/*
* %CopyrightBegin%
*
* Copyright Ericsson AB 2006-2010. All Rights Reserved.
*
* The contents of this file are subject to the Erlang Public License,
* Version 1.1, (the "License"); you may not use this file except in
* compliance with the License. You should have received a copy of the
* Erlang Public License along with this software. If not, it can be
* retrieved online at http://www.erlang.org/.
*
* Software distributed under the License is distributed on an "AS IS"
* basis, WITHOUT WARRANTY OF ANY KIND, either express or implied. See
* the License for the specific language governing rights and limitations
* under the License.
*
* %CopyrightEnd%
*/
#ifdef HAVE_CONFIG_H
#include "config.h"
#endif
#if defined(__WIN32__)
# include <windows.h>
#endif
#include "erl_misc_utils.h"
#if defined(__WIN32__)
#elif defined(VXWORKS)
# include <selectLib.h>
#else /* UNIX */
# include <stdio.h>
# include <sys/types.h>
# include <sys/param.h>
# include <limits.h>
# include <dirent.h>
# include <sys/stat.h>
# include <fcntl.h>
# ifdef SYS_SELECT_H
# include <sys/select.h>
# endif
# if TIME_WITH_SYS_TIME
# include <sys/time.h>
# include <time.h>
# else
# if HAVE_SYS_TIME_H
# include <sys/time.h>
# else
# include <time.h>
# endif
# endif
# include <string.h>
# ifdef HAVE_UNISTD_H
# include <unistd.h>
# endif
# if (defined(NO_SYSCONF) || !defined(_SC_NPROCESSORS_CONF))
# ifdef HAVE_SYS_SYSCTL_H
# include <sys/sysctl.h>
# endif
# endif
#endif
#if defined(HAVE_SCHED_xETAFFINITY)
# include <sched.h>
# define ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__
#define ERTS_MU_GET_PROC_AFFINITY__(CPUINFOP, CPUSET) \
(sched_getaffinity((CPUINFOP)->pid, \
sizeof(cpu_set_t), \
(CPUSET)) != 0 ? -errno : 0)
#define ERTS_MU_SET_THR_AFFINITY__(SETP) \
(sched_setaffinity(0, sizeof(cpu_set_t), (SETP)) != 0 ? -errno : 0)
#elif defined(HAVE_CPUSET_xETAFFINITY)
# include <sys/param.h>
# include <sys/cpuset.h>
# define ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__
#define ERTS_MU_GET_PROC_AFFINITY__(CPUINFOP, CPUSET) \
(cpuset_getaffinity(CPU_LEVEL_WHICH, CPU_WHICH_PID, -1, \
sizeof(cpuset_t), \
(CPUSET)) != 0 ? -errno : 0)
#define ERTS_MU_SET_THR_AFFINITY__(CPUSETP) \
(cpuset_setaffinity(CPU_LEVEL_WHICH, CPU_WHICH_TID, -1, \
sizeof(cpuset_t), \
(CPUSETP)) != 0 ? -errno : 0)
# define cpu_set_t cpuset_t
#elif defined(__WIN32__)
# define ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__
# define cpu_set_t DWORD
# define CPU_SETSIZE (sizeof(DWORD)*8)
# define CPU_ZERO(SETP) (*(SETP) = (DWORD) 0)
# define CPU_SET(CPU, SETP) (*(SETP) |= (((DWORD) 1) << (CPU)))
# define CPU_CLR(CPU, SETP) (*(SETP) &= ~(((DWORD) 1) << (CPU)))
# define CPU_ISSET(CPU, SETP) ((*(SETP) & (((DWORD) 1) << (CPU))) != (DWORD) 0)
#define ERTS_MU_GET_PROC_AFFINITY__ get_proc_affinity
#define ERTS_MU_SET_THR_AFFINITY__ set_thr_affinity
#endif
#ifdef HAVE_PSET_INFO
# include <sys/pset.h>
#endif
#ifdef HAVE_PROCESSOR_BIND
# include <sys/processor.h>
# include <sys/procset.h>
#endif
#include <stdlib.h>
#ifdef HAVE_LIMITS_H
#include <limits.h>
#endif
#ifdef __linux__
# define ERTS_SYS_NODE_PATH "/sys/devices/system/node"
# define ERTS_SYS_CPU_PATH "/sys/devices/system/cpu"
#endif
#ifdef __FreeBSD__
#include <sys/types.h>
#include <sys/sysctl.h>
#endif
static int read_topology(erts_cpu_info_t *cpuinfo);
#if defined(ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__)
static int
cpu_sets_are_eq(cpu_set_t *x, cpu_set_t *y)
{
int i;
for (i = 0; i < CPU_SETSIZE; i++) {
if (CPU_ISSET(i, x)) {
if (!CPU_ISSET(i, y))
return 0;
}
else {
if (CPU_ISSET(i, y))
return 0;
}
}
return 1;
}
#endif
int
erts_milli_sleep(long ms)
{
if (ms > 0) {
#ifdef __WIN32__
Sleep((DWORD) ms);
#else
struct timeval tv;
tv.tv_sec = ms / 1000;
tv.tv_usec = (ms % 1000) * 1000;
if (select(0, NULL, NULL, NULL, &tv) < 0)
return errno == EINTR ? 1 : -1;
#endif
}
return 0;
}
struct erts_cpu_info_t_ {
int configured;
int online;
int available;
int topology_size;
erts_cpu_topology_t *topology;
#if defined(ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__)
char *affinity_str;
char affinity_str_buf[CPU_SETSIZE/4+2];
cpu_set_t cpuset;
#if defined(HAVE_SCHED_xETAFFINITY)
pid_t pid;
#endif
#elif defined(HAVE_PSET_INFO)
processorid_t *cpuids;
#endif
};
#if defined(__WIN32__)
static __forceinline int
get_proc_affinity(erts_cpu_info_t *cpuinfo, cpu_set_t *cpuset)
{
DWORD pamask, samask;
if (GetProcessAffinityMask(GetCurrentProcess(), &pamask, &samask)) {
*cpuset = (cpu_set_t) pamask;
return 0;
}
else {
*cpuset = (cpu_set_t) 0;
return -erts_get_last_win_errno();
}
}
static __forceinline int
set_thr_affinity(cpu_set_t *set)
{
if (*set == (cpu_set_t) 0)
return -ENOTSUP;
if (SetThreadAffinityMask(GetCurrentThread(), *set) == 0)
return -erts_get_last_win_errno();
else
return 0;
}
#endif
erts_cpu_info_t *
erts_cpu_info_create(void)
{
erts_cpu_info_t *cpuinfo = malloc(sizeof(erts_cpu_info_t));
if (!cpuinfo)
return NULL;
#if defined(ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__)
cpuinfo->affinity_str = NULL;
#if defined(HAVE_SCHED_xETAFFINITY)
cpuinfo->pid = getpid();
#endif
#elif defined(HAVE_PSET_INFO)
cpuinfo->cpuids = NULL;
#endif
cpuinfo->topology_size = 0;
cpuinfo->topology = NULL;
cpuinfo->configured = -1;
cpuinfo->online = -1;
cpuinfo->available = -1;
erts_cpu_info_update(cpuinfo);
return cpuinfo;
}
void
erts_cpu_info_destroy(erts_cpu_info_t *cpuinfo)
{
if (cpuinfo) {
cpuinfo->configured = 0;
cpuinfo->online = 0;
cpuinfo->available = 0;
#ifdef HAVE_PSET_INFO
if (cpuinfo->cpuids)
free(cpuinfo->cpuids);
#endif
cpuinfo->topology_size = 0;
if (cpuinfo->topology) {
cpuinfo->topology = NULL;
free(cpuinfo->topology);
}
free(cpuinfo);
}
}
int
erts_cpu_info_update(erts_cpu_info_t *cpuinfo)
{
int changed = 0;
int configured = 0;
int online = 0;
int available = 0;
erts_cpu_topology_t *old_topology;
int old_topology_size;
#if defined(ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__)
cpu_set_t cpuset;
#endif
#ifdef __WIN32__
{
int i;
SYSTEM_INFO sys_info;
GetSystemInfo(&sys_info);
configured = (int) sys_info.dwNumberOfProcessors;
for (i = 0; i < sizeof(DWORD)*8; i++)
if (sys_info.dwActiveProcessorMask & (((DWORD) 1) << i))
online++;
}
#elif !defined(NO_SYSCONF) && (defined(_SC_NPROCESSORS_CONF) \
|| defined(_SC_NPROCESSORS_ONLN))
#ifdef _SC_NPROCESSORS_CONF
configured = (int) sysconf(_SC_NPROCESSORS_CONF);
if (configured < 0)
configured = 0;
#endif
#ifdef _SC_NPROCESSORS_ONLN
online = (int) sysconf(_SC_NPROCESSORS_ONLN);
if (online < 0)
online = 0;
#endif
#elif defined(HAVE_SYS_SYSCTL_H) && defined(CTL_HW) && (defined(HW_NCPU) \
|| defined(HW_AVAILCPU))
{
int mib[2];
size_t len;
#ifdef HW_NCPU
len = sizeof(int);
mib[0] = CTL_HW;
mib[1] = HW_NCPU;
if (sysctl(&mib[0], 2, &configured, &len, NULL, 0) < 0)
configured = 0;
#endif
#ifdef HW_AVAILCPU
len = sizeof(int);
mib[0] = CTL_HW;
mib[1] = HW_AVAILCPU;
if (sysctl(&mib[0], 2, &online, &len, NULL, 0) < 0)
online = 0;
#endif
}
#endif
if (online > configured)
online = configured;
if (cpuinfo->configured != configured)
changed = 1;
if (cpuinfo->online != online)
changed = 1;
#if defined(ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__)
if (ERTS_MU_GET_PROC_AFFINITY__(cpuinfo, &cpuset) == 0) {
if (!changed && !cpu_sets_are_eq(&cpuset, &cpuinfo->cpuset))
changed = 1;
if (!changed)
available = cpuinfo->available;
else {
int i, c, cn, si;
memcpy((void *) &cpuinfo->cpuset,
(void *) &cpuset,
sizeof(cpu_set_t));
c = cn = 0;
si = sizeof(cpuinfo->affinity_str_buf) - 1;
cpuinfo->affinity_str_buf[si] = '\0';
for (i = 0; i < CPU_SETSIZE; i++) {
if (CPU_ISSET(i, &cpuinfo->cpuset)) {
c |= 1 << cn;
available++;
}
cn++;
if (cn == 4) {
cpuinfo->affinity_str_buf[--si] = (c < 10
? '0' + c
: 'A' + c - 10);
c = cn = 0;
}
}
if (c)
cpuinfo->affinity_str_buf[--si] = (c < 10
? '0' + c
: 'A' + c - 10);
while (cpuinfo->affinity_str_buf[si] == '0')
si++;
cpuinfo->affinity_str = &cpuinfo->affinity_str_buf[si];
}
}
#elif defined(HAVE_PSET_INFO)
{
processorid_t *cpuids;
uint_t numcpus = configured;
cpuids = malloc(sizeof(processorid_t)*numcpus);
if (cpuids) {
if (pset_info(PS_MYID, NULL, &numcpus, &cpuids) == 0)
available = (int) numcpus;
if (available < 0) {
free(cpuids);
cpuids = NULL;
available = 0;
}
}
if (!cpuids) {
if (cpuinfo->cpuids)
changed = 1;
}
else {
if (cpuinfo->cpuids)
changed = 1;
if (memcmp((void *) cpuinfo->cpuids,
(void *) cpuids,
sizeof(processorid_t)*numcpus) != 0)
changed = 1;
}
if (!changed) {
if (cpuids)
free(cpuids);
}
else {
if (cpuinfo->cpuids)
free(cpuinfo->cpuids);
cpuinfo->cpuids = cpuids;
}
}
#endif
if (available > online)
available = online;
if (cpuinfo->available != available)
changed = 1;
cpuinfo->configured = configured;
cpuinfo->online = online;
cpuinfo->available = available;
old_topology = cpuinfo->topology;
old_topology_size = cpuinfo->topology_size;
cpuinfo->topology = NULL;
read_topology(cpuinfo);
if (cpuinfo->topology_size != old_topology_size
|| (old_topology_size != 0
&& memcmp((void *) cpuinfo->topology,
(void *) old_topology,
(sizeof(erts_cpu_topology_t)
* old_topology_size)) != 0)) {
changed = 1;
if (old_topology)
free(old_topology);
}
else {
if (cpuinfo->topology)
free(cpuinfo->topology);
cpuinfo->topology = old_topology;
}
return changed;
}
int
erts_get_cpu_configured(erts_cpu_info_t *cpuinfo)
{
if (!cpuinfo)
return -EINVAL;
if (cpuinfo->configured <= 0)
return -ENOTSUP;
return cpuinfo->configured;
}
int
erts_get_cpu_online(erts_cpu_info_t *cpuinfo)
{
if (!cpuinfo)
return -EINVAL;
if (cpuinfo->online <= 0)
return -ENOTSUP;
return cpuinfo->online;
}
int
erts_get_cpu_available(erts_cpu_info_t *cpuinfo)
{
if (!cpuinfo)
return -EINVAL;
if (cpuinfo->available <= 0)
return -ENOTSUP;
return cpuinfo->available;
}
char *
erts_get_unbind_from_cpu_str(erts_cpu_info_t *cpuinfo)
{
#if defined(ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__)
if (!cpuinfo)
return "false";
return cpuinfo->affinity_str;
#else
return "true";
#endif
}
int
erts_get_available_cpu(erts_cpu_info_t *cpuinfo, int no)
{
if (!cpuinfo || no < 1 || cpuinfo->available < no)
return -EINVAL;
#if defined(ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__)
{
cpu_set_t *allowed = &cpuinfo->cpuset;
int ix, n;
for (ix = 0, n = 1; ix < CPU_SETSIZE; ix++) {
if (CPU_ISSET(ix, allowed)) {
if (no == n)
return ix;
n++;
}
}
}
return -EINVAL;
#elif defined(HAVE_PROCESSOR_BIND)
#if defined(HAVE_PSET_INFO)
return (int) cpuinfo->cpuids[no-1];
#elif defined(HAVE_KSTAT)
if (cpuinfo->topology && cpuinfo->online <= no) {
/* May not be available, but this is the best we can do */
return cpuinfo->topology[no-1].logical;
}
return -EINVAL;
#endif
#else
return -ENOTSUP;
#endif
}
int
erts_is_cpu_available(erts_cpu_info_t *cpuinfo, int id)
{
if (cpuinfo && 0 <= id) {
#if defined(ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__)
if (id < CPU_SETSIZE)
return CPU_ISSET(id, &cpuinfo->cpuset);
#elif defined(HAVE_PROCESSOR_BIND)
int no;
#if defined(HAVE_PSET_INFO)
for (no = 0; no < cpuinfo->available; no++)
if (id == (int) cpuinfo->cpuids[no])
return 1;
#elif defined(HAVE_KSTAT)
if (cpuinfo->topology) {
for (no = 0; no < cpuinfo->online; no++) {
if (id == (int) cpuinfo->topology[no].logical) {
/* May not be available, but this is the best we can do... */
return 1;
}
}
}
#endif
#endif
}
return 0;
}
int
erts_get_cpu_topology_size(erts_cpu_info_t *cpuinfo)
{
return cpuinfo->topology_size;
}
int
erts_get_cpu_topology(erts_cpu_info_t *cpuinfo,
erts_cpu_topology_t *topology)
{
if (!cpuinfo->topology)
return 0;
memcpy((void *) topology,
(void *) cpuinfo->topology,
cpuinfo->topology_size*sizeof(erts_cpu_topology_t));
return cpuinfo->topology_size;
}
int
erts_bind_to_cpu(erts_cpu_info_t *cpuinfo, int cpu)
{
/*
* Caller can test for available functionality by
* passing a negative cpu id. If functionality is
* available -EINVAL is returned; otherwise,
* -ENOTSUP.
*/
if (!cpuinfo)
return -EINVAL;
#if defined(ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__)
{
cpu_set_t bind_set;
if (cpu < 0)
return -EINVAL;
if (!CPU_ISSET(cpu, &cpuinfo->cpuset))
return -EINVAL;
CPU_ZERO(&bind_set);
CPU_SET(cpu, &bind_set);
return ERTS_MU_SET_THR_AFFINITY__(&bind_set);
}
#elif defined(HAVE_PROCESSOR_BIND)
if (cpu < 0)
return -EINVAL;
if (processor_bind(P_LWPID, P_MYID, (processorid_t) cpu, NULL) != 0)
return -errno;
return 0;
#else
return -ENOTSUP;
#endif
}
int
erts_unbind_from_cpu(erts_cpu_info_t *cpuinfo)
{
if (!cpuinfo)
return -EINVAL;
#if defined(ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__)
return ERTS_MU_SET_THR_AFFINITY__(&cpuinfo->cpuset);
#elif defined(HAVE_PROCESSOR_BIND)
if (processor_bind(P_LWPID, P_MYID, PBIND_NONE, NULL) != 0)
return -errno;
return 0;
#else
return -ENOTSUP;
#endif
}
int
erts_unbind_from_cpu_str(char *str)
{
#if defined(ERTS_HAVE_MISC_UTIL_AFFINITY_MASK__)
char *c = str;
int cpus = 0;
int shft = 0;
cpu_set_t cpuset;
CPU_ZERO(&cpuset);
if (!c)
return -EINVAL;
while (*c)
c++;
while (c != str) {
int shft2;
int mask = 0;
c--;
switch (*c) {
case '0': mask = 0; break;
case '1': mask = 1; break;
case '2': mask = 2; break;
case '3': mask = 3; break;
case '4': mask = 4; break;
case '5': mask = 5; break;
case '6': mask = 6; break;
case '7': mask = 7; break;
case '8': mask = 8; break;
case '9': mask = 9; break;
case 'A': case 'a': mask = 10; break;
case 'B': case 'b': mask = 11; break;
case 'C': case 'c': mask = 12; break;
case 'D': case 'd': mask = 13; break;
case 'E': case 'e': mask = 14; break;
case 'F': case 'f': mask = 15; break;
default: return -EINVAL;
}
for (shft2 = 0; shft2 < 4; shft2++) {
if (mask & (1 << shft2)) {
int cpu = shft + shft2;
if (cpu >= CPU_SETSIZE)
return -EINVAL;
cpus++;
CPU_SET(cpu, &cpuset);
}
}
shft += 4;
}
if (!cpus)
return -EINVAL;
return ERTS_MU_SET_THR_AFFINITY__(&cpuset);
#elif defined(HAVE_PROCESSOR_BIND)
if (processor_bind(P_LWPID, P_MYID, PBIND_NONE, NULL) != 0)
return -errno;
return 0;
#else
return -ENOTSUP;
#endif
}
static int
pn_cmp(const void *vx, const void *vy)
{
erts_cpu_topology_t *x = (erts_cpu_topology_t *) vx;
erts_cpu_topology_t *y = (erts_cpu_topology_t *) vy;
if (x->processor != y->processor)
return x->processor - y->processor;
if (x->node != y->node)
return x->node - y->node;
if (x->processor_node != y->processor_node)
return x->processor_node - y->processor_node;
if (x->core != y->core)
return x->core - y->core;
if (x->thread != y->thread)
return x->thread - y->thread;
if (x->logical != y->logical)
return x->logical - y->logical;
return 0;
}
static int
cpu_cmp(const void *vx, const void *vy)
{
erts_cpu_topology_t *x = (erts_cpu_topology_t *) vx;
erts_cpu_topology_t *y = (erts_cpu_topology_t *) vy;
if (x->node != y->node)
return x->node - y->node;
if (x->processor != y->processor)
return x->processor - y->processor;
if (x->processor_node != y->processor_node)
return x->processor_node - y->processor_node;
if (x->core != y->core)
return x->core - y->core;
if (x->thread != y->thread)
return x->thread - y->thread;
if (x->logical != y->logical)
return x->logical - y->logical;
return 0;
}
static void
adjust_processor_nodes(erts_cpu_info_t *cpuinfo, int no_nodes)
{
erts_cpu_topology_t *prev, *this, *last;
if (no_nodes > 1) {
int processor = -1;
int processor_node = 0;
int node = -1;
qsort(cpuinfo->topology,
cpuinfo->topology_size,
sizeof(erts_cpu_topology_t),
pn_cmp);
prev = NULL;
this = &cpuinfo->topology[0];
last = &cpuinfo->topology[cpuinfo->configured-1];
while (1) {
if (processor == this->processor) {
if (node != this->node)
processor_node = 1;
}
else {
if (processor_node) {
make_processor_node:
while (prev->processor == processor) {
prev->processor_node = prev->node;
prev->node = -1;
if (prev == &cpuinfo->topology[0])
break;
prev--;
}
processor_node = 0;
}
processor = this->processor;
node = this->node;
}
if (this == last) {
if (processor_node) {
prev = this;
goto make_processor_node;
}
break;
}
prev = this++;
}
}
}
#ifdef __linux__
static int
read_file(char *path, char *buf, int size)
{
int ix = 0;
ssize_t sz = size-1;
int fd = open(path, O_RDONLY);
if (fd < 0)
goto error;
while (size > ix) {
sz = read(fd, &buf[ix], size - ix);
if (sz <= 0) {
if (sz == 0)
break;
if (errno == EINTR)
continue;
goto error;
}
ix += sz;
}
buf[ix] = '\0';
close(fd);
return ix;
error: {
int saved_errno = errno;
if (fd >= 0)
close(fd);
if (saved_errno)
return -saved_errno;
else
return -EINVAL;
}
}
static int
read_topology(erts_cpu_info_t *cpuinfo)
{
char npath[MAXPATHLEN];
char cpath[MAXPATHLEN];
char tpath[MAXPATHLEN];
char fpath[MAXPATHLEN];
DIR *ndir = NULL;
DIR *cdir = NULL;
struct dirent *nde;
int ix;
int res = 0;
int got_nodes = 0;
int no_nodes = 0;
errno = 0;
if (cpuinfo->configured < 1)
goto error;
cpuinfo->topology = malloc(sizeof(erts_cpu_topology_t)
* cpuinfo->configured);
if (!cpuinfo->topology)
goto error;
for (ix = 0; ix < cpuinfo->configured; ix++) {
cpuinfo->topology[ix].node = -1;
cpuinfo->topology[ix].processor = -1;
cpuinfo->topology[ix].processor_node = -1;
cpuinfo->topology[ix].core = -1;
cpuinfo->topology[ix].thread = -1;
cpuinfo->topology[ix].logical = -1;
}
ix = -1;
if (realpath(ERTS_SYS_NODE_PATH, npath)) {
got_nodes = 1;
ndir = opendir(npath);
}
do {
int node_id = -1;
if (!got_nodes) {
if (!realpath(ERTS_SYS_CPU_PATH, cpath))
goto error;
}
else {
nde = readdir(ndir);
if (!nde)
break;
if (sscanf(nde->d_name, "node%d", &node_id) != 1)
continue;
no_nodes++;
sprintf(tpath, "%s/node%d", npath, node_id);
if (!realpath(tpath, cpath))
goto error;
}
cdir = opendir(cpath);
if (!cdir)
goto error;
while (1) {
int cpu_id;
struct dirent *cde = readdir(cdir);
if (!cde) {
closedir(cdir);
cdir = NULL;
break;
}
if (sscanf(cde->d_name, "cpu%d", &cpu_id) == 1) {
char buf[50]; /* Much more than enough for an integer */
int processor_id, core_id;
sprintf(tpath, "%s/cpu%d/topology/physical_package_id",
cpath, cpu_id);
if (!realpath(tpath, fpath))
continue;
if (read_file(fpath, buf, sizeof(buf)) <= 0)
continue;
if (sscanf(buf, "%d", &processor_id) != 1)
continue;
sprintf(tpath, "%s/cpu%d/topology/core_id",
cpath, cpu_id);
if (!realpath(tpath, fpath))
continue;
if (read_file(fpath, buf, sizeof(buf)) <= 0)
continue;
if (sscanf(buf, "%d", &core_id) != 1)
continue;
/*
* We now know node id, processor id, and
* core id of the logical processor with
* the cpu id 'cpu_id'.
*/
ix++;
cpuinfo->topology[ix].node = node_id;
cpuinfo->topology[ix].processor = processor_id;
cpuinfo->topology[ix].processor_node = -1; /* Fixed later */
cpuinfo->topology[ix].core = core_id;
cpuinfo->topology[ix].thread = 0; /* we'll numerate later */
cpuinfo->topology[ix].logical = cpu_id;
}
}
} while (got_nodes);
res = ix+1;
if (!res || res < cpuinfo->online)
res = 0;
else {
erts_cpu_topology_t *prev, *this, *last;
cpuinfo->topology_size = res;
if (cpuinfo->topology_size != cpuinfo->configured) {
void *t = realloc(cpuinfo->topology, (sizeof(erts_cpu_topology_t)
* cpuinfo->topology_size));
if (t)
cpuinfo->topology = t;
}
adjust_processor_nodes(cpuinfo, no_nodes);
qsort(cpuinfo->topology,
cpuinfo->topology_size,
sizeof(erts_cpu_topology_t),
cpu_cmp);
this = &cpuinfo->topology[0];
this->thread = 0;
if (res > 1) {
prev = this++;
last = &cpuinfo->topology[cpuinfo->configured-1];
while (1) {
this->thread = ((this->node == prev->node
&& this->processor == prev->processor
&& this->processor_node == prev->processor_node
&& this->core == prev->core)
? prev->thread + 1
: 0);
if (this == last)
break;
prev = this++;
}
}
}
error:
if (res == 0) {
cpuinfo->topology_size = 0;
if (cpuinfo->topology) {
free(cpuinfo->topology);
cpuinfo->topology = NULL;
}
if (errno)
res = -errno;
else
res = -EINVAL;
}
if (ndir)
closedir(ndir);
if (cdir)
closedir(cdir);
return res;
}
#elif defined(HAVE_KSTAT) /* SunOS kstat */
#include <kstat.h>
static int
data_lookup_int(kstat_t *ks, char *what)
{
int res;
kstat_named_t *ks_n;
ks_n = kstat_data_lookup(ks, what);
if (!ks_n)
return 0;
switch (ks_n->data_type) {
case KSTAT_DATA_CHAR:
res = atoi(ks_n->value.c);
break;
case KSTAT_DATA_INT32:
res = (int) ks_n->value.i32;
break;
case KSTAT_DATA_UINT32:
res = (int) ks_n->value.ui32;
break;
case KSTAT_DATA_INT64:
res = (int) ks_n->value.i64;
break;
case KSTAT_DATA_UINT64:
res = (int) ks_n->value.ui64;
break;
default:
res = 0;
break;
}
return res;
}
static int
read_topology(erts_cpu_info_t *cpuinfo)
{
int res = 0;
int ix;
kstat_ctl_t *ks_ctl;
kstat_t *ks;
errno = 0;
if (cpuinfo->configured < 1)
goto error;
cpuinfo->topology = malloc(sizeof(erts_cpu_topology_t)
* cpuinfo->configured);
if (!cpuinfo->topology)
goto error;
for (ix = 0; ix < cpuinfo->configured; ix++) {
cpuinfo->topology[ix].node = -1;
cpuinfo->topology[ix].processor = -1;
cpuinfo->topology[ix].processor_node = -1;
cpuinfo->topology[ix].core = -1;
cpuinfo->topology[ix].thread = -1;
cpuinfo->topology[ix].logical = -1;
}
ks_ctl = kstat_open();
if (!ks_ctl)
goto error;
ix = 0;
for (ks = ks_ctl->kc_chain; ks; ks = ks->ks_next) {
if (strcmp("cpu_info", ks->ks_module) == 0) {
kstat_read(ks_ctl, ks, NULL);
if (ks->ks_type == KSTAT_TYPE_NAMED) {
/*
* Don't know how to figure numa nodes out;
* hope there is none...
*/
cpuinfo->topology[ix].node = -1;
cpuinfo->topology[ix].processor = data_lookup_int(ks,"chip_id");
cpuinfo->topology[ix].processor_node = -1;
cpuinfo->topology[ix].core = data_lookup_int(ks, "core_id");
cpuinfo->topology[ix].thread = 0; /* we'll numerate later */
cpuinfo->topology[ix].logical = ks->ks_instance;
if (++ix == cpuinfo->configured)
break;
}
}
}
kstat_close(ks_ctl);
res = ix;
if (!res || res < cpuinfo->online)
res = 0;
else {
erts_cpu_topology_t *prev, *this, *last;
cpuinfo->topology_size = res;
if (cpuinfo->topology_size != cpuinfo->configured) {
void *t = realloc(cpuinfo->topology, (sizeof(erts_cpu_topology_t)
* cpuinfo->topology_size));
if (t)
cpuinfo->topology = t;
}
qsort(cpuinfo->topology,
cpuinfo->topology_size,
sizeof(erts_cpu_topology_t),
cpu_cmp);
this = &cpuinfo->topology[0];
this->thread = 0;
if (res > 1) {
prev = this++;
last = &cpuinfo->topology[cpuinfo->configured-1];
while (1) {
this->thread = ((this->node == prev->node
&& this->processor == prev->processor
&& this->processor_node == prev->processor_node
&& this->core == prev->core)
? prev->thread + 1
: 0);
if (this == last)
break;
prev = this++;
}
}
}
adjust_processor_nodes(cpuinfo, 1);
error:
if (res == 0) {
cpuinfo->topology_size = 0;
if (cpuinfo->topology) {
free(cpuinfo->topology);
cpuinfo->topology = NULL;
}
if (errno)
res = -errno;
else
res = -EINVAL;
}
return res;
}
#elif defined(__WIN32__)
/*
* We cannot use Relation* out of the box since all of them are not
* always part of the LOGICAL_PROCESSOR_RELATIONSHIP enum. They are
* however documented as follows...
*/
#define ERTS_MU_RELATION_PROCESSOR_CORE 0 /* RelationProcessorCore */
#define ERTS_MU_RELATION_NUMA_NODE 1 /* RelationNumaNode */
#define ERTS_MU_RELATION_CACHE 2 /* RelationCache */
#define ERTS_MU_RELATION_PROCESSOR_PACKAGE 3 /* RelationProcessorPackage */
static __forceinline int
rel_cmp_val(int r)
{
switch (r) {
case ERTS_MU_RELATION_NUMA_NODE: return 0;
case ERTS_MU_RELATION_PROCESSOR_PACKAGE: return 1;
case ERTS_MU_RELATION_PROCESSOR_CORE: return 2;
default: /* currently not used */ return 3;
}
}
static int
slpi_cmp(const void *vx, const void *vy)
{
PSYSTEM_LOGICAL_PROCESSOR_INFORMATION x, y;
x = (PSYSTEM_LOGICAL_PROCESSOR_INFORMATION) vx;
y = (PSYSTEM_LOGICAL_PROCESSOR_INFORMATION) vy;
if ((int) x->Relationship != (int) y->Relationship)
return (rel_cmp_val((int) x->Relationship)
- rel_cmp_val((int) y->Relationship));
switch ((int) x->Relationship) {
case ERTS_MU_RELATION_NUMA_NODE:
if (x->NumaNode.NodeNumber == y->NumaNode.NodeNumber)
break;
return ((int) x->NumaNode.NodeNumber) - ((int) y->NumaNode.NodeNumber);
case ERTS_MU_RELATION_PROCESSOR_CORE:
case ERTS_MU_RELATION_PROCESSOR_PACKAGE:
default:
break;
}
if (x->ProcessorMask == y->ProcessorMask)
return 0;
return x->ProcessorMask < y->ProcessorMask ? -1 : 1;
}
typedef BOOL (WINAPI *glpi_t)(PSYSTEM_LOGICAL_PROCESSOR_INFORMATION, PDWORD);
static int
read_topology(erts_cpu_info_t *cpuinfo)
{
int res = 0;
glpi_t glpi;
int *core_id = NULL;
PSYSTEM_LOGICAL_PROCESSOR_INFORMATION slpip = NULL;
int wix, rix, max_l, l, packages, nodes, no_slpi;
DWORD slpi_size = 0;
glpi = (glpi_t) GetProcAddress(GetModuleHandle("kernel32"),
"GetLogicalProcessorInformation");
if (!glpi)
return -ENOTSUP;
cpuinfo->topology = NULL;
if (cpuinfo->configured < 1 || sizeof(ULONG_PTR)*8 < cpuinfo->configured)
goto error;
while (1) {
DWORD werr;
if (TRUE == glpi(slpip, &slpi_size))
break;
werr = GetLastError();
if (werr != ERROR_INSUFFICIENT_BUFFER) {
res = -erts_map_win_error_to_errno(werr);
goto error;
}
if (slpip)
free(slpip);
slpip = malloc(slpi_size);
if (!slpip) {
res = -ENOMEM;
goto error;
}
}
no_slpi = (int) slpi_size/sizeof(SYSTEM_LOGICAL_PROCESSOR_INFORMATION);
qsort(slpip,
no_slpi,
sizeof(SYSTEM_LOGICAL_PROCESSOR_INFORMATION),
slpi_cmp);
/*
* Now numa node relations appear before package relations which
* appear before core relations which appear before relations
* we aren't interested in...
*/
max_l = 0;
packages = 0;
nodes = 0;
for (rix = 0; rix < no_slpi; rix++) {
PSYSTEM_LOGICAL_PROCESSOR_INFORMATION this = &slpip[rix];
for (l = sizeof(ULONG_PTR)*8 - 1; l > 0; l--) {
if (slpip[rix].ProcessorMask & (((ULONG_PTR) 1) << l)) {
if (max_l < l)
max_l = l;
break;
}
}
if ((int) slpip[rix].Relationship == ERTS_MU_RELATION_PROCESSOR_PACKAGE)
packages++;
if ((int) slpip[rix].Relationship == ERTS_MU_RELATION_NUMA_NODE)
nodes++;
}
if (!packages) {
packages = 1;
}
core_id = malloc(sizeof(int)*packages);
if (!core_id) {
res = -ENOMEM;
goto error;
}
for (rix = 0; rix < packages; rix++)
core_id[rix] = 0;
cpuinfo->topology_size = max_l + 1;
cpuinfo->topology = malloc(sizeof(erts_cpu_topology_t)
* cpuinfo->topology_size);
if (!cpuinfo->topology) {
res = -ENOMEM;
goto error;
}
for (wix = 0; wix < cpuinfo->topology_size; wix++) {
cpuinfo->topology[wix].node = -1;
cpuinfo->topology[wix].processor = -1;
cpuinfo->topology[wix].processor_node = -1;
cpuinfo->topology[wix].core = -1;
cpuinfo->topology[wix].thread = -1;
cpuinfo->topology[wix].logical = -1;
}
nodes = 0;
packages = 0;
for (rix = 0; rix < no_slpi; rix++) {
switch ((int) slpip[rix].Relationship) {
case ERTS_MU_RELATION_NUMA_NODE:
for (l = 0; l < sizeof(ULONG_PTR)*8; l++) {
if (slpip[rix].ProcessorMask & (((ULONG_PTR) 1) << l)) {
cpuinfo->topology[l].logical = l;
cpuinfo->topology[l].node = slpip[rix].NumaNode.NodeNumber;
}
}
nodes++;
break;
case ERTS_MU_RELATION_PROCESSOR_PACKAGE:
for (l = 0; l < sizeof(ULONG_PTR)*8; l++) {
if (slpip[rix].ProcessorMask & (((ULONG_PTR) 1) << l)) {
cpuinfo->topology[l].logical = l;
cpuinfo->topology[l].processor = packages;
}
}
packages++;
break;
case ERTS_MU_RELATION_PROCESSOR_CORE: {
int thread = 0;
int processor = -1;
for (l = 0; l < sizeof(ULONG_PTR)*8; l++) {
/*
* Nodes and packages may not be supported; pretend
* that there are one if this is the case...
*/
if (slpip[rix].ProcessorMask & (((ULONG_PTR) 1) << l)) {
if (!nodes) {
cpuinfo->topology[l].node = 0;
}
if (!packages) {
cpuinfo->topology[l].processor = 0;
}
if (processor < 0) {
processor = cpuinfo->topology[l].processor;
if (processor < 0) {
res = -EINVAL;
goto error;
}
}
else if (processor != cpuinfo->topology[l].processor) {
res = -EINVAL;
goto error;
}
cpuinfo->topology[l].logical = l;
cpuinfo->topology[l].thread = thread;
cpuinfo->topology[l].core = core_id[processor];
thread++;
}
}
core_id[processor]++;
break;
}
default:
/*
* We have reached the end of the relationships
* that we (currently) are interested in...
*/
goto relationships_done;
}
}
relationships_done:
/*
* There may be unused entries; remove them...
*/
for (rix = wix = 0; rix < cpuinfo->topology_size; rix++) {
if (cpuinfo->topology[rix].logical >= 0) {
if (wix != rix)
cpuinfo->topology[wix] = cpuinfo->topology[rix];
wix++;
}
}
if (cpuinfo->topology_size != wix) {
erts_cpu_topology_t *new = cpuinfo->topology;
new = realloc(cpuinfo->topology,
sizeof(erts_cpu_topology_t)*wix);
if (!new) {
res = -ENOMEM;
goto error;
}
cpuinfo->topology = new;
cpuinfo->topology_size = wix;
}
res = wix;
adjust_processor_nodes(cpuinfo, nodes);
qsort(cpuinfo->topology,
cpuinfo->topology_size,
sizeof(erts_cpu_topology_t),
cpu_cmp);
if (res < cpuinfo->online)
res = -EINVAL;
error:
if (res <= 0) {
cpuinfo->topology_size = 0;
if (cpuinfo->topology) {
free(cpuinfo->topology);
cpuinfo->topology = NULL;
}
}
if (slpip)
free(slpip);
if (core_id)
free(core_id);
return res;
}
#elif defined(__FreeBSD__)
/**
* FreeBSD topology detection is based on kern.sched.topology_spec XML as
* exposed by the ULE scheduler and described in SMP(4). It is available in
* 8.0 and higher.
*
* Threads are identified in this XML chunk with a THREAD flag. The function
* (simplistically) distinguishes cores and processors by the amount of cache
* they share (0 => processor, otherwise => core). Nodes are not identified
* (ULE doesn't handle NUMA yet, I believe).
*/
/**
* Recursively parse a topology_spec <group> tag.
*/
static
const char* parse_topology_spec_group(erts_cpu_info_t *cpuinfo, const char* xml, int parentCacheLevel, int* processor_p, int* core_p, int* index_procs_p) {
int error = 0;
int cacheLevel = parentCacheLevel;
const char* next_group_start = strstr(xml + 1, "<group");
int is_thread_group = 0;
const char* next_cache_level;
const char* next_thread_flag;
const char* next_group_end;
const char* next_children;
const char* next_children_end;
/* parse the cache level */
next_cache_level = strstr(xml, "cache-level=\"");
if (next_cache_level && (next_group_start == NULL || next_cache_level < next_group_start)) {
sscanf(next_cache_level, "cache-level=\"%i\"", &cacheLevel);
}
/* parse the threads flag */
next_thread_flag = strstr(xml, "THREAD");
if (next_thread_flag && (next_group_start == NULL || next_thread_flag < next_group_start))
is_thread_group = 1;
/* Determine if it's a leaf with the position of the next children tag */
next_group_end = strstr(xml, "</group>");
next_children = strstr(xml, "<children>");
next_children_end = strstr(xml, "</children>");
if (next_children == NULL || next_group_end < next_children) {
do {
const char* next_cpu_start;
const char* next_cpu_cdata;
const char* next_cpu_end;
int cpu_str_size;
char* cpu_str;
char* cpu_crsr;
char* brkb;
int thread = 0;
int index_procs = *index_procs_p;
next_cpu_start = strstr(xml, "<cpu");
if (!next_cpu_start) {
error = 1;
break;
}
next_cpu_cdata = strstr(next_cpu_start, ">") + 1;
if (!next_cpu_cdata) {
error = 1;
break;
}
next_cpu_end = strstr(next_cpu_cdata, "</cpu>");
if (!next_cpu_end) {
error = 1;
break;
}
cpu_str_size = next_cpu_end - next_cpu_cdata;
cpu_str = (char*) malloc(cpu_str_size + 1);
memcpy(cpu_str, (const char*) next_cpu_cdata, cpu_str_size);
cpu_str[cpu_str_size] = 0;
for (cpu_crsr = strtok_r(cpu_str, " \t,", &brkb); cpu_crsr; cpu_crsr = strtok_r(NULL, " \t,", &brkb)) {
int cpu_id;
if (index_procs >= cpuinfo->configured) {
void* t = realloc(cpuinfo->topology, (sizeof(erts_cpu_topology_t) * (index_procs + 1)));
if (t) {
cpuinfo->topology = t;
} else {
error = 1;
break;
}
}
cpu_id = atoi(cpu_crsr);
cpuinfo->topology[index_procs].node = -1;
cpuinfo->topology[index_procs].processor = *processor_p;
cpuinfo->topology[index_procs].processor_node = -1;
cpuinfo->topology[index_procs].core = *core_p;
cpuinfo->topology[index_procs].thread = thread;
cpuinfo->topology[index_procs].logical = cpu_id;
if (is_thread_group) {
thread++;
} else {
*core_p = (*core_p)++;
}
index_procs++;
}
*index_procs_p = index_procs;
free(cpu_str);
} while (0);
xml = next_group_end;
} else {
while (next_group_start != NULL && next_group_start < next_children_end) {
xml = parse_topology_spec_group(cpuinfo, next_group_start, cacheLevel, processor_p, core_p, index_procs_p);
if (!xml)
break;
next_group_start = strstr(xml, "<group");
next_children_end = strstr(xml, "</children>");
}
}
if (cacheLevel == 0) {
*core_p = 0;
*processor_p = (*processor_p)++;
} else {
*core_p = (*core_p)++;
}
if (error)
xml = NULL;
return xml;
}
/**
* Parse the topology_spec. Return the number of CPUs or 0 if parsing failed.
*/
static
int parse_topology_spec(erts_cpu_info_t *cpuinfo, const char* xml) {
int res = 1;
int index_procs = 0;
int core = 0;
int processor = 0;
xml = strstr(xml, "<groups");
if (!xml)
return -1;
xml += 7;
xml = strstr(xml, "<group");
while (xml) {
xml = parse_topology_spec_group(cpuinfo, xml, 0, &processor, &core, &index_procs);
if (!xml) {
res = 0;
break;
}
xml = strstr(xml, "<group");
}
if (res)
res = index_procs;
return res;
}
static int
read_topology(erts_cpu_info_t *cpuinfo)
{
int ix;
int res = 0;
size_t topology_spec_size = 0;
void* topology_spec = NULL;
errno = 0;
if (cpuinfo->configured < 1)
goto error;
cpuinfo->topology_size = cpuinfo->configured;
cpuinfo->topology = malloc(sizeof(erts_cpu_topology_t)
* cpuinfo->configured);
if (!cpuinfo->topology) {
res = -ENOMEM;
goto error;
}
for (ix = 0; ix < cpuinfo->configured; ix++) {
cpuinfo->topology[ix].node = -1;
cpuinfo->topology[ix].processor = -1;
cpuinfo->topology[ix].processor_node = -1;
cpuinfo->topology[ix].core = -1;
cpuinfo->topology[ix].thread = -1;
cpuinfo->topology[ix].logical = -1;
}
if (!sysctlbyname("kern.sched.topology_spec", NULL, &topology_spec_size, NULL, 0)) {
topology_spec = malloc(topology_spec_size);
if (!topology_spec) {
res = -ENOMEM;
goto error;
}
if (sysctlbyname("kern.sched.topology_spec", topology_spec, &topology_spec_size, NULL, 0)) {
goto error;
}
res = parse_topology_spec(cpuinfo, topology_spec);
if (!res || res < cpuinfo->online)
res = 0;
else {
cpuinfo->topology_size = res;
if (cpuinfo->topology_size != cpuinfo->configured) {
void *t = realloc(cpuinfo->topology, (sizeof(erts_cpu_topology_t)
* cpuinfo->topology_size));
if (t)
cpuinfo->topology = t;
}
adjust_processor_nodes(cpuinfo, 1);
qsort(cpuinfo->topology,
cpuinfo->topology_size,
sizeof(erts_cpu_topology_t),
cpu_cmp);
}
}
error:
if (res == 0) {
cpuinfo->topology_size = 0;
if (cpuinfo->topology) {
free(cpuinfo->topology);
cpuinfo->topology = NULL;
}
if (errno)
res = -errno;
else
res = -EINVAL;
}
if (topology_spec)
free(topology_spec);
return res;
}
#else
static int
read_topology(erts_cpu_info_t *cpuinfo)
{
return -ENOTSUP;
}
#endif
#if defined(__WIN32__)
int
erts_map_win_error_to_errno(DWORD win_error)
{
switch (win_error) {
case ERROR_INVALID_FUNCTION: return EINVAL; /* 1 */
case ERROR_FILE_NOT_FOUND: return ENOENT; /* 2 */
case ERROR_PATH_NOT_FOUND: return ENOENT; /* 3 */
case ERROR_TOO_MANY_OPEN_FILES: return EMFILE; /* 4 */
case ERROR_ACCESS_DENIED: return EACCES; /* 5 */
case ERROR_INVALID_HANDLE: return EBADF; /* 6 */
case ERROR_ARENA_TRASHED: return ENOMEM; /* 7 */
case ERROR_NOT_ENOUGH_MEMORY: return ENOMEM; /* 8 */
case ERROR_INVALID_BLOCK: return ENOMEM; /* 9 */
case ERROR_BAD_ENVIRONMENT: return E2BIG; /* 10 */
case ERROR_BAD_FORMAT: return ENOEXEC; /* 11 */
case ERROR_INVALID_ACCESS: return EINVAL; /* 12 */
case ERROR_INVALID_DATA: return EINVAL; /* 13 */
case ERROR_OUTOFMEMORY: return ENOMEM; /* 14 */
case ERROR_INVALID_DRIVE: return ENOENT; /* 15 */
case ERROR_CURRENT_DIRECTORY: return EACCES; /* 16 */
case ERROR_NOT_SAME_DEVICE: return EXDEV; /* 17 */
case ERROR_NO_MORE_FILES: return ENOENT; /* 18 */
case ERROR_WRITE_PROTECT: return EACCES; /* 19 */
case ERROR_BAD_UNIT: return EACCES; /* 20 */
case ERROR_NOT_READY: return EACCES; /* 21 */
case ERROR_BAD_COMMAND: return EACCES; /* 22 */
case ERROR_CRC: return EACCES; /* 23 */
case ERROR_BAD_LENGTH: return EACCES; /* 24 */
case ERROR_SEEK: return EACCES; /* 25 */
case ERROR_NOT_DOS_DISK: return EACCES; /* 26 */
case ERROR_SECTOR_NOT_FOUND: return EACCES; /* 27 */
case ERROR_OUT_OF_PAPER: return EACCES; /* 28 */
case ERROR_WRITE_FAULT: return EACCES; /* 29 */
case ERROR_READ_FAULT: return EACCES; /* 30 */
case ERROR_GEN_FAILURE: return EACCES; /* 31 */
case ERROR_SHARING_VIOLATION: return EACCES; /* 32 */
case ERROR_LOCK_VIOLATION: return EACCES; /* 33 */
case ERROR_WRONG_DISK: return EACCES; /* 34 */
case ERROR_SHARING_BUFFER_EXCEEDED: return EACCES; /* 36 */
case ERROR_BAD_NETPATH: return ENOENT; /* 53 */
case ERROR_NETWORK_ACCESS_DENIED: return EACCES; /* 65 */
case ERROR_BAD_NET_NAME: return ENOENT; /* 67 */
case ERROR_FILE_EXISTS: return EEXIST; /* 80 */
case ERROR_CANNOT_MAKE: return EACCES; /* 82 */
case ERROR_FAIL_I24: return EACCES; /* 83 */
case ERROR_INVALID_PARAMETER: return EINVAL; /* 87 */
case ERROR_NO_PROC_SLOTS: return EAGAIN; /* 89 */
case ERROR_DRIVE_LOCKED: return EACCES; /* 108 */
case ERROR_BROKEN_PIPE: return EPIPE; /* 109 */
case ERROR_DISK_FULL: return ENOSPC; /* 112 */
case ERROR_INVALID_TARGET_HANDLE: return EBADF; /* 114 */
case ERROR_WAIT_NO_CHILDREN: return ECHILD; /* 128 */
case ERROR_CHILD_NOT_COMPLETE: return ECHILD; /* 129 */
case ERROR_DIRECT_ACCESS_HANDLE: return EBADF; /* 130 */
case ERROR_NEGATIVE_SEEK: return EINVAL; /* 131 */
case ERROR_SEEK_ON_DEVICE: return EACCES; /* 132 */
case ERROR_DIR_NOT_EMPTY: return ENOTEMPTY;/* 145 */
case ERROR_NOT_LOCKED: return EACCES; /* 158 */
case ERROR_BAD_PATHNAME: return ENOENT; /* 161 */
case ERROR_MAX_THRDS_REACHED: return EAGAIN; /* 164 */
case ERROR_LOCK_FAILED: return EACCES; /* 167 */
case ERROR_ALREADY_EXISTS: return EEXIST; /* 183 */
case ERROR_INVALID_STARTING_CODESEG: return ENOEXEC; /* 188 */
case ERROR_INVALID_STACKSEG: return ENOEXEC; /* 189 */
case ERROR_INVALID_MODULETYPE: return ENOEXEC; /* 190 */
case ERROR_INVALID_EXE_SIGNATURE: return ENOEXEC; /* 191 */
case ERROR_EXE_MARKED_INVALID: return ENOEXEC; /* 192 */
case ERROR_BAD_EXE_FORMAT: return ENOEXEC; /* 193 */
case ERROR_ITERATED_DATA_EXCEEDS_64k: return ENOEXEC; /* 194 */
case ERROR_INVALID_MINALLOCSIZE: return ENOEXEC; /* 195 */
case ERROR_DYNLINK_FROM_INVALID_RING: return ENOEXEC; /* 196 */
case ERROR_IOPL_NOT_ENABLED: return ENOEXEC; /* 197 */
case ERROR_INVALID_SEGDPL: return ENOEXEC; /* 198 */
case ERROR_AUTODATASEG_EXCEEDS_64k: return ENOEXEC; /* 199 */
case ERROR_RING2SEG_MUST_BE_MOVABLE: return ENOEXEC; /* 200 */
case ERROR_RELOC_CHAIN_XEEDS_SEGLIM: return ENOEXEC; /* 201 */
case ERROR_INFLOOP_IN_RELOC_CHAIN: return ENOEXEC; /* 202 */
case ERROR_FILENAME_EXCED_RANGE: return ENOENT; /* 206 */
case ERROR_NESTING_NOT_ALLOWED: return EAGAIN; /* 215 */
case ERROR_NOT_ENOUGH_QUOTA: return ENOMEM; /* 1816 */
default: return EINVAL;
}
}
int
erts_get_last_win_errno(void)
{
return erts_map_win_error_to_errno(GetLastError());
}
#endif