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core-parse-opts.c
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core-parse-opts.c
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/*
* Copyright (C) 2013-2021 Canonical, Ltd.
* Copyright (C) 2022-2024 Colin Ian King.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
*/
#include "stress-ng.h"
#include "core-attribute.h"
#include "core-parse-opts.h"
#include "core-cpu-cache.h"
#include "core-net.h"
#include <ctype.h>
typedef const char * (*stress_method_func)(const size_t idx);
typedef void (*stress_callback_func)(const char *opt_name, const char *opt_arg, stress_type_id_t *type_id, void *value);
/*
* stress_check_max_stressors()
* sanity check number of stressors
*/
void stress_check_max_stressors(
const char *const msg,
const int val)
{
if ((val < 0) || (val > STRESS_PROCS_MAX)) {
(void)fprintf(stderr, "Number of %s stressors must be between "
"0 and %d\n", msg, STRESS_PROCS_MAX);
longjmp(g_error_env, 1);
}
}
/*
* stress_check_signed_range()
* Sanity check val against a lo - hi range
*/
void stress_check_signed_range(
const char *const opt,
const int64_t val,
const int64_t lo,
const int64_t hi)
{
if ((val < lo) || (val > hi)) {
(void)fprintf(stderr, "Value %" PRId64 " is out of range for %s,"
" allowed: %" PRId64 " .. %" PRId64 "\n",
val, opt, lo, hi);
longjmp(g_error_env, 1);
}
}
/*
* stress_check_range()
* Sanity check val against a lo - hi range
*/
void stress_check_range(
const char *const opt,
const uint64_t val,
const uint64_t lo,
const uint64_t hi)
{
if ((val < lo) || (val > hi)) {
(void)fprintf(stderr, "Value %" PRIu64 " is out of range for %s,"
" allowed: %" PRIu64 " .. %" PRIu64 "\n",
val, opt, lo, hi);
longjmp(g_error_env, 1);
}
}
/*
* stress_check_range()
* Sanity check val against a lo - hi range
*/
void stress_check_range_bytes(
const char *const opt,
const uint64_t val,
const uint64_t lo,
const uint64_t hi)
{
if ((val < lo) || (val > hi)) {
char strval[32], strlo[32], strhi[32];
(void)fprintf(stderr, "Value %sB is out of range for %s,"
" allowed: %sB .. %sB\n",
stress_uint64_to_str(strval, sizeof(strval), val),
opt,
stress_uint64_to_str(strlo, sizeof(strlo), lo),
stress_uint64_to_str(strhi, sizeof(strhi), hi));
longjmp(g_error_env, 1);
}
}
/*
* stress_ensure_numeric()
* ensure just numeric values
*/
static void stress_ensure_numeric(const char *const str)
{
const char *ptr = str;
if (*ptr == '-')
ptr++;
while (*ptr) {
if (!isdigit((int)*ptr))
break;
ptr++;
}
if (*ptr == '\0')
return;
(void)fprintf(stderr, "Value %s contains non-numeric: '%s'\n",
str, ptr);
longjmp(g_error_env, 1);
}
/*
* stress_ensure_positive()
* ensure string contains just a +ve value
*/
static void stress_ensure_positive(const char *const str)
{
const char *ptr;
bool negative = false;
for (ptr = str; *ptr; ptr++) {
if (*ptr == '-') {
negative = true;
continue;
}
if (isdigit((int)*ptr)) {
if (!negative)
return;
(void)fprintf(stderr, "Invalid negative number %s\n", str);
longjmp(g_error_env, 1);
}
}
}
/*
* stress_get_uint8()
* string to uint8_t
*/
uint8_t stress_get_uint8(const char *const str)
{
uint64_t val;
stress_ensure_positive(str);
stress_ensure_numeric(str);
if (sscanf(str, "%" SCNu64, &val) != 1) {
(void)fprintf(stderr, "Invalid number %s\n", str);
longjmp(g_error_env, 1);
}
if (val > UINT8_MAX) {
(void)fprintf(stderr, "Invalid number %s too large (> %u)\n",
str, UINT8_MAX);
longjmp(g_error_env, 1);
}
return (uint8_t)val;
}
/*
* stress_get_int8()
* string to int8_t
*/
int8_t stress_get_int8(const char *const str)
{
int64_t val;
stress_ensure_numeric(str);
if (sscanf(str, "%" SCNd64, &val) != 1) {
(void)fprintf(stderr, "Invalid number %s\n", str);
longjmp(g_error_env, 1);
}
if (val > INT8_MAX) {
(void)fprintf(stderr, "Invalid number %s too large (> %ld)\n", str, (long)INT8_MAX);
longjmp(g_error_env, 1);
}
if (val < INT8_MIN) {
(void)fprintf(stderr, "Invalid number %s too small (< %ld)\n", str, (long)INT8_MIN);
longjmp(g_error_env, 1);
}
return (int8_t)val;
}
/*
* stress_get_uint16()
* string to uint16_t
*/
uint16_t stress_get_uint16(const char *const str)
{
uint64_t val;
stress_ensure_positive(str);
stress_ensure_numeric(str);
if (sscanf(str, "%" SCNu64, &val) != 1) {
(void)fprintf(stderr, "Invalid number %s\n", str);
longjmp(g_error_env, 1);
}
if (val > UINT16_MAX) {
(void)fprintf(stderr, "Invalid number %s too large (> %u)\n", str, UINT16_MAX);
longjmp(g_error_env, 1);
}
return (uint16_t)val;
}
/*
* stress_get_int16()
* string to int16_t
*/
int16_t stress_get_int16(const char *const str)
{
int64_t val;
stress_ensure_numeric(str);
if (sscanf(str, "%" SCNd64, &val) != 1) {
(void)fprintf(stderr, "Invalid number %s\n", str);
longjmp(g_error_env, 1);
}
if (val > INT16_MAX) {
(void)fprintf(stderr, "Invalid number %s too large (> %ld)\n", str, (long)INT16_MAX);
longjmp(g_error_env, 1);
}
if (val < INT16_MIN) {
(void)fprintf(stderr, "Invalid number %s too small (< %ld)\n", str, (long)INT16_MIN);
longjmp(g_error_env, 1);
}
return (int16_t)val;
}
/*
* stress_get_uint32()
* string to uint32_t
*/
uint32_t stress_get_uint32(const char *const str)
{
uint64_t val;
stress_ensure_positive(str);
stress_ensure_numeric(str);
if (sscanf(str, "%" SCNu64, &val) != 1) {
(void)fprintf(stderr, "Invalid number %s\n", str);
longjmp(g_error_env, 1);
}
if (val > UINT32_MAX) {
(void)fprintf(stderr, "Invalid number %s too large (> %u)\n", str, UINT32_MAX);
longjmp(g_error_env, 1);
}
return (uint32_t)val;
}
/*
* stress_get_int32()
* string to int32_t
*/
int32_t stress_get_int32(const char *const str)
{
int64_t val;
stress_ensure_numeric(str);
if (sscanf(str, "%" SCNd64, &val) != 1) {
(void)fprintf(stderr, "Invalid number %s\n", str);
longjmp(g_error_env, 1);
}
if (val > INT32_MAX) {
(void)fprintf(stderr, "Invalid number %s too large (> %ld)\n", str, (long)INT32_MAX);
longjmp(g_error_env, 1);
}
if (val < INT32_MIN) {
(void)fprintf(stderr, "Invalid number %s too small (< %ld)\n", str, (long)INT32_MIN);
longjmp(g_error_env, 1);
}
return (int32_t)val;
}
/*
* stress_get_uint64()
* string to uint64_t
*/
uint64_t stress_get_uint64(const char *const str)
{
uint64_t val;
stress_ensure_positive(str);
stress_ensure_numeric(str);
if (sscanf(str, "%" SCNu64, &val) != 1) {
(void)fprintf(stderr, "Invalid number %s\n", str);
longjmp(g_error_env, 1);
}
return val;
}
/*
* stress_get_int64()
* string to int64_t
*/
int64_t stress_get_int64(const char *const str)
{
int64_t val;
stress_ensure_numeric(str);
if (sscanf(str, "%" SCNd64, &val) != 1) {
(void)fprintf(stderr, "Invalid number %s\n", str);
longjmp(g_error_env, 1);
}
return val;
}
/*
* stress_get_uint()
* string to unsigned int
*/
unsigned int stress_get_uint(const char *const str)
{
uint64_t val;
stress_ensure_positive(str);
stress_ensure_numeric(str);
if (sscanf(str, "%" SCNu64, &val) != 1) {
(void)fprintf(stderr, "Invalid number %s\n", str);
longjmp(g_error_env, 1);
}
if (val > UINT_MAX) {
(void)fprintf(stderr, "Invalid number %s too large (> %u)\n", str, UINT_MAX);
longjmp(g_error_env, 1);
}
return (unsigned int)val;
}
/*
* stress_get_int()
* string to int
*/
int stress_get_int(const char *const str)
{
int64_t val;
stress_ensure_numeric(str);
if (sscanf(str, "%" SCNd64, &val) != 1) {
(void)fprintf(stderr, "Invalid number %s\n", str);
longjmp(g_error_env, 1);
}
if (val > INT_MAX) {
(void)fprintf(stderr, "Invalid number %s too large (> %ld)\n", str, (long)INT_MAX);
longjmp(g_error_env, 1);
}
if (val < INT_MIN) {
(void)fprintf(stderr, "Invalid number %s too small (< %ld)\n", str, (long)INT_MIN);
longjmp(g_error_env, 1);
}
return (int)val;
}
/*
* stress_get_uint64_scale()
* get a value and scale it by the given scale factor
*/
uint64_t stress_get_uint64_scale(
const char *const str,
const stress_scale_t scales[],
const char *const msg)
{
uint64_t val;
size_t len = strlen(str);
int ch;
int i;
stress_ensure_positive(str);
if (sscanf(str, "%" SCNu64, &val) != 1) {
(void)fprintf(stderr, "Invalid number %s\n", str);
goto err;
}
if (!len) {
(void)fprintf(stderr, "Value %s is an invalid size\n", str);
goto err;
}
len--;
ch = str[len];
if (isdigit(ch))
return val;
ch = tolower(ch);
for (i = 0; scales[i].ch; i++) {
if (ch == scales[i].ch)
return val * scales[i].scale;
}
(void)fprintf(stderr, "Illegal %s specifier %c\n", msg, str[len]);
err:
longjmp(g_error_env, 1);
/* should never get here */
return 0;
}
/*
* stress_get_uint64_byte()
* size in bytes, K bytes, M bytes or G bytes
*/
uint64_t stress_get_uint64_byte(const char *const str)
{
static const stress_scale_t scales[] = {
{ 'b', 1ULL }, /* bytes */
{ 'k', 1ULL << 10 }, /* kilobytes */
{ 'm', 1ULL << 20 }, /* megabytes */
{ 'g', 1ULL << 30 }, /* gigabytes */
{ 't', 1ULL << 40 }, /* terabytes */
{ 'p', 1ULL << 50 }, /* petabytes */
{ 'e', 1ULL << 60 }, /* exabytes */
{ 0, 0 },
};
size_t llc_size = 0, cache_line_size = 0;
if (strncasecmp(str, "L", 1) != 0)
return stress_get_uint64_scale(str, scales, "length");
/* Try cache sizes */
if (strcasecmp(str, "LLC") == 0) {
stress_cpu_cache_get_llc_size(&llc_size, &cache_line_size);
} else {
const int cache_level = atoi(str + 1);
if ((cache_level < 0) || (cache_level > 5)) {
(void)fprintf(stderr, "Illegal cache size '%s'\n", str);
longjmp(g_error_env, 1);
}
stress_cpu_cache_get_level_size((uint16_t)cache_level, &llc_size, &cache_line_size);
}
if (llc_size == 0) {
(void)fprintf(stderr, "Cannot determine %s cache size\n", str);
longjmp(g_error_env, 1);
}
return (uint64_t)llc_size;
}
/*
* stress_get_uint64_percent()
* get a value by whole number or by percentage
*/
uint64_t stress_get_uint64_percent(
const char *const str,
const uint32_t instances,
const uint64_t max,
const char *const errmsg)
{
const size_t len = strlen(str);
/* Convert to % over N instances */
if ((len > 1) && (str[len - 1] == '%')) {
double val, percent;
/* Avoid division by zero */
if (max == 0) {
(void)fprintf(stderr, "%s\n", errmsg);
longjmp(g_error_env, 1);
}
/* Should NEVER happen */
if (instances < 1) {
(void)fprintf(stderr, "Invalid number of instances\n");
longjmp(g_error_env, 1);
}
if (sscanf(str, "%lf", &val) != 1) {
(void)fprintf(stderr, "Invalid percentage %s\n", str);
longjmp(g_error_env, 1);
}
if (val < 0.0) {
(void)fprintf(stderr, "Invalid percentage %s\n", str);
longjmp(g_error_env, 1);
}
percent = ((double)max * (double)val) / (100.0 * (double)instances);
return (uint64_t)percent;
}
return stress_get_uint64_byte(str);
}
/*
* stress_get_uint64_byte_memory()
* get memory size from string. If it contains %
* at the end, then convert it into the available
* physical memory scaled by that percentage divided
* by the number of stressor instances
*/
uint64_t stress_get_uint64_byte_memory(
const char *const str,
const uint32_t instances)
{
const uint64_t phys_mem = stress_get_phys_mem_size();
return stress_get_uint64_percent(str, instances, phys_mem,
"Cannot determine physical memory size");
}
/*
* stress_get_uint64_byte_filesystem()
* get file size from string. If it contains %
* at the end, then convert it into the available
* file system space scaled by that percentage divided
* by the number of stressor instances
*/
uint64_t stress_get_uint64_byte_filesystem(
const char *const str,
const uint32_t instances)
{
const uint64_t bytes = stress_get_filesystem_size();
return stress_get_uint64_percent(str, instances, bytes,
"Cannot determine available space on file system");
}
/*
* stress_get_uint64_time()
* time in seconds, minutes, hours, days or years
*/
uint64_t stress_get_uint64_time(const char *const str)
{
static const stress_scale_t scales[] = {
{ 's', 1ULL }, /* seconds */
{ 'm', 60ULL }, /* minutes */
{ 'h', 3600ULL }, /* hours */
{ 'd', 24ULL * 3600 }, /* days */
{ 'w', 24ULL * 3600 * 7 }, /* weeks */
{ 'y', 31536000 }, /* years */
};
return stress_get_uint64_scale(str, scales, "time");
}
int stress_parse_opt(const char *stressor_name, const char *opt_arg, const stress_opt_t *opt)
{
const char *opt_name = opt->opt_name;
const uint64_t min = opt->min;
const uint64_t max = opt->max;
stress_setting_t setting;
int domain_mask;
stress_method_func method_func;
stress_callback_func callback_func;
stress_type_id_t type_id;
const char *str;
size_t i;
(void)memset(&setting, 0, sizeof(setting));
switch (opt->type_id) {
case TYPE_ID_UINT8:
setting.u.uint8 = stress_get_uint8(opt_arg);
stress_check_range(opt_name, (uint64_t)setting.u.uint8, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_UINT8, &setting.u.uint8);
case TYPE_ID_INT8:
setting.u.int8 = stress_get_int8(opt_arg);
stress_check_signed_range(opt_name, (int64_t)setting.u.int8, (int64_t)min, (int64_t)max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_INT8, &setting.u.int8);
case TYPE_ID_UINT16:
setting.u.uint16 = stress_get_uint16(opt_arg);
stress_check_range(opt_name, (uint64_t)setting.u.uint16, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_UINT16, &setting.u.uint16);
case TYPE_ID_INT16:
setting.u.int16 = stress_get_int16(opt_arg);
stress_check_signed_range(opt_name, (int64_t)setting.u.int16, (int64_t)min, (int64_t)max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_INT16, &setting.u.int16);
case TYPE_ID_UINT32:
setting.u.uint32 = stress_get_uint32(opt_arg);
stress_check_range(opt_name, (uint64_t)setting.u.uint32, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_UINT32, &setting.u.uint32);
case TYPE_ID_INT32:
setting.u.int32 = stress_get_int32(opt_arg);
stress_check_signed_range(opt_name, (int64_t)setting.u.int32, (int64_t)min, (int64_t)max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_INT32, &setting.u.int32);
case TYPE_ID_UINT64:
setting.u.uint64 = stress_get_uint64(opt_arg);
stress_check_range(opt_name, setting.u.uint64, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_UINT64, &setting.u.uint64);
case TYPE_ID_UINT64_BYTES_FS:
/* uint64 in bytes units */
setting.u.uint64 = stress_get_uint64_byte_filesystem(opt_arg, 1);
stress_check_range_bytes(opt_name, (uint64_t)setting.u.uint64, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_UINT64_BYTES_FS, &setting.u.uint64);
case TYPE_ID_UINT64_BYTES_VM:
/* uint64 in bytes units */
setting.u.uint64 = stress_get_uint64_byte_memory(opt_arg, 1);
stress_check_range_bytes(opt_name, (uint64_t)setting.u.uint64, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_UINT64_BYTES_VM, &setting.u.uint64);
case TYPE_ID_INT64:
setting.u.int64 = stress_get_int64(opt_arg);
stress_check_signed_range(opt_name, (int64_t)setting.u.int64, (int64_t)min, (int64_t)max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_INT64, &setting.u.int64);
case TYPE_ID_SIZE_T:
setting.u.size = (size_t)stress_get_uint64(opt_arg);
stress_check_range(opt_name, (uint64_t)setting.u.size, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_SIZE_T, &setting.u.size);
case TYPE_ID_SIZE_T_BYTES_FS:
/* size_t in bytes units */
setting.u.size = (size_t)stress_get_uint64_byte_filesystem(opt_arg, 1);
stress_check_range(opt_name, (uint64_t)setting.u.size, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_SIZE_T_BYTES_FS, &setting.u.size);
case TYPE_ID_SIZE_T_BYTES_VM:
/* size_t in bytes units */
setting.u.size = (size_t)stress_get_uint64_byte_memory(opt_arg, 1);
stress_check_range(opt_name, (uint64_t)setting.u.size, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_SIZE_T_BYTES_VM, &setting.u.size);
case TYPE_ID_SIZE_T_METHOD:
method_func = (stress_method_func)opt->data;
if (!method_func) {
fprintf(stderr, "%s: no method function provided for option\n", opt_name);
longjmp(g_error_env, 1);
}
for (i = 0; (str = method_func(i)) != NULL ; i++) {
if (strcmp(str, opt_arg) == 0)
return stress_set_setting(stressor_name, opt_name, TYPE_ID_SIZE_T_METHOD, &i);
}
if (i == 0) {
(void)fprintf(stderr, "option %s choice '%s' not known, there are none available (stressor unimplemented)\n", opt_name, opt_arg);
} else {
(void)fprintf(stderr, "option %s choice '%s' not known, choices are:", opt_name, opt_arg);
for (i = 0; (str = method_func(i)) != NULL ; i++)
(void)fprintf(stderr, " %s", str);
(void)fprintf(stderr, "\n");
}
longjmp(g_error_env, 1);
case TYPE_ID_SSIZE_T:
setting.u.ssize = (ssize_t)stress_get_int64(opt_arg);
stress_check_signed_range(opt_name, (int64_t)setting.u.ssize, (int64_t)min, (int64_t)max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_SSIZE_T, &setting.u.ssize);
case TYPE_ID_UINT:
setting.u.uint = stress_get_uint(opt_arg);
stress_check_range(opt_name, (uint64_t)setting.u.uint, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_UINT, &setting.u.uint);
case TYPE_ID_INT:
setting.u.sint = stress_get_int(opt_arg);
stress_check_signed_range(opt_name, (int64_t)setting.u.sint, (int64_t)min, (int64_t)max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_INT, &setting.u.sint);
case TYPE_ID_INT_DOMAIN:
domain_mask = (opt->data == NULL) ? 0 : *(int *)opt->data;
if (stress_set_net_domain(domain_mask, opt_name, opt_arg, &setting.u.sint) < 0)
longjmp(g_error_env, 1);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_UINT, &setting.u.sint);
case TYPE_ID_INT_PORT:
stress_set_net_port(opt_name, opt_arg, (int)min, (int)max, &setting.u.sint);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_INT, &setting.u.sint);
case TYPE_ID_OFF_T:
/* off_t always in bytes units */
setting.u.off = (off_t)stress_get_uint64_byte_filesystem(opt_arg, 1);
stress_check_range_bytes(opt_name, (uint64_t)setting.u.off, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_OFF_T, &setting.u.off);
case TYPE_ID_STR:
return stress_set_setting(stressor_name, opt_name, TYPE_ID_STR, opt_arg);
case TYPE_ID_BOOL:
if (!opt_arg)
return stress_set_setting_true(stressor_name, opt_name, opt_arg);
setting.u.boolean = (bool)stress_get_uint8(opt_arg);
stress_check_range(opt_name, (uint64_t)setting.u.boolean, min, max);
return stress_set_setting(stressor_name, opt_name, TYPE_ID_BOOL, &setting.u.boolean);
case TYPE_ID_CALLBACK:
callback_func = (stress_callback_func)opt->data;
if (!callback_func) {
fprintf(stderr, "%s: no callback function provided for option\n", opt_name);
longjmp(g_error_env, 1);
}
type_id = TYPE_ID_UNDEFINED;
callback_func(opt_name, opt_arg, &type_id, &setting.u);
if (type_id != TYPE_ID_UNDEFINED)
return stress_set_setting(stressor_name, opt_name, type_id, &setting.u);
return EXIT_SUCCESS;
case TYPE_ID_UNDEFINED:
default:
pr_inf("%s: unknown type %u for value '%s'\n", opt_name, opt->type_id, opt_arg);
break;
}
return EXIT_SUCCESS;
}
/*
* stress_unimplemented_method()
* method handler for methods that are unimplemented
* (e.g. stressor not supported)
*/
const char * PURE stress_unimplemented_method(const size_t i)
{
(void)i;
return NULL;
}