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pal_process.c
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pal_process.c
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// Licensed to the .NET Foundation under one or more agreements.
// The .NET Foundation licenses this file to you under the MIT license.
#include "pal_config.h"
#include "pal_process.h"
#include "pal_io.h"
#include "pal_utilities.h"
#include <assert.h>
#include <errno.h>
#include <grp.h>
#include <limits.h>
#include <signal.h>
#include <stdlib.h>
#include <sys/resource.h>
#include <sys/types.h>
#include <sys/wait.h>
#include <syslog.h>
#include <unistd.h>
#if HAVE_CRT_EXTERNS_H
#include <crt_externs.h>
#endif
#if HAVE_PIPE2
#include <fcntl.h>
#endif
#include <pthread.h>
#if HAVE_SCHED_SETAFFINITY || HAVE_SCHED_GETAFFINITY
#include <sched.h>
#endif
#ifdef __APPLE__
#include <mach-o/dyld.h>
#endif
#ifdef __FreeBSD__
#include <sys/types.h>
#include <sys/param.h>
#include <sys/sysctl.h>
#endif
#include <getexepath.h>
// Validate that our SysLogPriority values are correct for the platform
c_static_assert(PAL_LOG_EMERG == LOG_EMERG);
c_static_assert(PAL_LOG_ALERT == LOG_ALERT);
c_static_assert(PAL_LOG_CRIT == LOG_CRIT);
c_static_assert(PAL_LOG_ERR == LOG_ERR);
c_static_assert(PAL_LOG_WARNING == LOG_WARNING);
c_static_assert(PAL_LOG_NOTICE == LOG_NOTICE);
c_static_assert(PAL_LOG_INFO == LOG_INFO);
c_static_assert(PAL_LOG_DEBUG == LOG_DEBUG);
// Validate that out PriorityWhich values are correct for the platform
c_static_assert(PAL_PRIO_PROCESS == (int)PRIO_PROCESS);
c_static_assert(PAL_PRIO_PGRP == (int)PRIO_PGRP);
c_static_assert(PAL_PRIO_USER == (int)PRIO_USER);
#if !HAVE_PIPE2
static pthread_mutex_t ProcessCreateLock = PTHREAD_MUTEX_INITIALIZER;
#endif
enum
{
READ_END_OF_PIPE = 0,
WRITE_END_OF_PIPE = 1,
};
static void CloseIfOpen(int fd)
{
if (fd >= 0)
{
close(fd); // Ignoring errors from close is a deliberate choice
}
}
static int Dup2WithInterruptedRetry(int oldfd, int newfd)
{
int result;
while (CheckInterrupted(result = dup2(oldfd, newfd)));
return result;
}
static ssize_t WriteSize(int fd, const void* buffer, size_t count)
{
ssize_t rv = 0;
while (count > 0)
{
ssize_t result = 0;
while (CheckInterrupted(result = write(fd, buffer, count)));
if (result > 0)
{
rv += result;
buffer = (const uint8_t*)buffer + result;
count -= (size_t)result;
}
else
{
return -1;
}
}
return rv;
}
static ssize_t ReadSize(int fd, void* buffer, size_t count)
{
ssize_t rv = 0;
while (count > 0)
{
ssize_t result = 0;
while (CheckInterrupted(result = read(fd, buffer, count)));
if (result > 0)
{
rv += result;
buffer = (uint8_t*)buffer + result;
count -= (size_t)result;
}
else
{
return -1;
}
}
return rv;
}
__attribute__((noreturn))
static void ExitChild(int pipeToParent, int error)
{
if (pipeToParent != -1)
{
WriteSize(pipeToParent, &error, sizeof(error));
}
_exit(error != 0 ? error : EXIT_FAILURE);
}
static int compare_groups(const void * a, const void * b)
{
// Cast to signed because we need a signed return value.
// It's okay to changed signedness (groups are uint), we just need an order.
return *(const int32_t*)a - *(const int32_t*)b;
}
static int SetGroups(uint32_t* userGroups, int32_t userGroupsLength, uint32_t* processGroups)
{
#if defined(__linux__) || defined(TARGET_WASM)
size_t platformGroupsLength = Int32ToSizeT(userGroupsLength);
#else // BSD
int platformGroupsLength = userGroupsLength;
#endif
int rv = setgroups(platformGroupsLength, userGroups);
// We fall back to using the current process' groups, if they are a subset of the user groups.
// We do this to support a user setting UserName to himself but not having setgroups permissions.
// And for dealing with platforms with low NGROUP_MAX (e.g. 16 on OSX).
if (rv == -1 && ((errno == EPERM) ||
(errno == EINVAL && userGroupsLength > NGROUPS_MAX)))
{
int processGroupsLength = getgroups(userGroupsLength, processGroups);
if (processGroupsLength >= 0)
{
if (userGroupsLength == 0)
{
// calling setgroups with zero size returns number of groups.
rv = processGroupsLength == 0 ? 0 : -1;
}
else
{
rv = 0;
// sort the groups so we can efficiently search them.
qsort(userGroups, (size_t)userGroupsLength, sizeof(uint32_t), compare_groups);
for (int i = 0; i < processGroupsLength; i++)
{
bool isUserGroup = NULL != bsearch(&processGroups[i], userGroups, (size_t)userGroupsLength, sizeof(uint32_t), compare_groups);
if (!isUserGroup)
{
rv = -1;
break;
}
}
}
}
}
// Truncate on platforms with a low NGROUPS_MAX.
if (rv == -1 && (errno == EINVAL && userGroupsLength > NGROUPS_MAX))
{
platformGroupsLength = NGROUPS_MAX;
rv = setgroups(platformGroupsLength, userGroups);
}
return rv;
}
int32_t SystemNative_ForkAndExecProcess(const char* filename,
char* const argv[],
char* const envp[],
const char* cwd,
int32_t redirectStdin,
int32_t redirectStdout,
int32_t redirectStderr,
int32_t setCredentials,
uint32_t userId,
uint32_t groupId,
uint32_t* groups,
int32_t groupsLength,
int32_t* childPid,
int32_t* stdinFd,
int32_t* stdoutFd,
int32_t* stderrFd)
{
#if HAVE_FORK
#if !HAVE_PIPE2
bool haveProcessCreateLock = false;
#endif
bool success = true;
int stdinFds[2] = {-1, -1}, stdoutFds[2] = {-1, -1}, stderrFds[2] = {-1, -1}, waitForChildToExecPipe[2] = {-1, -1};
pid_t processId = -1;
uint32_t* getGroupsBuffer = NULL;
sigset_t signal_set;
sigset_t old_signal_set;
#if HAVE_PTHREAD_SETCANCELSTATE
int thread_cancel_state;
// None of this code can be canceled without leaking handles, so just don't allow it
pthread_setcancelstate(PTHREAD_CANCEL_DISABLE, &thread_cancel_state);
#endif
// Validate arguments
if (NULL == filename || NULL == argv || NULL == envp || NULL == stdinFd || NULL == stdoutFd ||
NULL == stderrFd || NULL == childPid || (groupsLength > 0 && groups == NULL))
{
assert(false && "null argument.");
errno = EINVAL;
success = false;
goto done;
}
if ((redirectStdin & ~1) != 0 || (redirectStdout & ~1) != 0 || (redirectStderr & ~1) != 0 || (setCredentials & ~1) != 0)
{
assert(false && "Boolean redirect* inputs must be 0 or 1.");
errno = EINVAL;
success = false;
goto done;
}
if (setCredentials && groupsLength > 0)
{
getGroupsBuffer = malloc(sizeof(uint32_t) * Int32ToSizeT(groupsLength));
if (getGroupsBuffer == NULL)
{
success = false;
goto done;
}
}
// Make sure we can find and access the executable. exec will do this, of course, but at that point it's already
// in the child process, at which point it'll translate to the child process' exit code rather than to failing
// the Start itself. There's a race condition here, in that this could change prior to exec's checks, but there's
// little we can do about that. There are also more rigorous checks exec does, such as validating the executable
// format of the target; such errors will emerge via the child process' exit code.
if (access(filename, X_OK) != 0)
{
success = false;
goto done;
}
#if !HAVE_PIPE2
// We do not have pipe2(); take the lock to emulate it race free.
// If another process were to be launched between the pipe creation and the fcntl call to set CLOEXEC on it, that
// file descriptor will be inherited into the other child process, eventually causing a deadlock either in the loop
// below that waits for that pipe to be closed or in StreamReader.ReadToEnd() in the calling code.
if (pthread_mutex_lock(&ProcessCreateLock) != 0)
{
// This check is pretty much just checking for trashed memory.
success = false;
goto done;
}
haveProcessCreateLock = true;
#endif
// Open pipes for any requests to redirect stdin/stdout/stderr and set the
// close-on-exec flag to the pipe file descriptors.
if ((redirectStdin && SystemNative_Pipe(stdinFds, PAL_O_CLOEXEC) != 0) ||
(redirectStdout && SystemNative_Pipe(stdoutFds, PAL_O_CLOEXEC) != 0) ||
(redirectStderr && SystemNative_Pipe(stderrFds, PAL_O_CLOEXEC) != 0))
{
success = false;
goto done;
}
// We create a pipe purely for the benefit of knowing when the child process has called exec.
// We can use that to block waiting on the pipe to be closed, which lets us block the parent
// from returning until the child process is actually transitioned to the target program. This
// avoids problems where the parent process uses members of Process, like ProcessName, when the
// Process is still the clone of this one. This is a best-effort attempt, so ignore any errors.
// If the child fails to exec we use the pipe to pass the errno to the parent process.
#if HAVE_PIPE2
(void)! pipe2(waitForChildToExecPipe, O_CLOEXEC);
#else
(void)! SystemNative_Pipe(waitForChildToExecPipe, PAL_O_CLOEXEC);
#endif
// The fork child must not be signalled until it calls exec(): our signal handlers do not
// handle being raised in the child process correctly
sigfillset(&signal_set);
pthread_sigmask(SIG_SETMASK, &signal_set, &old_signal_set);
#if HAVE_VFORK && !(defined(__APPLE__)) // We don't trust vfork on OS X right now.
// This platform has vfork(). vfork() is either a synonym for fork or provides shared memory
// semantics. For a one gigabyte process, the expected performance gain of using shared memory
// vfork() rather than fork() is 99.5% merely due to avoiding page faults as the kernel does not
// need to set all writable pages in the parent process to copy-on-write because the child process
// is allowed to write to the parent process memory pages.
// The thing to remember about shared memory vfork() is the documentation is way out of date.
// It does the following things:
// * creates a new process in the memory space of the calling process.
// * blocks the calling thread (not process!) in an uninterruptable sleep
// * sets up the process records so the following happen:
// + execve() replaces the memory space in the child and unblocks the parent
// + process exit by any means unblocks the parent
// + ptrace() makes a security demand against the parent process
// + accessing the terminal with read() or write() fail in system-dependent ways
// Due to lack of documentation, setting signal handlers in the vfork() child is a bad idea. We don't
// do this, but it's worth pointing out.
// All platforms that provide shared memory vfork() check the parent process's context when
// ptrace() is used on the child, thus making setuid() safe to use after vfork(). The fabled vfork()
// security hole is the other way around; if a multithreaded host were to execute setuid()
// on another thread while a vfork() child is still pending, bad things are possible; however we
// do not do that.
#if defined (__GLIBC__)
if ((processId = vfork()) == 0) // processId == 0 if this is child process
#else
// musl libc has an undocumented failure mode around setuid(); we must exclude it.
if (setCredentials)
{
processId = fork();
}
else
{
processId = vfork();
}
if (processId == 0)
#endif
#else
if ((processId = fork()) == 0) // processId == 0 if this is child process
#endif
{
// It turns out that child processes depend on their sigmask being set to something sane rather than mask all.
// On the other hand, we have to mask all to avoid our own signal handlers running in the child process, writing
// to the pipe, and waking up the handling thread in the parent process. This also avoids third-party code getting
// equally confused.
// Remove all signals, then restore signal mask.
// Since we are in a vfork() child, the only safe signal values are SIG_DFL and SIG_IGN. See man 3 libthr on BSD.
// "The implementation interposes the user-installed signal(3) handlers....to pospone signal delivery to threads
// which entered (libthr-internal) critical sections..." We want to pass SIG_DFL anyway.
sigset_t junk_signal_set;
struct sigaction sa_default;
struct sigaction sa_old;
memset(&sa_default, 0, sizeof(sa_default)); // On some architectures, sa_mask is a struct so assigning zero to it doesn't compile
sa_default.sa_handler = SIG_DFL;
for (int sig = 1; sig < NSIG; ++sig)
{
if (sig == SIGKILL || sig == SIGSTOP)
{
continue;
}
if (!sigaction(sig, NULL, &sa_old))
{
void (*oldhandler)(int) = (((unsigned int)sa_old.sa_flags) & SA_SIGINFO) ? (void (*)(int))sa_old.sa_sigaction : sa_old.sa_handler;
if (oldhandler != SIG_IGN && oldhandler != SIG_DFL)
{
// It has a custom handler, put the default handler back.
// We check first to preserve flags on default handlers.
sigaction(sig, &sa_default, NULL);
}
}
}
pthread_sigmask(SIG_SETMASK, &old_signal_set, &junk_signal_set); // Not all architectures allow NULL here
// For any redirections that should happen, dup the pipe descriptors onto stdin/out/err.
// We don't need to explicitly close out the old pipe descriptors as they will be closed on the 'execve' call.
if ((redirectStdin && Dup2WithInterruptedRetry(stdinFds[READ_END_OF_PIPE], STDIN_FILENO) == -1) ||
(redirectStdout && Dup2WithInterruptedRetry(stdoutFds[WRITE_END_OF_PIPE], STDOUT_FILENO) == -1) ||
(redirectStderr && Dup2WithInterruptedRetry(stderrFds[WRITE_END_OF_PIPE], STDERR_FILENO) == -1))
{
ExitChild(waitForChildToExecPipe[WRITE_END_OF_PIPE], errno);
}
if (setCredentials)
{
if (SetGroups(groups, groupsLength, getGroupsBuffer) == -1 ||
setgid(groupId) == -1 ||
setuid(userId) == -1)
{
ExitChild(waitForChildToExecPipe[WRITE_END_OF_PIPE], errno);
}
}
// Change to the designated working directory, if one was specified
if (NULL != cwd)
{
int result;
while (CheckInterrupted(result = chdir(cwd)));
if (result == -1)
{
ExitChild(waitForChildToExecPipe[WRITE_END_OF_PIPE], errno);
}
}
// Finally, execute the new process. execve will not return if it's successful.
execve(filename, argv, envp);
ExitChild(waitForChildToExecPipe[WRITE_END_OF_PIPE], errno); // execve failed
}
// Restore signal mask in the parent process immediately after fork() or vfork() call
pthread_sigmask(SIG_SETMASK, &old_signal_set, &signal_set);
if (processId < 0)
{
// failed
success = false;
goto done;
}
// This is the parent process. processId == pid of the child
*childPid = processId;
*stdinFd = stdinFds[WRITE_END_OF_PIPE];
*stdoutFd = stdoutFds[READ_END_OF_PIPE];
*stderrFd = stderrFds[READ_END_OF_PIPE];
done:;
#if !HAVE_PIPE2
if (haveProcessCreateLock)
{
pthread_mutex_unlock(&ProcessCreateLock);
}
#endif
int priorErrno = errno;
// Regardless of success or failure, close the parent's copy of the child's end of
// any opened pipes. The parent doesn't need them anymore.
CloseIfOpen(stdinFds[READ_END_OF_PIPE]);
CloseIfOpen(stdoutFds[WRITE_END_OF_PIPE]);
CloseIfOpen(stderrFds[WRITE_END_OF_PIPE]);
// Also close the write end of the exec waiting pipe, and wait for the pipe to be closed
// by trying to read from it (the read will wake up when the pipe is closed and broken).
// Ignore any errors... this is a best-effort attempt.
CloseIfOpen(waitForChildToExecPipe[WRITE_END_OF_PIPE]);
if (waitForChildToExecPipe[READ_END_OF_PIPE] != -1)
{
int childError;
if (success)
{
ssize_t result = ReadSize(waitForChildToExecPipe[READ_END_OF_PIPE], &childError, sizeof(childError));
if (result == sizeof(childError))
{
success = false;
priorErrno = childError;
}
}
CloseIfOpen(waitForChildToExecPipe[READ_END_OF_PIPE]);
}
// If we failed, close everything else and give back error values in all out arguments.
if (!success)
{
CloseIfOpen(stdinFds[WRITE_END_OF_PIPE]);
CloseIfOpen(stdoutFds[READ_END_OF_PIPE]);
CloseIfOpen(stderrFds[READ_END_OF_PIPE]);
// Reap child
if (processId > 0)
{
int status;
waitpid(processId, &status, 0);
}
*stdinFd = -1;
*stdoutFd = -1;
*stderrFd = -1;
*childPid = -1;
errno = priorErrno;
}
#if HAVE_PTHREAD_SETCANCELSTATE
// Restore thread cancel state
pthread_setcancelstate(thread_cancel_state, &thread_cancel_state);
#endif
free(getGroupsBuffer);
return success ? 0 : -1;
#else
return -1;
#endif
}
// Each platform type has it's own RLIMIT values but the same name, so we need
// to convert our standard types into the platform specific ones.
static int32_t ConvertRLimitResourcesPalToPlatform(RLimitResources value)
{
switch (value)
{
case PAL_RLIMIT_CPU:
return RLIMIT_CPU;
case PAL_RLIMIT_FSIZE:
return RLIMIT_FSIZE;
case PAL_RLIMIT_DATA:
return RLIMIT_DATA;
case PAL_RLIMIT_STACK:
return RLIMIT_STACK;
case PAL_RLIMIT_CORE:
return RLIMIT_CORE;
case PAL_RLIMIT_AS:
return RLIMIT_AS;
#ifdef RLIMIT_RSS
case PAL_RLIMIT_RSS:
return RLIMIT_RSS;
#endif
#ifdef RLIMIT_MEMLOCK
case PAL_RLIMIT_MEMLOCK:
return RLIMIT_MEMLOCK;
#elif defined(RLIMIT_VMEM)
case PAL_RLIMIT_MEMLOCK:
return RLIMIT_VMEM;
#endif
#ifdef RLIMIT_NPROC
case PAL_RLIMIT_NPROC:
return RLIMIT_NPROC;
#endif
case PAL_RLIMIT_NOFILE:
return RLIMIT_NOFILE;
#if !defined(RLIMIT_RSS) || !(defined(RLIMIT_MEMLOCK) || defined(RLIMIT_VMEM)) || !defined(RLIMIT_NPROC)
default:
break;
#endif
}
assert_msg(false, "Unknown RLIMIT value", (int)value);
return -1;
}
#define LIMIT_MAX(T) _Generic(((T)0), \
unsigned int: UINT_MAX, \
unsigned long: ULONG_MAX, \
long: LONG_MAX, \
unsigned long long: ULLONG_MAX)
// Because RLIM_INFINITY is different per-platform, use the max value of a uint64 (which is RLIM_INFINITY on Ubuntu)
// to signify RLIM_INIFINITY; on OS X, where RLIM_INFINITY is slightly lower, we'll translate it to the correct value
// here.
static rlim_t ConvertFromManagedRLimitInfinityToPalIfNecessary(uint64_t value)
{
// rlim_t type can vary per platform, so we also treat anything outside its range as infinite.
if (value == UINT64_MAX || value > LIMIT_MAX(rlim_t))
return RLIM_INFINITY;
return (rlim_t)value;
}
// Because RLIM_INFINITY is different per-platform, use the max value of a uint64 (which is RLIM_INFINITY on Ubuntu)
// to signify RLIM_INIFINITY; on OS X, where RLIM_INFINITY is slightly lower, we'll translate it to the correct value
// here.
static uint64_t ConvertFromNativeRLimitInfinityToManagedIfNecessary(rlim_t value)
{
if (value == RLIM_INFINITY)
return UINT64_MAX;
assert(value >= 0);
return (uint64_t)value;
}
static void ConvertFromRLimitManagedToPal(const RLimit* pal, struct rlimit* native)
{
native->rlim_cur = ConvertFromManagedRLimitInfinityToPalIfNecessary(pal->CurrentLimit);
native->rlim_max = ConvertFromManagedRLimitInfinityToPalIfNecessary(pal->MaximumLimit);
}
static void ConvertFromPalRLimitToManaged(const struct rlimit* native, RLimit* pal)
{
pal->CurrentLimit = ConvertFromNativeRLimitInfinityToManagedIfNecessary(native->rlim_cur);
pal->MaximumLimit = ConvertFromNativeRLimitInfinityToManagedIfNecessary(native->rlim_max);
}
#if defined(__USE_GNU) && !defined(__cplusplus) && !defined(TARGET_ANDROID)
typedef __rlimit_resource_t rlimitResource;
typedef __priority_which_t priorityWhich;
#else
typedef int rlimitResource;
typedef int priorityWhich;
#endif
int32_t SystemNative_GetRLimit(RLimitResources resourceType, RLimit* limits)
{
assert(limits != NULL);
int32_t platformLimit = ConvertRLimitResourcesPalToPlatform(resourceType);
struct rlimit internalLimit;
int result = getrlimit((rlimitResource)platformLimit, &internalLimit);
if (result == 0)
{
ConvertFromPalRLimitToManaged(&internalLimit, limits);
}
else
{
memset(limits, 0, sizeof(RLimit));
}
return result;
}
int32_t SystemNative_SetRLimit(RLimitResources resourceType, const RLimit* limits)
{
assert(limits != NULL);
int32_t platformLimit = ConvertRLimitResourcesPalToPlatform(resourceType);
struct rlimit internalLimit;
ConvertFromRLimitManagedToPal(limits, &internalLimit);
return setrlimit((rlimitResource)platformLimit, &internalLimit);
}
int32_t SystemNative_Kill(int32_t pid, int32_t signal)
{
switch (signal)
{
case PAL_NONE:
signal = 0;
break;
case PAL_SIGKILL:
signal = SIGKILL;
break;
case PAL_SIGSTOP:
signal = SIGSTOP;
break;
default:
assert_msg(false, "Unknown signal", signal);
errno = EINVAL;
return -1;
}
return kill(pid, signal);
}
int32_t SystemNative_GetPid()
{
return getpid();
}
int32_t SystemNative_GetSid(int32_t pid)
{
return getsid(pid);
}
void SystemNative_SysLog(SysLogPriority priority, const char* message, const char* arg1)
{
syslog((int)(LOG_USER | priority), message, arg1);
}
int32_t SystemNative_WaitIdAnyExitedNoHangNoWait()
{
siginfo_t siginfo;
memset(&siginfo, 0, sizeof(siginfo));
int32_t result;
while (CheckInterrupted(result = waitid(P_ALL, 0, &siginfo, WEXITED | WNOHANG | WNOWAIT)));
if (result == 0)
{
// When there are no waitable children and WNOHANG is specified,
// waitid may return zero with si_pid unchanged.
assert(siginfo.si_pid == 0 || // no waitable child
siginfo.si_signo == SIGCHLD); // waitable child
result = siginfo.si_pid;
}
else if (errno == ECHILD)
{
// The calling process has no existing unwaited-for child processes.
result = 0;
}
return result;
}
int32_t SystemNative_WaitPidExitedNoHang(int32_t pid, int32_t* exitCode)
{
assert(exitCode != NULL);
int32_t result;
int status;
while (CheckInterrupted(result = waitpid(pid, &status, WNOHANG)));
if (result > 0)
{
if (WIFEXITED(status))
{
// the child terminated normally.
*exitCode = WEXITSTATUS(status);
}
else if (WIFSIGNALED(status))
{
// child process was terminated by a signal.
*exitCode = 128 + WTERMSIG(status);
}
else
{
assert(false);
}
}
return result;
}
int64_t SystemNative_PathConf(const char* path, PathConfName name)
{
int32_t confValue = -1;
switch (name)
{
case PAL_PC_LINK_MAX:
confValue = _PC_LINK_MAX;
break;
case PAL_PC_MAX_CANON:
confValue = _PC_MAX_CANON;
break;
case PAL_PC_MAX_INPUT:
confValue = _PC_MAX_INPUT;
break;
case PAL_PC_NAME_MAX:
confValue = _PC_NAME_MAX;
break;
case PAL_PC_PATH_MAX:
confValue = _PC_PATH_MAX;
break;
case PAL_PC_PIPE_BUF:
confValue = _PC_PIPE_BUF;
break;
case PAL_PC_CHOWN_RESTRICTED:
confValue = _PC_CHOWN_RESTRICTED;
break;
case PAL_PC_NO_TRUNC:
confValue = _PC_NO_TRUNC;
break;
case PAL_PC_VDISABLE:
confValue = _PC_VDISABLE;
break;
}
if (confValue == -1)
{
assert_msg(false, "Unknown PathConfName", (int)name);
errno = EINVAL;
return -1;
}
return pathconf(path, confValue);
}
int32_t SystemNative_GetPriority(PriorityWhich which, int32_t who)
{
// GetPriority uses errno 0 to show success to make sure we don't have a stale value
errno = 0;
#if PRIORITY_REQUIRES_INT_WHO
return getpriority((priorityWhich)which, who);
#else
return getpriority((priorityWhich)which, (id_t)who);
#endif
}
int32_t SystemNative_SetPriority(PriorityWhich which, int32_t who, int32_t nice)
{
#if PRIORITY_REQUIRES_INT_WHO
return setpriority((priorityWhich)which, who, nice);
#else
return setpriority((priorityWhich)which, (id_t)who, nice);
#endif
}
char* SystemNative_GetCwd(char* buffer, int32_t bufferSize)
{
assert(bufferSize >= 0);
if (bufferSize < 0)
{
errno = EINVAL;
return NULL;
}
return getcwd(buffer, Int32ToSizeT(bufferSize));
}
#if HAVE_SCHED_SETAFFINITY
int32_t SystemNative_SchedSetAffinity(int32_t pid, intptr_t* mask)
{
assert(mask != NULL);
int maxCpu = sizeof(intptr_t) * 8;
assert(maxCpu <= CPU_SETSIZE);
cpu_set_t set;
CPU_ZERO(&set);
intptr_t bits = *mask;
for (int cpu = 0; cpu < maxCpu; cpu++)
{
if ((bits & (((intptr_t)1u) << cpu)) != 0)
{
CPU_SET(cpu, &set);
}
}
return sched_setaffinity(pid, sizeof(cpu_set_t), &set);
}
#else
int32_t SystemNative_SchedSetAffinity(int32_t pid, intptr_t* mask)
{
(void)pid;
(void)mask;
errno = ENOTSUP;
return -1;
}
#endif
#if HAVE_SCHED_GETAFFINITY
int32_t SystemNative_SchedGetAffinity(int32_t pid, intptr_t* mask)
{
assert(mask != NULL);
cpu_set_t set;
int32_t result = sched_getaffinity(pid, sizeof(cpu_set_t), &set);
if (result == 0)
{
int maxCpu = sizeof(intptr_t) * 8;
assert(maxCpu <= CPU_SETSIZE);
intptr_t bits = 0;
for (int cpu = 0; cpu < maxCpu; cpu++)
{
if (CPU_ISSET(cpu, &set))
{
bits |= ((intptr_t)1) << cpu;
}
}
*mask = bits;
}
else
{
*mask = 0;
}
return result;
}
#else
int32_t SystemNative_SchedGetAffinity(int32_t pid, intptr_t* mask)
{
(void)pid;
(void)mask;
errno = ENOTSUP;
return -1;
}
#endif
char* SystemNative_GetProcessPath()
{
return getexepath();
}