/*
* Copyright (C) 2006, Intel Corporation
* Copyright (C) 2012, Neil Horman <nhorman@tuxdriver.com>
*
* This file is part of irqbalance
*
* This program file 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; version 2 of the License.
*
* 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 in a file named COPYING; if not, write to the
* Free Software Foundation, Inc.,
* 51 Franklin Street, Fifth Floor,
* Boston, MA 02110-1301 USA
*/
/*
* This file contains the code to construct and manipulate a hierarchy of processors,
* cache domains and processor cores.
*/
#include "config.h"
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <dirent.h>
#include <glib.h>
#include "irqbalance.h"
extern char *banned_cpumask_from_ui;
GList *cpus;
GList *cache_domains;
GList *packages;
int package_count;
int cache_domain_count;
int core_count;
/* Users want to be able to keep interrupts away from some cpus; store these in a cpumask_t */
cpumask_t banned_cpus;
cpumask_t cpu_possible_map;
/*
it's convenient to have the complement of banned_cpus available so that
the AND operator can be used to mask out unwanted cpus
*/
cpumask_t unbanned_cpus;
/*
* By default do not place IRQs on CPUs the kernel keeps isolated or
* nohz_full, as specified through the boot commandline. Users can
* override this with the IRQBALANCE_BANNED_CPUS environment variable.
*/
static void setup_banned_cpus(void)
{
FILE *file;
char *line = NULL;
size_t size = 0;
char buffer[4096];
cpumask_t nohz_full;
cpumask_t isolated_cpus;
cpus_clear(isolated_cpus);
cpus_clear(nohz_full);
/* A manually specified cpumask overrides auto-detection. */
if (banned_cpumask_from_ui != NULL) {
cpulist_parse(banned_cpumask_from_ui,
strlen(banned_cpumask_from_ui), banned_cpus);
goto out;
}
if (getenv("IRQBALANCE_BANNED_CPUS")) {
cpumask_parse_user(getenv("IRQBALANCE_BANNED_CPUS"), strlen(getenv("IRQBALANCE_BANNED_CPUS")), banned_cpus);
goto out;
}
file = fopen("/sys/devices/system/cpu/isolated", "r");
if (file) {
if (getline(&line, &size, file) > 0) {
if (strlen(line) && line[0] != '\n')
cpulist_parse(line, strlen(line), isolated_cpus);
free(line);
line = NULL;
size = 0;
}
fclose(file);
}
file = fopen("/sys/devices/system/cpu/nohz_full", "r");
if (file) {
if (getline(&line, &size, file) > 0) {
if (strlen(line) && line[0] != '\n')
cpulist_parse(line, strlen(line), nohz_full);
free(line);
line = NULL;
size = 0;
}
fclose(file);
}
cpus_or(banned_cpus, nohz_full, isolated_cpus);
out:
cpumask_scnprintf(buffer, 4096, isolated_cpus);
log(TO_CONSOLE, LOG_INFO, "Isolated CPUs: %s\n", buffer);
cpumask_scnprintf(buffer, 4096, nohz_full);
log(TO_CONSOLE, LOG_INFO, "Adaptive-ticks CPUs: %s\n", buffer);
cpumask_scnprintf(buffer, 4096, banned_cpus);
log(TO_CONSOLE, LOG_INFO, "Banned CPUs: %s\n", buffer);
}
static void add_numa_node_to_topo_obj(struct topo_obj *obj, int nodeid)
{
GList *entry;
struct topo_obj *node;
struct topo_obj *cand_node;
node = get_numa_node(nodeid);
if (!node || node->number == -1)
return;
entry = g_list_first(obj->numa_nodes);
while (entry) {
cand_node = entry->data;
if (cand_node == node)
break;
entry = g_list_next(entry);
}
if (!entry)
obj->numa_nodes = g_list_append(obj->numa_nodes, node);
}
static struct topo_obj* add_cache_domain_to_package(struct topo_obj *cache,
int packageid,
cpumask_t package_mask,
int nodeid)
{
GList *entry;
struct topo_obj *package;
struct topo_obj *lcache;
entry = g_list_first(packages);
while (entry) {
package = entry->data;
if (cpus_equal(package_mask, package->mask)) {
if (packageid != package->number)
log(TO_ALL, LOG_WARNING, "package_mask with different physical_package_id found!\n");
break;
}
entry = g_list_next(entry);
}
if (!entry) {
package = calloc(sizeof(struct topo_obj), 1);
if (!package)
return NULL;
package->mask = package_mask;
package->obj_type = OBJ_TYPE_PACKAGE;
package->obj_type_list = &packages;
package->number = packageid;
packages = g_list_append(packages, package);
package_count++;
}
entry = g_list_first(package->children);
while (entry) {
lcache = entry->data;
if (lcache == cache)
break;
entry = g_list_next(entry);
}
if (!entry) {
package->children = g_list_append(package->children, cache);
cache->parent = package;
}
if (nodeid > -1)
add_numa_node_to_topo_obj(package, nodeid);
return package;
}
static struct topo_obj* add_cpu_to_cache_domain(struct topo_obj *cpu,
cpumask_t cache_mask,
int nodeid)
{
GList *entry;
struct topo_obj *cache;
struct topo_obj *lcpu;
entry = g_list_first(cache_domains);
while (entry) {
cache = entry->data;
if (cpus_equal(cache_mask, cache->mask))
break;
entry = g_list_next(entry);
}
if (!entry) {
cache = calloc(sizeof(struct topo_obj), 1);
if (!cache)
return NULL;
cache->obj_type = OBJ_TYPE_CACHE;
cache->mask = cache_mask;
cache->number = cache_domain_count;
cache->obj_type_list = &cache_domains;
cache_domains = g_list_append(cache_domains, cache);
cache_domain_count++;
}
entry = g_list_first(cache->children);
while (entry) {
lcpu = entry->data;
if (lcpu == cpu)
break;
entry = g_list_next(entry);
}
if (!entry) {
cache->children = g_list_append(cache->children, cpu);
cpu->parent = (struct topo_obj *)cache;
}
if (nodeid > -1)
add_numa_node_to_topo_obj(cache, nodeid);
return cache;
}
static void do_one_cpu(char *path)
{
struct topo_obj *cpu;
FILE *file;
char new_path[PATH_MAX];
cpumask_t cache_mask, package_mask;
struct topo_obj *cache;
DIR *dir;
struct dirent *entry;
int nodeid;
int packageid = 0;
unsigned int max_cache_index, cache_index, cache_stat;
/* skip offline cpus */
snprintf(new_path, PATH_MAX, "%s/online", path);
file = fopen(new_path, "r");
if (file) {
char *line = NULL;
size_t size = 0;
if (getline(&line, &size, file)==0)
return;
fclose(file);
if (line && line[0]=='0') {
free(line);
return;
}
free(line);
}
cpu = calloc(sizeof(struct topo_obj), 1);
if (!cpu)
return;
cpu->obj_type = OBJ_TYPE_CPU;
cpu->number = strtoul(&path[27], NULL, 10);
cpu_set(cpu->number, cpu_possible_map);
cpu_set(cpu->number, cpu->mask);
/*
* Default the cache_domain mask to be equal to the cpu
*/
cpus_clear(cache_mask);
cpu_set(cpu->number, cache_mask);
/* if the cpu is on the banned list, just don't add it */
if (cpus_intersects(cpu->mask, banned_cpus)) {
free(cpu);
/* even though we don't use the cpu we do need to count it */
core_count++;
return;
}
/* try to read the package mask; if it doesn't exist assume solitary */
snprintf(new_path, PATH_MAX, "%s/topology/core_siblings", path);
file = fopen(new_path, "r");
cpu_set(cpu->number, package_mask);
if (file) {
char *line = NULL;
size_t size = 0;
if (getline(&line, &size, file))
cpumask_parse_user(line, strlen(line), package_mask);
fclose(file);
free(line);
}
/* try to read the package id */
snprintf(new_path, PATH_MAX, "%s/topology/physical_package_id", path);
file = fopen(new_path, "r");
if (file) {
char *line = NULL;
size_t size = 0;
if (getline(&line, &size, file))
packageid = strtoul(line, NULL, 10);
fclose(file);
free(line);
}
/* try to read the cache mask; if it doesn't exist assume solitary */
/* We want the deepest cache level available */
cpu_set(cpu->number, cache_mask);
max_cache_index = 0;
cache_index = 1;
do {
struct stat sb;
snprintf(new_path, PATH_MAX, "%s/cache/index%d/shared_cpu_map", path, cache_index);
cache_stat = stat(new_path, &sb);
if (!cache_stat) {
max_cache_index = cache_index;
if (max_cache_index == deepest_cache)
break;
cache_index ++;
}
} while(!cache_stat);
if (max_cache_index > 0) {
snprintf(new_path, PATH_MAX, "%s/cache/index%d/shared_cpu_map", path, max_cache_index);
file = fopen(new_path, "r");
if (file) {
char *line = NULL;
size_t size = 0;
if (getline(&line, &size, file))
cpumask_parse_user(line, strlen(line), cache_mask);
fclose(file);
free(line);
}
}
nodeid=-1;
if (numa_avail) {
struct topo_obj *node;
dir = opendir(path);
do {
entry = readdir(dir);
if (!entry)
break;
if (strncmp(entry->d_name, "node", 4) == 0) {
char *end;
int num;
num = strtol(entry->d_name + 4, &end, 10);
if (!*end && num >= 0) {
nodeid = num;
break;
}
}
} while (entry);
closedir(dir);
/*
* In case of multiple NUMA nodes within a CPU package,
* we override package_mask with node mask.
*/
node = get_numa_node(nodeid);
if (node && (cpus_weight(package_mask) > cpus_weight(node->mask)))
cpus_and(package_mask, package_mask, node->mask);
}
/*
blank out the banned cpus from the various masks so that interrupts
will never be told to go there
*/
cpus_and(cache_mask, cache_mask, unbanned_cpus);
cpus_and(package_mask, package_mask, unbanned_cpus);
cache = add_cpu_to_cache_domain(cpu, cache_mask, nodeid);
add_cache_domain_to_package(cache, packageid, package_mask,
nodeid);
cpu->obj_type_list = &cpus;
cpus = g_list_append(cpus, cpu);
core_count++;
}
static void dump_irq(struct irq_info *info, void *data)
{
int spaces = (long int)data;
int i;
char * indent = malloc (sizeof(char) * (spaces + 1));
for ( i = 0; i < spaces; i++ )
indent[i] = log_indent[0];
indent[i] = '\0';
log(TO_CONSOLE, LOG_INFO, "%sInterrupt %i node_num is %d (%s/%lu:%lu) \n", indent,
info->irq, irq_numa_node(info)->number, classes[info->class], info->load, (info->irq_count - info->last_irq_count));
free(indent);
}
static void dump_numa_node_num(struct topo_obj *p, void *data __attribute__((unused)))
{
log(TO_CONSOLE, LOG_INFO, "%d ", p->number);
}
static void dump_balance_obj(struct topo_obj *d, void *data __attribute__((unused)))
{
struct topo_obj *c = (struct topo_obj *)d;
log(TO_CONSOLE, LOG_INFO, "%s%s%s%sCPU number %i numa_node is ",
log_indent, log_indent, log_indent, log_indent, c->number);
for_each_object(cpu_numa_node(c), dump_numa_node_num, NULL);
log(TO_CONSOLE, LOG_INFO, "(load %lu)\n", (unsigned long)c->load);
if (c->interrupts)
for_each_irq(c->interrupts, dump_irq, (void *)18);
}
static void dump_cache_domain(struct topo_obj *d, void *data)
{
char *buffer = data;
cpumask_scnprintf(buffer, 4095, d->mask);
log(TO_CONSOLE, LOG_INFO, "%s%sCache domain %i: numa_node is ",
log_indent, log_indent, d->number);
for_each_object(d->numa_nodes, dump_numa_node_num, NULL);
log(TO_CONSOLE, LOG_INFO, "cpu mask is %s (load %lu) \n", buffer,
(unsigned long)d->load);
if (d->children)
for_each_object(d->children, dump_balance_obj, NULL);
if (g_list_length(d->interrupts) > 0)
for_each_irq(d->interrupts, dump_irq, (void *)10);
}
static void dump_package(struct topo_obj *d, void *data)
{
char *buffer = data;
cpumask_scnprintf(buffer, 4096, d->mask);
log(TO_CONSOLE, LOG_INFO, "Package %i: numa_node ", d->number);
for_each_object(d->numa_nodes, dump_numa_node_num, NULL);
log(TO_CONSOLE, LOG_INFO, "cpu mask is %s (load %lu)\n",
buffer, (unsigned long)d->load);
if (d->children)
for_each_object(d->children, dump_cache_domain, buffer);
if (g_list_length(d->interrupts) > 0)
for_each_irq(d->interrupts, dump_irq, (void *)2);
}
void dump_tree(void)
{
char buffer[4096];
for_each_object(packages, dump_package, buffer);
}
static void clear_irq_stats(struct irq_info *info, void *data __attribute__((unused)))
{
info->load = 0;
}
static void clear_obj_stats(struct topo_obj *d, void *data __attribute__((unused)))
{
for_each_object(d->children, clear_obj_stats, NULL);
for_each_irq(d->interrupts, clear_irq_stats, NULL);
}
/*
* this function removes previous state from the cpu tree, such as
* which level does how much work and the actual lists of interrupts
* assigned to each component
*/
void clear_work_stats(void)
{
for_each_object(numa_nodes, clear_obj_stats, NULL);
}
void parse_cpu_tree(void)
{
DIR *dir;
struct dirent *entry;
setup_banned_cpus();
cpus_complement(unbanned_cpus, banned_cpus);
dir = opendir("/sys/devices/system/cpu");
if (!dir)
return;
do {
int num;
char pad;
entry = readdir(dir);
/*
* We only want to count real cpus, not cpufreq and
* cpuidle
*/
if (entry &&
sscanf(entry->d_name, "cpu%d%c", &num, &pad) == 1 &&
!strchr(entry->d_name, ' ')) {
char new_path[PATH_MAX];
sprintf(new_path, "/sys/devices/system/cpu/%s", entry->d_name);
do_one_cpu(new_path);
}
} while (entry);
closedir(dir);
for_each_object(packages, connect_cpu_mem_topo, NULL);
if (debug_mode)
dump_tree();
}
/*
* This function frees all memory related to a cpu tree so that a new tree
* can be read
*/
void clear_cpu_tree(void)
{
GList *item;
struct topo_obj *cpu;
struct topo_obj *cache_domain;
struct topo_obj *package;
while (packages) {
item = g_list_first(packages);
package = item->data;
g_list_free(package->children);
g_list_free(package->interrupts);
g_list_free(package->numa_nodes);
free(package);
packages = g_list_delete_link(packages, item);
}
package_count = 0;
while (cache_domains) {
item = g_list_first(cache_domains);
cache_domain = item->data;
g_list_free(cache_domain->children);
g_list_free(cache_domain->interrupts);
g_list_free(cache_domain->numa_nodes);
free(cache_domain);
cache_domains = g_list_delete_link(cache_domains, item);
}
cache_domain_count = 0;
while (cpus) {
item = g_list_first(cpus);
cpu = item->data;
g_list_free(cpu->interrupts);
free(cpu);
cpus = g_list_delete_link(cpus, item);
}
core_count = 0;
}
static gint compare_cpus(gconstpointer a, gconstpointer b)
{
const struct topo_obj *ai = a;
const struct topo_obj *bi = b;
return ai->number - bi->number;
}
struct topo_obj *find_cpu_core(int cpunr)
{
GList *entry;
struct topo_obj find;
find.number = cpunr;
entry = g_list_find_custom(cpus, &find, compare_cpus);
return entry ? entry->data : NULL;
}
int get_cpu_count(void)
{
return g_list_length(cpus);
}