iproute2/rdma/utils.c
Chiara Meiohas 57d7a8fd90 rdma: Add an option to display driver-specific QPs in the rdma tool
Utilize the -dd flag (driver-specific details) in the rdmatool
to view driver-specific QPs which are not exposed yet.

The following examples show mlx5 UMR QP which is visible now:

$ rdma resource show qp link ibp8s0f1
link ibp8s0f1/1 lqpn 360 type UD state RTS sq-psn 0 comm [mlx5_ib]
link ibp8s0f1/1 lqpn 0 type SMI state RTS sq-psn 0 comm [ib_core]
link ibp8s0f1/1 lqpn 1 type GSI state RTS sq-psn 0 comm [ib_core]

$ rdma resource show qp link ibp8s0f1 -dd
link ibp8s0f1/1 lqpn 360 type UD state RTS sq-psn 0 comm [mlx5_ib]
link ibp8s0f1/1 lqpn 465 type DRIVER subtype REG_UMR state RTS sq-psn 0 comm [mlx5_ib]
link ibp8s0f1/1 lqpn 0 type SMI state RTS sq-psn 0 comm [ib_core]
link ibp8s0f1/1 lqpn 1 type GSI state RTS sq-psn 0 comm [ib_core]

$ rdma resource show
0: ibp8s0f0: pd 3 cq 4 qp 3 cm_id 0 mr 0 ctx 0 srq 2
1: ibp8s0f1: pd 3 cq 4 qp 3 cm_id 0 mr 0 ctx 0 srq 2

$ rdma resource show -dd
0: ibp8s0f0: pd 3 cq 4 qp 4 cm_id 0 mr 0 ctx 0 srq 2
1: ibp8s0f1: pd 3 cq 4 qp 4 cm_id 0 mr 0 ctx 0 srq 2

Signed-off-by: Chiara Meiohas <cmeiohas@nvidia.com>
Signed-off-by: Leon Romanovsky <leonro@nvidia.com>
Signed-off-by: David Ahern <dsahern@kernel.org>
2024-05-03 15:15:22 +00:00

960 lines
22 KiB
C

// SPDX-License-Identifier: GPL-2.0 OR Linux-OpenIB
/*
* utils.c RDMA tool
* Authors: Leon Romanovsky <leonro@mellanox.com>
*/
#include "rdma.h"
#include <ctype.h>
#include <inttypes.h>
int rd_argc(struct rd *rd)
{
return rd->argc;
}
char *rd_argv(struct rd *rd)
{
if (!rd_argc(rd))
return NULL;
return *rd->argv;
}
int strcmpx(const char *str1, const char *str2)
{
if (strlen(str1) > strlen(str2))
return -1;
return strncmp(str1, str2, strlen(str1));
}
static bool rd_argv_match(struct rd *rd, const char *pattern)
{
if (!rd_argc(rd))
return false;
return strcmpx(rd_argv(rd), pattern) == 0;
}
void rd_arg_inc(struct rd *rd)
{
if (!rd_argc(rd))
return;
rd->argc--;
rd->argv++;
}
bool rd_no_arg(struct rd *rd)
{
return rd_argc(rd) == 0;
}
bool rd_is_multiarg(struct rd *rd)
{
if (!rd_argc(rd))
return false;
return strpbrk(rd_argv(rd), ",-") != NULL;
}
/*
* Possible input:output
* dev/port | first port | is_dump_all
* mlx5_1 | 0 | true
* mlx5_1/ | 0 | true
* mlx5_1/0 | 0 | false
* mlx5_1/1 | 1 | false
* mlx5_1/- | 0 | false
*
* In strict port mode, a non-0 port must be provided
*/
static int get_port_from_argv(struct rd *rd, uint32_t *port,
bool *is_dump_all, bool strict_port)
{
char *slash;
*port = 0;
*is_dump_all = strict_port ? false : true;
slash = strchr(rd_argv(rd), '/');
/* if no port found, return 0 */
if (slash == NULL) {
if (strict_port)
return -EINVAL;
else
return 0;
}
if (slash++) {
if (*slash == '-') {
if (strict_port)
return -EINVAL;
*is_dump_all = false;
return 0;
}
if (isdigit(*slash)) {
*is_dump_all = false;
*port = atoi(slash);
}
if (!*port && strlen(slash))
return -EINVAL;
}
if (strict_port && (*port == 0))
return -EINVAL;
return 0;
}
static struct dev_map *dev_map_alloc(const char *dev_name)
{
struct dev_map *dev_map;
dev_map = calloc(1, sizeof(*dev_map));
if (!dev_map)
return NULL;
dev_map->dev_name = strdup(dev_name);
if (!dev_map->dev_name) {
free(dev_map);
return NULL;
}
return dev_map;
}
static void dev_map_cleanup(struct rd *rd)
{
struct dev_map *dev_map, *tmp;
list_for_each_entry_safe(dev_map, tmp,
&rd->dev_map_list, list) {
list_del(&dev_map->list);
free(dev_map->dev_name);
free(dev_map);
}
}
static int add_filter(struct rd *rd, char *key, char *value,
const struct filters valid_filters[])
{
char cset[] = "1234567890,-";
struct filter_entry *fe;
bool key_found = false;
int idx = 0;
char *endp;
int ret;
fe = calloc(1, sizeof(*fe));
if (!fe)
return -ENOMEM;
while (idx < MAX_NUMBER_OF_FILTERS && valid_filters[idx].name) {
if (!strcmpx(key, valid_filters[idx].name)) {
key_found = true;
break;
}
idx++;
}
if (!key_found) {
pr_err("Unsupported filter option: %s\n", key);
ret = -EINVAL;
goto err;
}
/*
* Check the filter validity, not optimal, but works
*
* Actually, there are three types of filters
* numeric - for example PID or QPN
* string - for example states
* link - user requested to filter on specific link
* e.g. mlx5_1/1, mlx5_1/-, mlx5_1 ...
*/
if (valid_filters[idx].is_number &&
strspn(value, cset) != strlen(value)) {
pr_err("%s filter accepts \"%s\" characters only\n", key, cset);
ret = -EINVAL;
goto err;
}
fe->key = strdup(key);
fe->value = strdup(value);
if (!fe->key || !fe->value) {
ret = -ENOMEM;
goto err_alloc;
}
errno = 0;
strtol(fe->value, &endp, 10);
if (valid_filters[idx].is_doit && !errno && *endp == '\0')
fe->is_doit = true;
for (idx = 0; idx < strlen(fe->value); idx++)
fe->value[idx] = tolower(fe->value[idx]);
list_add_tail(&fe->list, &rd->filter_list);
return 0;
err_alloc:
free(fe->value);
free(fe->key);
err:
free(fe);
return ret;
}
bool rd_doit_index(struct rd *rd, uint32_t *idx)
{
struct filter_entry *fe;
list_for_each_entry(fe, &rd->filter_list, list) {
if (fe->is_doit) {
*idx = atoi(fe->value);
return true;
}
}
return false;
}
int rd_build_filter(struct rd *rd, const struct filters valid_filters[])
{
int ret = 0;
int idx = 0;
if (!valid_filters || !rd_argc(rd))
goto out;
if (rd_argc(rd) == 1) {
pr_err("No filter data was supplied to filter option %s\n", rd_argv(rd));
ret = -EINVAL;
goto out;
}
if (rd_argc(rd) % 2) {
pr_err("There is filter option without data\n");
ret = -EINVAL;
goto out;
}
while (idx != rd_argc(rd)) {
/*
* We can do micro-optimization and skip "dev"
* and "link" filters, but it is not worth of it.
*/
ret = add_filter(rd, *(rd->argv + idx),
*(rd->argv + idx + 1), valid_filters);
if (ret)
goto out;
idx += 2;
}
out:
return ret;
}
static bool rd_check_is_key_exist(struct rd *rd, const char *key)
{
struct filter_entry *fe;
list_for_each_entry(fe, &rd->filter_list, list) {
if (!strcmpx(fe->key, key))
return true;
}
return false;
}
/*
* Check if string entry is filtered:
* * key doesn't exist -> user didn't request -> not filtered
*/
static bool rd_check_is_string_filtered(struct rd *rd, const char *key,
const char *val)
{
bool key_is_filtered = false;
struct filter_entry *fe;
char *p = NULL;
char *str;
list_for_each_entry(fe, &rd->filter_list, list) {
if (!strcmpx(fe->key, key)) {
/* We found the key */
p = strdup(fe->value);
key_is_filtered = true;
if (!p) {
/*
* Something extremely wrong if we fail
* to allocate small amount of bytes.
*/
pr_err("Found key, but failed to allocate memory to store value\n");
return key_is_filtered;
}
/*
* Need to check if value in range
* It can come in the following formats
* and their permutations:
* str
* str1,str2
*/
str = strtok(p, ",");
while (str) {
if (strlen(str) == strlen(val) &&
!strcasecmp(str, val)) {
key_is_filtered = false;
goto out;
}
str = strtok(NULL, ",");
}
goto out;
}
}
out:
free(p);
return key_is_filtered;
}
/*
* Check if key is filtered:
* key doesn't exist -> user didn't request -> not filtered
*/
static bool rd_check_is_filtered(struct rd *rd, const char *key, uint32_t val)
{
bool key_is_filtered = false;
struct filter_entry *fe;
list_for_each_entry(fe, &rd->filter_list, list) {
uint32_t left_val = 0, fe_value = 0;
bool range_check = false;
char *p = fe->value;
if (!strcmpx(fe->key, key)) {
/* We found the key */
key_is_filtered = true;
/*
* Need to check if value in range
* It can come in the following formats
* (and their permutations):
* numb
* numb1,numb2
* ,numb1,numb2
* numb1-numb2
* numb1,numb2-numb3,numb4-numb5
*/
while (*p) {
if (isdigit(*p)) {
fe_value = strtol(p, &p, 10);
if (fe_value == val ||
(range_check && left_val < val &&
val < fe_value)) {
key_is_filtered = false;
goto out;
}
range_check = false;
} else {
if (*p == '-') {
left_val = fe_value;
range_check = true;
}
p++;
}
}
goto out;
}
}
out:
return key_is_filtered;
}
bool rd_is_filtered_attr(struct rd *rd, const char *key, uint32_t val,
struct nlattr *attr)
{
if (!attr)
return rd_check_is_key_exist(rd, key);
return rd_check_is_filtered(rd, key, val);
}
bool rd_is_string_filtered_attr(struct rd *rd, const char *key, const char *val,
struct nlattr *attr)
{
if (!attr)
rd_check_is_key_exist(rd, key);
return rd_check_is_string_filtered(rd, key, val);
}
static void filters_cleanup(struct rd *rd)
{
struct filter_entry *fe, *tmp;
list_for_each_entry_safe(fe, tmp,
&rd->filter_list, list) {
list_del(&fe->list);
free(fe->key);
free(fe->value);
free(fe);
}
}
static const enum mnl_attr_data_type nldev_policy[RDMA_NLDEV_ATTR_MAX] = {
[RDMA_NLDEV_ATTR_DEV_INDEX] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_DEV_NAME] = MNL_TYPE_NUL_STRING,
[RDMA_NLDEV_ATTR_PORT_INDEX] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_CAP_FLAGS] = MNL_TYPE_U64,
[RDMA_NLDEV_ATTR_FW_VERSION] = MNL_TYPE_NUL_STRING,
[RDMA_NLDEV_ATTR_NODE_GUID] = MNL_TYPE_U64,
[RDMA_NLDEV_ATTR_SYS_IMAGE_GUID] = MNL_TYPE_U64,
[RDMA_NLDEV_ATTR_LID] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_SM_LID] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_LMC] = MNL_TYPE_U8,
[RDMA_NLDEV_ATTR_PORT_STATE] = MNL_TYPE_U8,
[RDMA_NLDEV_ATTR_PORT_PHYS_STATE] = MNL_TYPE_U8,
[RDMA_NLDEV_ATTR_DEV_NODE_TYPE] = MNL_TYPE_U8,
[RDMA_NLDEV_ATTR_RES_SUMMARY] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_SUMMARY_ENTRY] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_SUMMARY_ENTRY_NAME] = MNL_TYPE_NUL_STRING,
[RDMA_NLDEV_ATTR_RES_SUMMARY_ENTRY_CURR] = MNL_TYPE_U64,
[RDMA_NLDEV_ATTR_RES_QP] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_QP_ENTRY] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_LQPN] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_RES_RQPN] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_RES_RQ_PSN] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_RES_SQ_PSN] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_RES_PATH_MIG_STATE] = MNL_TYPE_U8,
[RDMA_NLDEV_ATTR_RES_TYPE] = MNL_TYPE_U8,
[RDMA_NLDEV_ATTR_RES_SUBTYPE] = MNL_TYPE_NUL_STRING,
[RDMA_NLDEV_ATTR_RES_STATE] = MNL_TYPE_U8,
[RDMA_NLDEV_ATTR_RES_PID] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_RES_KERN_NAME] = MNL_TYPE_NUL_STRING,
[RDMA_NLDEV_ATTR_RES_CM_ID] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_CM_ID_ENTRY] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_PS] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_RES_SRC_ADDR] = MNL_TYPE_UNSPEC,
[RDMA_NLDEV_ATTR_RES_DST_ADDR] = MNL_TYPE_UNSPEC,
[RDMA_NLDEV_ATTR_RES_CQ] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_CQ_ENTRY] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_CQE] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_RES_USECNT] = MNL_TYPE_U64,
[RDMA_NLDEV_ATTR_RES_POLL_CTX] = MNL_TYPE_U8,
[RDMA_NLDEV_ATTR_RES_MR] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_MR_ENTRY] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_RKEY] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_RES_LKEY] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_RES_IOVA] = MNL_TYPE_U64,
[RDMA_NLDEV_ATTR_RES_MRLEN] = MNL_TYPE_U64,
[RDMA_NLDEV_ATTR_RES_CTX] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_CTX_ENTRY] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_CTXN] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_RES_SRQ] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_SRQ_ENTRY] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_RES_SRQN] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_MIN_RANGE] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_MAX_RANGE] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_NDEV_INDEX] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_NDEV_NAME] = MNL_TYPE_NUL_STRING,
[RDMA_NLDEV_ATTR_DRIVER] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_DRIVER_ENTRY] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_DRIVER_STRING] = MNL_TYPE_NUL_STRING,
[RDMA_NLDEV_ATTR_DRIVER_PRINT_TYPE] = MNL_TYPE_U8,
[RDMA_NLDEV_ATTR_DRIVER_S32] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_DRIVER_U32] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_DRIVER_S64] = MNL_TYPE_U64,
[RDMA_NLDEV_ATTR_DRIVER_U64] = MNL_TYPE_U64,
[RDMA_NLDEV_SYS_ATTR_NETNS_MODE] = MNL_TYPE_U8,
[RDMA_NLDEV_ATTR_STAT_COUNTER] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_STAT_COUNTER_ENTRY] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_STAT_COUNTER_ID] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_STAT_HWCOUNTERS] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_STAT_HWCOUNTER_ENTRY] = MNL_TYPE_NESTED,
[RDMA_NLDEV_ATTR_STAT_HWCOUNTER_ENTRY_NAME] = MNL_TYPE_NUL_STRING,
[RDMA_NLDEV_ATTR_STAT_HWCOUNTER_ENTRY_VALUE] = MNL_TYPE_U64,
[RDMA_NLDEV_ATTR_STAT_MODE] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_STAT_RES] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_STAT_AUTO_MODE_MASK] = MNL_TYPE_U32,
[RDMA_NLDEV_ATTR_DEV_DIM] = MNL_TYPE_U8,
[RDMA_NLDEV_ATTR_RES_RAW] = MNL_TYPE_BINARY,
[RDMA_NLDEV_SYS_ATTR_PRIVILEGED_QKEY_MODE] = MNL_TYPE_U8,
};
static int rd_attr_check(const struct nlattr *attr, int *typep)
{
int type;
if (mnl_attr_type_valid(attr, RDMA_NLDEV_ATTR_MAX) < 0)
return MNL_CB_ERROR;
type = mnl_attr_get_type(attr);
if (mnl_attr_validate(attr, nldev_policy[type]) < 0)
return MNL_CB_ERROR;
*typep = nldev_policy[type];
return MNL_CB_OK;
}
int rd_attr_cb(const struct nlattr *attr, void *data)
{
const struct nlattr **tb = data;
int type;
if (mnl_attr_type_valid(attr, RDMA_NLDEV_ATTR_MAX - 1) < 0)
/* We received unknown attribute */
return MNL_CB_OK;
type = mnl_attr_get_type(attr);
if (mnl_attr_validate(attr, nldev_policy[type]) < 0)
return MNL_CB_ERROR;
tb[type] = attr;
return MNL_CB_OK;
}
int rd_dev_init_cb(const struct nlmsghdr *nlh, void *data)
{
struct nlattr *tb[RDMA_NLDEV_ATTR_MAX] = {};
struct dev_map *dev_map;
struct rd *rd = data;
const char *dev_name;
mnl_attr_parse(nlh, 0, rd_attr_cb, tb);
if (!tb[RDMA_NLDEV_ATTR_DEV_NAME] || !tb[RDMA_NLDEV_ATTR_DEV_INDEX])
return MNL_CB_ERROR;
if (!tb[RDMA_NLDEV_ATTR_PORT_INDEX]) {
pr_err("This tool doesn't support switches yet\n");
return MNL_CB_ERROR;
}
dev_name = mnl_attr_get_str(tb[RDMA_NLDEV_ATTR_DEV_NAME]);
dev_map = dev_map_alloc(dev_name);
if (!dev_map)
/* The main function will cleanup the allocations */
return MNL_CB_ERROR;
list_add_tail(&dev_map->list, &rd->dev_map_list);
dev_map->num_ports = mnl_attr_get_u32(tb[RDMA_NLDEV_ATTR_PORT_INDEX]);
dev_map->idx = mnl_attr_get_u32(tb[RDMA_NLDEV_ATTR_DEV_INDEX]);
return MNL_CB_OK;
}
void rd_free(struct rd *rd)
{
if (!rd)
return;
free(rd->buff);
dev_map_cleanup(rd);
filters_cleanup(rd);
}
int rd_set_arg_to_devname(struct rd *rd)
{
int ret = 0;
while (!rd_no_arg(rd)) {
if (rd_argv_match(rd, "dev") || rd_argv_match(rd, "link")) {
rd_arg_inc(rd);
if (rd_no_arg(rd)) {
pr_err("No device name was supplied\n");
ret = -EINVAL;
}
goto out;
}
rd_arg_inc(rd);
}
out:
return ret;
}
int rd_exec_link(struct rd *rd, int (*cb)(struct rd *rd), bool strict_port)
{
struct dev_map *dev_map;
uint32_t port;
int ret = 0;
new_json_obj(json);
if (rd_no_arg(rd)) {
list_for_each_entry(dev_map, &rd->dev_map_list, list) {
rd->dev_idx = dev_map->idx;
port = (strict_port) ? 1 : 0;
for (; port < dev_map->num_ports + 1; port++) {
rd->port_idx = port;
ret = cb(rd);
if (ret)
goto out;
}
}
} else {
bool is_dump_all;
dev_map = dev_map_lookup(rd, true);
ret = get_port_from_argv(rd, &port, &is_dump_all, strict_port);
if (!dev_map || port > dev_map->num_ports || (!port && ret)) {
pr_err("Wrong device name\n");
ret = -ENOENT;
goto out;
}
rd_arg_inc(rd);
rd->dev_idx = dev_map->idx;
rd->port_idx = port;
for (; rd->port_idx < dev_map->num_ports + 1; rd->port_idx++) {
ret = cb(rd);
if (ret)
goto out;
if (!is_dump_all)
/*
* We got request to show link for devname
* with port index.
*/
break;
}
}
out:
delete_json_obj();
return ret;
}
int rd_exec_dev(struct rd *rd, int (*cb)(struct rd *rd))
{
struct dev_map *dev_map;
int ret = 0;
new_json_obj(json);
if (rd_no_arg(rd)) {
list_for_each_entry(dev_map, &rd->dev_map_list, list) {
rd->dev_idx = dev_map->idx;
ret = cb(rd);
if (ret)
goto out;
}
} else {
dev_map = dev_map_lookup(rd, false);
if (!dev_map) {
pr_err("Wrong device name - %s\n", rd_argv(rd));
ret = -ENOENT;
goto out;
}
rd_arg_inc(rd);
rd->dev_idx = dev_map->idx;
ret = cb(rd);
}
out:
delete_json_obj();
return ret;
}
int rd_exec_require_dev(struct rd *rd, int (*cb)(struct rd *rd))
{
if (rd_no_arg(rd)) {
pr_err("Please provide device name.\n");
return -EINVAL;
}
return rd_exec_dev(rd, cb);
}
int rd_exec_cmd(struct rd *rd, const struct rd_cmd *cmds, const char *str)
{
const struct rd_cmd *c;
/* First argument in objs table is default variant */
if (rd_no_arg(rd))
return cmds->func(rd);
for (c = cmds + 1; c->cmd; ++c) {
if (rd_argv_match(rd, c->cmd)) {
/* Move to next argument */
rd_arg_inc(rd);
return c->func(rd);
}
}
pr_err("Unknown %s '%s'.\n", str, rd_argv(rd));
return 0;
}
void rd_prepare_msg(struct rd *rd, uint32_t cmd, uint32_t *seq, uint16_t flags)
{
*seq = time(NULL);
rd->nlh = mnl_nlmsg_put_header(rd->buff);
rd->nlh->nlmsg_type = RDMA_NL_GET_TYPE(RDMA_NL_NLDEV, cmd);
rd->nlh->nlmsg_seq = *seq;
rd->nlh->nlmsg_flags = flags;
}
int rd_send_msg(struct rd *rd)
{
int ret;
rd->nl = mnlu_socket_open(NETLINK_RDMA);
if (!rd->nl) {
pr_err("Failed to open NETLINK_RDMA socket\n");
return -ENODEV;
}
ret = mnl_socket_sendto(rd->nl, rd->nlh, rd->nlh->nlmsg_len);
if (ret < 0) {
pr_err("Failed to send to socket with err %d\n", ret);
goto err;
}
return 0;
err:
mnl_socket_close(rd->nl);
return ret;
}
int rd_recv_msg(struct rd *rd, mnl_cb_t callback, void *data, unsigned int seq)
{
char buf[MNL_SOCKET_BUFFER_SIZE];
int ret;
ret = mnlu_socket_recv_run(rd->nl, seq, buf, MNL_SOCKET_BUFFER_SIZE,
callback, data);
if (ret < 0 && !rd->suppress_errors)
perror("error");
return ret;
}
static int null_cb(const struct nlmsghdr *nlh, void *data)
{
return MNL_CB_OK;
}
int rd_sendrecv_msg(struct rd *rd, unsigned int seq)
{
int ret;
ret = rd_send_msg(rd);
if (!ret)
ret = rd_recv_msg(rd, null_cb, rd, seq);
return ret;
}
static struct dev_map *_dev_map_lookup(struct rd *rd, const char *dev_name)
{
struct dev_map *dev_map;
list_for_each_entry(dev_map, &rd->dev_map_list, list)
if (strcmp(dev_name, dev_map->dev_name) == 0)
return dev_map;
return NULL;
}
struct dev_map *dev_map_lookup(struct rd *rd, bool allow_port_index)
{
struct dev_map *dev_map;
char *dev_name;
char *slash;
if (rd_no_arg(rd))
return NULL;
dev_name = strdup(rd_argv(rd));
if (!dev_name)
return NULL;
if (allow_port_index) {
slash = strrchr(dev_name, '/');
if (slash)
*slash = '\0';
}
dev_map = _dev_map_lookup(rd, dev_name);
free(dev_name);
return dev_map;
}
#define nla_type(attr) ((attr)->nla_type & NLA_TYPE_MASK)
/* End of device object always print a newline */
void newline(void)
{
putchar('\n');
fflush(stdout);
}
/* End of partial multi-line segment of a device object */
void newline_indent(void)
{
if (!is_json_context())
printf("%s ", _SL_);
}
static int print_driver_string(const char *key_str, const char *val_str)
{
print_string(PRINT_ANY, key_str, key_str, val_str);
print_string(PRINT_FP, NULL, " %s ", val_str);
return 0;
}
static int print_driver_s32(const char *key_str, int32_t val,
enum rdma_nldev_print_type print_type)
{
if (!is_json_context()) {
switch (print_type) {
case RDMA_NLDEV_PRINT_TYPE_UNSPEC:
return pr_out("%s %d ", key_str, val);
case RDMA_NLDEV_PRINT_TYPE_HEX:
return pr_out("%s 0x%x ", key_str, val);
default:
return -EINVAL;
}
}
print_int(PRINT_JSON, key_str, NULL, val);
return 0;
}
static int print_driver_u32(const char *key_str, uint32_t val,
enum rdma_nldev_print_type print_type)
{
if (!is_json_context()) {
switch (print_type) {
case RDMA_NLDEV_PRINT_TYPE_UNSPEC:
return pr_out("%s %u ", key_str, val);
case RDMA_NLDEV_PRINT_TYPE_HEX:
return pr_out("%s 0x%x ", key_str, val);
default:
return -EINVAL;
}
}
print_int(PRINT_JSON, key_str, NULL, val);
return 0;
}
static int print_driver_s64(const char *key_str, int64_t val,
enum rdma_nldev_print_type print_type)
{
if (!is_json_context()) {
switch (print_type) {
case RDMA_NLDEV_PRINT_TYPE_UNSPEC:
return pr_out("%s %" PRId64 " ", key_str, val);
case RDMA_NLDEV_PRINT_TYPE_HEX:
return pr_out("%s 0x%" PRIx64 " ", key_str, val);
default:
return -EINVAL;
}
}
print_int(PRINT_JSON, key_str, NULL, val);
return 0;
}
static int print_driver_u64(const char *key_str, uint64_t val,
enum rdma_nldev_print_type print_type)
{
if (!is_json_context()) {
switch (print_type) {
case RDMA_NLDEV_PRINT_TYPE_UNSPEC:
return pr_out("%s %" PRIu64 " ", key_str, val);
case RDMA_NLDEV_PRINT_TYPE_HEX:
return pr_out("%s 0x%" PRIx64 " ", key_str, val);
default:
return -EINVAL;
}
}
print_int(PRINT_JSON, key_str, NULL, val);
return 0;
}
static int print_driver_entry(struct nlattr *key_attr, struct nlattr *val_attr,
enum rdma_nldev_print_type print_type)
{
int attr_type = nla_type(val_attr);
int ret = -EINVAL;
char *key_str;
if (asprintf(&key_str, "drv_%s", mnl_attr_get_str(key_attr)) == -1)
return -ENOMEM;
switch (attr_type) {
case RDMA_NLDEV_ATTR_DRIVER_STRING:
ret = print_driver_string(key_str, mnl_attr_get_str(val_attr));
break;
case RDMA_NLDEV_ATTR_DRIVER_S32:
ret = print_driver_s32(key_str, mnl_attr_get_u32(val_attr), print_type);
break;
case RDMA_NLDEV_ATTR_DRIVER_U32:
ret = print_driver_u32(key_str, mnl_attr_get_u32(val_attr), print_type);
break;
case RDMA_NLDEV_ATTR_DRIVER_S64:
ret = print_driver_s64(key_str, mnl_attr_get_u64(val_attr), print_type);
break;
case RDMA_NLDEV_ATTR_DRIVER_U64:
ret = print_driver_u64(key_str, mnl_attr_get_u64(val_attr), print_type);
break;
}
free(key_str);
return ret;
}
void print_raw_data(struct rd *rd, struct nlattr **nla_line)
{
uint8_t *data;
uint32_t len;
int i = 0;
if (!rd->show_raw)
return;
len = mnl_attr_get_payload_len(nla_line[RDMA_NLDEV_ATTR_RES_RAW]);
data = mnl_attr_get_payload(nla_line[RDMA_NLDEV_ATTR_RES_RAW]);
open_json_array(PRINT_JSON, "data");
while (i < len) {
print_uint(PRINT_ANY, NULL, "%d", data[i]);
i++;
}
close_json_array(PRINT_ANY, ">");
}
void print_driver_table(struct rd *rd, struct nlattr *tb)
{
int print_type = RDMA_NLDEV_PRINT_TYPE_UNSPEC;
struct nlattr *tb_entry, *key = NULL, *val;
int type, cc = 0;
int ret;
if (!rd->show_driver_details || !tb)
return;
newline_indent();
/*
* Driver attrs are tuples of {key, [print-type], value}.
* The key must be a string. If print-type is present, it
* defines an alternate printf format type vs the native format
* for the attribute. And the value can be any available
* driver type.
*/
mnl_attr_for_each_nested(tb_entry, tb) {
if (cc > MAX_LINE_LENGTH) {
newline_indent();
cc = 0;
}
if (rd_attr_check(tb_entry, &type) != MNL_CB_OK)
return;
if (!key) {
if (type != MNL_TYPE_NUL_STRING)
return;
key = tb_entry;
} else if (type == MNL_TYPE_U8) {
print_type = mnl_attr_get_u8(tb_entry);
} else {
val = tb_entry;
ret = print_driver_entry(key, val, print_type);
if (ret < 0)
return;
cc += ret;
print_type = RDMA_NLDEV_PRINT_TYPE_UNSPEC;
key = NULL;
}
}
return;
}