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numam-dpdk/drivers/net/sfc/sfc_rx.c
Wei Dai a4996bd89c ethdev: new Rx/Tx offloads API 
This patch check if a input requested offloading is valid or not.
Any reuqested offloading must be supported in the device capabilities.
Any offloading is disabled by default if it is not set in the parameter
dev_conf->[rt]xmode.offloads to rte_eth_dev_configure() and
[rt]x_conf->offloads to rte_eth_[rt]x_queue_setup().
If any offloading is enabled in rte_eth_dev_configure() by application,
it is enabled on all queues no matter whether it is per-queue or
per-port type and no matter whether it is set or cleared in
[rt]x_conf->offloads to rte_eth_[rt]x_queue_setup().
If a per-queue offloading hasn't be enabled in rte_eth_dev_configure(),
it can be enabled or disabled for individual queue in
ret_eth_[rt]x_queue_setup().
A new added offloading is the one which hasn't been enabled in
rte_eth_dev_configure() and is reuqested to be enabled in
rte_eth_[rt]x_queue_setup(), it must be per-queue type,
otherwise trigger an error log.
The underlying PMD must be aware that the requested offloadings
to PMD specific queue_setup() function only carries those
new added offloadings of per-queue type.

This patch can make above such checking in a common way in rte_ethdev
layer to avoid same checking in underlying PMD.

This patch assumes that all PMDs in 18.05-rc2 have already
converted to offload API defined in 17.11 . It also assumes
that all PMDs can return correct offloading capabilities
in rte_eth_dev_infos_get().

In the beginning of [rt]x_queue_setup() of underlying PMD,
add offloads = [rt]xconf->offloads |
dev->data->dev_conf.[rt]xmode.offloads; to keep same as offload API
defined in 17.11 to avoid upper application broken due to offload
API change.
PMD can use the info that input [rt]xconf->offloads only carry
the new added per-queue offloads to do some optimization or some
code change on base of this patch.

Signed-off-by: Wei Dai <wei.dai@intel.com>
Signed-off-by: Ferruh Yigit <ferruh.yigit@intel.com>
Signed-off-by: Qi Zhang <qi.z.zhang@intel.com>
2018-05-14 22:31:51 +01:00

1583 lines
38 KiB
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/* SPDX-License-Identifier: BSD-3-Clause
*
* Copyright (c) 2016-2018 Solarflare Communications Inc.
* All rights reserved.
*
* This software was jointly developed between OKTET Labs (under contract
* for Solarflare) and Solarflare Communications, Inc.
*/
#include <rte_mempool.h>
#include "efx.h"
#include "sfc.h"
#include "sfc_debug.h"
#include "sfc_log.h"
#include "sfc_ev.h"
#include "sfc_rx.h"
#include "sfc_kvargs.h"
#include "sfc_tweak.h"
/*
* Maximum number of Rx queue flush attempt in the case of failure or
* flush timeout
*/
#define SFC_RX_QFLUSH_ATTEMPTS (3)
/*
* Time to wait between event queue polling attempts when waiting for Rx
* queue flush done or failed events.
*/
#define SFC_RX_QFLUSH_POLL_WAIT_MS (1)
/*
* Maximum number of event queue polling attempts when waiting for Rx queue
* flush done or failed events. It defines Rx queue flush attempt timeout
* together with SFC_RX_QFLUSH_POLL_WAIT_MS.
*/
#define SFC_RX_QFLUSH_POLL_ATTEMPTS (2000)
void
sfc_rx_qflush_done(struct sfc_rxq *rxq)
{
rxq->state |= SFC_RXQ_FLUSHED;
rxq->state &= ~SFC_RXQ_FLUSHING;
}
void
sfc_rx_qflush_failed(struct sfc_rxq *rxq)
{
rxq->state |= SFC_RXQ_FLUSH_FAILED;
rxq->state &= ~SFC_RXQ_FLUSHING;
}
static void
sfc_efx_rx_qrefill(struct sfc_efx_rxq *rxq)
{
unsigned int free_space;
unsigned int bulks;
void *objs[SFC_RX_REFILL_BULK];
efsys_dma_addr_t addr[RTE_DIM(objs)];
unsigned int added = rxq->added;
unsigned int id;
unsigned int i;
struct sfc_efx_rx_sw_desc *rxd;
struct rte_mbuf *m;
uint16_t port_id = rxq->dp.dpq.port_id;
free_space = rxq->max_fill_level - (added - rxq->completed);
if (free_space < rxq->refill_threshold)
return;
bulks = free_space / RTE_DIM(objs);
/* refill_threshold guarantees that bulks is positive */
SFC_ASSERT(bulks > 0);
id = added & rxq->ptr_mask;
do {
if (unlikely(rte_mempool_get_bulk(rxq->refill_mb_pool, objs,
RTE_DIM(objs)) < 0)) {
/*
* It is hardly a safe way to increment counter
* from different contexts, but all PMDs do it.
*/
rxq->evq->sa->eth_dev->data->rx_mbuf_alloc_failed +=
RTE_DIM(objs);
/* Return if we have posted nothing yet */
if (added == rxq->added)
return;
/* Push posted */
break;
}
for (i = 0; i < RTE_DIM(objs);
++i, id = (id + 1) & rxq->ptr_mask) {
m = objs[i];
rxd = &rxq->sw_desc[id];
rxd->mbuf = m;
SFC_ASSERT(rte_mbuf_refcnt_read(m) == 1);
m->data_off = RTE_PKTMBUF_HEADROOM;
SFC_ASSERT(m->next == NULL);
SFC_ASSERT(m->nb_segs == 1);
m->port = port_id;
addr[i] = rte_pktmbuf_iova(m);
}
efx_rx_qpost(rxq->common, addr, rxq->buf_size,
RTE_DIM(objs), rxq->completed, added);
added += RTE_DIM(objs);
} while (--bulks > 0);
SFC_ASSERT(added != rxq->added);
rxq->added = added;
efx_rx_qpush(rxq->common, added, &rxq->pushed);
}
static uint64_t
sfc_efx_rx_desc_flags_to_offload_flags(const unsigned int desc_flags)
{
uint64_t mbuf_flags = 0;
switch (desc_flags & (EFX_PKT_IPV4 | EFX_CKSUM_IPV4)) {
case (EFX_PKT_IPV4 | EFX_CKSUM_IPV4):
mbuf_flags |= PKT_RX_IP_CKSUM_GOOD;
break;
case EFX_PKT_IPV4:
mbuf_flags |= PKT_RX_IP_CKSUM_BAD;
break;
default:
RTE_BUILD_BUG_ON(PKT_RX_IP_CKSUM_UNKNOWN != 0);
SFC_ASSERT((mbuf_flags & PKT_RX_IP_CKSUM_MASK) ==
PKT_RX_IP_CKSUM_UNKNOWN);
break;
}
switch ((desc_flags &
(EFX_PKT_TCP | EFX_PKT_UDP | EFX_CKSUM_TCPUDP))) {
case (EFX_PKT_TCP | EFX_CKSUM_TCPUDP):
case (EFX_PKT_UDP | EFX_CKSUM_TCPUDP):
mbuf_flags |= PKT_RX_L4_CKSUM_GOOD;
break;
case EFX_PKT_TCP:
case EFX_PKT_UDP:
mbuf_flags |= PKT_RX_L4_CKSUM_BAD;
break;
default:
RTE_BUILD_BUG_ON(PKT_RX_L4_CKSUM_UNKNOWN != 0);
SFC_ASSERT((mbuf_flags & PKT_RX_L4_CKSUM_MASK) ==
PKT_RX_L4_CKSUM_UNKNOWN);
break;
}
return mbuf_flags;
}
static uint32_t
sfc_efx_rx_desc_flags_to_packet_type(const unsigned int desc_flags)
{
return RTE_PTYPE_L2_ETHER |
((desc_flags & EFX_PKT_IPV4) ?
RTE_PTYPE_L3_IPV4_EXT_UNKNOWN : 0) |
((desc_flags & EFX_PKT_IPV6) ?
RTE_PTYPE_L3_IPV6_EXT_UNKNOWN : 0) |
((desc_flags & EFX_PKT_TCP) ? RTE_PTYPE_L4_TCP : 0) |
((desc_flags & EFX_PKT_UDP) ? RTE_PTYPE_L4_UDP : 0);
}
static const uint32_t *
sfc_efx_supported_ptypes_get(__rte_unused uint32_t tunnel_encaps)
{
static const uint32_t ptypes[] = {
RTE_PTYPE_L2_ETHER,
RTE_PTYPE_L3_IPV4_EXT_UNKNOWN,
RTE_PTYPE_L3_IPV6_EXT_UNKNOWN,
RTE_PTYPE_L4_TCP,
RTE_PTYPE_L4_UDP,
RTE_PTYPE_UNKNOWN
};
return ptypes;
}
static void
sfc_efx_rx_set_rss_hash(struct sfc_efx_rxq *rxq, unsigned int flags,
struct rte_mbuf *m)
{
uint8_t *mbuf_data;
if ((rxq->flags & SFC_EFX_RXQ_FLAG_RSS_HASH) == 0)
return;
mbuf_data = rte_pktmbuf_mtod(m, uint8_t *);
if (flags & (EFX_PKT_IPV4 | EFX_PKT_IPV6)) {
m->hash.rss = efx_pseudo_hdr_hash_get(rxq->common,
EFX_RX_HASHALG_TOEPLITZ,
mbuf_data);
m->ol_flags |= PKT_RX_RSS_HASH;
}
}
static uint16_t
sfc_efx_recv_pkts(void *rx_queue, struct rte_mbuf **rx_pkts, uint16_t nb_pkts)
{
struct sfc_dp_rxq *dp_rxq = rx_queue;
struct sfc_efx_rxq *rxq = sfc_efx_rxq_by_dp_rxq(dp_rxq);
unsigned int completed;
unsigned int prefix_size = rxq->prefix_size;
unsigned int done_pkts = 0;
boolean_t discard_next = B_FALSE;
struct rte_mbuf *scatter_pkt = NULL;
if (unlikely((rxq->flags & SFC_EFX_RXQ_FLAG_RUNNING) == 0))
return 0;
sfc_ev_qpoll(rxq->evq);
completed = rxq->completed;
while (completed != rxq->pending && done_pkts < nb_pkts) {
unsigned int id;
struct sfc_efx_rx_sw_desc *rxd;
struct rte_mbuf *m;
unsigned int seg_len;
unsigned int desc_flags;
id = completed++ & rxq->ptr_mask;
rxd = &rxq->sw_desc[id];
m = rxd->mbuf;
desc_flags = rxd->flags;
if (discard_next)
goto discard;
if (desc_flags & (EFX_ADDR_MISMATCH | EFX_DISCARD))
goto discard;
if (desc_flags & EFX_PKT_PREFIX_LEN) {
uint16_t tmp_size;
int rc __rte_unused;
rc = efx_pseudo_hdr_pkt_length_get(rxq->common,
rte_pktmbuf_mtod(m, uint8_t *), &tmp_size);
SFC_ASSERT(rc == 0);
seg_len = tmp_size;
} else {
seg_len = rxd->size - prefix_size;
}
rte_pktmbuf_data_len(m) = seg_len;
rte_pktmbuf_pkt_len(m) = seg_len;
if (scatter_pkt != NULL) {
if (rte_pktmbuf_chain(scatter_pkt, m) != 0) {
rte_pktmbuf_free(scatter_pkt);
goto discard;
}
/* The packet to deliver */
m = scatter_pkt;
}
if (desc_flags & EFX_PKT_CONT) {
/* The packet is scattered, more fragments to come */
scatter_pkt = m;
/* Further fragments have no prefix */
prefix_size = 0;
continue;
}
/* Scattered packet is done */
scatter_pkt = NULL;
/* The first fragment of the packet has prefix */
prefix_size = rxq->prefix_size;
m->ol_flags =
sfc_efx_rx_desc_flags_to_offload_flags(desc_flags);
m->packet_type =
sfc_efx_rx_desc_flags_to_packet_type(desc_flags);
/*
* Extract RSS hash from the packet prefix and
* set the corresponding field (if needed and possible)
*/
sfc_efx_rx_set_rss_hash(rxq, desc_flags, m);
m->data_off += prefix_size;
*rx_pkts++ = m;
done_pkts++;
continue;
discard:
discard_next = ((desc_flags & EFX_PKT_CONT) != 0);
rte_mempool_put(rxq->refill_mb_pool, m);
rxd->mbuf = NULL;
}
/* pending is only moved when entire packet is received */
SFC_ASSERT(scatter_pkt == NULL);
rxq->completed = completed;
sfc_efx_rx_qrefill(rxq);
return done_pkts;
}
static sfc_dp_rx_qdesc_npending_t sfc_efx_rx_qdesc_npending;
static unsigned int
sfc_efx_rx_qdesc_npending(struct sfc_dp_rxq *dp_rxq)
{
struct sfc_efx_rxq *rxq = sfc_efx_rxq_by_dp_rxq(dp_rxq);
if ((rxq->flags & SFC_EFX_RXQ_FLAG_RUNNING) == 0)
return 0;
sfc_ev_qpoll(rxq->evq);
return rxq->pending - rxq->completed;
}
static sfc_dp_rx_qdesc_status_t sfc_efx_rx_qdesc_status;
static int
sfc_efx_rx_qdesc_status(struct sfc_dp_rxq *dp_rxq, uint16_t offset)
{
struct sfc_efx_rxq *rxq = sfc_efx_rxq_by_dp_rxq(dp_rxq);
if (unlikely(offset > rxq->ptr_mask))
return -EINVAL;
/*
* Poll EvQ to derive up-to-date 'rxq->pending' figure;
* it is required for the queue to be running, but the
* check is omitted because API design assumes that it
* is the duty of the caller to satisfy all conditions
*/
SFC_ASSERT((rxq->flags & SFC_EFX_RXQ_FLAG_RUNNING) ==
SFC_EFX_RXQ_FLAG_RUNNING);
sfc_ev_qpoll(rxq->evq);
/*
* There is a handful of reserved entries in the ring,
* but an explicit check whether the offset points to
* a reserved entry is neglected since the two checks
* below rely on the figures which take the HW limits
* into account and thus if an entry is reserved, the
* checks will fail and UNAVAIL code will be returned
*/
if (offset < (rxq->pending - rxq->completed))
return RTE_ETH_RX_DESC_DONE;
if (offset < (rxq->added - rxq->completed))
return RTE_ETH_RX_DESC_AVAIL;
return RTE_ETH_RX_DESC_UNAVAIL;
}
struct sfc_rxq *
sfc_rxq_by_dp_rxq(const struct sfc_dp_rxq *dp_rxq)
{
const struct sfc_dp_queue *dpq = &dp_rxq->dpq;
struct rte_eth_dev *eth_dev;
struct sfc_adapter *sa;
struct sfc_rxq *rxq;
SFC_ASSERT(rte_eth_dev_is_valid_port(dpq->port_id));
eth_dev = &rte_eth_devices[dpq->port_id];
sa = eth_dev->data->dev_private;
SFC_ASSERT(dpq->queue_id < sa->rxq_count);
rxq = sa->rxq_info[dpq->queue_id].rxq;
SFC_ASSERT(rxq != NULL);
return rxq;
}
static sfc_dp_rx_qsize_up_rings_t sfc_efx_rx_qsize_up_rings;
static int
sfc_efx_rx_qsize_up_rings(uint16_t nb_rx_desc,
__rte_unused struct rte_mempool *mb_pool,
unsigned int *rxq_entries,
unsigned int *evq_entries,
unsigned int *rxq_max_fill_level)
{
*rxq_entries = nb_rx_desc;
*evq_entries = nb_rx_desc;
*rxq_max_fill_level = EFX_RXQ_LIMIT(*rxq_entries);
return 0;
}
static sfc_dp_rx_qcreate_t sfc_efx_rx_qcreate;
static int
sfc_efx_rx_qcreate(uint16_t port_id, uint16_t queue_id,
const struct rte_pci_addr *pci_addr, int socket_id,
const struct sfc_dp_rx_qcreate_info *info,
struct sfc_dp_rxq **dp_rxqp)
{
struct sfc_efx_rxq *rxq;
int rc;
rc = ENOMEM;
rxq = rte_zmalloc_socket("sfc-efx-rxq", sizeof(*rxq),
RTE_CACHE_LINE_SIZE, socket_id);
if (rxq == NULL)
goto fail_rxq_alloc;
sfc_dp_queue_init(&rxq->dp.dpq, port_id, queue_id, pci_addr);
rc = ENOMEM;
rxq->sw_desc = rte_calloc_socket("sfc-efx-rxq-sw_desc",
info->rxq_entries,
sizeof(*rxq->sw_desc),
RTE_CACHE_LINE_SIZE, socket_id);
if (rxq->sw_desc == NULL)
goto fail_desc_alloc;
/* efx datapath is bound to efx control path */
rxq->evq = sfc_rxq_by_dp_rxq(&rxq->dp)->evq;
if (info->flags & SFC_RXQ_FLAG_RSS_HASH)
rxq->flags |= SFC_EFX_RXQ_FLAG_RSS_HASH;
rxq->ptr_mask = info->rxq_entries - 1;
rxq->batch_max = info->batch_max;
rxq->prefix_size = info->prefix_size;
rxq->max_fill_level = info->max_fill_level;
rxq->refill_threshold = info->refill_threshold;
rxq->buf_size = info->buf_size;
rxq->refill_mb_pool = info->refill_mb_pool;
*dp_rxqp = &rxq->dp;
return 0;
fail_desc_alloc:
rte_free(rxq);
fail_rxq_alloc:
return rc;
}
static sfc_dp_rx_qdestroy_t sfc_efx_rx_qdestroy;
static void
sfc_efx_rx_qdestroy(struct sfc_dp_rxq *dp_rxq)
{
struct sfc_efx_rxq *rxq = sfc_efx_rxq_by_dp_rxq(dp_rxq);
rte_free(rxq->sw_desc);
rte_free(rxq);
}
static sfc_dp_rx_qstart_t sfc_efx_rx_qstart;
static int
sfc_efx_rx_qstart(struct sfc_dp_rxq *dp_rxq,
__rte_unused unsigned int evq_read_ptr)
{
/* libefx-based datapath is specific to libefx-based PMD */
struct sfc_efx_rxq *rxq = sfc_efx_rxq_by_dp_rxq(dp_rxq);
struct sfc_rxq *crxq = sfc_rxq_by_dp_rxq(dp_rxq);
rxq->common = crxq->common;
rxq->pending = rxq->completed = rxq->added = rxq->pushed = 0;
sfc_efx_rx_qrefill(rxq);
rxq->flags |= (SFC_EFX_RXQ_FLAG_STARTED | SFC_EFX_RXQ_FLAG_RUNNING);
return 0;
}
static sfc_dp_rx_qstop_t sfc_efx_rx_qstop;
static void
sfc_efx_rx_qstop(struct sfc_dp_rxq *dp_rxq,
__rte_unused unsigned int *evq_read_ptr)
{
struct sfc_efx_rxq *rxq = sfc_efx_rxq_by_dp_rxq(dp_rxq);
rxq->flags &= ~SFC_EFX_RXQ_FLAG_RUNNING;
/* libefx-based datapath is bound to libefx-based PMD and uses
* event queue structure directly. So, there is no necessity to
* return EvQ read pointer.
*/
}
static sfc_dp_rx_qpurge_t sfc_efx_rx_qpurge;
static void
sfc_efx_rx_qpurge(struct sfc_dp_rxq *dp_rxq)
{
struct sfc_efx_rxq *rxq = sfc_efx_rxq_by_dp_rxq(dp_rxq);
unsigned int i;
struct sfc_efx_rx_sw_desc *rxd;
for (i = rxq->completed; i != rxq->added; ++i) {
rxd = &rxq->sw_desc[i & rxq->ptr_mask];
rte_mempool_put(rxq->refill_mb_pool, rxd->mbuf);
rxd->mbuf = NULL;
/* Packed stream relies on 0 in inactive SW desc.
* Rx queue stop is not performance critical, so
* there is no harm to do it always.
*/
rxd->flags = 0;
rxd->size = 0;
}
rxq->flags &= ~SFC_EFX_RXQ_FLAG_STARTED;
}
struct sfc_dp_rx sfc_efx_rx = {
.dp = {
.name = SFC_KVARG_DATAPATH_EFX,
.type = SFC_DP_RX,
.hw_fw_caps = 0,
},
.features = SFC_DP_RX_FEAT_SCATTER,
.qsize_up_rings = sfc_efx_rx_qsize_up_rings,
.qcreate = sfc_efx_rx_qcreate,
.qdestroy = sfc_efx_rx_qdestroy,
.qstart = sfc_efx_rx_qstart,
.qstop = sfc_efx_rx_qstop,
.qpurge = sfc_efx_rx_qpurge,
.supported_ptypes_get = sfc_efx_supported_ptypes_get,
.qdesc_npending = sfc_efx_rx_qdesc_npending,
.qdesc_status = sfc_efx_rx_qdesc_status,
.pkt_burst = sfc_efx_recv_pkts,
};
unsigned int
sfc_rx_qdesc_npending(struct sfc_adapter *sa, unsigned int sw_index)
{
struct sfc_rxq *rxq;
SFC_ASSERT(sw_index < sa->rxq_count);
rxq = sa->rxq_info[sw_index].rxq;
if (rxq == NULL || (rxq->state & SFC_RXQ_STARTED) == 0)
return 0;
return sa->dp_rx->qdesc_npending(rxq->dp);
}
int
sfc_rx_qdesc_done(struct sfc_dp_rxq *dp_rxq, unsigned int offset)
{
struct sfc_rxq *rxq = sfc_rxq_by_dp_rxq(dp_rxq);
return offset < rxq->evq->sa->dp_rx->qdesc_npending(dp_rxq);
}
static void
sfc_rx_qflush(struct sfc_adapter *sa, unsigned int sw_index)
{
struct sfc_rxq *rxq;
unsigned int retry_count;
unsigned int wait_count;
int rc;
rxq = sa->rxq_info[sw_index].rxq;
SFC_ASSERT(rxq->state & SFC_RXQ_STARTED);
/*
* Retry Rx queue flushing in the case of flush failed or
* timeout. In the worst case it can delay for 6 seconds.
*/
for (retry_count = 0;
((rxq->state & SFC_RXQ_FLUSHED) == 0) &&
(retry_count < SFC_RX_QFLUSH_ATTEMPTS);
++retry_count) {
rc = efx_rx_qflush(rxq->common);
if (rc != 0) {
rxq->state |= (rc == EALREADY) ?
SFC_RXQ_FLUSHED : SFC_RXQ_FLUSH_FAILED;
break;
}
rxq->state &= ~SFC_RXQ_FLUSH_FAILED;
rxq->state |= SFC_RXQ_FLUSHING;
/*
* Wait for Rx queue flush done or failed event at least
* SFC_RX_QFLUSH_POLL_WAIT_MS milliseconds and not more
* than 2 seconds (SFC_RX_QFLUSH_POLL_WAIT_MS multiplied
* by SFC_RX_QFLUSH_POLL_ATTEMPTS).
*/
wait_count = 0;
do {
rte_delay_ms(SFC_RX_QFLUSH_POLL_WAIT_MS);
sfc_ev_qpoll(rxq->evq);
} while ((rxq->state & SFC_RXQ_FLUSHING) &&
(wait_count++ < SFC_RX_QFLUSH_POLL_ATTEMPTS));
if (rxq->state & SFC_RXQ_FLUSHING)
sfc_err(sa, "RxQ %u flush timed out", sw_index);
if (rxq->state & SFC_RXQ_FLUSH_FAILED)
sfc_err(sa, "RxQ %u flush failed", sw_index);
if (rxq->state & SFC_RXQ_FLUSHED)
sfc_notice(sa, "RxQ %u flushed", sw_index);
}
sa->dp_rx->qpurge(rxq->dp);
}
static int
sfc_rx_default_rxq_set_filter(struct sfc_adapter *sa, struct sfc_rxq *rxq)
{
struct sfc_rss *rss = &sa->rss;
boolean_t need_rss = (rss->channels > 0) ? B_TRUE : B_FALSE;
struct sfc_port *port = &sa->port;
int rc;
/*
* If promiscuous or all-multicast mode has been requested, setting
* filter for the default Rx queue might fail, in particular, while
* running over PCI function which is not a member of corresponding
* privilege groups; if this occurs, few iterations will be made to
* repeat this step without promiscuous and all-multicast flags set
*/
retry:
rc = efx_mac_filter_default_rxq_set(sa->nic, rxq->common, need_rss);
if (rc == 0)
return 0;
else if (rc != EOPNOTSUPP)
return rc;
if (port->promisc) {
sfc_warn(sa, "promiscuous mode has been requested, "
"but the HW rejects it");
sfc_warn(sa, "promiscuous mode will be disabled");
port->promisc = B_FALSE;
rc = sfc_set_rx_mode(sa);
if (rc != 0)
return rc;
goto retry;
}
if (port->allmulti) {
sfc_warn(sa, "all-multicast mode has been requested, "
"but the HW rejects it");
sfc_warn(sa, "all-multicast mode will be disabled");
port->allmulti = B_FALSE;
rc = sfc_set_rx_mode(sa);
if (rc != 0)
return rc;
goto retry;
}
return rc;
}
int
sfc_rx_qstart(struct sfc_adapter *sa, unsigned int sw_index)
{
struct sfc_port *port = &sa->port;
struct sfc_rxq_info *rxq_info;
struct sfc_rxq *rxq;
struct sfc_evq *evq;
int rc;
sfc_log_init(sa, "sw_index=%u", sw_index);
SFC_ASSERT(sw_index < sa->rxq_count);
rxq_info = &sa->rxq_info[sw_index];
rxq = rxq_info->rxq;
SFC_ASSERT(rxq->state == SFC_RXQ_INITIALIZED);
evq = rxq->evq;
rc = sfc_ev_qstart(evq, sfc_evq_index_by_rxq_sw_index(sa, sw_index));
if (rc != 0)
goto fail_ev_qstart;
switch (rxq_info->type) {
case EFX_RXQ_TYPE_DEFAULT:
rc = efx_rx_qcreate(sa->nic, rxq->hw_index, 0, rxq_info->type,
&rxq->mem, rxq_info->entries, 0 /* not used on EF10 */,
rxq_info->type_flags, evq->common, &rxq->common);
break;
case EFX_RXQ_TYPE_ES_SUPER_BUFFER: {
struct rte_mempool *mp = rxq->refill_mb_pool;
struct rte_mempool_info mp_info;
rc = rte_mempool_ops_get_info(mp, &mp_info);
if (rc != 0) {
/* Positive errno is used in the driver */
rc = -rc;
goto fail_mp_get_info;
}
if (mp_info.contig_block_size <= 0) {
rc = EINVAL;
goto fail_bad_contig_block_size;
}
rc = efx_rx_qcreate_es_super_buffer(sa->nic, rxq->hw_index, 0,
mp_info.contig_block_size, rxq->buf_size,
mp->header_size + mp->elt_size + mp->trailer_size,
sa->rxd_wait_timeout_ns,
&rxq->mem, rxq_info->entries, rxq_info->type_flags,
evq->common, &rxq->common);
break;
}
default:
rc = ENOTSUP;
}
if (rc != 0)
goto fail_rx_qcreate;
efx_rx_qenable(rxq->common);
rc = sa->dp_rx->qstart(rxq->dp, evq->read_ptr);
if (rc != 0)
goto fail_dp_qstart;
rxq->state |= SFC_RXQ_STARTED;
if ((sw_index == 0) && !port->isolated) {
rc = sfc_rx_default_rxq_set_filter(sa, rxq);
if (rc != 0)
goto fail_mac_filter_default_rxq_set;
}
/* It seems to be used by DPDK for debug purposes only ('rte_ether') */
sa->eth_dev->data->rx_queue_state[sw_index] =
RTE_ETH_QUEUE_STATE_STARTED;
return 0;
fail_mac_filter_default_rxq_set:
sa->dp_rx->qstop(rxq->dp, &rxq->evq->read_ptr);
fail_dp_qstart:
sfc_rx_qflush(sa, sw_index);
fail_rx_qcreate:
fail_bad_contig_block_size:
fail_mp_get_info:
sfc_ev_qstop(evq);
fail_ev_qstart:
return rc;
}
void
sfc_rx_qstop(struct sfc_adapter *sa, unsigned int sw_index)
{
struct sfc_rxq_info *rxq_info;
struct sfc_rxq *rxq;
sfc_log_init(sa, "sw_index=%u", sw_index);
SFC_ASSERT(sw_index < sa->rxq_count);
rxq_info = &sa->rxq_info[sw_index];
rxq = rxq_info->rxq;
if (rxq->state == SFC_RXQ_INITIALIZED)
return;
SFC_ASSERT(rxq->state & SFC_RXQ_STARTED);
/* It seems to be used by DPDK for debug purposes only ('rte_ether') */
sa->eth_dev->data->rx_queue_state[sw_index] =
RTE_ETH_QUEUE_STATE_STOPPED;
sa->dp_rx->qstop(rxq->dp, &rxq->evq->read_ptr);
if (sw_index == 0)
efx_mac_filter_default_rxq_clear(sa->nic);
sfc_rx_qflush(sa, sw_index);
rxq->state = SFC_RXQ_INITIALIZED;
efx_rx_qdestroy(rxq->common);
sfc_ev_qstop(rxq->evq);
}
uint64_t
sfc_rx_get_dev_offload_caps(struct sfc_adapter *sa)
{
const efx_nic_cfg_t *encp = efx_nic_cfg_get(sa->nic);
uint64_t caps = 0;
caps |= DEV_RX_OFFLOAD_JUMBO_FRAME;
caps |= DEV_RX_OFFLOAD_CRC_STRIP;
caps |= DEV_RX_OFFLOAD_IPV4_CKSUM;
caps |= DEV_RX_OFFLOAD_UDP_CKSUM;
caps |= DEV_RX_OFFLOAD_TCP_CKSUM;
if (encp->enc_tunnel_encapsulations_supported &&
(sa->dp_rx->features & SFC_DP_RX_FEAT_TUNNELS))
caps |= DEV_RX_OFFLOAD_OUTER_IPV4_CKSUM;
return caps;
}
uint64_t
sfc_rx_get_queue_offload_caps(struct sfc_adapter *sa)
{
uint64_t caps = 0;
if (sa->dp_rx->features & SFC_DP_RX_FEAT_SCATTER)
caps |= DEV_RX_OFFLOAD_SCATTER;
return caps;
}
static int
sfc_rx_qcheck_conf(struct sfc_adapter *sa, unsigned int rxq_max_fill_level,
const struct rte_eth_rxconf *rx_conf,
uint64_t offloads)
{
uint64_t offloads_supported = sfc_rx_get_dev_offload_caps(sa) |
sfc_rx_get_queue_offload_caps(sa);
int rc = 0;
if (rx_conf->rx_thresh.pthresh != 0 ||
rx_conf->rx_thresh.hthresh != 0 ||
rx_conf->rx_thresh.wthresh != 0) {
sfc_warn(sa,
"RxQ prefetch/host/writeback thresholds are not supported");
}
if (rx_conf->rx_free_thresh > rxq_max_fill_level) {
sfc_err(sa,
"RxQ free threshold too large: %u vs maximum %u",
rx_conf->rx_free_thresh, rxq_max_fill_level);
rc = EINVAL;
}
if (rx_conf->rx_drop_en == 0) {
sfc_err(sa, "RxQ drop disable is not supported");
rc = EINVAL;
}
if ((offloads & DEV_RX_OFFLOAD_CHECKSUM) !=
DEV_RX_OFFLOAD_CHECKSUM)
sfc_warn(sa, "Rx checksum offloads cannot be disabled - always on (IPv4/TCP/UDP)");
if ((offloads_supported & DEV_RX_OFFLOAD_OUTER_IPV4_CKSUM) &&
(~offloads & DEV_RX_OFFLOAD_OUTER_IPV4_CKSUM))
sfc_warn(sa, "Rx outer IPv4 checksum offload cannot be disabled - always on");
return rc;
}
static unsigned int
sfc_rx_mbuf_data_alignment(struct rte_mempool *mb_pool)
{
uint32_t data_off;
uint32_t order;
/* The mbuf object itself is always cache line aligned */
order = rte_bsf32(RTE_CACHE_LINE_SIZE);
/* Data offset from mbuf object start */
data_off = sizeof(struct rte_mbuf) + rte_pktmbuf_priv_size(mb_pool) +
RTE_PKTMBUF_HEADROOM;
order = MIN(order, rte_bsf32(data_off));
return 1u << order;
}
static uint16_t
sfc_rx_mb_pool_buf_size(struct sfc_adapter *sa, struct rte_mempool *mb_pool)
{
const efx_nic_cfg_t *encp = efx_nic_cfg_get(sa->nic);
const uint32_t nic_align_start = MAX(1, encp->enc_rx_buf_align_start);
const uint32_t nic_align_end = MAX(1, encp->enc_rx_buf_align_end);
uint16_t buf_size;
unsigned int buf_aligned;
unsigned int start_alignment;
unsigned int end_padding_alignment;
/* Below it is assumed that both alignments are power of 2 */
SFC_ASSERT(rte_is_power_of_2(nic_align_start));
SFC_ASSERT(rte_is_power_of_2(nic_align_end));
/*
* mbuf is always cache line aligned, double-check
* that it meets rx buffer start alignment requirements.
*/
/* Start from mbuf pool data room size */
buf_size = rte_pktmbuf_data_room_size(mb_pool);
/* Remove headroom */
if (buf_size <= RTE_PKTMBUF_HEADROOM) {
sfc_err(sa,
"RxQ mbuf pool %s object data room size %u is smaller than headroom %u",
mb_pool->name, buf_size, RTE_PKTMBUF_HEADROOM);
return 0;
}
buf_size -= RTE_PKTMBUF_HEADROOM;
/* Calculate guaranteed data start alignment */
buf_aligned = sfc_rx_mbuf_data_alignment(mb_pool);
/* Reserve space for start alignment */
if (buf_aligned < nic_align_start) {
start_alignment = nic_align_start - buf_aligned;
if (buf_size <= start_alignment) {
sfc_err(sa,
"RxQ mbuf pool %s object data room size %u is insufficient for headroom %u and buffer start alignment %u required by NIC",
mb_pool->name,
rte_pktmbuf_data_room_size(mb_pool),
RTE_PKTMBUF_HEADROOM, start_alignment);
return 0;
}
buf_aligned = nic_align_start;
buf_size -= start_alignment;
} else {
start_alignment = 0;
}
/* Make sure that end padding does not write beyond the buffer */
if (buf_aligned < nic_align_end) {
/*
* Estimate space which can be lost. If guarnteed buffer
* size is odd, lost space is (nic_align_end - 1). More
* accurate formula is below.
*/
end_padding_alignment = nic_align_end -
MIN(buf_aligned, 1u << (rte_bsf32(buf_size) - 1));
if (buf_size <= end_padding_alignment) {
sfc_err(sa,
"RxQ mbuf pool %s object data room size %u is insufficient for headroom %u, buffer start alignment %u and end padding alignment %u required by NIC",
mb_pool->name,
rte_pktmbuf_data_room_size(mb_pool),
RTE_PKTMBUF_HEADROOM, start_alignment,
end_padding_alignment);
return 0;
}
buf_size -= end_padding_alignment;
} else {
/*
* Start is aligned the same or better than end,
* just align length.
*/
buf_size = P2ALIGN(buf_size, nic_align_end);
}
return buf_size;
}
int
sfc_rx_qinit(struct sfc_adapter *sa, unsigned int sw_index,
uint16_t nb_rx_desc, unsigned int socket_id,
const struct rte_eth_rxconf *rx_conf,
struct rte_mempool *mb_pool)
{
const efx_nic_cfg_t *encp = efx_nic_cfg_get(sa->nic);
struct sfc_rss *rss = &sa->rss;
int rc;
unsigned int rxq_entries;
unsigned int evq_entries;
unsigned int rxq_max_fill_level;
uint64_t offloads;
uint16_t buf_size;
struct sfc_rxq_info *rxq_info;
struct sfc_evq *evq;
struct sfc_rxq *rxq;
struct sfc_dp_rx_qcreate_info info;
rc = sa->dp_rx->qsize_up_rings(nb_rx_desc, mb_pool, &rxq_entries,
&evq_entries, &rxq_max_fill_level);
if (rc != 0)
goto fail_size_up_rings;
SFC_ASSERT(rxq_entries >= EFX_RXQ_MINNDESCS);
SFC_ASSERT(rxq_entries <= EFX_RXQ_MAXNDESCS);
SFC_ASSERT(rxq_max_fill_level <= nb_rx_desc);
offloads = rx_conf->offloads |
sa->eth_dev->data->dev_conf.rxmode.offloads;
rc = sfc_rx_qcheck_conf(sa, rxq_max_fill_level, rx_conf, offloads);
if (rc != 0)
goto fail_bad_conf;
buf_size = sfc_rx_mb_pool_buf_size(sa, mb_pool);
if (buf_size == 0) {
sfc_err(sa, "RxQ %u mbuf pool object size is too small",
sw_index);
rc = EINVAL;
goto fail_bad_conf;
}
if ((buf_size < sa->port.pdu + encp->enc_rx_prefix_size) &&
(~offloads & DEV_RX_OFFLOAD_SCATTER)) {
sfc_err(sa, "Rx scatter is disabled and RxQ %u mbuf pool "
"object size is too small", sw_index);
sfc_err(sa, "RxQ %u calculated Rx buffer size is %u vs "
"PDU size %u plus Rx prefix %u bytes",
sw_index, buf_size, (unsigned int)sa->port.pdu,
encp->enc_rx_prefix_size);
rc = EINVAL;
goto fail_bad_conf;
}
SFC_ASSERT(sw_index < sa->rxq_count);
rxq_info = &sa->rxq_info[sw_index];
SFC_ASSERT(rxq_entries <= rxq_info->max_entries);
rxq_info->entries = rxq_entries;
if (sa->dp_rx->dp.hw_fw_caps & SFC_DP_HW_FW_CAP_RX_ES_SUPER_BUFFER)
rxq_info->type = EFX_RXQ_TYPE_ES_SUPER_BUFFER;
else
rxq_info->type = EFX_RXQ_TYPE_DEFAULT;
rxq_info->type_flags =
(offloads & DEV_RX_OFFLOAD_SCATTER) ?
EFX_RXQ_FLAG_SCATTER : EFX_RXQ_FLAG_NONE;
if ((encp->enc_tunnel_encapsulations_supported != 0) &&
(sa->dp_rx->features & SFC_DP_RX_FEAT_TUNNELS))
rxq_info->type_flags |= EFX_RXQ_FLAG_INNER_CLASSES;
rc = sfc_ev_qinit(sa, SFC_EVQ_TYPE_RX, sw_index,
evq_entries, socket_id, &evq);
if (rc != 0)
goto fail_ev_qinit;
rc = ENOMEM;
rxq = rte_zmalloc_socket("sfc-rxq", sizeof(*rxq), RTE_CACHE_LINE_SIZE,
socket_id);
if (rxq == NULL)
goto fail_rxq_alloc;
rxq_info->rxq = rxq;
rxq->evq = evq;
rxq->hw_index = sw_index;
rxq->refill_threshold =
RTE_MAX(rx_conf->rx_free_thresh, SFC_RX_REFILL_BULK);
rxq->refill_mb_pool = mb_pool;
rxq->buf_size = buf_size;
rc = sfc_dma_alloc(sa, "rxq", sw_index, EFX_RXQ_SIZE(rxq_info->entries),
socket_id, &rxq->mem);
if (rc != 0)
goto fail_dma_alloc;
memset(&info, 0, sizeof(info));
info.refill_mb_pool = rxq->refill_mb_pool;
info.max_fill_level = rxq_max_fill_level;
info.refill_threshold = rxq->refill_threshold;
info.buf_size = buf_size;
info.batch_max = encp->enc_rx_batch_max;
info.prefix_size = encp->enc_rx_prefix_size;
if (rss->hash_support == EFX_RX_HASH_AVAILABLE && rss->channels > 0)
info.flags |= SFC_RXQ_FLAG_RSS_HASH;
info.rxq_entries = rxq_info->entries;
info.rxq_hw_ring = rxq->mem.esm_base;
info.evq_entries = evq_entries;
info.evq_hw_ring = evq->mem.esm_base;
info.hw_index = rxq->hw_index;
info.mem_bar = sa->mem_bar.esb_base;
info.vi_window_shift = encp->enc_vi_window_shift;
rc = sa->dp_rx->qcreate(sa->eth_dev->data->port_id, sw_index,
&RTE_ETH_DEV_TO_PCI(sa->eth_dev)->addr,
socket_id, &info, &rxq->dp);
if (rc != 0)
goto fail_dp_rx_qcreate;
evq->dp_rxq = rxq->dp;
rxq->state = SFC_RXQ_INITIALIZED;
rxq_info->deferred_start = (rx_conf->rx_deferred_start != 0);
return 0;
fail_dp_rx_qcreate:
sfc_dma_free(sa, &rxq->mem);
fail_dma_alloc:
rxq_info->rxq = NULL;
rte_free(rxq);
fail_rxq_alloc:
sfc_ev_qfini(evq);
fail_ev_qinit:
rxq_info->entries = 0;
fail_bad_conf:
fail_size_up_rings:
sfc_log_init(sa, "failed %d", rc);
return rc;
}
void
sfc_rx_qfini(struct sfc_adapter *sa, unsigned int sw_index)
{
struct sfc_rxq_info *rxq_info;
struct sfc_rxq *rxq;
SFC_ASSERT(sw_index < sa->rxq_count);
rxq_info = &sa->rxq_info[sw_index];
rxq = rxq_info->rxq;
SFC_ASSERT(rxq->state == SFC_RXQ_INITIALIZED);
sa->dp_rx->qdestroy(rxq->dp);
rxq->dp = NULL;
rxq_info->rxq = NULL;
rxq_info->entries = 0;
sfc_dma_free(sa, &rxq->mem);
sfc_ev_qfini(rxq->evq);
rxq->evq = NULL;
rte_free(rxq);
}
/*
* Mapping between RTE RSS hash functions and their EFX counterparts.
*/
struct sfc_rss_hf_rte_to_efx sfc_rss_hf_map[] = {
{ ETH_RSS_NONFRAG_IPV4_TCP,
EFX_RX_HASH(IPV4_TCP, 4TUPLE) },
{ ETH_RSS_NONFRAG_IPV4_UDP,
EFX_RX_HASH(IPV4_UDP, 4TUPLE) },
{ ETH_RSS_NONFRAG_IPV6_TCP | ETH_RSS_IPV6_TCP_EX,
EFX_RX_HASH(IPV6_TCP, 4TUPLE) },
{ ETH_RSS_NONFRAG_IPV6_UDP | ETH_RSS_IPV6_UDP_EX,
EFX_RX_HASH(IPV6_UDP, 4TUPLE) },
{ ETH_RSS_IPV4 | ETH_RSS_FRAG_IPV4 | ETH_RSS_NONFRAG_IPV4_OTHER,
EFX_RX_HASH(IPV4_TCP, 2TUPLE) | EFX_RX_HASH(IPV4_UDP, 2TUPLE) |
EFX_RX_HASH(IPV4, 2TUPLE) },
{ ETH_RSS_IPV6 | ETH_RSS_FRAG_IPV6 | ETH_RSS_NONFRAG_IPV6_OTHER |
ETH_RSS_IPV6_EX,
EFX_RX_HASH(IPV6_TCP, 2TUPLE) | EFX_RX_HASH(IPV6_UDP, 2TUPLE) |
EFX_RX_HASH(IPV6, 2TUPLE) }
};
static efx_rx_hash_type_t
sfc_rx_hash_types_mask_supp(efx_rx_hash_type_t hash_type,
unsigned int *hash_type_flags_supported,
unsigned int nb_hash_type_flags_supported)
{
efx_rx_hash_type_t hash_type_masked = 0;
unsigned int i, j;
for (i = 0; i < nb_hash_type_flags_supported; ++i) {
unsigned int class_tuple_lbn[] = {
EFX_RX_CLASS_IPV4_TCP_LBN,
EFX_RX_CLASS_IPV4_UDP_LBN,
EFX_RX_CLASS_IPV4_LBN,
EFX_RX_CLASS_IPV6_TCP_LBN,
EFX_RX_CLASS_IPV6_UDP_LBN,
EFX_RX_CLASS_IPV6_LBN
};
for (j = 0; j < RTE_DIM(class_tuple_lbn); ++j) {
unsigned int tuple_mask = EFX_RX_CLASS_HASH_4TUPLE;
unsigned int flag;
tuple_mask <<= class_tuple_lbn[j];
flag = hash_type & tuple_mask;
if (flag == hash_type_flags_supported[i])
hash_type_masked |= flag;
}
}
return hash_type_masked;
}
int
sfc_rx_hash_init(struct sfc_adapter *sa)
{
struct sfc_rss *rss = &sa->rss;
const efx_nic_cfg_t *encp = efx_nic_cfg_get(sa->nic);
uint32_t alg_mask = encp->enc_rx_scale_hash_alg_mask;
efx_rx_hash_alg_t alg;
unsigned int flags_supp[EFX_RX_HASH_NFLAGS];
unsigned int nb_flags_supp;
struct sfc_rss_hf_rte_to_efx *hf_map;
struct sfc_rss_hf_rte_to_efx *entry;
efx_rx_hash_type_t efx_hash_types;
unsigned int i;
int rc;
if (alg_mask & (1U << EFX_RX_HASHALG_TOEPLITZ))
alg = EFX_RX_HASHALG_TOEPLITZ;
else if (alg_mask & (1U << EFX_RX_HASHALG_PACKED_STREAM))
alg = EFX_RX_HASHALG_PACKED_STREAM;
else
return EINVAL;
rc = efx_rx_scale_hash_flags_get(sa->nic, alg, flags_supp,
&nb_flags_supp);
if (rc != 0)
return rc;
hf_map = rte_calloc_socket("sfc-rss-hf-map",
RTE_DIM(sfc_rss_hf_map),
sizeof(*hf_map), 0, sa->socket_id);
if (hf_map == NULL)
return ENOMEM;
entry = hf_map;
efx_hash_types = 0;
for (i = 0; i < RTE_DIM(sfc_rss_hf_map); ++i) {
efx_rx_hash_type_t ht;
ht = sfc_rx_hash_types_mask_supp(sfc_rss_hf_map[i].efx,
flags_supp, nb_flags_supp);
if (ht != 0) {
entry->rte = sfc_rss_hf_map[i].rte;
entry->efx = ht;
efx_hash_types |= ht;
++entry;
}
}
rss->hash_alg = alg;
rss->hf_map_nb_entries = (unsigned int)(entry - hf_map);
rss->hf_map = hf_map;
rss->hash_types = efx_hash_types;
return 0;
}
void
sfc_rx_hash_fini(struct sfc_adapter *sa)
{
struct sfc_rss *rss = &sa->rss;
rte_free(rss->hf_map);
}
int
sfc_rx_hf_rte_to_efx(struct sfc_adapter *sa, uint64_t rte,
efx_rx_hash_type_t *efx)
{
struct sfc_rss *rss = &sa->rss;
efx_rx_hash_type_t hash_types = 0;
unsigned int i;
for (i = 0; i < rss->hf_map_nb_entries; ++i) {
uint64_t rte_mask = rss->hf_map[i].rte;
if ((rte & rte_mask) != 0) {
rte &= ~rte_mask;
hash_types |= rss->hf_map[i].efx;
}
}
if (rte != 0) {
sfc_err(sa, "unsupported hash functions requested");
return EINVAL;
}
*efx = hash_types;
return 0;
}
uint64_t
sfc_rx_hf_efx_to_rte(struct sfc_adapter *sa, efx_rx_hash_type_t efx)
{
struct sfc_rss *rss = &sa->rss;
uint64_t rte = 0;
unsigned int i;
for (i = 0; i < rss->hf_map_nb_entries; ++i) {
efx_rx_hash_type_t hash_type = rss->hf_map[i].efx;
if ((efx & hash_type) == hash_type)
rte |= rss->hf_map[i].rte;
}
return rte;
}
static int
sfc_rx_process_adv_conf_rss(struct sfc_adapter *sa,
struct rte_eth_rss_conf *conf)
{
struct sfc_rss *rss = &sa->rss;
efx_rx_hash_type_t efx_hash_types = rss->hash_types;
uint64_t rss_hf = sfc_rx_hf_efx_to_rte(sa, efx_hash_types);
int rc;
if (rss->context_type != EFX_RX_SCALE_EXCLUSIVE) {
if ((conf->rss_hf != 0 && conf->rss_hf != rss_hf) ||
conf->rss_key != NULL)
return EINVAL;
}
if (conf->rss_hf != 0) {
rc = sfc_rx_hf_rte_to_efx(sa, conf->rss_hf, &efx_hash_types);
if (rc != 0)
return rc;
}
if (conf->rss_key != NULL) {
if (conf->rss_key_len != sizeof(rss->key)) {
sfc_err(sa, "RSS key size is wrong (should be %lu)",
sizeof(rss->key));
return EINVAL;
}
rte_memcpy(rss->key, conf->rss_key, sizeof(rss->key));
}
rss->hash_types = efx_hash_types;
return 0;
}
static int
sfc_rx_rss_config(struct sfc_adapter *sa)
{
struct sfc_rss *rss = &sa->rss;
int rc = 0;
if (rss->channels > 0) {
rc = efx_rx_scale_mode_set(sa->nic, EFX_RSS_CONTEXT_DEFAULT,
rss->hash_alg, rss->hash_types,
B_TRUE);
if (rc != 0)
goto finish;
rc = efx_rx_scale_key_set(sa->nic, EFX_RSS_CONTEXT_DEFAULT,
rss->key, sizeof(rss->key));
if (rc != 0)
goto finish;
rc = efx_rx_scale_tbl_set(sa->nic, EFX_RSS_CONTEXT_DEFAULT,
rss->tbl, RTE_DIM(rss->tbl));
}
finish:
return rc;
}
int
sfc_rx_start(struct sfc_adapter *sa)
{
unsigned int sw_index;
int rc;
sfc_log_init(sa, "rxq_count=%u", sa->rxq_count);
rc = efx_rx_init(sa->nic);
if (rc != 0)
goto fail_rx_init;
rc = sfc_rx_rss_config(sa);
if (rc != 0)
goto fail_rss_config;
for (sw_index = 0; sw_index < sa->rxq_count; ++sw_index) {
if ((!sa->rxq_info[sw_index].deferred_start ||
sa->rxq_info[sw_index].deferred_started)) {
rc = sfc_rx_qstart(sa, sw_index);
if (rc != 0)
goto fail_rx_qstart;
}
}
return 0;
fail_rx_qstart:
while (sw_index-- > 0)
sfc_rx_qstop(sa, sw_index);
fail_rss_config:
efx_rx_fini(sa->nic);
fail_rx_init:
sfc_log_init(sa, "failed %d", rc);
return rc;
}
void
sfc_rx_stop(struct sfc_adapter *sa)
{
unsigned int sw_index;
sfc_log_init(sa, "rxq_count=%u", sa->rxq_count);
sw_index = sa->rxq_count;
while (sw_index-- > 0) {
if (sa->rxq_info[sw_index].rxq != NULL)
sfc_rx_qstop(sa, sw_index);
}
efx_rx_fini(sa->nic);
}
static int
sfc_rx_qinit_info(struct sfc_adapter *sa, unsigned int sw_index)
{
struct sfc_rxq_info *rxq_info = &sa->rxq_info[sw_index];
unsigned int max_entries;
max_entries = EFX_RXQ_MAXNDESCS;
SFC_ASSERT(rte_is_power_of_2(max_entries));
rxq_info->max_entries = max_entries;
return 0;
}
static int
sfc_rx_check_mode(struct sfc_adapter *sa, struct rte_eth_rxmode *rxmode)
{
struct sfc_rss *rss = &sa->rss;
int rc = 0;
switch (rxmode->mq_mode) {
case ETH_MQ_RX_NONE:
/* No special checks are required */
break;
case ETH_MQ_RX_RSS:
if (rss->context_type == EFX_RX_SCALE_UNAVAILABLE) {
sfc_err(sa, "RSS is not available");
rc = EINVAL;
}
break;
default:
sfc_err(sa, "Rx multi-queue mode %u not supported",
rxmode->mq_mode);
rc = EINVAL;
}
if (~rxmode->offloads & DEV_RX_OFFLOAD_CRC_STRIP) {
sfc_warn(sa, "FCS stripping cannot be disabled - always on");
rxmode->offloads |= DEV_RX_OFFLOAD_CRC_STRIP;
rxmode->hw_strip_crc = 1;
}
return rc;
}
/**
* Destroy excess queues that are no longer needed after reconfiguration
* or complete close.
*/
static void
sfc_rx_fini_queues(struct sfc_adapter *sa, unsigned int nb_rx_queues)
{
int sw_index;
SFC_ASSERT(nb_rx_queues <= sa->rxq_count);
sw_index = sa->rxq_count;
while (--sw_index >= (int)nb_rx_queues) {
if (sa->rxq_info[sw_index].rxq != NULL)
sfc_rx_qfini(sa, sw_index);
}
sa->rxq_count = nb_rx_queues;
}
/**
* Initialize Rx subsystem.
*
* Called at device (re)configuration stage when number of receive queues is
* specified together with other device level receive configuration.
*
* It should be used to allocate NUMA-unaware resources.
*/
int
sfc_rx_configure(struct sfc_adapter *sa)
{
struct sfc_rss *rss = &sa->rss;
struct rte_eth_conf *dev_conf = &sa->eth_dev->data->dev_conf;
const unsigned int nb_rx_queues = sa->eth_dev->data->nb_rx_queues;
int rc;
sfc_log_init(sa, "nb_rx_queues=%u (old %u)",
nb_rx_queues, sa->rxq_count);
rc = sfc_rx_check_mode(sa, &dev_conf->rxmode);
if (rc != 0)
goto fail_check_mode;
if (nb_rx_queues == sa->rxq_count)
goto done;
if (sa->rxq_info == NULL) {
rc = ENOMEM;
sa->rxq_info = rte_calloc_socket("sfc-rxqs", nb_rx_queues,
sizeof(sa->rxq_info[0]), 0,
sa->socket_id);
if (sa->rxq_info == NULL)
goto fail_rxqs_alloc;
} else {
struct sfc_rxq_info *new_rxq_info;
if (nb_rx_queues < sa->rxq_count)
sfc_rx_fini_queues(sa, nb_rx_queues);
rc = ENOMEM;
new_rxq_info =
rte_realloc(sa->rxq_info,
nb_rx_queues * sizeof(sa->rxq_info[0]), 0);
if (new_rxq_info == NULL && nb_rx_queues > 0)
goto fail_rxqs_realloc;
sa->rxq_info = new_rxq_info;
if (nb_rx_queues > sa->rxq_count)
memset(&sa->rxq_info[sa->rxq_count], 0,
(nb_rx_queues - sa->rxq_count) *
sizeof(sa->rxq_info[0]));
}
while (sa->rxq_count < nb_rx_queues) {
rc = sfc_rx_qinit_info(sa, sa->rxq_count);
if (rc != 0)
goto fail_rx_qinit_info;
sa->rxq_count++;
}
rss->channels = (dev_conf->rxmode.mq_mode == ETH_MQ_RX_RSS) ?
MIN(sa->rxq_count, EFX_MAXRSS) : 0;
if (rss->channels > 0) {
struct rte_eth_rss_conf *adv_conf_rss;
unsigned int sw_index;
for (sw_index = 0; sw_index < EFX_RSS_TBL_SIZE; ++sw_index)
rss->tbl[sw_index] = sw_index % rss->channels;
adv_conf_rss = &dev_conf->rx_adv_conf.rss_conf;
rc = sfc_rx_process_adv_conf_rss(sa, adv_conf_rss);
if (rc != 0)
goto fail_rx_process_adv_conf_rss;
}
done:
return 0;
fail_rx_process_adv_conf_rss:
fail_rx_qinit_info:
fail_rxqs_realloc:
fail_rxqs_alloc:
sfc_rx_close(sa);
fail_check_mode:
sfc_log_init(sa, "failed %d", rc);
return rc;
}
/**
* Shutdown Rx subsystem.
*
* Called at device close stage, for example, before device shutdown.
*/
void
sfc_rx_close(struct sfc_adapter *sa)
{
struct sfc_rss *rss = &sa->rss;
sfc_rx_fini_queues(sa, 0);
rss->channels = 0;
rte_free(sa->rxq_info);
sa->rxq_info = NULL;
}
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