numam-spdk/app/spdk_top/spdk_top.c
Krzysztof Karas f79e0fc945 spdk_top: refactor refresh_pollers_tab function
Refactors refresh_pollers_tab function to avoid future code duplication,
while displaying pollers details.

Signed-off-by: Krzysztof Karas <krzysztof.karas@intel.com>
Change-Id: I4432a8044a718fc4be0d71ca5b4c59323d90e6e9
Reviewed-on: https://review.spdk.io/gerrit/c/spdk/spdk/+/6001
Reviewed-by: Jim Harris <james.r.harris@intel.com>
Reviewed-by: Tomasz Zawadzki <tomasz.zawadzki@intel.com>
Reviewed-by: Maciej Szwed <maciej.szwed@intel.com>
Tested-by: SPDK CI Jenkins <sys_sgci@intel.com>
2021-01-22 18:31:52 +00:00

2180 lines
61 KiB
C

/*-
* BSD LICENSE
*
* Copyright (c) Intel Corporation.
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* * Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in
* the documentation and/or other materials provided with the
* distribution.
* * Neither the name of Intel Corporation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
* A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
* OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
* SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
* LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "spdk/stdinc.h"
#include "spdk/jsonrpc.h"
#include "spdk/rpc.h"
#include "spdk/event.h"
#include "spdk/util.h"
#include "spdk/env.h"
#if defined __has_include
#if __has_include(<ncurses/panel.h>)
#include <ncurses/ncurses.h>
#include <ncurses/panel.h>
#include <ncurses/menu.h>
#else
#include <ncurses.h>
#include <panel.h>
#include <menu.h>
#endif
#else
#include <ncurses.h>
#include <panel.h>
#include <menu.h>
#endif
#define RPC_MAX_THREADS 1024
#define RPC_MAX_POLLERS 1024
#define RPC_MAX_CORES 255
#define MAX_THREAD_NAME 128
#define MAX_POLLER_NAME 128
#define MAX_THREADS 4096
#define RR_MAX_VALUE 255
#define MAX_STRING_LEN 12289 /* 3x 4k monitors + 1 */
#define TAB_WIN_HEIGHT 3
#define TAB_WIN_LOCATION_ROW 1
#define TABS_SPACING 2
#define TABS_LOCATION_ROW 4
#define TABS_LOCATION_COL 0
#define TABS_DATA_START_ROW 3
#define TABS_DATA_START_COL 2
#define TABS_COL_COUNT 10
#define MENU_WIN_HEIGHT 3
#define MENU_WIN_SPACING 4
#define MENU_WIN_LOCATION_COL 0
#define RR_WIN_WIDTH 32
#define RR_WIN_HEIGHT 5
#define MAX_THREAD_NAME_LEN 26
#define MAX_THREAD_COUNT_STR_LEN 14
#define MAX_POLLER_NAME_LEN 36
#define MAX_POLLER_COUNT_STR_LEN 16
#define MAX_POLLER_TYPE_STR_LEN 8
#define MAX_CORE_MASK_STR_LEN 16
#define MAX_CORE_STR_LEN 6
#define MAX_TIME_STR_LEN 10
#define MAX_PERIOD_STR_LEN 12
#define WINDOW_HEADER 12
#define FROM_HEX 16
#define THREAD_WIN_WIDTH 69
#define THREAD_WIN_HEIGHT 9
#define THREAD_WIN_HOR_POS 75
#define THREAD_WIN_FIRST_COL 2
enum tabs {
THREADS_TAB,
POLLERS_TAB,
CORES_TAB,
NUMBER_OF_TABS,
};
enum spdk_poller_type {
SPDK_ACTIVE_POLLER,
SPDK_TIMED_POLLER,
SPDK_PAUSED_POLLER,
SPDK_POLLER_TYPES_COUNT,
};
struct col_desc {
const char *name;
uint8_t name_len;
uint8_t max_data_string;
bool disabled;
};
struct run_counter_history {
char *poller_name;
uint64_t thread_id;
uint64_t last_run_counter;
TAILQ_ENTRY(run_counter_history) link;
};
struct core_info {
uint32_t core;
uint64_t threads_count;
uint64_t pollers_count;
uint64_t idle;
uint64_t last_idle;
uint64_t busy;
uint64_t last_busy;
};
uint8_t g_sleep_time = 1;
uint16_t g_selected_row;
uint16_t g_max_selected_row;
struct rpc_thread_info *g_thread_info[MAX_THREADS];
const char *poller_type_str[SPDK_POLLER_TYPES_COUNT] = {"Active", "Timed", "Paused"};
const char *g_tab_title[NUMBER_OF_TABS] = {"[1] THREADS", "[2] POLLERS", "[3] CORES"};
struct spdk_jsonrpc_client *g_rpc_client;
static TAILQ_HEAD(, run_counter_history) g_run_counter_history = TAILQ_HEAD_INITIALIZER(
g_run_counter_history);
struct core_info g_cores_history[RPC_MAX_CORES];
WINDOW *g_menu_win, *g_tab_win[NUMBER_OF_TABS], *g_tabs[NUMBER_OF_TABS];
PANEL *g_panels[NUMBER_OF_TABS];
uint16_t g_max_row, g_max_col;
uint16_t g_data_win_size, g_max_data_rows;
uint32_t g_last_threads_count, g_last_pollers_count, g_last_cores_count;
uint8_t g_current_sort_col[NUMBER_OF_TABS] = {0, 0, 0};
static struct col_desc g_col_desc[NUMBER_OF_TABS][TABS_COL_COUNT] = {
{ {.name = "Thread name", .max_data_string = MAX_THREAD_NAME_LEN},
{.name = "Core", .max_data_string = MAX_CORE_STR_LEN},
{.name = "Active pollers", .max_data_string = MAX_POLLER_COUNT_STR_LEN},
{.name = "Timed pollers", .max_data_string = MAX_POLLER_COUNT_STR_LEN},
{.name = "Paused pollers", .max_data_string = MAX_POLLER_COUNT_STR_LEN},
{.name = "Idle [us]", .max_data_string = MAX_TIME_STR_LEN},
{.name = "Busy [us]", .max_data_string = MAX_TIME_STR_LEN},
{.name = (char *)NULL}
},
{ {.name = "Poller name", .max_data_string = MAX_POLLER_NAME_LEN},
{.name = "Type", .max_data_string = MAX_POLLER_TYPE_STR_LEN},
{.name = "On thread", .max_data_string = MAX_THREAD_NAME_LEN},
{.name = "Run count", .max_data_string = MAX_TIME_STR_LEN},
{.name = "Period [us]", .max_data_string = MAX_PERIOD_STR_LEN},
{.name = (char *)NULL}
},
{ {.name = "Core", .max_data_string = MAX_CORE_STR_LEN},
{.name = "Thread count", .max_data_string = MAX_THREAD_COUNT_STR_LEN},
{.name = "Poller count", .max_data_string = MAX_POLLER_COUNT_STR_LEN},
{.name = "Idle [us]", .max_data_string = MAX_TIME_STR_LEN},
{.name = "Busy [us]", .max_data_string = MAX_TIME_STR_LEN},
{.name = (char *)NULL}
}
};
struct rpc_thread_info {
char *name;
uint64_t id;
uint32_t core_num;
char *cpumask;
uint64_t busy;
uint64_t last_busy;
uint64_t idle;
uint64_t last_idle;
uint64_t active_pollers_count;
uint64_t timed_pollers_count;
uint64_t paused_pollers_count;
};
struct rpc_threads {
uint64_t threads_count;
struct rpc_thread_info thread_info[RPC_MAX_THREADS];
};
struct rpc_threads_stats {
uint64_t tick_rate;
struct rpc_threads threads;
};
struct rpc_poller_info {
char *name;
char *state;
uint64_t run_count;
uint64_t busy_count;
uint64_t period_ticks;
enum spdk_poller_type type;
char thread_name[MAX_THREAD_NAME];
uint64_t thread_id;
};
struct rpc_pollers {
uint64_t pollers_count;
struct rpc_poller_info pollers[RPC_MAX_POLLERS];
};
struct rpc_poller_thread_info {
char *name;
uint64_t id;
struct rpc_pollers active_pollers;
struct rpc_pollers timed_pollers;
struct rpc_pollers paused_pollers;
};
struct rpc_pollers_threads {
uint64_t threads_count;
struct rpc_poller_thread_info threads[RPC_MAX_THREADS];
};
struct rpc_pollers_stats {
uint64_t tick_rate;
struct rpc_pollers_threads pollers_threads;
};
struct rpc_core_thread_info {
char *name;
uint64_t id;
char *cpumask;
uint64_t elapsed;
};
struct rpc_core_threads {
uint64_t threads_count;
struct rpc_core_thread_info thread[RPC_MAX_THREADS];
};
struct rpc_core_info {
uint32_t lcore;
uint64_t busy;
uint64_t idle;
struct rpc_core_threads threads;
};
struct rpc_cores {
uint64_t cores_count;
struct rpc_core_info core[RPC_MAX_CORES];
};
struct rpc_cores_stats {
uint64_t tick_rate;
struct rpc_cores cores;
};
struct rpc_threads_stats g_threads_stats;
struct rpc_pollers_stats g_pollers_stats;
struct rpc_cores_stats g_cores_stats;
struct rpc_thread_info g_thread_history[RPC_MAX_THREADS];
static void
init_str_len(void)
{
int i, j;
for (i = 0; i < NUMBER_OF_TABS; i++) {
for (j = 0; g_col_desc[i][j].name != NULL; j++) {
g_col_desc[i][j].name_len = strlen(g_col_desc[i][j].name);
}
}
}
static void
free_rpc_threads_stats(struct rpc_threads_stats *req)
{
uint64_t i;
for (i = 0; i < req->threads.threads_count; i++) {
free(req->threads.thread_info[i].name);
req->threads.thread_info[i].name = NULL;
free(req->threads.thread_info[i].cpumask);
req->threads.thread_info[i].cpumask = NULL;
}
}
static const struct spdk_json_object_decoder rpc_thread_info_decoders[] = {
{"name", offsetof(struct rpc_thread_info, name), spdk_json_decode_string},
{"id", offsetof(struct rpc_thread_info, id), spdk_json_decode_uint64},
{"cpumask", offsetof(struct rpc_thread_info, cpumask), spdk_json_decode_string},
{"busy", offsetof(struct rpc_thread_info, busy), spdk_json_decode_uint64},
{"idle", offsetof(struct rpc_thread_info, idle), spdk_json_decode_uint64},
{"active_pollers_count", offsetof(struct rpc_thread_info, active_pollers_count), spdk_json_decode_uint64},
{"timed_pollers_count", offsetof(struct rpc_thread_info, timed_pollers_count), spdk_json_decode_uint64},
{"paused_pollers_count", offsetof(struct rpc_thread_info, paused_pollers_count), spdk_json_decode_uint64},
};
static int
rpc_decode_threads_object(const struct spdk_json_val *val, void *out)
{
struct rpc_thread_info *info = out;
return spdk_json_decode_object(val, rpc_thread_info_decoders,
SPDK_COUNTOF(rpc_thread_info_decoders), info);
}
static int
rpc_decode_threads_array(const struct spdk_json_val *val, void *out)
{
struct rpc_threads *threads = out;
return spdk_json_decode_array(val, rpc_decode_threads_object, threads->thread_info, RPC_MAX_THREADS,
&threads->threads_count, sizeof(struct rpc_thread_info));
}
static const struct spdk_json_object_decoder rpc_threads_stats_decoders[] = {
{"tick_rate", offsetof(struct rpc_threads_stats, tick_rate), spdk_json_decode_uint64},
{"threads", offsetof(struct rpc_threads_stats, threads), rpc_decode_threads_array},
};
static void
free_rpc_poller(struct rpc_poller_info *poller)
{
free(poller->name);
poller->name = NULL;
free(poller->state);
poller->state = NULL;
}
static void
free_rpc_pollers_stats(struct rpc_pollers_stats *req)
{
struct rpc_poller_thread_info *thread;
uint64_t i, j;
for (i = 0; i < req->pollers_threads.threads_count; i++) {
thread = &req->pollers_threads.threads[i];
for (j = 0; j < thread->active_pollers.pollers_count; j++) {
free_rpc_poller(&thread->active_pollers.pollers[j]);
}
for (j = 0; j < thread->timed_pollers.pollers_count; j++) {
free_rpc_poller(&thread->timed_pollers.pollers[j]);
}
for (j = 0; j < thread->paused_pollers.pollers_count; j++) {
free_rpc_poller(&thread->paused_pollers.pollers[j]);
}
free(thread->name);
thread->name = NULL;
}
}
static void
free_rpc_cores_stats(struct rpc_cores_stats *req)
{
struct rpc_core_info *core;
struct rpc_core_thread_info *thread;
uint64_t i, j;
for (i = 0; i < req->cores.cores_count; i++) {
core = &req->cores.core[i];
for (j = 0; j < core->threads.threads_count; j++) {
thread = &core->threads.thread[j];
free(thread->name);
free(thread->cpumask);
}
}
}
static const struct spdk_json_object_decoder rpc_pollers_decoders[] = {
{"name", offsetof(struct rpc_poller_info, name), spdk_json_decode_string},
{"state", offsetof(struct rpc_poller_info, state), spdk_json_decode_string},
{"run_count", offsetof(struct rpc_poller_info, run_count), spdk_json_decode_uint64},
{"busy_count", offsetof(struct rpc_poller_info, busy_count), spdk_json_decode_uint64},
{"period_ticks", offsetof(struct rpc_poller_info, period_ticks), spdk_json_decode_uint64, true},
};
static int
rpc_decode_pollers_object(const struct spdk_json_val *val, void *out)
{
struct rpc_poller_info *info = out;
return spdk_json_decode_object(val, rpc_pollers_decoders, SPDK_COUNTOF(rpc_pollers_decoders), info);
}
static int
rpc_decode_pollers_array(const struct spdk_json_val *val, void *out)
{
struct rpc_pollers *pollers = out;
return spdk_json_decode_array(val, rpc_decode_pollers_object, pollers->pollers, RPC_MAX_THREADS,
&pollers->pollers_count, sizeof(struct rpc_poller_info));
}
static const struct spdk_json_object_decoder rpc_pollers_threads_decoders[] = {
{"name", offsetof(struct rpc_poller_thread_info, name), spdk_json_decode_string},
{"id", offsetof(struct rpc_poller_thread_info, id), spdk_json_decode_uint64},
{"active_pollers", offsetof(struct rpc_poller_thread_info, active_pollers), rpc_decode_pollers_array},
{"timed_pollers", offsetof(struct rpc_poller_thread_info, timed_pollers), rpc_decode_pollers_array},
{"paused_pollers", offsetof(struct rpc_poller_thread_info, paused_pollers), rpc_decode_pollers_array},
};
static int
rpc_decode_pollers_threads_object(const struct spdk_json_val *val, void *out)
{
struct rpc_poller_thread_info *info = out;
return spdk_json_decode_object(val, rpc_pollers_threads_decoders,
SPDK_COUNTOF(rpc_pollers_threads_decoders), info);
}
static int
rpc_decode_pollers_threads_array(const struct spdk_json_val *val, void *out)
{
struct rpc_pollers_threads *pollers_threads = out;
return spdk_json_decode_array(val, rpc_decode_pollers_threads_object, pollers_threads->threads,
RPC_MAX_THREADS, &pollers_threads->threads_count, sizeof(struct rpc_poller_thread_info));
}
static const struct spdk_json_object_decoder rpc_pollers_stats_decoders[] = {
{"tick_rate", offsetof(struct rpc_pollers_stats, tick_rate), spdk_json_decode_uint64},
{"threads", offsetof(struct rpc_pollers_stats, pollers_threads), rpc_decode_pollers_threads_array},
};
static const struct spdk_json_object_decoder rpc_core_thread_info_decoders[] = {
{"name", offsetof(struct rpc_core_thread_info, name), spdk_json_decode_string},
{"id", offsetof(struct rpc_core_thread_info, id), spdk_json_decode_uint64},
{"cpumask", offsetof(struct rpc_core_thread_info, cpumask), spdk_json_decode_string},
{"elapsed", offsetof(struct rpc_core_thread_info, elapsed), spdk_json_decode_uint64},
};
static int
rpc_decode_core_threads_object(const struct spdk_json_val *val, void *out)
{
struct rpc_core_thread_info *info = out;
return spdk_json_decode_object(val, rpc_core_thread_info_decoders,
SPDK_COUNTOF(rpc_core_thread_info_decoders), info);
}
static int
rpc_decode_cores_lw_threads(const struct spdk_json_val *val, void *out)
{
struct rpc_core_threads *threads = out;
return spdk_json_decode_array(val, rpc_decode_core_threads_object, threads->thread, RPC_MAX_THREADS,
&threads->threads_count, sizeof(struct rpc_core_thread_info));
}
static const struct spdk_json_object_decoder rpc_core_info_decoders[] = {
{"lcore", offsetof(struct rpc_core_info, lcore), spdk_json_decode_uint32},
{"busy", offsetof(struct rpc_core_info, busy), spdk_json_decode_uint64},
{"idle", offsetof(struct rpc_core_info, idle), spdk_json_decode_uint64},
{"lw_threads", offsetof(struct rpc_core_info, threads), rpc_decode_cores_lw_threads},
};
static int
rpc_decode_core_object(const struct spdk_json_val *val, void *out)
{
struct rpc_core_info *info = out;
return spdk_json_decode_object(val, rpc_core_info_decoders,
SPDK_COUNTOF(rpc_core_info_decoders), info);
}
static int
rpc_decode_cores_array(const struct spdk_json_val *val, void *out)
{
struct rpc_cores *cores = out;
return spdk_json_decode_array(val, rpc_decode_core_object, cores->core,
RPC_MAX_THREADS, &cores->cores_count, sizeof(struct rpc_core_info));
}
static const struct spdk_json_object_decoder rpc_cores_stats_decoders[] = {
{"tick_rate", offsetof(struct rpc_cores_stats, tick_rate), spdk_json_decode_uint64},
{"reactors", offsetof(struct rpc_cores_stats, cores), rpc_decode_cores_array},
};
static int
rpc_send_req(char *rpc_name, struct spdk_jsonrpc_client_response **resp)
{
struct spdk_jsonrpc_client_response *json_resp = NULL;
struct spdk_json_write_ctx *w;
struct spdk_jsonrpc_client_request *request;
int rc;
request = spdk_jsonrpc_client_create_request();
if (request == NULL) {
return -ENOMEM;
}
w = spdk_jsonrpc_begin_request(request, 1, rpc_name);
spdk_jsonrpc_end_request(request, w);
spdk_jsonrpc_client_send_request(g_rpc_client, request);
do {
rc = spdk_jsonrpc_client_poll(g_rpc_client, 1);
} while (rc == 0 || rc == -ENOTCONN);
if (rc <= 0) {
return -1;
}
json_resp = spdk_jsonrpc_client_get_response(g_rpc_client);
if (json_resp == NULL) {
return -1;
}
/* Check for error response */
if (json_resp->error != NULL) {
return -1;
}
assert(json_resp->result);
*resp = json_resp;
return 0;
}
static int
get_data(void)
{
struct spdk_jsonrpc_client_response *json_resp = NULL;
struct rpc_thread_info *thread_info;
struct rpc_core_info *core_info;
uint64_t i, j;
int rc = 0;
rc = rpc_send_req("thread_get_stats", &json_resp);
if (rc) {
goto end;
}
/* Decode json */
if (spdk_json_decode_object(json_resp->result, rpc_threads_stats_decoders,
SPDK_COUNTOF(rpc_threads_stats_decoders), &g_threads_stats)) {
rc = -EINVAL;
goto end;
}
spdk_jsonrpc_client_free_response(json_resp);
for (i = 0; i < g_threads_stats.threads.threads_count; i++) {
thread_info = &g_threads_stats.threads.thread_info[i];
g_thread_info[thread_info->id] = thread_info;
}
rc = rpc_send_req("thread_get_pollers", &json_resp);
if (rc) {
goto end;
}
/* Decode json */
memset(&g_pollers_stats, 0, sizeof(g_pollers_stats));
if (spdk_json_decode_object(json_resp->result, rpc_pollers_stats_decoders,
SPDK_COUNTOF(rpc_pollers_stats_decoders), &g_pollers_stats)) {
rc = -EINVAL;
goto end;
}
spdk_jsonrpc_client_free_response(json_resp);
rc = rpc_send_req("framework_get_reactors", &json_resp);
if (rc) {
goto end;
}
/* Decode json */
memset(&g_cores_stats, 0, sizeof(g_cores_stats));
if (spdk_json_decode_object(json_resp->result, rpc_cores_stats_decoders,
SPDK_COUNTOF(rpc_cores_stats_decoders), &g_cores_stats)) {
rc = -EINVAL;
goto end;
}
for (i = 0; i < g_cores_stats.cores.cores_count; i++) {
core_info = &g_cores_stats.cores.core[i];
for (j = 0; j < core_info->threads.threads_count; j++) {
g_thread_info[core_info->threads.thread[j].id]->core_num = core_info->lcore;
}
}
end:
spdk_jsonrpc_client_free_response(json_resp);
return rc;
}
static void
free_data(void)
{
free_rpc_threads_stats(&g_threads_stats);
free_rpc_pollers_stats(&g_pollers_stats);
free_rpc_cores_stats(&g_cores_stats);
}
enum str_alignment {
ALIGN_LEFT,
ALIGN_RIGHT,
};
static void
print_max_len(WINDOW *win, int row, uint16_t col, uint16_t max_len, enum str_alignment alignment,
const char *string)
{
const char dots[] = "...";
int DOTS_STR_LEN = sizeof(dots) / sizeof(dots[0]);
char tmp_str[MAX_STRING_LEN];
int len, max_col, max_str, cmp_len;
int max_row;
len = strlen(string);
getmaxyx(win, max_row, max_col);
if (row > max_row) {
/* We are in a process of resizing and this may happen */
return;
}
if (max_len != 0 && col + max_len < max_col) {
max_col = col + max_len;
}
max_str = max_col - col;
if (max_str <= DOTS_STR_LEN + 1) {
/* No space to print anything, but we have to let a user know about it */
mvwprintw(win, row, max_col - DOTS_STR_LEN - 1, "...");
refresh();
wrefresh(win);
return;
}
if (max_len) {
if (alignment == ALIGN_LEFT) {
snprintf(tmp_str, max_str, "%s%*c", string, max_len - len - 1, ' ');
} else {
snprintf(tmp_str, max_str, "%*c%s", max_len - len - 1, ' ', string);
}
cmp_len = max_len - 1;
} else {
snprintf(tmp_str, max_str, "%s", string);
cmp_len = len;
}
if (col + cmp_len > max_col - 1) {
snprintf(&tmp_str[max_str - DOTS_STR_LEN - 2], DOTS_STR_LEN, "%s", dots);
}
mvwprintw(win, row, col, tmp_str);
refresh();
wrefresh(win);
}
static void
draw_menu_win(void)
{
wbkgd(g_menu_win, COLOR_PAIR(2));
box(g_menu_win, 0, 0);
print_max_len(g_menu_win, 1, 1, 0, ALIGN_LEFT,
" [q] Quit | [1-3] TAB selection | [PgUp] Previous page | [PgDown] Next page | [c] Columns | [s] Sorting | [r] Refresh rate");
}
static void
draw_tab_win(enum tabs tab)
{
uint16_t col;
uint8_t white_spaces = TABS_SPACING * NUMBER_OF_TABS;
wbkgd(g_tab_win[tab], COLOR_PAIR(2));
box(g_tab_win[tab], 0, 0);
col = ((g_max_col - white_spaces) / NUMBER_OF_TABS / 2) - (strlen(g_tab_title[tab]) / 2) -
TABS_SPACING;
print_max_len(g_tab_win[tab], 1, col, 0, ALIGN_LEFT, g_tab_title[tab]);
}
static void
draw_tabs(enum tabs tab_index, uint8_t sort_col)
{
struct col_desc *col_desc = g_col_desc[tab_index];
WINDOW *tab = g_tabs[tab_index];
int i, j;
uint16_t offset, draw_offset;
for (i = 0; col_desc[i].name != NULL; i++) {
if (col_desc[i].disabled) {
continue;
}
offset = 1;
for (j = i; j != 0; j--) {
if (!col_desc[j - 1].disabled) {
offset += col_desc[j - 1].max_data_string;
offset += col_desc[j - 1].name_len % 2 + 1;
}
}
draw_offset = offset + (col_desc[i].max_data_string / 2) - (col_desc[i].name_len / 2);
if (i == sort_col) {
wattron(tab, COLOR_PAIR(3));
print_max_len(tab, 1, draw_offset, 0, ALIGN_LEFT, col_desc[i].name);
wattroff(tab, COLOR_PAIR(3));
} else {
print_max_len(tab, 1, draw_offset, 0, ALIGN_LEFT, col_desc[i].name);
}
if (offset != 1) {
print_max_len(tab, 1, offset - 1, 0, ALIGN_LEFT, "|");
}
}
print_max_len(tab, 2, 1, 0, ALIGN_LEFT, ""); /* Move to next line */
whline(tab, ACS_HLINE, MAX_STRING_LEN);
box(tab, 0, 0);
wrefresh(tab);
}
static void
resize_interface(enum tabs tab)
{
int i;
clear();
wclear(g_menu_win);
mvwin(g_menu_win, g_max_row - MENU_WIN_SPACING, MENU_WIN_LOCATION_COL);
wresize(g_menu_win, MENU_WIN_HEIGHT, g_max_col);
draw_menu_win();
for (i = 0; i < NUMBER_OF_TABS; i++) {
wclear(g_tabs[i]);
wresize(g_tabs[i], g_max_row - MENU_WIN_HEIGHT - TAB_WIN_HEIGHT - 2, g_max_col);
mvwin(g_tabs[i], TABS_LOCATION_ROW, TABS_LOCATION_COL);
draw_tabs(i, g_current_sort_col[i]);
}
draw_tabs(tab, g_current_sort_col[tab]);
for (i = 0; i < NUMBER_OF_TABS; i++) {
wclear(g_tab_win[i]);
wresize(g_tab_win[i], TAB_WIN_HEIGHT,
(g_max_col - (TABS_SPACING * NUMBER_OF_TABS)) / NUMBER_OF_TABS);
mvwin(g_tab_win[i], TAB_WIN_LOCATION_ROW, 1 + (g_max_col / NUMBER_OF_TABS) * i);
draw_tab_win(i);
}
update_panels();
doupdate();
}
static void
switch_tab(enum tabs tab)
{
top_panel(g_panels[tab]);
update_panels();
doupdate();
}
static void
get_time_str(uint64_t ticks, char *time_str)
{
uint64_t time;
time = ticks * SPDK_SEC_TO_USEC / g_cores_stats.tick_rate;
snprintf(time_str, MAX_TIME_STR_LEN, "%" PRIu64, time);
}
static int
sort_threads(const void *p1, const void *p2)
{
const struct rpc_thread_info *thread_info1 = *(struct rpc_thread_info **)p1;
const struct rpc_thread_info *thread_info2 = *(struct rpc_thread_info **)p2;
uint64_t count1, count2;
switch (g_current_sort_col[THREADS_TAB]) {
case 0: /* Sort by name */
return strcmp(thread_info1->name, thread_info2->name);
case 1: /* Sort by core */
count2 = thread_info1->core_num;
count1 = thread_info2->core_num;
break;
case 2: /* Sort by active pollers number */
count1 = thread_info1->active_pollers_count;
count2 = thread_info2->active_pollers_count;
break;
case 3: /* Sort by timed pollers number */
count1 = thread_info1->timed_pollers_count;
count2 = thread_info2->timed_pollers_count;
break;
case 4: /* Sort by paused pollers number */
count1 = thread_info1->paused_pollers_count;
count2 = thread_info2->paused_pollers_count;
break;
case 5: /* Sort by idle time */
count1 = thread_info1->idle - thread_info1->last_idle;
count2 = thread_info2->idle - thread_info2->last_idle;
break;
case 6: /* Sort by busy time */
count1 = thread_info1->busy - thread_info1->last_busy;
count2 = thread_info2->busy - thread_info2->last_busy;
break;
default:
return 0;
}
if (count2 > count1) {
return 1;
} else if (count2 < count1) {
return -1;
} else {
return 0;
}
}
static void
draw_row_background(uint8_t item_index, uint8_t tab)
{
int k;
if (item_index == g_selected_row) {
wattron(g_tabs[tab], COLOR_PAIR(2));
}
for (k = 1; k < g_max_col - 1; k++) {
mvwprintw(g_tabs[tab], TABS_DATA_START_ROW + item_index, k, " ");
}
}
static uint8_t
refresh_threads_tab(uint8_t current_page)
{
struct col_desc *col_desc = g_col_desc[THREADS_TAB];
uint64_t i, threads_count;
uint16_t j;
uint16_t col;
uint8_t max_pages, item_index;
static uint8_t last_page = 0;
char pollers_number[MAX_POLLER_COUNT_STR_LEN], idle_time[MAX_TIME_STR_LEN],
busy_time[MAX_TIME_STR_LEN], core_str[MAX_CORE_MASK_STR_LEN];
struct rpc_thread_info *thread_info[g_threads_stats.threads.threads_count];
threads_count = g_threads_stats.threads.threads_count;
/* Clear screen if number of threads changed */
if (g_last_threads_count != threads_count) {
for (i = TABS_DATA_START_ROW; i < g_data_win_size; i++) {
for (j = 1; j < (uint64_t)g_max_col - 1; j++) {
mvwprintw(g_tabs[THREADS_TAB], i, j, " ");
}
}
g_last_threads_count = threads_count;
}
/* Thread IDs starts from '1', so we have to take this into account when copying.
* TODO: In future we can have gaps in ID list, so we will need to change the way we
* handle copying threads list below */
memcpy(thread_info, &g_thread_info[1], sizeof(struct rpc_thread_info *) * threads_count);
if (last_page != current_page) {
for (i = 0; i < threads_count; i++) {
/* Thread IDs start from 1, so we have to do i + 1 */
g_threads_stats.threads.thread_info[i].last_idle = g_thread_info[i + 1]->idle;
g_threads_stats.threads.thread_info[i].last_busy = g_thread_info[i + 1]->busy;
}
last_page = current_page;
}
max_pages = (threads_count + g_max_data_rows - 1) / g_max_data_rows;
qsort(thread_info, threads_count, sizeof(thread_info[0]), sort_threads);
for (i = current_page * g_max_data_rows;
i < spdk_min(threads_count, (uint64_t)((current_page + 1) * g_max_data_rows));
i++) {
item_index = i - (current_page * g_max_data_rows);
col = TABS_DATA_START_COL;
draw_row_background(item_index, THREADS_TAB);
if (!col_desc[0].disabled) {
print_max_len(g_tabs[THREADS_TAB], TABS_DATA_START_ROW + item_index, col,
col_desc[0].max_data_string, ALIGN_LEFT, thread_info[i]->name);
col += col_desc[0].max_data_string;
}
if (!col_desc[1].disabled) {
snprintf(core_str, MAX_CORE_STR_LEN, "%d", thread_info[i]->core_num);
print_max_len(g_tabs[THREADS_TAB], TABS_DATA_START_ROW + item_index,
col, col_desc[1].max_data_string, ALIGN_RIGHT, core_str);
col += col_desc[1].max_data_string + 2;
}
if (!col_desc[2].disabled) {
snprintf(pollers_number, MAX_POLLER_COUNT_STR_LEN, "%ld", thread_info[i]->active_pollers_count);
print_max_len(g_tabs[THREADS_TAB], TABS_DATA_START_ROW + item_index,
col + (col_desc[2].name_len / 2), col_desc[2].max_data_string, ALIGN_LEFT, pollers_number);
col += col_desc[2].max_data_string + 2;
}
if (!col_desc[3].disabled) {
snprintf(pollers_number, MAX_POLLER_COUNT_STR_LEN, "%ld", thread_info[i]->timed_pollers_count);
print_max_len(g_tabs[THREADS_TAB], TABS_DATA_START_ROW + item_index,
col + (col_desc[3].name_len / 2), col_desc[3].max_data_string, ALIGN_LEFT, pollers_number);
col += col_desc[3].max_data_string + 1;
}
if (!col_desc[4].disabled) {
snprintf(pollers_number, MAX_POLLER_COUNT_STR_LEN, "%ld", thread_info[i]->paused_pollers_count);
print_max_len(g_tabs[THREADS_TAB], TABS_DATA_START_ROW + item_index,
col + (col_desc[4].name_len / 2), col_desc[4].max_data_string, ALIGN_LEFT, pollers_number);
col += col_desc[4].max_data_string + 2;
}
g_thread_history[thread_info[i]->id].idle = thread_info[i]->idle - thread_info[i]->last_idle;
if (!col_desc[5].disabled) {
get_time_str(thread_info[i]->idle - thread_info[i]->last_idle, idle_time);
print_max_len(g_tabs[THREADS_TAB], TABS_DATA_START_ROW + item_index, col,
col_desc[5].max_data_string, ALIGN_RIGHT, idle_time);
col += col_desc[5].max_data_string;
thread_info[i]->last_idle = thread_info[i]->idle;
}
g_thread_history[thread_info[i]->id].busy = thread_info[i]->busy - thread_info[i]->last_busy;
if (!col_desc[6].disabled) {
get_time_str(thread_info[i]->busy - thread_info[i]->last_busy, busy_time);
print_max_len(g_tabs[THREADS_TAB], TABS_DATA_START_ROW + item_index, col,
col_desc[6].max_data_string, ALIGN_RIGHT, busy_time);
thread_info[i]->last_busy = thread_info[i]->busy;
}
if (item_index == g_selected_row) {
wattroff(g_tabs[THREADS_TAB], COLOR_PAIR(2));
}
}
g_max_selected_row = i - current_page * g_max_data_rows - 1;
return max_pages;
}
static uint64_t *
get_last_run_counter(const char *poller_name, uint64_t thread_id)
{
struct run_counter_history *history;
TAILQ_FOREACH(history, &g_run_counter_history, link) {
if (!strcmp(history->poller_name, poller_name) && history->thread_id == thread_id) {
return &history->last_run_counter;
}
}
return NULL;
}
static void
store_last_run_counter(const char *poller_name, uint64_t thread_id, uint64_t last_run_counter)
{
struct run_counter_history *history;
TAILQ_FOREACH(history, &g_run_counter_history, link) {
if (!strcmp(history->poller_name, poller_name) && history->thread_id == thread_id) {
history->last_run_counter = last_run_counter;
return;
}
}
history = calloc(1, sizeof(*history));
if (history == NULL) {
fprintf(stderr, "Unable to allocate a history object in store_last_run_counter.\n");
return;
}
history->poller_name = strdup(poller_name);
history->thread_id = thread_id;
history->last_run_counter = last_run_counter;
TAILQ_INSERT_TAIL(&g_run_counter_history, history, link);
}
enum sort_type {
BY_NAME,
USE_GLOBAL,
};
static int
#ifdef __FreeBSD__
sort_pollers(void *arg, const void *p1, const void *p2)
#else
sort_pollers(const void *p1, const void *p2, void *arg)
#endif
{
const struct rpc_poller_info *poller1 = *(struct rpc_poller_info **)p1;
const struct rpc_poller_info *poller2 = *(struct rpc_poller_info **)p2;
enum sort_type sorting = *(enum sort_type *)arg;
uint64_t count1, count2;
uint64_t *last_run_counter;
if (sorting == BY_NAME) {
/* Sorting by name requested explicitly */
return strcmp(poller1->name, poller2->name);
} else {
/* Use globaly set sorting */
switch (g_current_sort_col[POLLERS_TAB]) {
case 0: /* Sort by name */
return strcmp(poller1->name, poller2->name);
case 1: /* Sort by type */
return poller1->type - poller2->type;
case 2: /* Sort by thread */
return strcmp(poller1->thread_name, poller2->thread_name);
case 3: /* Sort by run counter */
last_run_counter = get_last_run_counter(poller1->name, poller1->thread_id);
assert(last_run_counter != NULL);
count1 = poller1->run_count - *last_run_counter;
last_run_counter = get_last_run_counter(poller2->name, poller2->thread_id);
assert(last_run_counter != NULL);
count2 = poller2->run_count - *last_run_counter;
break;
case 4: /* Sort by period */
count1 = poller1->period_ticks;
count2 = poller2->period_ticks;
break;
default:
return 0;
}
}
if (count2 > count1) {
return 1;
} else if (count2 < count1) {
return -1;
} else {
return 0;
}
}
static void
copy_pollers(struct rpc_pollers *pollers, uint64_t pollers_count, enum spdk_poller_type type,
struct rpc_poller_thread_info *thread, uint64_t *current_count, bool reset_last_counter,
struct rpc_poller_info **pollers_info)
{
uint64_t *last_run_counter;
uint64_t i;
for (i = 0; i < pollers_count; i++) {
if (reset_last_counter) {
last_run_counter = get_last_run_counter(pollers->pollers[i].name, thread->id);
if (last_run_counter == NULL) {
store_last_run_counter(pollers->pollers[i].name, thread->id, pollers->pollers[i].run_count);
last_run_counter = get_last_run_counter(pollers->pollers[i].name, thread->id);
}
assert(last_run_counter != NULL);
*last_run_counter = pollers->pollers[i].run_count;
}
pollers_info[*current_count] = &pollers->pollers[i];
snprintf(pollers_info[*current_count]->thread_name, MAX_POLLER_NAME - 1, "%s", thread->name);
pollers_info[*current_count]->thread_id = thread->id;
pollers_info[(*current_count)++]->type = type;
}
}
static uint8_t
prepare_poller_data(uint8_t current_page, struct rpc_poller_info **pollers,
uint64_t *count, uint8_t last_page)
{
struct rpc_poller_thread_info *thread;
uint64_t i;
bool reset_last_counter = false;
enum sort_type sorting;
for (i = 0; i < g_pollers_stats.pollers_threads.threads_count; i++) {
thread = &g_pollers_stats.pollers_threads.threads[i];
if (last_page != current_page) {
reset_last_counter = true;
}
copy_pollers(&thread->active_pollers, thread->active_pollers.pollers_count, SPDK_ACTIVE_POLLER,
thread, count, reset_last_counter, pollers);
copy_pollers(&thread->timed_pollers, thread->timed_pollers.pollers_count, SPDK_TIMED_POLLER, thread,
count, reset_last_counter, pollers);
copy_pollers(&thread->paused_pollers, thread->paused_pollers.pollers_count, SPDK_PAUSED_POLLER,
thread, count, reset_last_counter, pollers);
}
if (last_page != current_page) {
last_page = current_page;
}
/* Timed pollers can switch their possition on a list because of how they work.
* Let's sort them by name first so that they won't switch on data refresh */
sorting = BY_NAME;
qsort_r(pollers, *count, sizeof(pollers[0]), sort_pollers, (void *)&sorting);
sorting = USE_GLOBAL;
qsort_r(pollers, *count, sizeof(pollers[0]), sort_pollers, (void *)&sorting);
return last_page;
}
static uint8_t
refresh_pollers_tab(uint8_t current_page)
{
struct col_desc *col_desc = g_col_desc[POLLERS_TAB];
uint64_t *last_run_counter;
uint64_t i, count = 0;
uint16_t col, j;
uint8_t max_pages, item_index;
static uint8_t g_last_page = 0xF;
/* Init g_last_page with value != 0 to force store_last_run_counter() call in copy_pollers()
* so that initial values for run_counter are stored in g_run_counter_history */
char run_count[MAX_TIME_STR_LEN], period_ticks[MAX_PERIOD_STR_LEN];
struct rpc_poller_info *pollers[RPC_MAX_POLLERS];
g_last_page = prepare_poller_data(current_page, pollers, &count, g_last_page);
max_pages = (count + g_max_data_rows - 1) / g_max_data_rows;
/* Clear screen if number of pollers changed */
if (g_last_pollers_count != count) {
for (i = TABS_DATA_START_ROW; i < g_data_win_size; i++) {
for (j = 1; j < (uint64_t)g_max_col - 1; j++) {
mvwprintw(g_tabs[POLLERS_TAB], i, j, " ");
}
}
g_last_pollers_count = count;
/* We need to run store_last_run_counter() again, so the easiest way is to call this function
* again with changed g_last_page value */
g_last_page = 0xF;
refresh_pollers_tab(current_page);
return max_pages;
}
/* Display info */
for (i = current_page * g_max_data_rows;
i < spdk_min(count, (uint64_t)((current_page + 1) * g_max_data_rows));
i++) {
item_index = i - (current_page * g_max_data_rows);
col = TABS_DATA_START_COL;
draw_row_background(item_index, POLLERS_TAB);
if (!col_desc[0].disabled) {
print_max_len(g_tabs[POLLERS_TAB], TABS_DATA_START_ROW + item_index, col + 1,
col_desc[0].max_data_string, ALIGN_LEFT, pollers[i]->name);
col += col_desc[0].max_data_string + 2;
}
if (!col_desc[1].disabled) {
print_max_len(g_tabs[POLLERS_TAB], TABS_DATA_START_ROW + item_index, col,
col_desc[1].max_data_string, ALIGN_LEFT, poller_type_str[pollers[i]->type]);
col += col_desc[1].max_data_string + 2;
}
if (!col_desc[2].disabled) {
print_max_len(g_tabs[POLLERS_TAB], TABS_DATA_START_ROW + item_index, col,
col_desc[2].max_data_string, ALIGN_LEFT, pollers[i]->thread_name);
col += col_desc[2].max_data_string + 1;
}
if (!col_desc[3].disabled) {
last_run_counter = get_last_run_counter(pollers[i]->name, pollers[i]->thread_id);
assert(last_run_counter != NULL);
snprintf(run_count, MAX_TIME_STR_LEN, "%" PRIu64, pollers[i]->run_count - *last_run_counter);
print_max_len(g_tabs[POLLERS_TAB], TABS_DATA_START_ROW + item_index, col,
col_desc[3].max_data_string, ALIGN_RIGHT, run_count);
col += col_desc[3].max_data_string;
store_last_run_counter(pollers[i]->name, pollers[i]->thread_id, pollers[i]->run_count);
}
if (!col_desc[4].disabled) {
if (pollers[i]->period_ticks != 0) {
get_time_str(pollers[i]->period_ticks, period_ticks);
print_max_len(g_tabs[POLLERS_TAB], TABS_DATA_START_ROW + item_index, col,
col_desc[4].max_data_string, ALIGN_RIGHT, period_ticks);
}
}
if (item_index == g_selected_row) {
wattroff(g_tabs[POLLERS_TAB], COLOR_PAIR(2));
}
}
g_max_selected_row = i - current_page * g_max_data_rows - 1;
return max_pages;
}
static int
sort_cores(const void *p1, const void *p2)
{
const struct core_info core_info1 = *(struct core_info *)p1;
const struct core_info core_info2 = *(struct core_info *)p2;
uint64_t count1, count2;
switch (g_current_sort_col[CORES_TAB]) {
case 0: /* Sort by core */
count1 = core_info2.core;
count2 = core_info1.core;
break;
case 1: /* Sort by threads number */
count1 = core_info1.threads_count;
count2 = core_info2.threads_count;
break;
case 2: /* Sort by pollers number */
count1 = core_info1.pollers_count;
count2 = core_info2.pollers_count;
break;
case 3: /* Sort by idle time */
count2 = g_cores_history[core_info1.core].last_idle - core_info1.idle;
count1 = g_cores_history[core_info2.core].last_idle - core_info2.idle;
break;
case 4: /* Sort by busy time */
count2 = g_cores_history[core_info1.core].last_busy - core_info1.busy;
count1 = g_cores_history[core_info2.core].last_busy - core_info2.busy;
break;
default:
return 0;
}
if (count2 > count1) {
return 1;
} else if (count2 < count1) {
return -1;
} else {
return 0;
}
}
static void
store_core_last_stats(uint32_t core, uint64_t idle, uint64_t busy)
{
g_cores_history[core].last_idle = idle;
g_cores_history[core].last_busy = busy;
}
static void
get_core_last_stats(uint32_t core, uint64_t *idle, uint64_t *busy)
{
*idle = g_cores_history[core].last_idle;
*busy = g_cores_history[core].last_busy;
}
static uint8_t
refresh_cores_tab(uint8_t current_page)
{
struct col_desc *col_desc = g_col_desc[CORES_TAB];
uint64_t i;
uint32_t core_num;
uint16_t offset, count = 0;
uint8_t max_pages, item_index;
static uint8_t last_page = 0;
char core[MAX_CORE_STR_LEN], threads_number[MAX_THREAD_COUNT_STR_LEN],
pollers_number[MAX_POLLER_COUNT_STR_LEN], idle_time[MAX_TIME_STR_LEN], busy_time[MAX_TIME_STR_LEN];
struct core_info cores[RPC_MAX_CORES];
memset(&cores, 0, sizeof(cores));
for (i = 0; i < g_threads_stats.threads.threads_count; i++) {
core_num = g_threads_stats.threads.thread_info[i].core_num;
cores[core_num].threads_count++;
cores[core_num].pollers_count += g_threads_stats.threads.thread_info[i].active_pollers_count +
g_threads_stats.threads.thread_info[i].timed_pollers_count +
g_threads_stats.threads.thread_info[i].paused_pollers_count;
}
count = g_cores_stats.cores.cores_count;
for (i = 0; i < count; i++) {
core_num = g_cores_stats.cores.core[i].lcore;
cores[core_num].core = core_num;
cores[core_num].busy = g_cores_stats.cores.core[i].busy;
cores[core_num].idle = g_cores_stats.cores.core[i].idle;
if (last_page != current_page) {
store_core_last_stats(cores[core_num].core, cores[core_num].idle, cores[core_num].busy);
}
}
if (last_page != current_page) {
last_page = current_page;
}
max_pages = (count + g_max_row - WINDOW_HEADER - 1) / (g_max_row - WINDOW_HEADER);
qsort(&cores, count, sizeof(cores[0]), sort_cores);
for (i = current_page * g_max_data_rows;
i < spdk_min(count, (uint64_t)((current_page + 1) * g_max_data_rows));
i++) {
item_index = i - (current_page * g_max_data_rows);
core_num = g_cores_stats.cores.core[i].lcore;
snprintf(threads_number, MAX_THREAD_COUNT_STR_LEN, "%ld", cores[core_num].threads_count);
snprintf(pollers_number, MAX_POLLER_COUNT_STR_LEN, "%ld", cores[core_num].pollers_count);
get_core_last_stats(cores[core_num].core, &cores[core_num].last_idle, &cores[core_num].last_busy);
offset = 1;
draw_row_background(item_index, CORES_TAB);
if (!col_desc[0].disabled) {
snprintf(core, MAX_CORE_STR_LEN, "%d", cores[core_num].core);
print_max_len(g_tabs[CORES_TAB], TABS_DATA_START_ROW + item_index, offset,
col_desc[0].max_data_string, ALIGN_RIGHT, core);
offset += col_desc[0].max_data_string + 2;
}
if (!col_desc[1].disabled) {
print_max_len(g_tabs[CORES_TAB], TABS_DATA_START_ROW + item_index,
offset + (col_desc[1].name_len / 2), col_desc[1].max_data_string, ALIGN_LEFT, threads_number);
offset += col_desc[1].max_data_string + 2;
}
if (!col_desc[2].disabled) {
print_max_len(g_tabs[CORES_TAB], TABS_DATA_START_ROW + item_index,
offset + (col_desc[2].name_len / 2), col_desc[2].max_data_string, ALIGN_LEFT, pollers_number);
offset += col_desc[2].max_data_string;
}
if (!col_desc[3].disabled) {
get_time_str(cores[core_num].idle - cores[core_num].last_idle, idle_time);
print_max_len(g_tabs[CORES_TAB], TABS_DATA_START_ROW + item_index, offset,
col_desc[3].max_data_string, ALIGN_RIGHT, idle_time);
offset += col_desc[3].max_data_string + 2;
}
if (!col_desc[4].disabled) {
get_time_str(cores[core_num].busy - cores[core_num].last_busy, busy_time);
print_max_len(g_tabs[CORES_TAB], TABS_DATA_START_ROW + item_index, offset,
col_desc[4].max_data_string, ALIGN_RIGHT, busy_time);
}
store_core_last_stats(cores[core_num].core, cores[core_num].idle, cores[core_num].busy);
if (item_index == g_selected_row) {
wattroff(g_tabs[CORES_TAB], COLOR_PAIR(2));
}
}
g_max_selected_row = i - current_page * g_max_data_rows - 1;
return max_pages;
}
static uint8_t
refresh_tab(enum tabs tab, uint8_t current_page)
{
uint8_t (*refresh_function[NUMBER_OF_TABS])(uint8_t current_page) = {refresh_threads_tab, refresh_pollers_tab, refresh_cores_tab};
int color_pair[NUMBER_OF_TABS] = {COLOR_PAIR(2), COLOR_PAIR(2), COLOR_PAIR(2)};
int i;
uint8_t max_pages = 0;
color_pair[tab] = COLOR_PAIR(1);
for (i = 0; i < NUMBER_OF_TABS; i++) {
wbkgd(g_tab_win[i], color_pair[i]);
}
max_pages = (*refresh_function[tab])(current_page);
refresh();
for (i = 0; i < NUMBER_OF_TABS; i++) {
wrefresh(g_tab_win[i]);
}
return max_pages;
}
static void
print_in_middle(WINDOW *win, int starty, int startx, int width, char *string, chtype color)
{
int length, temp;
length = strlen(string);
temp = (width - length) / 2;
wattron(win, color);
mvwprintw(win, starty, startx + temp, "%s", string);
wattroff(win, color);
refresh();
}
static void
print_left(WINDOW *win, int starty, int startx, int width, char *string, chtype color)
{
wattron(win, color);
mvwprintw(win, starty, startx, "%s", string);
wattroff(win, color);
refresh();
}
static void
apply_filters(enum tabs tab)
{
wclear(g_tabs[tab]);
draw_tabs(tab, g_current_sort_col[tab]);
}
static ITEM **
draw_filtering_menu(uint8_t position, WINDOW *filter_win, uint8_t tab, MENU **my_menu)
{
const int ADDITIONAL_ELEMENTS = 3;
const int ROW_PADDING = 6;
const int WINDOW_START_X = 1;
const int WINDOW_START_Y = 3;
const int WINDOW_COLUMNS = 2;
struct col_desc *col_desc = g_col_desc[tab];
ITEM **my_items;
MENU *menu;
int i, elements;
uint8_t len = 0;
for (i = 0; col_desc[i].name != NULL; ++i) {
len = spdk_max(col_desc[i].name_len, len);
}
elements = i;
my_items = (ITEM **)calloc(elements * WINDOW_COLUMNS + ADDITIONAL_ELEMENTS, sizeof(ITEM *));
if (my_items == NULL) {
fprintf(stderr, "Unable to allocate an item list in draw_filtering_menu.\n");
return NULL;
}
for (i = 0; i < elements * 2; i++) {
my_items[i] = new_item(col_desc[i / WINDOW_COLUMNS].name, NULL);
i++;
my_items[i] = new_item(col_desc[i / WINDOW_COLUMNS].disabled ? "[ ]" : "[*]", NULL);
}
my_items[i] = new_item(" CLOSE", NULL);
set_item_userptr(my_items[i], apply_filters);
menu = new_menu((ITEM **)my_items);
menu_opts_off(menu, O_SHOWDESC);
set_menu_format(menu, elements + 1, WINDOW_COLUMNS);
set_menu_win(menu, filter_win);
set_menu_sub(menu, derwin(filter_win, elements + 1, len + ROW_PADDING, WINDOW_START_Y,
WINDOW_START_X));
*my_menu = menu;
post_menu(menu);
refresh();
wrefresh(filter_win);
for (i = 0; i < position / WINDOW_COLUMNS; i++) {
menu_driver(menu, REQ_DOWN_ITEM);
}
return my_items;
}
static void
delete_filtering_menu(MENU *my_menu, ITEM **my_items, uint8_t elements)
{
int i;
unpost_menu(my_menu);
free_menu(my_menu);
for (i = 0; i < elements * 2 + 2; ++i) {
free_item(my_items[i]);
}
free(my_items);
}
static ITEM **
refresh_filtering_menu(MENU **my_menu, WINDOW *filter_win, uint8_t tab, ITEM **my_items,
uint8_t elements, uint8_t position)
{
delete_filtering_menu(*my_menu, my_items, elements);
return draw_filtering_menu(position, filter_win, tab, my_menu);
}
static void
filter_columns(uint8_t tab)
{
const int WINDOW_HEADER_LEN = 5;
const int WINDOW_BORDER_LEN = 8;
const int WINDOW_HEADER_END_LINE = 2;
const int WINDOW_COLUMNS = 2;
struct col_desc *col_desc = g_col_desc[tab];
PANEL *filter_panel;
WINDOW *filter_win;
ITEM **my_items;
MENU *my_menu = NULL;
int i, c, elements;
bool stop_loop = false;
ITEM *cur;
void (*p)(enum tabs tab);
uint8_t current_index, len = 0;
for (i = 0; col_desc[i].name != NULL; ++i) {
len = spdk_max(col_desc[i].name_len, len);
}
elements = i;
filter_win = newwin(elements + WINDOW_HEADER_LEN, len + WINDOW_BORDER_LEN,
(g_max_row - elements - 1) / 2, (g_max_col - len) / 2);
assert(filter_win != NULL);
keypad(filter_win, TRUE);
filter_panel = new_panel(filter_win);
assert(filter_panel != NULL);
top_panel(filter_panel);
update_panels();
doupdate();
box(filter_win, 0, 0);
print_in_middle(filter_win, 1, 0, len + WINDOW_BORDER_LEN, "Filtering", COLOR_PAIR(3));
mvwaddch(filter_win, WINDOW_HEADER_END_LINE, 0, ACS_LTEE);
mvwhline(filter_win, WINDOW_HEADER_END_LINE, 1, ACS_HLINE, len + WINDOW_BORDER_LEN - 2);
mvwaddch(filter_win, WINDOW_HEADER_END_LINE, len + WINDOW_BORDER_LEN - 1, ACS_RTEE);
my_items = draw_filtering_menu(0, filter_win, tab, &my_menu);
if (my_items == NULL || my_menu == NULL) {
goto fail;
}
while (!stop_loop) {
c = wgetch(filter_win);
switch (c) {
case KEY_DOWN:
menu_driver(my_menu, REQ_DOWN_ITEM);
break;
case KEY_UP:
menu_driver(my_menu, REQ_UP_ITEM);
break;
case 27: /* ESC */
case 'q':
stop_loop = true;
break;
case ' ': /* Space */
cur = current_item(my_menu);
current_index = item_index(cur) / WINDOW_COLUMNS;
col_desc[current_index].disabled = !col_desc[current_index].disabled;
my_items = refresh_filtering_menu(&my_menu, filter_win, tab, my_items, elements,
item_index(cur) + 1);
if (my_items == NULL || my_menu == NULL) {
goto fail;
}
break;
case 10: /* Enter */
cur = current_item(my_menu);
current_index = item_index(cur) / WINDOW_COLUMNS;
if (current_index == elements) {
stop_loop = true;
p = item_userptr(cur);
p(tab);
} else {
col_desc[current_index].disabled = !col_desc[current_index].disabled;
my_items = refresh_filtering_menu(&my_menu, filter_win, tab, my_items, elements,
item_index(cur) + 1);
if (my_items == NULL || my_menu == NULL) {
goto fail;
}
}
break;
}
wrefresh(filter_win);
}
delete_filtering_menu(my_menu, my_items, elements);
del_panel(filter_panel);
delwin(filter_win);
wclear(g_menu_win);
draw_menu_win();
return;
fail:
fprintf(stderr, "Unable to filter the columns due to allocation failure.\n");
assert(false);
}
static void
sort_type(enum tabs tab, int item_index)
{
g_current_sort_col[tab] = item_index;
wclear(g_tabs[tab]);
draw_tabs(tab, g_current_sort_col[tab]);
}
static void
change_sorting(uint8_t tab)
{
const int WINDOW_HEADER_LEN = 4;
const int WINDOW_BORDER_LEN = 3;
const int WINDOW_START_X = 1;
const int WINDOW_START_Y = 3;
const int WINDOW_HEADER_END_LINE = 2;
PANEL *sort_panel;
WINDOW *sort_win;
ITEM **my_items;
MENU *my_menu;
int i, c, elements;
bool stop_loop = false;
ITEM *cur;
void (*p)(enum tabs tab, int item_index);
uint8_t len = 0;
for (i = 0; g_col_desc[tab][i].name != NULL; ++i) {
len = spdk_max(len, g_col_desc[tab][i].name_len);
}
elements = i;
my_items = (ITEM **)calloc(elements + 1, sizeof(ITEM *));
if (my_items == NULL) {
fprintf(stderr, "Unable to allocate an item list in change_sorting.\n");
return;
}
for (i = 0; i < elements; ++i) {
my_items[i] = new_item(g_col_desc[tab][i].name, NULL);
set_item_userptr(my_items[i], sort_type);
}
my_menu = new_menu((ITEM **)my_items);
menu_opts_off(my_menu, O_SHOWDESC);
sort_win = newwin(elements + WINDOW_HEADER_LEN, len + WINDOW_BORDER_LEN, (g_max_row - elements) / 2,
(g_max_col - len) / 2);
assert(sort_win != NULL);
keypad(sort_win, TRUE);
sort_panel = new_panel(sort_win);
assert(sort_panel != NULL);
top_panel(sort_panel);
update_panels();
doupdate();
set_menu_win(my_menu, sort_win);
set_menu_sub(my_menu, derwin(sort_win, elements, len + 1, WINDOW_START_Y, WINDOW_START_X));
box(sort_win, 0, 0);
print_in_middle(sort_win, 1, 0, len + WINDOW_BORDER_LEN, "Sorting", COLOR_PAIR(3));
mvwaddch(sort_win, WINDOW_HEADER_END_LINE, 0, ACS_LTEE);
mvwhline(sort_win, WINDOW_HEADER_END_LINE, 1, ACS_HLINE, len + 1);
mvwaddch(sort_win, WINDOW_HEADER_END_LINE, len + WINDOW_BORDER_LEN - 1, ACS_RTEE);
post_menu(my_menu);
refresh();
wrefresh(sort_win);
while (!stop_loop) {
c = wgetch(sort_win);
switch (c) {
case KEY_DOWN:
menu_driver(my_menu, REQ_DOWN_ITEM);
break;
case KEY_UP:
menu_driver(my_menu, REQ_UP_ITEM);
break;
case 27: /* ESC */
stop_loop = true;
break;
case 10: /* Enter */
stop_loop = true;
cur = current_item(my_menu);
p = item_userptr(cur);
p(tab, item_index(cur));
break;
}
wrefresh(sort_win);
}
unpost_menu(my_menu);
free_menu(my_menu);
for (i = 0; i < elements; ++i) {
free_item(my_items[i]);
}
free(my_items);
del_panel(sort_panel);
delwin(sort_win);
wclear(g_menu_win);
draw_menu_win();
}
static void
change_refresh_rate(void)
{
const int WINDOW_HEADER_END_LINE = 2;
PANEL *refresh_panel;
WINDOW *refresh_win;
int c;
bool stop_loop = false;
uint32_t rr_tmp, refresh_rate = 0;
char refresh_rate_str[MAX_STRING_LEN];
refresh_win = newwin(RR_WIN_HEIGHT, RR_WIN_WIDTH, (g_max_row - RR_WIN_HEIGHT - 1) / 2,
(g_max_col - RR_WIN_WIDTH) / 2);
assert(refresh_win != NULL);
keypad(refresh_win, TRUE);
refresh_panel = new_panel(refresh_win);
assert(refresh_panel != NULL);
top_panel(refresh_panel);
update_panels();
doupdate();
box(refresh_win, 0, 0);
print_in_middle(refresh_win, 1, 0, RR_WIN_WIDTH + 1, "Enter refresh rate value [s]", COLOR_PAIR(3));
mvwaddch(refresh_win, WINDOW_HEADER_END_LINE, 0, ACS_LTEE);
mvwhline(refresh_win, WINDOW_HEADER_END_LINE, 1, ACS_HLINE, RR_WIN_WIDTH - 2);
mvwaddch(refresh_win, WINDOW_HEADER_END_LINE, RR_WIN_WIDTH, ACS_RTEE);
mvwprintw(refresh_win, WINDOW_HEADER_END_LINE + 1, (RR_WIN_WIDTH - 1) / 2, "%d", refresh_rate);
refresh();
wrefresh(refresh_win);
while (!stop_loop) {
c = wgetch(refresh_win);
switch (c) {
case '0':
case '1':
case '2':
case '3':
case '4':
case '5':
case '6':
case '7':
case '8':
case '9':
rr_tmp = refresh_rate * 10 + c - '0';
if (rr_tmp <= RR_MAX_VALUE) {
refresh_rate = rr_tmp;
snprintf(refresh_rate_str, MAX_STRING_LEN - 1, "%d", refresh_rate);
mvwprintw(refresh_win, WINDOW_HEADER_END_LINE + 1,
(RR_WIN_WIDTH - 1 - strlen(refresh_rate_str)) / 2, "%d", refresh_rate);
refresh();
wrefresh(refresh_win);
}
break;
case KEY_BACKSPACE:
case 127:
case '\b':
refresh_rate = refresh_rate / 10;
snprintf(refresh_rate_str, MAX_STRING_LEN - 1, "%d", refresh_rate);
mvwprintw(refresh_win, WINDOW_HEADER_END_LINE + 1,
(RR_WIN_WIDTH - 1 - strlen(refresh_rate_str) - 2) / 2, " ");
mvwprintw(refresh_win, WINDOW_HEADER_END_LINE + 1,
(RR_WIN_WIDTH - 1 - strlen(refresh_rate_str)) / 2, "%d", refresh_rate);
refresh();
wrefresh(refresh_win);
break;
case 27: /* ESC */
case 'q':
stop_loop = true;
break;
case 10: /* Enter */
g_sleep_time = refresh_rate;
stop_loop = true;
break;
}
wrefresh(refresh_win);
}
del_panel(refresh_panel);
delwin(refresh_win);
}
static void
free_resources(void)
{
struct run_counter_history *history, *tmp;
TAILQ_FOREACH_SAFE(history, &g_run_counter_history, link, tmp) {
TAILQ_REMOVE(&g_run_counter_history, history, link);
free(history->poller_name);
free(history);
}
}
static void
display_thread(struct rpc_thread_info *thread_info)
{
PANEL *thread_panel;
WINDOW *thread_win;
struct rpc_poller_thread_info *thread;
struct rpc_pollers *pollers;
struct rpc_poller_info *poller;
uint64_t pollers_count, current_row, i, j, time;
int c;
bool stop_loop = false;
char idle_time[MAX_TIME_STR_LEN], busy_time[MAX_TIME_STR_LEN], run_count[MAX_POLLER_COUNT_STR_LEN];
pollers_count = thread_info->active_pollers_count +
thread_info->timed_pollers_count +
thread_info->paused_pollers_count;
thread_win = newwin(pollers_count + THREAD_WIN_HEIGHT, THREAD_WIN_WIDTH,
(g_max_row - pollers_count) / 2, (g_max_col - THREAD_WIN_HOR_POS) / 2);
keypad(thread_win, TRUE);
thread_panel = new_panel(thread_win);
top_panel(thread_panel);
update_panels();
doupdate();
box(thread_win, 0, 0);
print_in_middle(thread_win, 1, 0, THREAD_WIN_WIDTH, thread_info->name,
COLOR_PAIR(3));
mvwhline(thread_win, 2, 1, ACS_HLINE, THREAD_WIN_WIDTH - 2);
mvwaddch(thread_win, 2, THREAD_WIN_WIDTH, ACS_RTEE);
print_left(thread_win, 3, THREAD_WIN_FIRST_COL, THREAD_WIN_WIDTH,
"Core: Idle [us]: Busy [us]:", COLOR_PAIR(5));
mvwprintw(thread_win, 3, THREAD_WIN_FIRST_COL + 6, "%" PRIu64,
thread_info->core_num);
get_time_str(g_thread_history[thread_info->id].idle, idle_time);
mvwprintw(thread_win, 3, THREAD_WIN_FIRST_COL + 32, idle_time);
get_time_str(g_thread_history[thread_info->id].busy, busy_time);
mvwprintw(thread_win, 3, THREAD_WIN_FIRST_COL + 54, busy_time);
print_left(thread_win, 4, THREAD_WIN_FIRST_COL, THREAD_WIN_WIDTH,
"Active pollers: Timed pollers: Paused pollers:", COLOR_PAIR(5));
mvwprintw(thread_win, 4, THREAD_WIN_FIRST_COL + 17, "%" PRIu64,
thread_info->active_pollers_count);
mvwprintw(thread_win, 4, THREAD_WIN_FIRST_COL + 36, "%" PRIu64,
thread_info->timed_pollers_count);
mvwprintw(thread_win, 4, THREAD_WIN_FIRST_COL + 59, "%" PRIu64,
thread_info->paused_pollers_count);
mvwhline(thread_win, 5, 1, ACS_HLINE, THREAD_WIN_WIDTH - 2);
print_in_middle(thread_win, 6, 0, THREAD_WIN_WIDTH,
"Pollers Type Total run count Period", COLOR_PAIR(5));
mvwhline(thread_win, 7, 1, ACS_HLINE, THREAD_WIN_WIDTH - 2);
current_row = 8;
for (i = 0; i < g_pollers_stats.pollers_threads.threads_count; i++) {
thread = &g_pollers_stats.pollers_threads.threads[i];
if (thread->id == thread_info->id) {
pollers = &thread->active_pollers;
for (j = 0; j < pollers->pollers_count; j++) {
poller = &pollers->pollers[j];
mvwprintw(thread_win, current_row, THREAD_WIN_FIRST_COL, "%s", poller->name);
mvwprintw(thread_win, current_row, THREAD_WIN_FIRST_COL + 33, "Active");
snprintf(run_count, MAX_POLLER_COUNT_STR_LEN, "%" PRIu64, poller->run_count);
mvwprintw(thread_win, current_row, THREAD_WIN_FIRST_COL + 41, run_count);
current_row++;
}
pollers = &thread->timed_pollers;
for (j = 0; j < pollers->pollers_count; j++) {
poller = &pollers->pollers[j];
mvwprintw(thread_win, current_row, THREAD_WIN_FIRST_COL, "%s", poller->name);
mvwprintw(thread_win, current_row, THREAD_WIN_FIRST_COL + 33, "Timed");
mvwprintw(thread_win, current_row, THREAD_WIN_FIRST_COL + 41, "%" PRIu64, poller->run_count);
time = poller->period_ticks * SPDK_SEC_TO_USEC / g_cores_stats.tick_rate;
mvwprintw(thread_win, current_row, THREAD_WIN_FIRST_COL + 59, "%" PRIu64, time);
current_row++;
}
pollers = &thread->paused_pollers;
for (j = 0; j < pollers->pollers_count; j++) {
poller = &pollers->pollers[j];
mvwprintw(thread_win, current_row, THREAD_WIN_FIRST_COL, "%s", poller->name);
mvwprintw(thread_win, current_row, THREAD_WIN_FIRST_COL + 33, "Paused");
mvwprintw(thread_win, current_row, THREAD_WIN_FIRST_COL + 41, "%" PRIu64, poller->run_count);
current_row++;
}
}
}
refresh();
wrefresh(thread_win);
while (!stop_loop) {
c = wgetch(thread_win);
switch (c) {
case 10: /* ENTER */
case 27: /* ESC */
stop_loop = true;
break;
default:
break;
}
}
del_panel(thread_panel);
delwin(thread_win);
}
static void
show_thread(uint8_t current_page)
{
struct rpc_thread_info *thread_info[g_threads_stats.threads.threads_count];
uint64_t thread_number = current_page * g_max_data_rows + g_selected_row;
uint64_t i;
get_data();
for (i = 0; i < g_threads_stats.threads.threads_count; i++) {
thread_info[i] = &g_threads_stats.threads.thread_info[i];
}
qsort(thread_info, g_threads_stats.threads.threads_count, sizeof(thread_info[0]), sort_threads);
display_thread(thread_info[thread_number]);
free_data();
}
static void
show_stats(void)
{
const int CURRENT_PAGE_STR_LEN = 50;
const char *refresh_error = "ERROR occurred while getting data";
long int time_last, time_dif;
struct timespec time_now;
int c, rc;
int max_row, max_col;
uint8_t active_tab = THREADS_TAB;
uint8_t current_page = 0;
uint8_t max_pages = 1;
char current_page_str[CURRENT_PAGE_STR_LEN];
bool force_refresh = true;
clock_gettime(CLOCK_REALTIME, &time_now);
time_last = time_now.tv_sec;
switch_tab(THREADS_TAB);
while (1) {
/* Check if interface has to be resized (terminal size changed) */
getmaxyx(stdscr, max_row, max_col);
if (max_row != g_max_row || max_col != g_max_col) {
g_max_row = max_row;
g_max_col = max_col;
g_data_win_size = g_max_row - MENU_WIN_HEIGHT - TAB_WIN_HEIGHT - TABS_DATA_START_ROW;
g_max_data_rows = g_max_row - WINDOW_HEADER;
resize_interface(active_tab);
}
c = getch();
if (c == 'q') {
free_resources();
break;
}
force_refresh = true;
switch (c) {
case '1':
case '2':
case '3':
active_tab = c - '1';
current_page = 0;
g_selected_row = 0;
switch_tab(active_tab);
break;
case '\t':
if (active_tab < NUMBER_OF_TABS - 1) {
active_tab++;
} else {
active_tab = THREADS_TAB;
}
current_page = 0;
switch_tab(active_tab);
break;
case 's':
change_sorting(active_tab);
break;
case 'c':
filter_columns(active_tab);
break;
case 'r':
change_refresh_rate();
break;
case KEY_NPAGE: /* PgDown */
if (current_page + 1 < max_pages) {
current_page++;
}
wclear(g_tabs[active_tab]);
g_selected_row = 0;
draw_tabs(active_tab, g_current_sort_col[active_tab]);
break;
case KEY_PPAGE: /* PgUp */
if (current_page > 0) {
current_page--;
}
wclear(g_tabs[active_tab]);
g_selected_row = 0;
draw_tabs(active_tab, g_current_sort_col[active_tab]);
break;
case KEY_UP: /* Arrow up */
if (g_selected_row > 0) {
g_selected_row--;
}
break;
case KEY_DOWN: /* Arrow down */
if (g_selected_row < g_max_selected_row) {
g_selected_row++;
}
break;
case 10: /* Enter */
if (active_tab == THREADS_TAB) {
show_thread(current_page);
}
break;
default:
force_refresh = false;
break;
}
clock_gettime(CLOCK_REALTIME, &time_now);
time_dif = time_now.tv_sec - time_last;
if (time_dif < 0) {
time_dif = g_sleep_time;
}
if (time_dif >= g_sleep_time || force_refresh) {
time_last = time_now.tv_sec;
rc = get_data();
if (rc) {
mvprintw(g_max_row - 1, g_max_col - strlen(refresh_error) - 2, refresh_error);
}
max_pages = refresh_tab(active_tab, current_page);
snprintf(current_page_str, CURRENT_PAGE_STR_LEN - 1, "Page: %d/%d", current_page + 1, max_pages);
mvprintw(g_max_row - 1, 1, current_page_str);
free_data();
refresh();
}
}
}
static void
draw_interface(void)
{
int i;
getmaxyx(stdscr, g_max_row, g_max_col);
g_data_win_size = g_max_row - MENU_WIN_HEIGHT - TAB_WIN_HEIGHT - TABS_DATA_START_ROW;
g_max_data_rows = g_max_row - WINDOW_HEADER;
g_menu_win = newwin(MENU_WIN_HEIGHT, g_max_col, g_max_row - MENU_WIN_HEIGHT - 1,
MENU_WIN_LOCATION_COL);
assert(g_menu_win != NULL);
draw_menu_win();
for (i = 0; i < NUMBER_OF_TABS; i++) {
g_tab_win[i] = newwin(TAB_WIN_HEIGHT, g_max_col / NUMBER_OF_TABS - TABS_SPACING,
TAB_WIN_LOCATION_ROW, g_max_col / NUMBER_OF_TABS * i + 1);
assert(g_tab_win[i] != NULL);
draw_tab_win(i);
g_tabs[i] = newwin(g_max_row - MENU_WIN_HEIGHT - TAB_WIN_HEIGHT - 2, g_max_col, TABS_LOCATION_ROW,
TABS_LOCATION_COL);
draw_tabs(i, g_current_sort_col[i]);
g_panels[i] = new_panel(g_tabs[i]);
assert(g_panels[i] != NULL);
}
update_panels();
doupdate();
}
static void finish(int sig)
{
/* End ncurses mode */
endwin();
spdk_jsonrpc_client_close(g_rpc_client);
exit(0);
}
static void
setup_ncurses(void)
{
clear();
noecho();
timeout(1);
curs_set(0);
keypad(stdscr, TRUE);
start_color();
init_pair(1, COLOR_BLACK, COLOR_GREEN);
init_pair(2, COLOR_BLACK, COLOR_WHITE);
init_pair(3, COLOR_YELLOW, COLOR_BLACK);
init_pair(4, COLOR_BLACK, COLOR_YELLOW);
init_pair(5, COLOR_GREEN, COLOR_BLACK);
if (has_colors() == FALSE) {
endwin();
printf("Your terminal does not support color\n");
exit(1);
}
/* Handle signals to exit gracfully cleaning up ncurses */
(void) signal(SIGINT, finish);
(void) signal(SIGPIPE, finish);
(void) signal(SIGABRT, finish);
}
static void
usage(const char *program_name)
{
printf("%s [options]", program_name);
printf("\n");
printf("options:\n");
printf(" -r <path> RPC listen address (default: /var/tmp/spdk.sock\n");
printf(" -h show this usage\n");
}
int main(int argc, char **argv)
{
int op;
char *socket = SPDK_DEFAULT_RPC_ADDR;
while ((op = getopt(argc, argv, "r:h")) != -1) {
switch (op) {
case 'r':
socket = optarg;
break;
case 'H':
default:
usage(argv[0]);
return 1;
}
}
g_rpc_client = spdk_jsonrpc_client_connect(socket, AF_UNIX);
if (!g_rpc_client) {
fprintf(stderr, "spdk_jsonrpc_client_connect() failed: %d\n", errno);
return 1;
}
initscr();
init_str_len();
setup_ncurses();
draw_interface();
show_stats();
finish(0);
return (0);
}