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numam-dpdk/drivers/net/mlx4/mlx4_mr.c
Feifei Wang f0f7c557f3 net/mlx4: remove barrier for memory region cache 
'dev_gen' is a variable to trigger all cores to flush their local caches
once the global MR cache has been rebuilt.

This is due to MR cache's R/W lock can maintain synchronization between
threads:

1. dev_gen and global cache updating ordering inside the lock protected
section does not matter. Because other threads cannot take the lock
until global cache has been updated. Thus, in out of order platform,
even if other agents firstly observe updated dev_gen but global does
not update, they still have to wait the lock. As a result, it is
unnecessary to add a wmb between global cache rebuilding and updating
the dev_gen to keep the memory store order.

2. Store-Release of unlock provides the implicit wmb at the level
visible by software. This makes 'rebuilding global cache' and 'updating
dev_gen' be observed before local_cache starts to be updated by other
agents. Thus, wmb after 'updating dev_gen' can be removed.

Suggested-by: Ruifeng Wang <ruifeng.wang@arm.com>
Signed-off-by: Feifei Wang <feifei.wang2@arm.com>
Reviewed-by: Ruifeng Wang <ruifeng.wang@arm.com>
Acked-by: Viacheslav Ovsiienko <viacheslavo@nvidia.com>
2021-06-23 17:02:35 +02:00

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/* SPDX-License-Identifier: BSD-3-Clause
* Copyright 2017 6WIND S.A.
* Copyright 2017 Mellanox Technologies, Ltd
*/
/**
* @file
* Memory management functions for mlx4 driver.
*/
#include <errno.h>
#include <inttypes.h>
#include <stddef.h>
#include <stdint.h>
#include <string.h>
/* Verbs headers do not support -pedantic. */
#ifdef PEDANTIC
#pragma GCC diagnostic ignored "-Wpedantic"
#endif
#include <infiniband/verbs.h>
#ifdef PEDANTIC
#pragma GCC diagnostic error "-Wpedantic"
#endif
#include <rte_branch_prediction.h>
#include <rte_common.h>
#include <rte_eal_memconfig.h>
#include <rte_errno.h>
#include <rte_malloc.h>
#include <rte_memory.h>
#include <rte_mempool.h>
#include <rte_rwlock.h>
#include "mlx4_glue.h"
#include "mlx4_mr.h"
#include "mlx4_rxtx.h"
#include "mlx4_utils.h"
struct mr_find_contig_memsegs_data {
uintptr_t addr;
uintptr_t start;
uintptr_t end;
const struct rte_memseg_list *msl;
};
struct mr_update_mp_data {
struct rte_eth_dev *dev;
struct mlx4_mr_ctrl *mr_ctrl;
int ret;
};
/**
* Expand B-tree table to a given size. Can't be called with holding
* memory_hotplug_lock or priv->mr.rwlock due to rte_realloc().
*
* @param bt
* Pointer to B-tree structure.
* @param n
* Number of entries for expansion.
*
* @return
* 0 on success, -1 on failure.
*/
static int
mr_btree_expand(struct mlx4_mr_btree *bt, int n)
{
void *mem;
int ret = 0;
if (n <= bt->size)
return ret;
/*
* Downside of directly using rte_realloc() is that SOCKET_ID_ANY is
* used inside if there's no room to expand. Because this is a quite
* rare case and a part of very slow path, it is very acceptable.
* Initially cache_bh[] will be given practically enough space and once
* it is expanded, expansion wouldn't be needed again ever.
*/
mem = rte_realloc(bt->table, n * sizeof(struct mlx4_mr_cache), 0);
if (mem == NULL) {
/* Not an error, B-tree search will be skipped. */
WARN("failed to expand MR B-tree (%p) table", (void *)bt);
ret = -1;
} else {
DEBUG("expanded MR B-tree table (size=%u)", n);
bt->table = mem;
bt->size = n;
}
return ret;
}
/**
* Look up LKey from given B-tree lookup table, store the last index and return
* searched LKey.
*
* @param bt
* Pointer to B-tree structure.
* @param[out] idx
* Pointer to index. Even on search failure, returns index where it stops
* searching so that index can be used when inserting a new entry.
* @param addr
* Search key.
*
* @return
* Searched LKey on success, UINT32_MAX on no match.
*/
static uint32_t
mr_btree_lookup(struct mlx4_mr_btree *bt, uint16_t *idx, uintptr_t addr)
{
struct mlx4_mr_cache *lkp_tbl;
uint16_t n;
uint16_t base = 0;
MLX4_ASSERT(bt != NULL);
lkp_tbl = *bt->table;
n = bt->len;
/* First entry must be NULL for comparison. */
MLX4_ASSERT(bt->len > 0 || (lkp_tbl[0].start == 0 &&
lkp_tbl[0].lkey == UINT32_MAX));
/* Binary search. */
do {
register uint16_t delta = n >> 1;
if (addr < lkp_tbl[base + delta].start) {
n = delta;
} else {
base += delta;
n -= delta;
}
} while (n > 1);
MLX4_ASSERT(addr >= lkp_tbl[base].start);
*idx = base;
if (addr < lkp_tbl[base].end)
return lkp_tbl[base].lkey;
/* Not found. */
return UINT32_MAX;
}
/**
* Insert an entry to B-tree lookup table.
*
* @param bt
* Pointer to B-tree structure.
* @param entry
* Pointer to new entry to insert.
*
* @return
* 0 on success, -1 on failure.
*/
static int
mr_btree_insert(struct mlx4_mr_btree *bt, struct mlx4_mr_cache *entry)
{
struct mlx4_mr_cache *lkp_tbl;
uint16_t idx = 0;
size_t shift;
MLX4_ASSERT(bt != NULL);
MLX4_ASSERT(bt->len <= bt->size);
MLX4_ASSERT(bt->len > 0);
lkp_tbl = *bt->table;
/* Find out the slot for insertion. */
if (mr_btree_lookup(bt, &idx, entry->start) != UINT32_MAX) {
DEBUG("abort insertion to B-tree(%p): already exist at"
" idx=%u [0x%" PRIxPTR ", 0x%" PRIxPTR ") lkey=0x%x",
(void *)bt, idx, entry->start, entry->end, entry->lkey);
/* Already exist, return. */
return 0;
}
/* If table is full, return error. */
if (unlikely(bt->len == bt->size)) {
bt->overflow = 1;
return -1;
}
/* Insert entry. */
++idx;
shift = (bt->len - idx) * sizeof(struct mlx4_mr_cache);
if (shift)
memmove(&lkp_tbl[idx + 1], &lkp_tbl[idx], shift);
lkp_tbl[idx] = *entry;
bt->len++;
DEBUG("inserted B-tree(%p)[%u],"
" [0x%" PRIxPTR ", 0x%" PRIxPTR ") lkey=0x%x",
(void *)bt, idx, entry->start, entry->end, entry->lkey);
return 0;
}
/**
* Initialize B-tree and allocate memory for lookup table.
*
* @param bt
* Pointer to B-tree structure.
* @param n
* Number of entries to allocate.
* @param socket
* NUMA socket on which memory must be allocated.
*
* @return
* 0 on success, a negative errno value otherwise and rte_errno is set.
*/
int
mlx4_mr_btree_init(struct mlx4_mr_btree *bt, int n, int socket)
{
if (bt == NULL) {
rte_errno = EINVAL;
return -rte_errno;
}
memset(bt, 0, sizeof(*bt));
bt->table = rte_calloc_socket("B-tree table",
n, sizeof(struct mlx4_mr_cache),
0, socket);
if (bt->table == NULL) {
rte_errno = ENOMEM;
ERROR("failed to allocate memory for btree cache on socket %d",
socket);
return -rte_errno;
}
bt->size = n;
/* First entry must be NULL for binary search. */
(*bt->table)[bt->len++] = (struct mlx4_mr_cache) {
.lkey = UINT32_MAX,
};
DEBUG("initialized B-tree %p with table %p",
(void *)bt, (void *)bt->table);
return 0;
}
/**
* Free B-tree resources.
*
* @param bt
* Pointer to B-tree structure.
*/
void
mlx4_mr_btree_free(struct mlx4_mr_btree *bt)
{
if (bt == NULL)
return;
DEBUG("freeing B-tree %p with table %p", (void *)bt, (void *)bt->table);
rte_free(bt->table);
memset(bt, 0, sizeof(*bt));
}
#ifdef RTE_LIBRTE_MLX4_DEBUG
/**
* Dump all the entries in a B-tree
*
* @param bt
* Pointer to B-tree structure.
*/
void
mlx4_mr_btree_dump(struct mlx4_mr_btree *bt)
{
int idx;
struct mlx4_mr_cache *lkp_tbl;
if (bt == NULL)
return;
lkp_tbl = *bt->table;
for (idx = 0; idx < bt->len; ++idx) {
struct mlx4_mr_cache *entry = &lkp_tbl[idx];
DEBUG("B-tree(%p)[%u],"
" [0x%" PRIxPTR ", 0x%" PRIxPTR ") lkey=0x%x",
(void *)bt, idx, entry->start, entry->end, entry->lkey);
}
}
#endif
/**
* Find virtually contiguous memory chunk in a given MR.
*
* @param dev
* Pointer to MR structure.
* @param[out] entry
* Pointer to returning MR cache entry. If not found, this will not be
* updated.
* @param start_idx
* Start index of the memseg bitmap.
*
* @return
* Next index to go on lookup.
*/
static int
mr_find_next_chunk(struct mlx4_mr *mr, struct mlx4_mr_cache *entry,
int base_idx)
{
uintptr_t start = 0;
uintptr_t end = 0;
uint32_t idx = 0;
/* MR for external memory doesn't have memseg list. */
if (mr->msl == NULL) {
struct ibv_mr *ibv_mr = mr->ibv_mr;
MLX4_ASSERT(mr->ms_bmp_n == 1);
MLX4_ASSERT(mr->ms_n == 1);
MLX4_ASSERT(base_idx == 0);
/*
* Can't search it from memseg list but get it directly from
* verbs MR as there's only one chunk.
*/
entry->start = (uintptr_t)ibv_mr->addr;
entry->end = (uintptr_t)ibv_mr->addr + mr->ibv_mr->length;
entry->lkey = rte_cpu_to_be_32(mr->ibv_mr->lkey);
/* Returning 1 ends iteration. */
return 1;
}
for (idx = base_idx; idx < mr->ms_bmp_n; ++idx) {
if (rte_bitmap_get(mr->ms_bmp, idx)) {
const struct rte_memseg_list *msl;
const struct rte_memseg *ms;
msl = mr->msl;
ms = rte_fbarray_get(&msl->memseg_arr,
mr->ms_base_idx + idx);
MLX4_ASSERT(msl->page_sz == ms->hugepage_sz);
if (!start)
start = ms->addr_64;
end = ms->addr_64 + ms->hugepage_sz;
} else if (start) {
/* Passed the end of a fragment. */
break;
}
}
if (start) {
/* Found one chunk. */
entry->start = start;
entry->end = end;
entry->lkey = rte_cpu_to_be_32(mr->ibv_mr->lkey);
}
return idx;
}
/**
* Insert a MR to the global B-tree cache. It may fail due to low-on-memory.
* Then, this entry will have to be searched by mr_lookup_dev_list() in
* mlx4_mr_create() on miss.
*
* @param dev
* Pointer to Ethernet device.
* @param mr
* Pointer to MR to insert.
*
* @return
* 0 on success, -1 on failure.
*/
static int
mr_insert_dev_cache(struct rte_eth_dev *dev, struct mlx4_mr *mr)
{
struct mlx4_priv *priv = dev->data->dev_private;
unsigned int n;
DEBUG("port %u inserting MR(%p) to global cache",
dev->data->port_id, (void *)mr);
for (n = 0; n < mr->ms_bmp_n; ) {
struct mlx4_mr_cache entry;
memset(&entry, 0, sizeof(entry));
/* Find a contiguous chunk and advance the index. */
n = mr_find_next_chunk(mr, &entry, n);
if (!entry.end)
break;
if (mr_btree_insert(&priv->mr.cache, &entry) < 0) {
/*
* Overflowed, but the global table cannot be expanded
* because of deadlock.
*/
return -1;
}
}
return 0;
}
/**
* Look up address in the original global MR list.
*
* @param dev
* Pointer to Ethernet device.
* @param[out] entry
* Pointer to returning MR cache entry. If no match, this will not be updated.
* @param addr
* Search key.
*
* @return
* Found MR on match, NULL otherwise.
*/
static struct mlx4_mr *
mr_lookup_dev_list(struct rte_eth_dev *dev, struct mlx4_mr_cache *entry,
uintptr_t addr)
{
struct mlx4_priv *priv = dev->data->dev_private;
struct mlx4_mr *mr;
/* Iterate all the existing MRs. */
LIST_FOREACH(mr, &priv->mr.mr_list, mr) {
unsigned int n;
if (mr->ms_n == 0)
continue;
for (n = 0; n < mr->ms_bmp_n; ) {
struct mlx4_mr_cache ret;
memset(&ret, 0, sizeof(ret));
n = mr_find_next_chunk(mr, &ret, n);
if (addr >= ret.start && addr < ret.end) {
/* Found. */
*entry = ret;
return mr;
}
}
}
return NULL;
}
/**
* Look up address on device.
*
* @param dev
* Pointer to Ethernet device.
* @param[out] entry
* Pointer to returning MR cache entry. If no match, this will not be updated.
* @param addr
* Search key.
*
* @return
* Searched LKey on success, UINT32_MAX on failure and rte_errno is set.
*/
static uint32_t
mr_lookup_dev(struct rte_eth_dev *dev, struct mlx4_mr_cache *entry,
uintptr_t addr)
{
struct mlx4_priv *priv = dev->data->dev_private;
uint16_t idx;
uint32_t lkey = UINT32_MAX;
struct mlx4_mr *mr;
/*
* If the global cache has overflowed since it failed to expand the
* B-tree table, it can't have all the existing MRs. Then, the address
* has to be searched by traversing the original MR list instead, which
* is very slow path. Otherwise, the global cache is all inclusive.
*/
if (!unlikely(priv->mr.cache.overflow)) {
lkey = mr_btree_lookup(&priv->mr.cache, &idx, addr);
if (lkey != UINT32_MAX)
*entry = (*priv->mr.cache.table)[idx];
} else {
/* Falling back to the slowest path. */
mr = mr_lookup_dev_list(dev, entry, addr);
if (mr != NULL)
lkey = entry->lkey;
}
MLX4_ASSERT(lkey == UINT32_MAX || (addr >= entry->start &&
addr < entry->end));
return lkey;
}
/**
* Free MR resources. MR lock must not be held to avoid a deadlock. rte_free()
* can raise memory free event and the callback function will spin on the lock.
*
* @param mr
* Pointer to MR to free.
*/
static void
mr_free(struct mlx4_mr *mr)
{
if (mr == NULL)
return;
DEBUG("freeing MR(%p):", (void *)mr);
if (mr->ibv_mr != NULL)
claim_zero(mlx4_glue->dereg_mr(mr->ibv_mr));
if (mr->ms_bmp != NULL)
rte_bitmap_free(mr->ms_bmp);
rte_free(mr);
}
/**
* Release resources of detached MR having no online entry.
*
* @param dev
* Pointer to Ethernet device.
*/
static void
mlx4_mr_garbage_collect(struct rte_eth_dev *dev)
{
struct mlx4_priv *priv = dev->data->dev_private;
struct mlx4_mr *mr_next;
struct mlx4_mr_list free_list = LIST_HEAD_INITIALIZER(free_list);
/* Must be called from the primary process. */
MLX4_ASSERT(rte_eal_process_type() == RTE_PROC_PRIMARY);
/*
* MR can't be freed with holding the lock because rte_free() could call
* memory free callback function. This will be a deadlock situation.
*/
rte_rwlock_write_lock(&priv->mr.rwlock);
/* Detach the whole free list and release it after unlocking. */
free_list = priv->mr.mr_free_list;
LIST_INIT(&priv->mr.mr_free_list);
rte_rwlock_write_unlock(&priv->mr.rwlock);
/* Release resources. */
mr_next = LIST_FIRST(&free_list);
while (mr_next != NULL) {
struct mlx4_mr *mr = mr_next;
mr_next = LIST_NEXT(mr, mr);
mr_free(mr);
}
}
/* Called during rte_memseg_contig_walk() by mlx4_mr_create(). */
static int
mr_find_contig_memsegs_cb(const struct rte_memseg_list *msl,
const struct rte_memseg *ms, size_t len, void *arg)
{
struct mr_find_contig_memsegs_data *data = arg;
if (data->addr < ms->addr_64 || data->addr >= ms->addr_64 + len)
return 0;
/* Found, save it and stop walking. */
data->start = ms->addr_64;
data->end = ms->addr_64 + len;
data->msl = msl;
return 1;
}
/**
* Create a new global Memory Region (MR) for a missing virtual address.
* This API should be called on a secondary process, then a request is sent to
* the primary process in order to create a MR for the address. As the global MR
* list is on the shared memory, following LKey lookup should succeed unless the
* request fails.
*
* @param dev
* Pointer to Ethernet device.
* @param[out] entry
* Pointer to returning MR cache entry, found in the global cache or newly
* created. If failed to create one, this will not be updated.
* @param addr
* Target virtual address to register.
*
* @return
* Searched LKey on success, UINT32_MAX on failure and rte_errno is set.
*/
static uint32_t
mlx4_mr_create_secondary(struct rte_eth_dev *dev, struct mlx4_mr_cache *entry,
uintptr_t addr)
{
struct mlx4_priv *priv = dev->data->dev_private;
int ret;
DEBUG("port %u requesting MR creation for address (%p)",
dev->data->port_id, (void *)addr);
ret = mlx4_mp_req_mr_create(dev, addr);
if (ret) {
DEBUG("port %u fail to request MR creation for address (%p)",
dev->data->port_id, (void *)addr);
return UINT32_MAX;
}
rte_rwlock_read_lock(&priv->mr.rwlock);
/* Fill in output data. */
mr_lookup_dev(dev, entry, addr);
/* Lookup can't fail. */
MLX4_ASSERT(entry->lkey != UINT32_MAX);
rte_rwlock_read_unlock(&priv->mr.rwlock);
DEBUG("port %u MR CREATED by primary process for %p:\n"
" [0x%" PRIxPTR ", 0x%" PRIxPTR "), lkey=0x%x",
dev->data->port_id, (void *)addr,
entry->start, entry->end, entry->lkey);
return entry->lkey;
}
/**
* Create a new global Memory Region (MR) for a missing virtual address.
* Register entire virtually contiguous memory chunk around the address.
* This must be called from the primary process.
*
* @param dev
* Pointer to Ethernet device.
* @param[out] entry
* Pointer to returning MR cache entry, found in the global cache or newly
* created. If failed to create one, this will not be updated.
* @param addr
* Target virtual address to register.
*
* @return
* Searched LKey on success, UINT32_MAX on failure and rte_errno is set.
*/
uint32_t
mlx4_mr_create_primary(struct rte_eth_dev *dev, struct mlx4_mr_cache *entry,
uintptr_t addr)
{
struct mlx4_priv *priv = dev->data->dev_private;
const struct rte_memseg_list *msl;
const struct rte_memseg *ms;
struct mlx4_mr *mr = NULL;
size_t len;
uint32_t ms_n;
uint32_t bmp_size;
void *bmp_mem;
int ms_idx_shift = -1;
unsigned int n;
struct mr_find_contig_memsegs_data data = {
.addr = addr,
};
struct mr_find_contig_memsegs_data data_re;
DEBUG("port %u creating a MR using address (%p)",
dev->data->port_id, (void *)addr);
/*
* Release detached MRs if any. This can't be called with holding either
* memory_hotplug_lock or priv->mr.rwlock. MRs on the free list have
* been detached by the memory free event but it couldn't be released
* inside the callback due to deadlock. As a result, releasing resources
* is quite opportunistic.
*/
mlx4_mr_garbage_collect(dev);
/*
* If enabled, find out a contiguous virtual address chunk in use, to
* which the given address belongs, in order to register maximum range.
* In the best case where mempools are not dynamically recreated and
* '--socket-mem' is specified as an EAL option, it is very likely to
* have only one MR(LKey) per a socket and per a hugepage-size even
* though the system memory is highly fragmented. As the whole memory
* chunk will be pinned by kernel, it can't be reused unless entire
* chunk is freed from EAL.
*
* If disabled, just register one memseg (page). Then, memory
* consumption will be minimized but it may drop performance if there
* are many MRs to lookup on the datapath.
*/
if (!priv->mr_ext_memseg_en) {
data.msl = rte_mem_virt2memseg_list((void *)addr);
data.start = RTE_ALIGN_FLOOR(addr, data.msl->page_sz);
data.end = data.start + data.msl->page_sz;
} else if (!rte_memseg_contig_walk(mr_find_contig_memsegs_cb, &data)) {
WARN("port %u unable to find virtually contiguous"
" chunk for address (%p)."
" rte_memseg_contig_walk() failed.",
dev->data->port_id, (void *)addr);
rte_errno = ENXIO;
goto err_nolock;
}
alloc_resources:
/* Addresses must be page-aligned. */
MLX4_ASSERT(rte_is_aligned((void *)data.start, data.msl->page_sz));
MLX4_ASSERT(rte_is_aligned((void *)data.end, data.msl->page_sz));
msl = data.msl;
ms = rte_mem_virt2memseg((void *)data.start, msl);
len = data.end - data.start;
MLX4_ASSERT(msl->page_sz == ms->hugepage_sz);
/* Number of memsegs in the range. */
ms_n = len / msl->page_sz;
DEBUG("port %u extending %p to [0x%" PRIxPTR ", 0x%" PRIxPTR "),"
" page_sz=0x%" PRIx64 ", ms_n=%u",
dev->data->port_id, (void *)addr,
data.start, data.end, msl->page_sz, ms_n);
/* Size of memory for bitmap. */
bmp_size = rte_bitmap_get_memory_footprint(ms_n);
mr = rte_zmalloc_socket(NULL,
RTE_ALIGN_CEIL(sizeof(*mr),
RTE_CACHE_LINE_SIZE) +
bmp_size,
RTE_CACHE_LINE_SIZE, msl->socket_id);
if (mr == NULL) {
WARN("port %u unable to allocate memory for a new MR of"
" address (%p).",
dev->data->port_id, (void *)addr);
rte_errno = ENOMEM;
goto err_nolock;
}
mr->msl = msl;
/*
* Save the index of the first memseg and initialize memseg bitmap. To
* see if a memseg of ms_idx in the memseg-list is still valid, check:
* rte_bitmap_get(mr->bmp, ms_idx - mr->ms_base_idx)
*/
mr->ms_base_idx = rte_fbarray_find_idx(&msl->memseg_arr, ms);
bmp_mem = RTE_PTR_ALIGN_CEIL(mr + 1, RTE_CACHE_LINE_SIZE);
mr->ms_bmp = rte_bitmap_init(ms_n, bmp_mem, bmp_size);
if (mr->ms_bmp == NULL) {
WARN("port %u unable to initialize bitmap for a new MR of"
" address (%p).",
dev->data->port_id, (void *)addr);
rte_errno = EINVAL;
goto err_nolock;
}
/*
* Should recheck whether the extended contiguous chunk is still valid.
* Because memory_hotplug_lock can't be held if there's any memory
* related calls in a critical path, resource allocation above can't be
* locked. If the memory has been changed at this point, try again with
* just single page. If not, go on with the big chunk atomically from
* here.
*/
rte_mcfg_mem_read_lock();
data_re = data;
if (len > msl->page_sz &&
!rte_memseg_contig_walk(mr_find_contig_memsegs_cb, &data_re)) {
WARN("port %u unable to find virtually contiguous"
" chunk for address (%p)."
" rte_memseg_contig_walk() failed.",
dev->data->port_id, (void *)addr);
rte_errno = ENXIO;
goto err_memlock;
}
if (data.start != data_re.start || data.end != data_re.end) {
/*
* The extended contiguous chunk has been changed. Try again
* with single memseg instead.
*/
data.start = RTE_ALIGN_FLOOR(addr, msl->page_sz);
data.end = data.start + msl->page_sz;
rte_mcfg_mem_read_unlock();
mr_free(mr);
goto alloc_resources;
}
MLX4_ASSERT(data.msl == data_re.msl);
rte_rwlock_write_lock(&priv->mr.rwlock);
/*
* Check the address is really missing. If other thread already created
* one or it is not found due to overflow, abort and return.
*/
if (mr_lookup_dev(dev, entry, addr) != UINT32_MAX) {
/*
* Insert to the global cache table. It may fail due to
* low-on-memory. Then, this entry will have to be searched
* here again.
*/
mr_btree_insert(&priv->mr.cache, entry);
DEBUG("port %u found MR for %p on final lookup, abort",
dev->data->port_id, (void *)addr);
rte_rwlock_write_unlock(&priv->mr.rwlock);
rte_mcfg_mem_read_unlock();
/*
* Must be unlocked before calling rte_free() because
* mlx4_mr_mem_event_free_cb() can be called inside.
*/
mr_free(mr);
return entry->lkey;
}
/*
* Trim start and end addresses for verbs MR. Set bits for registering
* memsegs but exclude already registered ones. Bitmap can be
* fragmented.
*/
for (n = 0; n < ms_n; ++n) {
uintptr_t start;
struct mlx4_mr_cache ret;
memset(&ret, 0, sizeof(ret));
start = data_re.start + n * msl->page_sz;
/* Exclude memsegs already registered by other MRs. */
if (mr_lookup_dev(dev, &ret, start) == UINT32_MAX) {
/*
* Start from the first unregistered memseg in the
* extended range.
*/
if (ms_idx_shift == -1) {
mr->ms_base_idx += n;
data.start = start;
ms_idx_shift = n;
}
data.end = start + msl->page_sz;
rte_bitmap_set(mr->ms_bmp, n - ms_idx_shift);
++mr->ms_n;
}
}
len = data.end - data.start;
mr->ms_bmp_n = len / msl->page_sz;
MLX4_ASSERT(ms_idx_shift + mr->ms_bmp_n <= ms_n);
/*
* Finally create a verbs MR for the memory chunk. ibv_reg_mr() can be
* called with holding the memory lock because it doesn't use
* mlx4_alloc_buf_extern() which eventually calls rte_malloc_socket()
* through mlx4_alloc_verbs_buf().
*/
mr->ibv_mr = mlx4_glue->reg_mr(priv->pd, (void *)data.start, len,
IBV_ACCESS_LOCAL_WRITE);
if (mr->ibv_mr == NULL) {
WARN("port %u fail to create a verbs MR for address (%p)",
dev->data->port_id, (void *)addr);
rte_errno = EINVAL;
goto err_mrlock;
}
MLX4_ASSERT((uintptr_t)mr->ibv_mr->addr == data.start);
MLX4_ASSERT(mr->ibv_mr->length == len);
LIST_INSERT_HEAD(&priv->mr.mr_list, mr, mr);
DEBUG("port %u MR CREATED (%p) for %p:\n"
" [0x%" PRIxPTR ", 0x%" PRIxPTR "),"
" lkey=0x%x base_idx=%u ms_n=%u, ms_bmp_n=%u",
dev->data->port_id, (void *)mr, (void *)addr,
data.start, data.end, rte_cpu_to_be_32(mr->ibv_mr->lkey),
mr->ms_base_idx, mr->ms_n, mr->ms_bmp_n);
/* Insert to the global cache table. */
mr_insert_dev_cache(dev, mr);
/* Fill in output data. */
mr_lookup_dev(dev, entry, addr);
/* Lookup can't fail. */
MLX4_ASSERT(entry->lkey != UINT32_MAX);
rte_rwlock_write_unlock(&priv->mr.rwlock);
rte_mcfg_mem_read_unlock();
return entry->lkey;
err_mrlock:
rte_rwlock_write_unlock(&priv->mr.rwlock);
err_memlock:
rte_mcfg_mem_read_unlock();
err_nolock:
/*
* In case of error, as this can be called in a datapath, a warning
* message per an error is preferable instead. Must be unlocked before
* calling rte_free() because mlx4_mr_mem_event_free_cb() can be called
* inside.
*/
mr_free(mr);
return UINT32_MAX;
}
/**
* Create a new global Memory Region (MR) for a missing virtual address.
* This can be called from primary and secondary process.
*
* @param dev
* Pointer to Ethernet device.
* @param[out] entry
* Pointer to returning MR cache entry, found in the global cache or newly
* created. If failed to create one, this will not be updated.
* @param addr
* Target virtual address to register.
*
* @return
* Searched LKey on success, UINT32_MAX on failure and rte_errno is set.
*/
static uint32_t
mlx4_mr_create(struct rte_eth_dev *dev, struct mlx4_mr_cache *entry,
uintptr_t addr)
{
uint32_t ret = 0;
switch (rte_eal_process_type()) {
case RTE_PROC_PRIMARY:
ret = mlx4_mr_create_primary(dev, entry, addr);
break;
case RTE_PROC_SECONDARY:
ret = mlx4_mr_create_secondary(dev, entry, addr);
break;
default:
break;
}
return ret;
}
/**
* Rebuild the global B-tree cache of device from the original MR list.
*
* @param dev
* Pointer to Ethernet device.
*/
static void
mr_rebuild_dev_cache(struct rte_eth_dev *dev)
{
struct mlx4_priv *priv = dev->data->dev_private;
struct mlx4_mr *mr;
DEBUG("port %u rebuild dev cache[]", dev->data->port_id);
/* Flush cache to rebuild. */
priv->mr.cache.len = 1;
priv->mr.cache.overflow = 0;
/* Iterate all the existing MRs. */
LIST_FOREACH(mr, &priv->mr.mr_list, mr)
if (mr_insert_dev_cache(dev, mr) < 0)
return;
}
/**
* Callback for memory free event. Iterate freed memsegs and check whether it
* belongs to an existing MR. If found, clear the bit from bitmap of MR. As a
* result, the MR would be fragmented. If it becomes empty, the MR will be freed
* later by mlx4_mr_garbage_collect().
*
* The global cache must be rebuilt if there's any change and this event has to
* be propagated to dataplane threads to flush the local caches.
*
* @param dev
* Pointer to Ethernet device.
* @param addr
* Address of freed memory.
* @param len
* Size of freed memory.
*/
static void
mlx4_mr_mem_event_free_cb(struct rte_eth_dev *dev, const void *addr, size_t len)
{
struct mlx4_priv *priv = dev->data->dev_private;
const struct rte_memseg_list *msl;
struct mlx4_mr *mr;
int ms_n;
int i;
int rebuild = 0;
DEBUG("port %u free callback: addr=%p, len=%zu",
dev->data->port_id, addr, len);
msl = rte_mem_virt2memseg_list(addr);
/* addr and len must be page-aligned. */
MLX4_ASSERT((uintptr_t)addr ==
RTE_ALIGN((uintptr_t)addr, msl->page_sz));
MLX4_ASSERT(len == RTE_ALIGN(len, msl->page_sz));
ms_n = len / msl->page_sz;
rte_rwlock_write_lock(&priv->mr.rwlock);
/* Clear bits of freed memsegs from MR. */
for (i = 0; i < ms_n; ++i) {
const struct rte_memseg *ms;
struct mlx4_mr_cache entry;
uintptr_t start;
int ms_idx;
uint32_t pos;
/* Find MR having this memseg. */
start = (uintptr_t)addr + i * msl->page_sz;
mr = mr_lookup_dev_list(dev, &entry, start);
if (mr == NULL)
continue;
MLX4_ASSERT(mr->msl); /* Can't be external memory. */
ms = rte_mem_virt2memseg((void *)start, msl);
MLX4_ASSERT(ms != NULL);
MLX4_ASSERT(msl->page_sz == ms->hugepage_sz);
ms_idx = rte_fbarray_find_idx(&msl->memseg_arr, ms);
pos = ms_idx - mr->ms_base_idx;
MLX4_ASSERT(rte_bitmap_get(mr->ms_bmp, pos));
MLX4_ASSERT(pos < mr->ms_bmp_n);
DEBUG("port %u MR(%p): clear bitmap[%u] for addr %p",
dev->data->port_id, (void *)mr, pos, (void *)start);
rte_bitmap_clear(mr->ms_bmp, pos);
if (--mr->ms_n == 0) {
LIST_REMOVE(mr, mr);
LIST_INSERT_HEAD(&priv->mr.mr_free_list, mr, mr);
DEBUG("port %u remove MR(%p) from list",
dev->data->port_id, (void *)mr);
}
/*
* MR is fragmented or will be freed. the global cache must be
* rebuilt.
*/
rebuild = 1;
}
if (rebuild) {
mr_rebuild_dev_cache(dev);
/*
* No explicit wmb is needed after updating dev_gen due to
* store-release ordering in unlock that provides the
* implicit barrier at the software visible level.
*/
++priv->mr.dev_gen;
DEBUG("broadcasting local cache flush, gen=%d",
priv->mr.dev_gen);
}
rte_rwlock_write_unlock(&priv->mr.rwlock);
#ifdef RTE_LIBRTE_MLX4_DEBUG
if (rebuild)
mlx4_mr_dump_dev(dev);
#endif
}
/**
* Callback for memory event.
*
* @param event_type
* Memory event type.
* @param addr
* Address of memory.
* @param len
* Size of memory.
*/
void
mlx4_mr_mem_event_cb(enum rte_mem_event event_type, const void *addr,
size_t len, void *arg __rte_unused)
{
struct mlx4_priv *priv;
struct mlx4_dev_list *dev_list = &mlx4_shared_data->mem_event_cb_list;
/* Must be called from the primary process. */
MLX4_ASSERT(rte_eal_process_type() == RTE_PROC_PRIMARY);
switch (event_type) {
case RTE_MEM_EVENT_FREE:
rte_rwlock_read_lock(&mlx4_shared_data->mem_event_rwlock);
/* Iterate all the existing mlx4 devices. */
LIST_FOREACH(priv, dev_list, mem_event_cb)
mlx4_mr_mem_event_free_cb(ETH_DEV(priv), addr, len);
rte_rwlock_read_unlock(&mlx4_shared_data->mem_event_rwlock);
break;
case RTE_MEM_EVENT_ALLOC:
default:
break;
}
}
/**
* Look up address in the global MR cache table. If not found, create a new MR.
* Insert the found/created entry to local bottom-half cache table.
*
* @param dev
* Pointer to Ethernet device.
* @param mr_ctrl
* Pointer to per-queue MR control structure.
* @param[out] entry
* Pointer to returning MR cache entry, found in the global cache or newly
* created. If failed to create one, this is not written.
* @param addr
* Search key.
*
* @return
* Searched LKey on success, UINT32_MAX on no match.
*/
static uint32_t
mlx4_mr_lookup_dev(struct rte_eth_dev *dev, struct mlx4_mr_ctrl *mr_ctrl,
struct mlx4_mr_cache *entry, uintptr_t addr)
{
struct mlx4_priv *priv = dev->data->dev_private;
struct mlx4_mr_btree *bt = &mr_ctrl->cache_bh;
uint16_t idx;
uint32_t lkey;
/* If local cache table is full, try to double it. */
if (unlikely(bt->len == bt->size))
mr_btree_expand(bt, bt->size << 1);
/* Look up in the global cache. */
rte_rwlock_read_lock(&priv->mr.rwlock);
lkey = mr_btree_lookup(&priv->mr.cache, &idx, addr);
if (lkey != UINT32_MAX) {
/* Found. */
*entry = (*priv->mr.cache.table)[idx];
rte_rwlock_read_unlock(&priv->mr.rwlock);
/*
* Update local cache. Even if it fails, return the found entry
* to update top-half cache. Next time, this entry will be found
* in the global cache.
*/
mr_btree_insert(bt, entry);
return lkey;
}
rte_rwlock_read_unlock(&priv->mr.rwlock);
/* First time to see the address? Create a new MR. */
lkey = mlx4_mr_create(dev, entry, addr);
/*
* Update the local cache if successfully created a new global MR. Even
* if failed to create one, there's no action to take in this datapath
* code. As returning LKey is invalid, this will eventually make HW
* fail.
*/
if (lkey != UINT32_MAX)
mr_btree_insert(bt, entry);
return lkey;
}
/**
* Bottom-half of LKey search on datapath. Firstly search in cache_bh[] and if
* misses, search in the global MR cache table and update the new entry to
* per-queue local caches.
*
* @param dev
* Pointer to Ethernet device.
* @param mr_ctrl
* Pointer to per-queue MR control structure.
* @param addr
* Search key.
*
* @return
* Searched LKey on success, UINT32_MAX on no match.
*/
static uint32_t
mlx4_mr_addr2mr_bh(struct rte_eth_dev *dev, struct mlx4_mr_ctrl *mr_ctrl,
uintptr_t addr)
{
uint32_t lkey;
uint16_t bh_idx = 0;
/* Victim in top-half cache to replace with new entry. */
struct mlx4_mr_cache *repl = &mr_ctrl->cache[mr_ctrl->head];
/* Binary-search MR translation table. */
lkey = mr_btree_lookup(&mr_ctrl->cache_bh, &bh_idx, addr);
/* Update top-half cache. */
if (likely(lkey != UINT32_MAX)) {
*repl = (*mr_ctrl->cache_bh.table)[bh_idx];
} else {
/*
* If missed in local lookup table, search in the global cache
* and local cache_bh[] will be updated inside if possible.
* Top-half cache entry will also be updated.
*/
lkey = mlx4_mr_lookup_dev(dev, mr_ctrl, repl, addr);
if (unlikely(lkey == UINT32_MAX))
return UINT32_MAX;
}
/* Update the most recently used entry. */
mr_ctrl->mru = mr_ctrl->head;
/* Point to the next victim, the oldest. */
mr_ctrl->head = (mr_ctrl->head + 1) % MLX4_MR_CACHE_N;
return lkey;
}
/**
* Bottom-half of LKey search on Rx.
*
* @param rxq
* Pointer to Rx queue structure.
* @param addr
* Search key.
*
* @return
* Searched LKey on success, UINT32_MAX on no match.
*/
uint32_t
mlx4_rx_addr2mr_bh(struct rxq *rxq, uintptr_t addr)
{
struct mlx4_mr_ctrl *mr_ctrl = &rxq->mr_ctrl;
struct mlx4_priv *priv = rxq->priv;
return mlx4_mr_addr2mr_bh(ETH_DEV(priv), mr_ctrl, addr);
}
/**
* Bottom-half of LKey search on Tx.
*
* @param txq
* Pointer to Tx queue structure.
* @param addr
* Search key.
*
* @return
* Searched LKey on success, UINT32_MAX on no match.
*/
static uint32_t
mlx4_tx_addr2mr_bh(struct txq *txq, uintptr_t addr)
{
struct mlx4_mr_ctrl *mr_ctrl = &txq->mr_ctrl;
struct mlx4_priv *priv = txq->priv;
return mlx4_mr_addr2mr_bh(ETH_DEV(priv), mr_ctrl, addr);
}
/**
* Bottom-half of LKey search on Tx. If it can't be searched in the memseg
* list, register the mempool of the mbuf as externally allocated memory.
*
* @param txq
* Pointer to Tx queue structure.
* @param mb
* Pointer to mbuf.
*
* @return
* Searched LKey on success, UINT32_MAX on no match.
*/
uint32_t
mlx4_tx_mb2mr_bh(struct txq *txq, struct rte_mbuf *mb)
{
uintptr_t addr = (uintptr_t)mb->buf_addr;
uint32_t lkey;
lkey = mlx4_tx_addr2mr_bh(txq, addr);
if (lkey == UINT32_MAX && rte_errno == ENXIO) {
/* Mempool may have externally allocated memory. */
return mlx4_tx_update_ext_mp(txq, addr, mlx4_mb2mp(mb));
}
return lkey;
}
/**
* Flush all of the local cache entries.
*
* @param mr_ctrl
* Pointer to per-queue MR control structure.
*/
void
mlx4_mr_flush_local_cache(struct mlx4_mr_ctrl *mr_ctrl)
{
/* Reset the most-recently-used index. */
mr_ctrl->mru = 0;
/* Reset the linear search array. */
mr_ctrl->head = 0;
memset(mr_ctrl->cache, 0, sizeof(mr_ctrl->cache));
/* Reset the B-tree table. */
mr_ctrl->cache_bh.len = 1;
mr_ctrl->cache_bh.overflow = 0;
/* Update the generation number. */
mr_ctrl->cur_gen = *mr_ctrl->dev_gen_ptr;
DEBUG("mr_ctrl(%p): flushed, cur_gen=%d",
(void *)mr_ctrl, mr_ctrl->cur_gen);
}
/**
* Called during rte_mempool_mem_iter() by mlx4_mr_update_ext_mp().
*
* Externally allocated chunk is registered and a MR is created for the chunk.
* The MR object is added to the global list. If memseg list of a MR object
* (mr->msl) is null, the MR object can be regarded as externally allocated
* memory.
*
* Once external memory is registered, it should be static. If the memory is
* freed and the virtual address range has different physical memory mapped
* again, it may cause crash on device due to the wrong translation entry. PMD
* can't track the free event of the external memory for now.
*/
static void
mlx4_mr_update_ext_mp_cb(struct rte_mempool *mp, void *opaque,
struct rte_mempool_memhdr *memhdr,
unsigned mem_idx __rte_unused)
{
struct mr_update_mp_data *data = opaque;
struct rte_eth_dev *dev = data->dev;
struct mlx4_priv *priv = dev->data->dev_private;
struct mlx4_mr_ctrl *mr_ctrl = data->mr_ctrl;
struct mlx4_mr *mr = NULL;
uintptr_t addr = (uintptr_t)memhdr->addr;
size_t len = memhdr->len;
struct mlx4_mr_cache entry;
uint32_t lkey;
MLX4_ASSERT(rte_eal_process_type() == RTE_PROC_PRIMARY);
/* If already registered, it should return. */
rte_rwlock_read_lock(&priv->mr.rwlock);
lkey = mr_lookup_dev(dev, &entry, addr);
rte_rwlock_read_unlock(&priv->mr.rwlock);
if (lkey != UINT32_MAX)
return;
mr = rte_zmalloc_socket(NULL,
RTE_ALIGN_CEIL(sizeof(*mr),
RTE_CACHE_LINE_SIZE),
RTE_CACHE_LINE_SIZE, mp->socket_id);
if (mr == NULL) {
WARN("port %u unable to allocate memory for a new MR of"
" mempool (%s).",
dev->data->port_id, mp->name);
data->ret = -1;
return;
}
DEBUG("port %u register MR for chunk #%d of mempool (%s)",
dev->data->port_id, mem_idx, mp->name);
mr->ibv_mr = mlx4_glue->reg_mr(priv->pd, (void *)addr, len,
IBV_ACCESS_LOCAL_WRITE);
if (mr->ibv_mr == NULL) {
WARN("port %u fail to create a verbs MR for address (%p)",
dev->data->port_id, (void *)addr);
rte_free(mr);
data->ret = -1;
return;
}
mr->msl = NULL; /* Mark it is external memory. */
mr->ms_bmp = NULL;
mr->ms_n = 1;
mr->ms_bmp_n = 1;
rte_rwlock_write_lock(&priv->mr.rwlock);
LIST_INSERT_HEAD(&priv->mr.mr_list, mr, mr);
DEBUG("port %u MR CREATED (%p) for external memory %p:\n"
" [0x%" PRIxPTR ", 0x%" PRIxPTR "),"
" lkey=0x%x base_idx=%u ms_n=%u, ms_bmp_n=%u",
dev->data->port_id, (void *)mr, (void *)addr,
addr, addr + len, rte_cpu_to_be_32(mr->ibv_mr->lkey),
mr->ms_base_idx, mr->ms_n, mr->ms_bmp_n);
/* Insert to the global cache table. */
mr_insert_dev_cache(dev, mr);
rte_rwlock_write_unlock(&priv->mr.rwlock);
/* Insert to the local cache table */
mlx4_mr_addr2mr_bh(dev, mr_ctrl, addr);
}
/**
* Register MR for entire memory chunks in a Mempool having externally allocated
* memory and fill in local cache.
*
* @param dev
* Pointer to Ethernet device.
* @param mr_ctrl
* Pointer to per-queue MR control structure.
* @param mp
* Pointer to registering Mempool.
*
* @return
* 0 on success, -1 on failure.
*/
static uint32_t
mlx4_mr_update_ext_mp(struct rte_eth_dev *dev, struct mlx4_mr_ctrl *mr_ctrl,
struct rte_mempool *mp)
{
struct mr_update_mp_data data = {
.dev = dev,
.mr_ctrl = mr_ctrl,
.ret = 0,
};
rte_mempool_mem_iter(mp, mlx4_mr_update_ext_mp_cb, &data);
return data.ret;
}
/**
* Register MR entire memory chunks in a Mempool having externally allocated
* memory and search LKey of the address to return.
*
* @param dev
* Pointer to Ethernet device.
* @param addr
* Search key.
* @param mp
* Pointer to registering Mempool where addr belongs.
*
* @return
* LKey for address on success, UINT32_MAX on failure.
*/
uint32_t
mlx4_tx_update_ext_mp(struct txq *txq, uintptr_t addr, struct rte_mempool *mp)
{
struct mlx4_mr_ctrl *mr_ctrl = &txq->mr_ctrl;
struct mlx4_priv *priv = txq->priv;
if (rte_eal_process_type() != RTE_PROC_PRIMARY) {
WARN("port %u using address (%p) from unregistered mempool"
" having externally allocated memory"
" in secondary process, please create mempool"
" prior to rte_eth_dev_start()",
PORT_ID(priv), (void *)addr);
return UINT32_MAX;
}
mlx4_mr_update_ext_mp(ETH_DEV(priv), mr_ctrl, mp);
return mlx4_tx_addr2mr_bh(txq, addr);
}
/* Called during rte_mempool_mem_iter() by mlx4_mr_update_mp(). */
static void
mlx4_mr_update_mp_cb(struct rte_mempool *mp __rte_unused, void *opaque,
struct rte_mempool_memhdr *memhdr,
unsigned mem_idx __rte_unused)
{
struct mr_update_mp_data *data = opaque;
uint32_t lkey;
/* Stop iteration if failed in the previous walk. */
if (data->ret < 0)
return;
/* Register address of the chunk and update local caches. */
lkey = mlx4_mr_addr2mr_bh(data->dev, data->mr_ctrl,
(uintptr_t)memhdr->addr);
if (lkey == UINT32_MAX)
data->ret = -1;
}
/**
* Register entire memory chunks in a Mempool.
*
* @param dev
* Pointer to Ethernet device.
* @param mr_ctrl
* Pointer to per-queue MR control structure.
* @param mp
* Pointer to registering Mempool.
*
* @return
* 0 on success, -1 on failure.
*/
int
mlx4_mr_update_mp(struct rte_eth_dev *dev, struct mlx4_mr_ctrl *mr_ctrl,
struct rte_mempool *mp)
{
struct mr_update_mp_data data = {
.dev = dev,
.mr_ctrl = mr_ctrl,
.ret = 0,
};
rte_mempool_mem_iter(mp, mlx4_mr_update_mp_cb, &data);
if (data.ret < 0 && rte_errno == ENXIO) {
/* Mempool may have externally allocated memory. */
return mlx4_mr_update_ext_mp(dev, mr_ctrl, mp);
}
return data.ret;
}
#ifdef RTE_LIBRTE_MLX4_DEBUG
/**
* Dump all the created MRs and the global cache entries.
*
* @param dev
* Pointer to Ethernet device.
*/
void
mlx4_mr_dump_dev(struct rte_eth_dev *dev)
{
struct mlx4_priv *priv = dev->data->dev_private;
struct mlx4_mr *mr;
int mr_n = 0;
int chunk_n = 0;
rte_rwlock_read_lock(&priv->mr.rwlock);
/* Iterate all the existing MRs. */
LIST_FOREACH(mr, &priv->mr.mr_list, mr) {
unsigned int n;
DEBUG("port %u MR[%u], LKey = 0x%x, ms_n = %u, ms_bmp_n = %u",
dev->data->port_id, mr_n++,
rte_cpu_to_be_32(mr->ibv_mr->lkey),
mr->ms_n, mr->ms_bmp_n);
if (mr->ms_n == 0)
continue;
for (n = 0; n < mr->ms_bmp_n; ) {
struct mlx4_mr_cache ret;
memset(&ret, 0, sizeof(ret));
n = mr_find_next_chunk(mr, &ret, n);
if (!ret.end)
break;
DEBUG(" chunk[%u], [0x%" PRIxPTR ", 0x%" PRIxPTR ")",
chunk_n++, ret.start, ret.end);
}
}
DEBUG("port %u dumping global cache", dev->data->port_id);
mlx4_mr_btree_dump(&priv->mr.cache);
rte_rwlock_read_unlock(&priv->mr.rwlock);
}
#endif
/**
* Release all the created MRs and resources. Remove device from memory callback
* list.
*
* @param dev
* Pointer to Ethernet device.
*/
void
mlx4_mr_release(struct rte_eth_dev *dev)
{
struct mlx4_priv *priv = dev->data->dev_private;
struct mlx4_mr *mr_next;
/* Remove from memory callback device list. */
rte_rwlock_write_lock(&mlx4_shared_data->mem_event_rwlock);
LIST_REMOVE(priv, mem_event_cb);
rte_rwlock_write_unlock(&mlx4_shared_data->mem_event_rwlock);
#ifdef RTE_LIBRTE_MLX4_DEBUG
mlx4_mr_dump_dev(dev);
#endif
rte_rwlock_write_lock(&priv->mr.rwlock);
/* Detach from MR list and move to free list. */
mr_next = LIST_FIRST(&priv->mr.mr_list);
while (mr_next != NULL) {
struct mlx4_mr *mr = mr_next;
mr_next = LIST_NEXT(mr, mr);
LIST_REMOVE(mr, mr);
LIST_INSERT_HEAD(&priv->mr.mr_free_list, mr, mr);
}
LIST_INIT(&priv->mr.mr_list);
/* Free global cache. */
mlx4_mr_btree_free(&priv->mr.cache);
rte_rwlock_write_unlock(&priv->mr.rwlock);
/* Free all remaining MRs. */
mlx4_mr_garbage_collect(dev);
}
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