blob: a54c08a743ef32605d6419d069e74c8e7a440a80 [file] [log] [blame]
/*
**************************************************************************
* Copyright (c) 2013-2017, 2019 The Linux Foundation. All rights reserved.
* Permission to use, copy, modify, and/or distribute this software for
* any purpose with or without fee is hereby granted, provided that the
* above copyright notice and this permission notice appear in all copies.
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT
* OF OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
**************************************************************************
*/
/*
* nss_rps.c
* NSS RPS based APIs
*/
#include "nss_tx_rx_common.h"
#define NSS_RPS_MAX_CORE_HASH_BITMAP ((1 << (NSS_HOST_CORES)) - 1)
/**< Maximum value that when all cores are available. */
#define NSS_RPS_PRI_MAP_PARAM_FIELD_COUNT 2
int nss_rps_config __read_mostly;
int nss_rps_hash_bitmap = NSS_RPS_MAX_CORE_HASH_BITMAP;
int nss_rps_pri_map[NSS_MAX_NUM_PRI];
/*
* It is used to parse priority and core from the input.
*/
struct nss_rps_pri_map_parse_data {
uint8_t pri; /**< Priority Index. */
int8_t core; /**< Host core-id. */
};
/*
* Private data structure.
*/
struct nss_rps_pvt {
struct semaphore sem; /* Semaphore structure. */
struct completion complete; /* Completion structure. */
int response; /* Response from FW. */
void *cb; /* Original cb for sync msgs. */
void *app_data; /* Original app_data for sync msgs. */
};
static struct nss_rps_pvt nss_rps_cfg_pvt;
/*
* nss_rps_pri_map_usage()
* Help function shows the usage of the command.
*/
static inline void nss_rps_pri_map_usage(void)
{
nss_info_always("\nUsage:\n");
nss_info_always("echo <priority> <core> > /proc/sys/dev/nss/rps/pri_map\n\n");
nss_info_always("priority[0 to %u] core[-1 to %u]:\n\n",
NSS_MAX_NUM_PRI - 1,
NSS_HOST_CORES - 1);
}
/*
* nss_rps_pri_map_print()
* Sysctl handler for printing rps/pri mapping.
*/
static int nss_rps_pri_map_print(struct ctl_table *ctl, void __user *buffer,
size_t *lenp, loff_t *ppos, int *pri_map)
{
char *r_buf;
int i, len;
size_t cp_bytes = 0;
/*
* (2 * 4) + 12 bytes for the buffer size is sufficient to write
* the table including the spaces and new line characters.
*/
r_buf = kzalloc(((4 * NSS_MAX_NUM_PRI) + 12) * sizeof(char),
GFP_KERNEL);
if (!r_buf) {
nss_warning("Failed to alloc buffer to print pri map\n");
return -EFAULT;
}
/*
* Write the core values that corresponds to each priorities.
*/
len = scnprintf(r_buf + cp_bytes, 8, "Cores: ");
cp_bytes += len;
for (i = 0; i < NSS_MAX_NUM_PRI; i++) {
len = scnprintf(r_buf + cp_bytes, 4, "%d ", pri_map[i]);
if (!len) {
nss_warning("failed to read from buffer %d\n", pri_map[i]);
kfree(r_buf);
return -EFAULT;
}
cp_bytes += len;
}
/*
* Add new line character at the end.
*/
len = scnprintf(r_buf + cp_bytes, 4, "\n");
cp_bytes += len;
cp_bytes = simple_read_from_buffer(buffer, *lenp, ppos, r_buf, cp_bytes);
*lenp = cp_bytes;
kfree(r_buf);
return 0;
}
/*
* nss_rps_pri_map_parse()
* Sysctl handler for rps/pri mappings.
*/
static int nss_rps_pri_map_parse(struct ctl_table *ctl, void __user *buffer,
size_t *lenp, loff_t *ppos, struct nss_rps_pri_map_parse_data *out)
{
size_t cp_bytes = 0;
char w_buf[5];
loff_t w_offset = 0;
char *str;
unsigned int pri;
int core, res;
/*
* Buffer length cannot be different than 4 or 5.
*/
if (*lenp < 4 || *lenp > 5) {
nss_warning("Buffer is not correct. Invalid lenght: %d\n", (int)*lenp);
return -EINVAL;
}
/*
* It's a write operation
*/
cp_bytes = simple_write_to_buffer(w_buf, *lenp, &w_offset, buffer, 5);
if (cp_bytes != *lenp) {
nss_warning("failed to write to buffer\n");
return -EFAULT;
}
str = w_buf;
res = sscanf(str, "%u %d", &pri, &core);
if (res != NSS_RPS_PRI_MAP_PARAM_FIELD_COUNT) {
nss_warning("failed to read the buffer\n");
return -EFAULT;
}
/*
* pri value cannot be higher than NSS_MAX_NUM_PRI.
*/
if (pri >= NSS_MAX_NUM_PRI) {
nss_warning("invalid pri value: %d\n", pri);
return -EINVAL;
}
/*
* Host core must be less than NSS_HOST_CORE.
*/
if (core >= NSS_HOST_CORES || core < NSS_N2H_RPS_PRI_DEFAULT) {
nss_warning("invalid priority value: %d\n", core);
return -EINVAL;
}
nss_info("priority: %d core: %d\n", pri, core);
out->pri = pri;
out->core = core;
return 0;
}
/*
* nss_rps_cfg_callback()
* Callback function for rps configuration.
*/
static void nss_rps_cfg_callback(void *app_data, struct nss_n2h_msg *nnm)
{
struct nss_ctx_instance *nss_ctx = (struct nss_ctx_instance *)app_data;
if (nnm->cm.response != NSS_CMN_RESPONSE_ACK) {
/*
* Error, hence we are not updating the nss_rps
* Send a FAILURE to restore the current value
* to its previous state.
*/
nss_rps_cfg_pvt.response = NSS_FAILURE;
complete(&nss_rps_cfg_pvt.complete);
nss_warning("%p: RPS configuration failed : %d\n", nss_ctx,
nnm->cm.error);
return;
}
nss_info("%p: RPS configuration succeeded: %d\n", nss_ctx,
nnm->cm.error);
nss_ctx->rps_en = nnm->msg.rps_cfg.enable;
nss_rps_cfg_pvt.response = NSS_SUCCESS;
complete(&nss_rps_cfg_pvt.complete);
}
/*
* nss_rps_pri_map_cfg_callback()
* Callback function for rps pri map configuration.
*/
static void nss_rps_pri_map_cfg_callback(void *app_data, struct nss_n2h_msg *nnm)
{
if (nnm->cm.response != NSS_CMN_RESPONSE_ACK) {
/*
* Error, hence we are not updating the nss_pri_map
* Send a failure to restore the current value
* to its previous state.
*/
nss_rps_cfg_pvt.response = NSS_FAILURE;
complete(&nss_rps_cfg_pvt.complete);
nss_warning("%p: RPS pri_map configuration failed : %d\n",
app_data, nnm->cm.error);
return;
}
nss_info("%p: RPS pri_map configuration succeeded: %d\n",
app_data, nnm->cm.error);
nss_rps_cfg_pvt.response = NSS_SUCCESS;
complete(&nss_rps_cfg_pvt.complete);
}
/*
* nss_rps_cfg()
* Send Message to NSS to enable RPS.
*/
static nss_tx_status_t nss_rps_cfg(struct nss_ctx_instance *nss_ctx, int enable_rps)
{
struct nss_n2h_msg nnm;
nss_tx_status_t nss_tx_status;
int ret;
down(&nss_rps_cfg_pvt.sem);
nss_n2h_msg_init(&nnm, NSS_N2H_INTERFACE, NSS_TX_METADATA_TYPE_N2H_RPS_CFG,
sizeof(struct nss_n2h_rps),
nss_rps_cfg_callback,
(void *)nss_ctx);
nnm.msg.rps_cfg.enable = enable_rps;
nss_tx_status = nss_n2h_tx_msg(nss_ctx, &nnm);
if (nss_tx_status != NSS_TX_SUCCESS) {
nss_warning("%p: nss_tx error setting rps\n", nss_ctx);
up(&nss_rps_cfg_pvt.sem);
return NSS_FAILURE;
}
/*
* Blocking call, wait till we get ACK for this msg.
*/
ret = wait_for_completion_timeout(&nss_rps_cfg_pvt.complete, msecs_to_jiffies(NSS_CONN_CFG_TIMEOUT));
if (ret == 0) {
nss_warning("%p: Waiting for ack timed out\n", nss_ctx);
up(&nss_rps_cfg_pvt.sem);
return NSS_FAILURE;
}
/*
* ACK/NACK received from NSS FW
* If NACK: Handler function will restore nss_rps_config
* to previous state.
*/
if (NSS_FAILURE == nss_rps_cfg_pvt.response) {
up(&nss_rps_cfg_pvt.sem);
return NSS_FAILURE;
}
up(&nss_rps_cfg_pvt.sem);
return NSS_SUCCESS;
}
/*
* nss_rps_ipv4_hash_bitmap_cfg()
* Send Message to NSS to configure hash_bitmap.
*/
static nss_tx_status_t nss_rps_ipv4_hash_bitmap_cfg(struct nss_ctx_instance *nss_ctx, int hash_bitmap)
{
struct nss_ipv4_msg nim;
nss_tx_status_t nss_tx_status;
down(&nss_rps_cfg_pvt.sem);
nss_ipv4_msg_init(&nim, NSS_IPV4_RX_INTERFACE, NSS_IPV4_TX_RPS_HASH_BITMAP_CFG_MSG,
sizeof(struct nss_ipv4_rps_hash_bitmap_cfg_msg),
NULL, NULL);
nim.msg.rps_hash_bitmap.hash_bitmap = hash_bitmap;
nss_tx_status = nss_ipv4_tx_sync(nss_ctx, &nim);
if (nss_tx_status != NSS_TX_SUCCESS) {
nss_warning("%p: nss_tx error setting rps\n", nss_ctx);
up(&nss_rps_cfg_pvt.sem);
return NSS_FAILURE;
}
up(&nss_rps_cfg_pvt.sem);
return NSS_SUCCESS;
}
/*
* nss_rps_ipv6_hash_bitmap_cfg()
* Send Message to NSS to configure hash_bitmap.
*/
static nss_tx_status_t nss_rps_ipv6_hash_bitmap_cfg(struct nss_ctx_instance *nss_ctx, int hash_bitmap)
{
struct nss_ipv6_msg nim;
nss_tx_status_t nss_tx_status;
down(&nss_rps_cfg_pvt.sem);
nss_ipv6_msg_init(&nim, NSS_IPV6_RX_INTERFACE, NSS_IPV6_TX_RPS_HASH_BITMAP_CFG_MSG,
sizeof(struct nss_ipv4_rps_hash_bitmap_cfg_msg),
NULL, NULL);
nim.msg.rps_hash_bitmap.hash_bitmap = hash_bitmap;
nss_tx_status = nss_ipv6_tx_sync(nss_ctx, &nim);
if (nss_tx_status != NSS_TX_SUCCESS) {
nss_warning("%p: nss_tx error setting rps\n", nss_ctx);
up(&nss_rps_cfg_pvt.sem);
return NSS_FAILURE;
}
up(&nss_rps_cfg_pvt.sem);
return NSS_SUCCESS;
}
/*
* nss_rps_pri_map_cfg()
* Send Message to NSS to configure pri_map.
*/
static nss_tx_status_t nss_rps_pri_map_cfg(struct nss_ctx_instance *nss_ctx, int *pri_map)
{
struct nss_n2h_msg nnm;
struct nss_n2h_rps_pri_map *rps_pri_map;
nss_tx_status_t nss_tx_status;
int ret, i;
down(&nss_rps_cfg_pvt.sem);
nss_n2h_msg_init(&nnm, NSS_N2H_INTERFACE, NSS_TX_METADATA_TYPE_N2H_RPS_PRI_MAP_CFG,
sizeof(struct nss_n2h_rps_pri_map),
nss_rps_pri_map_cfg_callback,
(void *)nss_ctx);
rps_pri_map = &nnm.msg.rps_pri_map;
/*
* Fill entries at pri_map.
*/
for (i = 0; i < NSS_MAX_NUM_PRI; i++) {
rps_pri_map->pri_map[i] = pri_map[i];
}
nss_tx_status = nss_n2h_tx_msg(nss_ctx, &nnm);
if (nss_tx_status != NSS_TX_SUCCESS) {
nss_warning("%p: nss_tx error setting rps\n", nss_ctx);
up(&nss_rps_cfg_pvt.sem);
return NSS_FAILURE;
}
/*
* Blocking call, wait till we get ACK for this msg.
*/
ret = wait_for_completion_timeout(&nss_rps_cfg_pvt.complete, msecs_to_jiffies(NSS_CONN_CFG_TIMEOUT));
if (ret == 0) {
nss_warning("%p: Waiting for ack timed out\n", nss_ctx);
up(&nss_rps_cfg_pvt.sem);
return NSS_FAILURE;
}
/*
* ACK/NACK received from NSS FW
* If NACK: Handler function will restore nss_rps_config
* to previous state.
*/
if (NSS_FAILURE == nss_rps_cfg_pvt.response) {
up(&nss_rps_cfg_pvt.sem);
return NSS_FAILURE;
}
up(&nss_rps_cfg_pvt.sem);
return NSS_SUCCESS;
}
/*
* nss_rps_cfg_handler()
* Enable NSS RPS.
*/
static int nss_rps_cfg_handler(struct ctl_table *ctl, int write,
void __user *buffer, size_t *lenp, loff_t *ppos)
{
struct nss_top_instance *nss_top = &nss_top_main;
struct nss_ctx_instance *nss_ctx;
int ret, ret_rps, current_state, i;
current_state = nss_rps_config;
ret = proc_dointvec(ctl, write, buffer, lenp, ppos);
if (ret != NSS_SUCCESS) {
return ret;
}
if (!write) {
return ret;
}
if (nss_rps_config == 0) {
nss_info_always("Runtime disabling of NSS RPS not supported\n");
return ret;
}
if (nss_rps_config != 1) {
nss_info_always("Invalid input value. Valid values are 0 and 1\n");
return ret;
}
for (i = 0; i < nss_top_main.num_nss; i++) {
nss_ctx = &nss_top->nss[i];
nss_info("Enabling NSS RPS\n");
ret_rps = nss_rps_cfg(nss_ctx, 1);
/*
* In here, we also need to revert the state of the previously enabled cores.
* However, runtime disabling is currently not supported since queues are not
* flushed in NSS FW.
* TODO: Flush queues in NSS FW.
*/
if (ret_rps != NSS_SUCCESS) {
nss_warning("%p: rps enabling failed\n", nss_ctx);
nss_rps_config = current_state;
return ret_rps;
}
}
return NSS_SUCCESS;
}
/*
* nss_rps_hash_bitmap_cfg_handler()
* Configure NSS rps_hash_bitmap
*/
static int nss_rps_hash_bitmap_cfg_handler(struct ctl_table *ctl, int write,
void __user *buffer, size_t *lenp, loff_t *ppos)
{
struct nss_top_instance *nss_top = &nss_top_main;
struct nss_ctx_instance *nss_ctx = &nss_top->nss[0];
int ret, ret_ipv4, ret_ipv6, current_state;
current_state = nss_rps_hash_bitmap;
ret = proc_dointvec(ctl, write, buffer, lenp, ppos);
if (ret != NSS_SUCCESS) {
nss_rps_hash_bitmap = current_state;
return ret;
}
if (!write) {
return ret;
}
if (nss_rps_hash_bitmap <= (NSS_RPS_MAX_CORE_HASH_BITMAP)) {
nss_info("Configuring NSS RPS hash_bitmap\n");
ret_ipv4 = nss_rps_ipv4_hash_bitmap_cfg(nss_ctx, nss_rps_hash_bitmap);
if (ret_ipv4 != NSS_SUCCESS) {
nss_warning("%p: ipv4 hash_bitmap config message failed\n", nss_ctx);
nss_rps_hash_bitmap = current_state;
return ret_ipv4;
}
ret_ipv6 = nss_rps_ipv6_hash_bitmap_cfg(nss_ctx, nss_rps_hash_bitmap);
if (ret_ipv6 != NSS_SUCCESS) {
nss_warning("%p: ipv6 hash_bitmap config message failed\n", nss_ctx);
nss_rps_hash_bitmap = current_state;
if (nss_rps_ipv4_hash_bitmap_cfg(nss_ctx, nss_rps_hash_bitmap != NSS_SUCCESS)) {
nss_warning("%p: ipv4 and ipv6 have different hash_bitmaps.\n", nss_ctx);
}
return ret_ipv6;
}
return 0;
}
nss_info_always("Invalid input value. Valid values are less than %d\n", (NSS_RPS_MAX_CORE_HASH_BITMAP));
return ret;
}
/* nss_rps_pri_map_cfg_handler()
* Configure NSS rps_pri_map
*/
static int nss_rps_pri_map_cfg_handler(struct ctl_table *ctl, int write,
void __user *buffer, size_t *lenp, loff_t *ppos)
{
struct nss_top_instance *nss_top = &nss_top_main;
struct nss_ctx_instance *nss_ctx = &nss_top->nss[0];
int ret, ret_pri_map;
struct nss_rps_pri_map_parse_data out, current_state;
if (!write) {
return nss_rps_pri_map_print(ctl, buffer, lenp, ppos, nss_rps_pri_map);
}
ret = nss_rps_pri_map_parse(ctl, buffer, lenp, ppos, &out);
if (ret != NSS_SUCCESS) {
nss_rps_pri_map_usage();
return ret;
}
nss_info("Configuring NSS RPS Priority Map\n");
current_state.pri = out.pri;
current_state.core = nss_rps_pri_map[out.pri];
nss_rps_pri_map[out.pri] = out.core;
ret_pri_map = nss_rps_pri_map_cfg(nss_ctx, nss_rps_pri_map);
if (ret_pri_map != NSS_SUCCESS) {
nss_rps_pri_map[current_state.pri] = current_state.core;
nss_warning("%p: pri_map config message failed\n", nss_ctx);
}
return ret_pri_map;
}
static struct ctl_table nss_rps_table[] = {
{
.procname = "enable",
.data = &nss_rps_config,
.maxlen = sizeof(int),
.mode = 0644,
.proc_handler = &nss_rps_cfg_handler,
},
{
.procname = "hash_bitmap",
.data = &nss_rps_hash_bitmap,
.maxlen = sizeof(int),
.mode = 0644,
.proc_handler = &nss_rps_hash_bitmap_cfg_handler,
},
{
.procname = "pri_map",
.data = &nss_rps_pri_map[NSS_MAX_NUM_PRI],
.maxlen = sizeof(int),
.mode = 0644,
.proc_handler = &nss_rps_pri_map_cfg_handler,
},
{ }
};
static struct ctl_table nss_rps_dir[] = {
{
.procname = "rps",
.mode = 0555,
.child = nss_rps_table,
},
{ }
};
static struct ctl_table nss_rps_root_dir[] = {
{
.procname = "nss",
.mode = 0555,
.child = nss_rps_dir,
},
{ }
};
static struct ctl_table nss_rps_root[] = {
{
.procname = "dev",
.mode = 0555,
.child = nss_rps_root_dir,
},
{ }
};
static struct ctl_table_header *nss_rps_header;
/*
* nss_rps_pri_map_init_handler()
* Initialize pri_map for priority based rps selection.
*/
void nss_rps_pri_map_init_handler(void)
{
int i;
/*
Initialize the mapping table with the default values.
*/
for (i = 0; i < NSS_MAX_NUM_PRI; i++) {
nss_rps_pri_map[i] = NSS_N2H_RPS_PRI_DEFAULT;
}
}
/*
* nss_rps_register_sysctl()
*/
void nss_rps_register_sysctl(void)
{
/*
* rps sema init.
*/
sema_init(&nss_rps_cfg_pvt.sem, 1);
init_completion(&nss_rps_cfg_pvt.complete);
nss_rps_pri_map_init_handler();
/*
* Register sysctl table.
*/
nss_rps_header = register_sysctl_table(nss_rps_root);
}
/*
* nss_rps_unregister_sysctl()
* Unregister sysctl specific to rps
*/
void nss_rps_unregister_sysctl(void)
{
/*
* Unregister sysctl table.
*/
if (nss_rps_header) {
unregister_sysctl_table(nss_rps_header);
}
}