by_user\" "
"configuration mismatch for shared %s context.",
sh->ibdev_name);
goto error;
}
if (sh->config.tx_pp ^ config->tx_pp) {
DRV_LOG(ERR, "\"tx_pp\" "
"configuration mismatch for shared %s context.",
sh->ibdev_name);
goto error;
}
if (sh->config.tx_skew ^ config->tx_skew) {
DRV_LOG(ERR, "\"tx_skew\" "
"configuration mismatch for shared %s context.",
sh->ibdev_name);
goto error;
}
mlx5_free(config);
return 0;
error:
mlx5_free(config);
rte_errno = EINVAL;
return -rte_errno;
}
/**
* Configures the minimal amount of data to inline into WQE
* while sending packets.
*
* - the txq_inline_min has the maximal priority, if this
* key is specified in devargs
* - if DevX is enabled the inline mode is queried from the
* device (HCA attributes and NIC vport context if needed).
* - otherwise L2 mode (18 bytes) is assumed for ConnectX-4/4 Lx
* and none (0 bytes) for other NICs
*
* @param priv
* Pointer to the private device data structure.
*/
void
mlx5_set_min_inline(struct mlx5_priv *priv)
{
struct mlx5_hca_attr *hca_attr = &priv->sh->cdev->config.hca_attr;
struct mlx5_port_config *config = &priv->config;
if (config->txq_inline_min != MLX5_ARG_UNSET) {
/* Application defines size of inlined data explicitly. */
if (priv->pci_dev != NULL) {
switch (priv->pci_dev->id.device_id) {
case PCI_DEVICE_ID_MELLANOX_CONNECTX4:
case PCI_DEVICE_ID_MELLANOX_CONNECTX4VF:
if (config->txq_inline_min <
(int)MLX5_INLINE_HSIZE_L2) {
DRV_LOG(DEBUG,
"txq_inline_mix aligned to minimal ConnectX-4 required value %d",
(int)MLX5_INLINE_HSIZE_L2);
config->txq_inline_min =
MLX5_INLINE_HSIZE_L2;
}
break;
}
}
goto exit;
}
if (hca_attr->eth_net_offloads) {
/* We have DevX enabled, inline mode queried successfully. */
switch (hca_attr->wqe_inline_mode) {
case MLX5_CAP_INLINE_MODE_L2:
/* outer L2 header must be inlined. */
config->txq_inline_min = MLX5_INLINE_HSIZE_L2;
goto exit;
case MLX5_CAP_INLINE_MODE_NOT_REQUIRED:
/* No inline data are required by NIC. */
config->txq_inline_min = MLX5_INLINE_HSIZE_NONE;
config->hw_vlan_insert =
hca_attr->wqe_vlan_insert;
DRV_LOG(DEBUG, "Tx VLAN insertion is supported");
goto exit;
case MLX5_CAP_INLINE_MODE_VPORT_CONTEXT:
/* inline mode is defined by NIC vport context. */
if (!hca_attr->eth_virt)
break;
switch (hca_attr->vport_inline_mode) {
case MLX5_INLINE_MODE_NONE:
config->txq_inline_min =
MLX5_INLINE_HSIZE_NONE;
goto exit;
case MLX5_INLINE_MODE_L2:
config->txq_inline_min =
MLX5_INLINE_HSIZE_L2;
goto exit;
case MLX5_INLINE_MODE_IP:
config->txq_inline_min =
MLX5_INLINE_HSIZE_L3;
goto exit;
case MLX5_INLINE_MODE_TCP_UDP:
config->txq_inline_min =
MLX5_INLINE_HSIZE_L4;
goto exit;
case MLX5_INLINE_MODE_INNER_L2:
config->txq_inline_min =
MLX5_INLINE_HSIZE_INNER_L2;
goto exit;
case MLX5_INLINE_MODE_INNER_IP:
config->txq_inline_min =
MLX5_INLINE_HSIZE_INNER_L3;
goto exit;
case MLX5_INLINE_MODE_INNER_TCP_UDP:
config->txq_inline_min =
MLX5_INLINE_HSIZE_INNER_L4;
goto exit;
}
}
}
if (priv->pci_dev == NULL) {
config->txq_inline_min = MLX5_INLINE_HSIZE_NONE;
goto exit;
}
/*
* We get here if we are unable to deduce
* inline data size with DevX. Try PCI ID
* to determine old NICs.
*/
switch (priv->pci_dev->id.device_id) {
case PCI_DEVICE_ID_MELLANOX_CONNECTX4:
case PCI_DEVICE_ID_MELLANOX_CONNECTX4VF:
case PCI_DEVICE_ID_MELLANOX_CONNECTX4LX:
case PCI_DEVICE_ID_MELLANOX_CONNECTX4LXVF:
config->txq_inline_min = MLX5_INLINE_HSIZE_L2;
config->hw_vlan_insert = 0;
break;
case PCI_DEVICE_ID_MELLANOX_CONNECTX5:
case PCI_DEVICE_ID_MELLANOX_CONNECTX5VF:
case PCI_DEVICE_ID_MELLANOX_CONNECTX5EX:
case PCI_DEVICE_ID_MELLANOX_CONNECTX5EXVF:
/*
* These NICs support VLAN insertion from WQE and
* report the wqe_vlan_insert flag. But there is the bug
* and PFC control may be broken, so disable feature.
*/
config->hw_vlan_insert = 0;
config->txq_inline_min = MLX5_INLINE_HSIZE_NONE;
break;
default:
config->txq_inline_min = MLX5_INLINE_HSIZE_NONE;
break;
}
exit:
DRV_LOG(DEBUG, "min tx inline configured: %d", config->txq_inline_min);
}
/**
* Configures the metadata mask fields in the shared context.
*
* @param [in] dev
* Pointer to Ethernet device.
*/
void
mlx5_set_metadata_mask(struct rte_eth_dev *dev)
{
struct mlx5_priv *priv = dev->data->dev_private;
struct mlx5_dev_ctx_shared *sh = priv->sh;
uint32_t meta, mark, reg_c0;
reg_c0 = ~priv->vport_meta_mask;
switch (sh->config.dv_xmeta_en) {
case MLX5_XMETA_MODE_LEGACY:
meta = UINT32_MAX;
mark = MLX5_FLOW_MARK_MASK;
break;
case MLX5_XMETA_MODE_META16:
meta = reg_c0 >> rte_bsf32(reg_c0);
mark = MLX5_FLOW_MARK_MASK;
break;
case MLX5_XMETA_MODE_META32:
meta = UINT32_MAX;
mark = (reg_c0 >> rte_bsf32(reg_c0)) & MLX5_FLOW_MARK_MASK;
break;
default:
meta = 0;
mark = 0;
MLX5_ASSERT(false);
break;
}
if (sh->dv_mark_mask && sh->dv_mark_mask != mark)
DRV_LOG(WARNING, "metadata MARK mask mismatch %08X:%08X",
sh->dv_mark_mask, mark);
else
sh->dv_mark_mask = mark;
if (sh->dv_meta_mask && sh->dv_meta_mask != meta)
DRV_LOG(WARNING, "metadata META mask mismatch %08X:%08X",
sh->dv_meta_mask, meta);
else
sh->dv_meta_mask = meta;
if (sh->dv_regc0_mask && sh->dv_regc0_mask != reg_c0)
DRV_LOG(WARNING, "metadata reg_c0 mask mismatch %08X:%08X",
sh->dv_meta_mask, reg_c0);
else
sh->dv_regc0_mask = reg_c0;
DRV_LOG(DEBUG, "metadata mode %u", sh->config.dv_xmeta_en);
DRV_LOG(DEBUG, "metadata MARK mask %08X", sh->dv_mark_mask);
DRV_LOG(DEBUG, "metadata META mask %08X", sh->dv_meta_mask);
DRV_LOG(DEBUG, "metadata reg_c0 mask %08X", sh->dv_regc0_mask);
}
int
rte_pmd_mlx5_get_dyn_flag_names(char *names[], unsigned int n)
{
static const char *const dynf_names[] = {
RTE_PMD_MLX5_FINE_GRANULARITY_INLINE,
RTE_MBUF_DYNFLAG_METADATA_NAME,
RTE_MBUF_DYNFLAG_TX_TIMESTAMP_NAME
};
unsigned int i;
if (n < RTE_DIM(dynf_names))
return -ENOMEM;
for (i = 0; i < RTE_DIM(dynf_names); i++) {
if (names[i] == NULL)
return -EINVAL;
strcpy(names[i], dynf_names[i]);
}
return RTE_DIM(dynf_names);
}
/**
* Look for the ethernet device belonging to mlx5 driver.
*
* @param[in] port_id
* port_id to start looking for device.
* @param[in] odev
* Pointer to the hint device. When device is being probed
* the its siblings (master and preceding representors might
* not have assigned driver yet (because the mlx5_os_pci_probe()
* is not completed yet, for this case match on hint
* device may be used to detect sibling device.
*
* @return
* port_id of found device, RTE_MAX_ETHPORT if not found.
*/
uint16_t
mlx5_eth_find_next(uint16_t port_id, struct rte_device *odev)
{
while (port_id < RTE_MAX_ETHPORTS) {
struct rte_eth_dev *dev = &rte_eth_devices[port_id];
if (dev->state != RTE_ETH_DEV_UNUSED &&
dev->device &&
(dev->device == odev ||
(dev->device->driver &&
dev->device->driver->name &&
((strcmp(dev->device->driver->name,
MLX5_PCI_DRIVER_NAME) == 0) ||
(strcmp(dev->device->driver->name,
MLX5_AUXILIARY_DRIVER_NAME) == 0)))))
break;
port_id++;
}
if (port_id >= RTE_MAX_ETHPORTS)
return RTE_MAX_ETHPORTS;
return port_id;
}
/**
* Callback to remove a device.
*
* This function removes all Ethernet devices belong to a given device.
*
* @param[in] cdev
* Pointer to the generic device.
*
* @return
* 0 on success, the function cannot fail.
*/
int
mlx5_net_remove(struct mlx5_common_device *cdev)
{
uint16_t port_id;
int ret = 0;
RTE_ETH_FOREACH_DEV_OF(port_id, cdev->dev) {
/*
* mlx5_dev_close() is not registered to secondary process,
* call the close function explicitly for secondary process.
*/
if (rte_eal_process_type() == RTE_PROC_SECONDARY)
ret |= mlx5_dev_close(&rte_eth_devices[port_id]);
else
ret |= rte_eth_dev_close(port_id);
}
return ret == 0 ? 0 : -EIO;
}
static const struct rte_pci_id mlx5_pci_id_map[] = {
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX4)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX4VF)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX4LX)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX4LXVF)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX5)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX5VF)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX5EX)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX5EXVF)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX5BF)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX5BFVF)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX6)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX6VF)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX6DX)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTXVF)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX6DXBF)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX6LX)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX7)
},
{
RTE_PCI_DEVICE(PCI_VENDOR_ID_MELLANOX,
PCI_DEVICE_ID_MELLANOX_CONNECTX7BF)
},
{
.vendor_id = 0
}
};
static struct mlx5_class_driver mlx5_net_driver = {
.drv_class = MLX5_CLASS_ETH,
.name = RTE_STR(MLX5_ETH_DRIVER_NAME),
.id_table = mlx5_pci_id_map,
.probe = mlx5_os_net_probe,
.remove = mlx5_net_remove,
.probe_again = 1,
.intr_lsc = 1,
.intr_rmv = 1,
};
/* Initialize driver log type. */
log: register with standardized names Let's try to enforce the convention where most drivers use a pmd. logtype with their class reflected in it, and libraries use a lib. logtype. Introduce two new macros: - RTE_LOG_REGISTER_DEFAULT can be used when a single logtype is used in a component. It is associated to the default name provided by the build system, - RTE_LOG_REGISTER_SUFFIX can be used when multiple logtypes are used, and then the passed name is appended to the default name, RTE_LOG_REGISTER is left untouched for existing external users and for components that do not comply with the convention. There is a new Meson variable log_prefix to adapt the default name for baseband (pmd.bb.), bus (no pmd.) and mempool (no pmd.) classes. Note: achieved with below commands + reverted change on net/bonding + edits on crypto/virtio, compress/mlx5, regex/mlx5 $ git grep -l RTE_LOG_REGISTER drivers/ | while read file; do pattern=${file##drivers/}; class=${pattern%%/*}; pattern=${pattern#$class/}; drv=${pattern%%/*}; case "$class" in baseband) pattern=pmd.bb.$drv;; bus) pattern=bus.$drv;; mempool) pattern=mempool.$drv;; *) pattern=pmd.$class.$drv;; esac sed -i -e 's/RTE_LOG_REGISTER(\(.*\), '$pattern',/RTE_LOG_REGISTER_DEFAULT(\1,/' $file; sed -i -e 's/RTE_LOG_REGISTER(\(.*\), '$pattern'\.\(.*\),/RTE_LOG_REGISTER_SUFFIX(\1, \2,/' $file; done $ git grep -l RTE_LOG_REGISTER lib/ | while read file; do pattern=${file##lib/}; pattern=lib.${pattern%%/*}; sed -i -e 's/RTE_LOG_REGISTER(\(.*\), '$pattern',/RTE_LOG_REGISTER_DEFAULT(\1,/' $file; sed -i -e 's/RTE_LOG_REGISTER(\(.*\), '$pattern'\.\(.*\),/RTE_LOG_REGISTER_SUFFIX(\1, \2,/' $file; done Signed-off-by: David Marchand <david.marchand@redhat.com> Signed-off-by: Thomas Monjalon <thomas@monjalon.net> Acked-by: Bruce Richardson <bruce.richardson@intel.com>
2021-04-26 12:51:08 +00:00
RTE_LOG_REGISTER_DEFAULT(mlx5_logtype, NOTICE)
/**
* Driver initialization routine.
*/
RTE_INIT(rte_mlx5_pmd_init)
{
pthread_mutex_init(&mlx5_dev_ctx_list_mutex, NULL);
mlx5_common_init();
/* Build the static tables for Verbs conversion. */
mlx5_set_ptype_table();
mlx5_set_cksum_table();
mlx5_set_swp_types_table();
if (mlx5_glue)
mlx5_class_driver_register(&mlx5_net_driver);
}
RTE_PMD_EXPORT_NAME(MLX5_ETH_DRIVER_NAME, __COUNTER__);
RTE_PMD_REGISTER_PCI_TABLE(MLX5_ETH_DRIVER_NAME, mlx5_pci_id_map);
RTE_PMD_REGISTER_KMOD_DEP(MLX5_ETH_DRIVER_NAME, "* ib_uverbs & mlx5_core & mlx5_ib");