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sortix--sortix/kernel/process.cpp
Jonas 'Sortie' Termansen 5e7605fad2 Implement threading primitives that truly sleep.
The idle thread is now actually run when the system is idle because it
truly goes idle. The idle thread is made power efficient by using the hlt
instruction rather than a busy loop.

The new futex(2) system call is used to implement fast user-space mutexes,
condition variables, and semaphores. The same backend and design is used as
kutexes for truly sleeping kernel mutexes and condition variables.

The new exit_thread(2) flag EXIT_THREAD_FUTEX_WAKE wakes a futex.

Sleeping on clocks in the kernel now uses timers for true sleep.

The interrupt worker thread now truly sleeps when idle.

Kernel threads are now named.

This is a compatible ABI change.
2021-06-23 22:10:47 +02:00

1822 lines
48 KiB
C++

/*
* Copyright (c) 2011-2016, 2021 Jonas 'Sortie' Termansen.
*
* Permission to use, copy, modify, and distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*
* process.cpp
* A named collection of threads.
*/
#include <sys/wait.h>
#include <assert.h>
#include <ctype.h>
#include <errno.h>
#include <limits.h>
#include <msr.h>
#include <scram.h>
#include <signal.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <sortix/clock.h>
#include <sortix/fcntl.h>
#include <sortix/fork.h>
#include <sortix/mman.h>
#include <sortix/resource.h>
#include <sortix/signal.h>
#include <sortix/stat.h>
#include <sortix/unistd.h>
#include <sortix/uthread.h>
#include <sortix/wait.h>
#include <sortix/kernel/addralloc.h>
#include <sortix/kernel/copy.h>
#include <sortix/kernel/descriptor.h>
#include <sortix/kernel/dtable.h>
#include <sortix/kernel/elf.h>
#include <sortix/kernel/ioctx.h>
#include <sortix/kernel/kernel.h>
#include <sortix/kernel/kthread.h>
#include <sortix/kernel/memorymanagement.h>
#include <sortix/kernel/mtable.h>
#include <sortix/kernel/process.h>
#include <sortix/kernel/ptable.h>
#include <sortix/kernel/refcount.h>
#include <sortix/kernel/scheduler.h>
#include <sortix/kernel/sortedlist.h>
#include <sortix/kernel/string.h>
#include <sortix/kernel/syscall.h>
#include <sortix/kernel/thread.h>
#include <sortix/kernel/time.h>
#include <sortix/kernel/worker.h>
#if defined(__i386__) || defined(__x86_64__)
#include "x86-family/float.h"
#include "x86-family/gdt.h"
#endif
namespace Sortix {
kthread_mutex_t process_family_lock = KTHREAD_MUTEX_INITIALIZER;
// The system is shutting down and creation of additional processes and threads
// should be prevented. Protected by process_family_lock.
static bool is_init_exiting = false;
Process::Process()
{
program_image_path = NULL;
addrspace = 0;
pid = 0;
nicelock = KTHREAD_MUTEX_INITIALIZER;
nice = 0;
idlock = KTHREAD_MUTEX_INITIALIZER;
uid = euid = 0;
gid = egid = 0;
umask = 0022;
ptrlock = KTHREAD_MUTEX_INITIALIZER;
// tty set to null reference in the member constructor.
// root set to null reference in the member constructor.
// cwd set to null reference in the member constructor.
// mtable set to null reference in the member constructor.
// dtable set to null reference in the member constructor.
// ptable set to null reference in the member constructor.
resource_limits_lock = KTHREAD_MUTEX_INITIALIZER;
for ( size_t i = 0; i < RLIMIT_NUM_DECLARED; i++ )
{
resource_limits[i].rlim_cur = RLIM_INFINITY;
resource_limits[i].rlim_max = RLIM_INFINITY;
}
signal_lock = KTHREAD_MUTEX_INITIALIZER;
memset(&signal_actions, 0, sizeof(signal_actions));
for ( int i = 0; i < SIG_MAX_NUM; i++ )
{
sigemptyset(&signal_actions[i].sa_mask);
signal_actions[i].sa_handler = SIG_DFL;
signal_actions[i].sa_cookie = NULL;
signal_actions[i].sa_flags = 0;
}
sigemptyset(&signal_pending);
sigreturn = NULL;
parent = NULL;
prevsibling = NULL;
nextsibling = NULL;
firstchild = NULL;
zombiechild = NULL;
group = NULL;
groupprev = NULL;
groupnext = NULL;
groupfirst = NULL;
session = NULL;
sessionprev = NULL;
sessionnext = NULL;
sessionfirst = NULL;
zombiecond = KTHREAD_COND_INITIALIZER;
iszombie = false;
nozombify = false;
limbo = false;
exit_code = -1;
firstthread = NULL;
threadlock = KTHREAD_MUTEX_INITIALIZER;
threads_not_exiting_count = 0;
threads_exiting = false;
futex_lock = KTHREAD_MUTEX_INITIALIZER;
futex_first_waiting = NULL;
futex_last_waiting = NULL;
segments = NULL;
segments_used = 0;
segments_length = 0;
segment_write_lock = KTHREAD_MUTEX_INITIALIZER;
segment_lock = KTHREAD_MUTEX_INITIALIZER;
user_timers_lock = KTHREAD_MUTEX_INITIALIZER;
memset(&user_timers, 0, sizeof(user_timers));
// alarm_timer initialized in member constructor.
// execute_clock initialized in member constructor.
// system_clock initialized in member constructor.
// child_execute_clock initialized in member constructor.
// child_system_clock initialized in member constructor.
Time::InitializeProcessClocks(this);
alarm_timer.Attach(Time::GetClock(CLOCK_MONOTONIC));
}
Process::~Process() // process_family_lock taken
{
if ( alarm_timer.IsAttached() )
alarm_timer.Detach();
delete[] program_image_path;
assert(!zombiechild);
assert(!session);
assert(!group);
assert(!parent);
assert(!sessionfirst);
assert(!groupfirst);
assert(!firstchild);
assert(!addrspace);
assert(!segments);
assert(!dtable);
assert(!mtable);
assert(!cwd);
assert(!root);
assert(!threads_not_exiting_count);
assert(ptable);
ptable->Free(pid);
ptable.Reset();
tty.Reset();
}
void Process::BootstrapTables(Ref<DescriptorTable> dtable, Ref<MountTable> mtable)
{
ScopedLock lock(&ptrlock);
assert(!this->dtable);
assert(!this->mtable);
this->dtable = dtable;
this->mtable = mtable;
}
void Process::BootstrapDirectories(Ref<Descriptor> root)
{
ScopedLock lock(&ptrlock);
assert(!this->root);
assert(!this->cwd);
this->root = root;
this->cwd = root;
}
void Process::OnLastThreadExit()
{
Process* init = Scheduler::GetInitProcess();
assert(init);
// Child processes can't be reparented away if we're init. The system is
// about to shut down, so broadcast SIGKILL every process and wait for every
// single process to exit. The operating system is finished when init has
// exited.
if ( init == this )
{
ScopedLock lock(&process_family_lock);
// Forbid any more processes and threads from being created, so this
// loop will always terminate.
is_init_exiting = true;
kthread_mutex_lock(&ptrlock);
for ( pid_t pid = ptable->Next(0); 0 < pid; pid = ptable->Next(pid) )
{
Process* process = ptable->Get(pid);
if ( process->pid != 0 && process != init )
process->DeliverSignal(SIGKILL);
}
kthread_mutex_unlock(&ptrlock);
// NotifyChildExit always signals zombiecond for init when
// is_init_exiting is true.
while ( firstchild )
kthread_cond_wait(&zombiecond, &process_family_lock);
}
}
void Process::OnThreadDestruction(Thread* thread)
{
assert(thread->process == this);
kthread_mutex_lock(&threadlock);
if ( thread->prevsibling )
thread->prevsibling->nextsibling = thread->nextsibling;
if ( thread->nextsibling )
thread->nextsibling->prevsibling = thread->prevsibling;
if ( thread == firstthread )
firstthread = thread->nextsibling;
if ( firstthread )
firstthread->prevsibling = NULL;
thread->prevsibling = thread->nextsibling = NULL;
bool threadsleft = firstthread;
kthread_mutex_unlock(&threadlock);
// We are called from the threads destructor, let it finish before we
// we handle the situation by killing ourselves.
if ( !threadsleft )
ScheduleDeath();
}
void Process__AfterLastThreadExit(void* user)
{
return ((Process*) user)->AfterLastThreadExit();
}
void Process::ScheduleDeath()
{
// All our threads must have exited at this point.
assert(!firstthread);
Worker::Schedule(Process__AfterLastThreadExit, this);
}
// Useful for killing a partially constructed process without waiting for
// it to die and garbage collect its zombie. It is not safe to access this
// process after this call as another thread may garbage collect it.
void Process::AbortConstruction()
{
nozombify = true;
ScheduleDeath();
}
void Process::AfterLastThreadExit()
{
LastPrayer();
}
void Process::DeleteTimers()
{
for ( timer_t i = 0; i < PROCESS_TIMER_NUM_MAX; i++ )
{
if ( user_timers[i].timer.IsAttached() )
{
user_timers[i].timer.Cancel();
user_timers[i].timer.Detach();
}
}
}
// This function runs in a worker thread and cannot block on another worker
// thread, or it may deadlock.
void Process::LastPrayer()
{
assert(this);
// This must never be called twice.
assert(!iszombie);
// This must be called from a thread using another address space as the
// address space of this process is about to be destroyed.
Thread* curthread = CurrentThread();
assert(curthread->process != this);
// This can't be called if the process is still alive.
assert(!firstthread);
// Disarm and detach all the timers in the process.
DeleteTimers();
if ( alarm_timer.IsAttached() )
{
alarm_timer.Cancel();
alarm_timer.Detach();
}
// We need to temporarily reload the correct addrese space of the dying
// process such that we can unmap and free its memory.
addr_t prevaddrspace = Memory::SwitchAddressSpace(addrspace);
ResetAddressSpace();
// tty is kept alive in session leader until no longer in limbo.
if ( dtable ) dtable.Reset();
if ( cwd ) cwd.Reset();
if ( root ) root.Reset();
if ( mtable ) mtable.Reset();
// Destroy the address space and safely switch to the replacement
// address space before things get dangerous.
Memory::DestroyAddressSpace(prevaddrspace);
addrspace = 0;
ScopedLock family_lock(&process_family_lock);
iszombie = true;
// Init is nice and will gladly raise our orphaned children and zombies.
Process* init = Scheduler::GetInitProcess();
assert(init);
// Child processes can't be reparented away if we're init. OnLastThreadExit
// must have already killed all the child processes and prevented more from
// being created.
if ( init == this )
{
assert(is_init_exiting);
assert(!firstchild);
}
while ( firstchild )
{
Process* process = firstchild;
firstchild = process->nextsibling;
process->parent = init;
process->prevsibling = NULL;
process->nextsibling = init->firstchild;
if ( init->firstchild )
init->firstchild->prevsibling = process;
init->firstchild = process;
process->nozombify = true;
}
// Since we have no more children (they are with init now), we don't
// have to worry about new zombie processes showing up, so just collect
// those that are left. Then we satisfiy the invariant !zombiechild that
// applies on process termination.
while ( zombiechild )
{
Process* zombie = zombiechild;
zombiechild = zombie->nextsibling;
zombie->nextsibling = NULL;
if ( zombiechild )
zombiechild->prevsibling = NULL;
zombie->nozombify = true;
zombie->WaitedFor();
}
// Remove ourself from our process group.
if ( group )
group->GroupRemoveMember(this);
// Remove ourself from our session.
if ( session )
session->SessionRemoveMember(this);
bool zombify = !nozombify;
// This class instance will be destroyed by our parent process when it
// has received and acknowledged our death.
if ( parent )
parent->NotifyChildExit(this, zombify);
// If nobody is waiting for us, then simply commit suicide.
if ( !zombify )
WaitedFor();
}
void Process::WaitedFor() // process_family_lock taken
{
parent = NULL;
limbo = false;
if ( groupfirst || sessionfirst )
limbo = true;
if ( !limbo )
delete this;
}
void Process::ResetAddressSpace()
{
ScopedLock lock1(&segment_write_lock);
ScopedLock lock2(&segment_lock);
assert(Memory::GetAddressSpace() == addrspace);
for ( size_t i = 0; i < segments_used; i++ )
Memory::UnmapRange(segments[i].addr, segments[i].size, PAGE_USAGE_USER_SPACE);
Memory::Flush();
segments_used = segments_length = 0;
free(segments);
segments = NULL;
}
void Process::GroupRemoveMember(Process* child) // process_family_lock taken
{
assert(child->group == this);
if ( child->groupprev )
child->groupprev->groupnext = child->groupnext;
else
groupfirst = child->groupnext;
if ( child->groupnext )
child->groupnext->groupprev = child->groupprev;
child->group = NULL;
if ( IsLimboDone() )
delete this;
}
void Process::SessionRemoveMember(Process* child) // process_family_lock taken
{
assert(child->session == this);
if ( child->sessionprev )
child->sessionprev->sessionnext = child->sessionnext;
else
sessionfirst = child->sessionnext;
if ( child->sessionnext )
child->sessionnext->sessionprev = child->sessionprev;
child->session = NULL;
if ( !sessionfirst )
{
// Remove reference to tty when session is empty.
ScopedLock lock(&ptrlock);
tty.Reset();
}
if ( IsLimboDone() )
delete this;
}
bool Process::IsLimboDone() // process_family_lock taken
{
return limbo && !groupfirst && !sessionfirst;
}
// process_family_lock taken
void Process::NotifyChildExit(Process* child, bool zombify)
{
if ( child->prevsibling )
child->prevsibling->nextsibling = child->nextsibling;
if ( child->nextsibling )
child->nextsibling->prevsibling = child->prevsibling;
if ( firstchild == child )
firstchild = child->nextsibling;
if ( firstchild )
firstchild->prevsibling = NULL;
if ( zombify )
{
if ( zombiechild )
zombiechild->prevsibling = child;
child->prevsibling = NULL;
child->nextsibling = zombiechild;
zombiechild = child;
}
// Notify this parent process about the child exiting if it's meant to
// become a zombie process. Additionally, always notify init about children
// when init is exiting, because OnLastThreadExit needs to be able to catch
// every child exiting.
if ( zombify || (is_init_exiting && Scheduler::GetInitProcess() == this) )
{
DeliverSignal(SIGCHLD);
kthread_cond_broadcast(&zombiecond);
}
}
pid_t Process::Wait(pid_t thepid, int* status_ptr, int options)
{
// TODO: Process groups are not supported yet.
if ( thepid < -1 || thepid == 0 )
return errno = ENOSYS, -1;
ScopedLock lock(&process_family_lock);
// A process can only wait if it has children.
if ( !firstchild && !zombiechild )
return errno = ECHILD, -1;
// Processes can only wait for their own children to exit.
if ( 0 < thepid )
{
// TODO: This is a slow but multithread safe way to verify that the
// target process has the correct parent.
bool found = false;
for ( Process* p = firstchild; !found && p; p = p->nextsibling )
if ( p->pid == thepid && !p->nozombify )
found = true;
for ( Process* p = zombiechild; !found && p; p = p->nextsibling )
if ( p->pid == thepid && !p->nozombify )
found = true;
if ( !found )
return errno = ECHILD, -1;
}
Process* zombie = NULL;
while ( !zombie )
{
for ( zombie = zombiechild; zombie; zombie = zombie->nextsibling )
if ( (thepid == -1 || thepid == zombie->pid) && !zombie->nozombify )
break;
if ( zombie )
break;
if ( options & WNOHANG )
return 0;
if ( !kthread_cond_wait_signal(&zombiecond, &process_family_lock) )
return errno = EINTR, -1;
}
// Remove from the list of zombies.
if ( zombie->prevsibling )
zombie->prevsibling->nextsibling = zombie->nextsibling;
if ( zombie->nextsibling )
zombie->nextsibling->prevsibling = zombie->prevsibling;
if ( zombiechild == zombie )
zombiechild = zombie->nextsibling;
if ( zombiechild )
zombiechild->prevsibling = NULL;
thepid = zombie->pid;
// It is safe to access these clocks directly as the child process is no
// longer running at this point and the values are nicely frozen.
child_execute_clock.Advance(zombie->child_execute_clock.current_time);
child_system_clock.Advance(zombie->child_system_clock.current_time);
int status = zombie->exit_code;
if ( status < 0 )
status = WCONSTRUCT(WNATURE_SIGNALED, 128 + SIGKILL, SIGKILL);
zombie->WaitedFor();
if ( status_ptr )
*status_ptr = status;
return thepid;
}
pid_t sys_waitpid(pid_t pid, int* user_status, int options)
{
int status = 0;
pid_t ret = CurrentProcess()->Wait(pid, &status, options);
if ( 0 < ret &&
user_status &&
!CopyToUser(user_status, &status, sizeof(status)) )
return -1;
return ret;
}
void Process::ExitThroughSignal(int signal)
{
ExitWithCode(WCONSTRUCT(WNATURE_SIGNALED, 128 + signal, signal));
}
void Process::ExitWithCode(int requested_exit_code)
{
ScopedLock lock(&threadlock);
if ( exit_code == -1 )
exit_code = requested_exit_code;
// Broadcast SIGKILL to all our threads which will begin our long path
// of process termination. We simply can't stop the threads as they may
// be running in kernel mode doing dangerous stuff. This thread will be
// destroyed by SIGKILL once the system call returns.
for ( Thread* t = firstthread; t; t = t->nextsibling )
t->DeliverSignal(SIGKILL);
}
Ref<MountTable> Process::GetMTable()
{
ScopedLock lock(&ptrlock);
assert(mtable);
return mtable;
}
Ref<DescriptorTable> Process::GetDTable()
{
ScopedLock lock(&ptrlock);
assert(dtable);
return dtable;
}
Ref<ProcessTable> Process::GetPTable()
{
ScopedLock lock(&ptrlock);
assert(ptable);
return ptable;
}
Ref<Descriptor> Process::GetTTY()
{
ScopedLock lock(&ptrlock);
return tty;
}
Ref<Descriptor> Process::GetRoot()
{
ScopedLock lock(&ptrlock);
assert(root);
return root;
}
Ref<Descriptor> Process::GetCWD()
{
ScopedLock lock(&ptrlock);
assert(cwd);
return cwd;
}
void Process::SetTTY(Ref<Descriptor> newtty)
{
ScopedLock lock(&ptrlock);
tty = newtty;
}
void Process::SetRoot(Ref<Descriptor> newroot)
{
ScopedLock lock(&ptrlock);
assert(newroot);
root = newroot;
}
void Process::SetCWD(Ref<Descriptor> newcwd)
{
ScopedLock lock(&ptrlock);
assert(newcwd);
cwd = newcwd;
}
Ref<Descriptor> Process::GetDescriptor(int fd)
{
ScopedLock lock(&ptrlock);
assert(dtable);
return dtable->Get(fd);
}
Process* Process::Fork()
{
assert(CurrentProcess() == this);
Process* clone = new Process;
if ( !clone )
return NULL;
struct segment* clone_segments = NULL;
// Fork the segment list.
if ( segments )
{
size_t segments_size = sizeof(struct segment) * segments_used;
if ( !(clone_segments = (struct segment*) malloc(segments_size)) )
{
delete clone;
return NULL;
}
memcpy(clone_segments, segments, segments_size);
}
// Fork address-space here and copy memory.
clone->addrspace = Memory::Fork();
if ( !clone->addrspace )
{
free(clone_segments);
delete clone;
return NULL;
}
// Now it's too late to clean up here, if anything goes wrong, we simply
// ask the process to commit suicide before it goes live.
clone->segments = clone_segments;
clone->segments_used = segments_used;
clone->segments_length = segments_used;
kthread_mutex_lock(&process_family_lock);
// Forbid the creation of new processes if init has exited.
if ( is_init_exiting )
{
kthread_mutex_unlock(&process_family_lock);
clone->AbortConstruction();
return NULL;
}
// Register the new process by assigning a pid.
if ( (clone->pid = (clone->ptable = ptable)->Allocate(clone)) < 0 )
{
kthread_mutex_unlock(&process_family_lock);
clone->AbortConstruction();
return NULL;
}
// Remember the relation to the child process.
clone->parent = this;
clone->nextsibling = firstchild;
clone->prevsibling = NULL;
if ( firstchild )
firstchild->prevsibling = clone;
firstchild = clone;
// Add the new process to the current process group.
clone->group = group;
clone->groupprev = NULL;
if ( (clone->groupnext = group->groupfirst) )
group->groupfirst->groupprev = clone;
group->groupfirst = clone;
// Add the new process to the current session.
clone->session = session;
clone->sessionprev = NULL;
if ( (clone->sessionnext = session->sessionfirst) )
session->sessionfirst->sessionprev = clone;
session->sessionfirst = clone;
kthread_mutex_unlock(&process_family_lock);
// Initialize everything that is safe and can't fail.
kthread_mutex_lock(&resource_limits_lock);
for ( size_t i = 0; i < RLIMIT_NUM_DECLARED; i++ )
clone->resource_limits[i] = resource_limits[i];
kthread_mutex_unlock(&resource_limits_lock);
kthread_mutex_lock(&nicelock);
clone->nice = nice;
kthread_mutex_unlock(&nicelock);
kthread_mutex_lock(&ptrlock);
clone->root = root;
clone->cwd = cwd;
kthread_mutex_unlock(&ptrlock);
kthread_mutex_lock(&idlock);
clone->uid = uid;
clone->gid = gid;
clone->euid = euid;
clone->egid = egid;
clone->umask = umask;
kthread_mutex_unlock(&idlock);
kthread_mutex_lock(&signal_lock);
memcpy(&clone->signal_actions, &signal_actions, sizeof(signal_actions));
sigemptyset(&clone->signal_pending);
clone->sigreturn = sigreturn;
kthread_mutex_unlock(&signal_lock);
// Initialize things that can fail and abort if needed.
bool failure = false;
kthread_mutex_lock(&ptrlock);
if ( !(clone->dtable = dtable->Fork()) )
failure = true;
//if ( !(clone->mtable = mtable->Fork()) )
// failure = true;
clone->mtable = mtable;
kthread_mutex_unlock(&ptrlock);
if ( !(clone->program_image_path = String::Clone(program_image_path)) )
failure = true;
// If the proces creation failed, ask the process to commit suicide and
// not become a zombie, as we don't wait for it to exit. It will clean
// up all the above resources and delete itself.
if ( failure )
{
clone->AbortConstruction();
return NULL;
}
return clone;
}
void Process::ResetForExecute()
{
DeleteTimers();
for ( int i = 0; i < SIG_MAX_NUM; i++ )
{
signal_actions[i].sa_flags = 0;
if ( signal_actions[i].sa_handler == SIG_DFL )
continue;
if ( signal_actions[i].sa_handler == SIG_IGN )
continue;
signal_actions[i].sa_handler = SIG_DFL;
}
sigreturn = NULL;
stack_t* signal_stack = &CurrentThread()->signal_stack;
memset(signal_stack, 0, sizeof(*signal_stack));
signal_stack->ss_flags = SS_DISABLE;
ResetAddressSpace();
}
bool Process::MapSegment(struct segment* result, void* hint, size_t size,
int flags, int prot)
{
// process->segment_write_lock is held at this point.
// process->segment_lock is held at this point.
if ( !size )
size = 1;
if ( !PlaceSegment(result, this, hint, size, flags) )
return false;
if ( !Memory::MapMemory(this, result->addr, result->size, result->prot = prot) )
{
// The caller is expected to self-destruct in this case, so the
// segment just created is not removed.
return false;
}
Memory::Flush();
return true;
}
int Process::Execute(const char* programname, const uint8_t* program,
size_t programsize, int argc, const char* const* argv,
int envc, const char* const* envp,
struct thread_registers* regs)
{
assert(argc != INT_MAX);
assert(envc != INT_MAX);
assert(CurrentProcess() == this);
char* programname_clone = String::Clone(programname);
if ( !programname_clone )
return -1;
ELF::Auxiliary aux;
addr_t entry = ELF::Load(program, programsize, &aux);
if ( !entry ) { delete[] programname_clone; return -1; }
delete[] program_image_path;
program_image_path = programname_clone; programname_clone = NULL;
uintptr_t userspace_addr;
size_t userspace_size;
Memory::GetUserVirtualArea(&userspace_addr, &userspace_size);
const size_t stack_size = 512UL * 1024UL;
void* stack_hint = (void*) (userspace_addr + userspace_size - stack_size);
const int stack_prot = PROT_READ | PROT_WRITE | PROT_KREAD | PROT_KWRITE | PROT_FORK;
if ( !aux.tls_mem_align )
aux.tls_mem_align = 1;
if ( Page::Size() < aux.tls_mem_align )
return errno = EINVAL, -1;
if ( !aux.uthread_align )
aux.uthread_align = 1;
if ( Page::Size() < aux.uthread_align )
return errno = EINVAL, -1;
if ( aux.uthread_size < sizeof(struct uthread) )
aux.uthread_size = sizeof(struct uthread);
size_t raw_tls_size = aux.tls_mem_size;
size_t raw_tls_size_aligned = -(-raw_tls_size & ~(aux.tls_mem_align-1));
if ( raw_tls_size && raw_tls_size_aligned == 0 /* overflow */ )
return errno = EINVAL, -1;
int raw_tls_kprot = PROT_KWRITE | PROT_FORK;
int raw_tls_prot = PROT_READ | PROT_KREAD | PROT_FORK;
void* raw_tls_hint = stack_hint;
size_t tls_size = raw_tls_size_aligned + aux.uthread_size;
size_t tls_offset_tls = 0;
size_t tls_offset_uthread = raw_tls_size_aligned;
if ( aux.tls_mem_align < aux.uthread_align )
{
size_t more_aligned = -(-raw_tls_size_aligned & ~(aux.uthread_align-1));
if ( raw_tls_size_aligned && more_aligned == 0 /* overflow */ )
return errno = EINVAL, -1;
size_t difference = more_aligned - raw_tls_size_aligned;
tls_size += difference;
tls_offset_tls += difference;
tls_offset_uthread += difference;
}
assert((tls_offset_tls & (aux.tls_mem_align-1)) == 0);
assert((tls_offset_uthread & (aux.uthread_align-1)) == 0);
int tls_prot = PROT_READ | PROT_WRITE | PROT_KREAD | PROT_KWRITE | PROT_FORK;
void* tls_hint = stack_hint;
size_t auxcode_size = Page::Size();
int auxcode_kprot = PROT_KWRITE | PROT_FORK;
int auxcode_prot = PROT_EXEC | PROT_READ | PROT_KREAD | PROT_FORK;
void* auxcode_hint = stack_hint;
size_t arg_size = 0;
size_t argv_size = sizeof(char*) * (argc + 1);
size_t envp_size = sizeof(char*) * (envc + 1);
arg_size += argv_size;
arg_size += envp_size;
for ( int i = 0; i < argc; i++ )
arg_size += strlen(argv[i]) + 1;
for ( int i = 0; i < envc; i++ )
arg_size += strlen(envp[i]) + 1;
struct segment arg_segment;
struct segment stack_segment;
struct segment raw_tls_segment;
struct segment tls_segment;
struct segment auxcode_segment;
kthread_mutex_lock(&segment_write_lock);
kthread_mutex_lock(&segment_lock);
if ( !(MapSegment(&arg_segment, stack_hint, arg_size, 0, stack_prot) &&
MapSegment(&stack_segment, stack_hint, stack_size, 0, stack_prot) &&
MapSegment(&raw_tls_segment, raw_tls_hint, raw_tls_size, 0, raw_tls_kprot) &&
MapSegment(&tls_segment, tls_hint, tls_size, 0, tls_prot) &&
MapSegment(&auxcode_segment, auxcode_hint, auxcode_size, 0, auxcode_kprot)) )
{
kthread_mutex_unlock(&segment_lock);
kthread_mutex_unlock(&segment_write_lock);
ResetForExecute();
return errno = ENOMEM, -1;
}
char** target_argv = (char**) ((char*) arg_segment.addr + 0);
char** target_envp = (char**) ((char*) arg_segment.addr + argv_size);
char* target_strings = (char*) ((char*) arg_segment.addr + argv_size + envp_size);
size_t target_strings_offset = 0;
for ( int i = 0; i < argc; i++ )
{
const char* arg = argv[i];
size_t arg_len = strlen(arg);
char* target_arg = target_strings + target_strings_offset;
strcpy(target_arg, arg);
target_argv[i] = target_arg;
target_strings_offset += arg_len + 1;
}
target_argv[argc] = (char*) NULL;
for ( int i = 0; i < envc; i++ )
{
const char* env = envp[i];
size_t env_len = strlen(env);
char* target_env = target_strings + target_strings_offset;
strcpy(target_env, env);
target_envp[i] = target_env;
target_strings_offset += env_len + 1;
}
target_envp[envc] = (char*) NULL;
const uint8_t* file_raw_tls = program + aux.tls_file_offset;
uint8_t* target_raw_tls = (uint8_t*) raw_tls_segment.addr;
memcpy(target_raw_tls, file_raw_tls, aux.tls_file_size);
memset(target_raw_tls + aux.tls_file_size, 0, aux.tls_mem_size - aux.tls_file_size);
Memory::ProtectMemory(this, raw_tls_segment.addr, raw_tls_segment.size, raw_tls_prot);
uint8_t* target_tls = (uint8_t*) (tls_segment.addr + tls_offset_tls);
assert((((uintptr_t) target_tls) & (aux.tls_mem_align-1)) == 0);
memcpy(target_tls, file_raw_tls, aux.tls_file_size);
memset(target_tls + aux.tls_file_size, 0, aux.tls_mem_size - aux.tls_file_size);
struct uthread* uthread = (struct uthread*) (tls_segment.addr + tls_offset_uthread);
assert((((uintptr_t) uthread) & (aux.uthread_align-1)) == 0);
memset(uthread, 0, sizeof(*uthread));
uthread->uthread_pointer = uthread;
uthread->uthread_size = aux.uthread_size;
uthread->uthread_flags = UTHREAD_FLAG_INITIAL;
uthread->tls_master_mmap = (void*) raw_tls_segment.addr;
uthread->tls_master_size = aux.tls_mem_size;
uthread->tls_master_align = aux.tls_mem_align;
uthread->tls_mmap = (void*) tls_segment.addr;
uthread->tls_size = tls_size;
uthread->stack_mmap = (void*) stack_segment.addr;
uthread->stack_size = stack_segment.size;
uthread->arg_mmap = (void*) arg_segment.addr;
uthread->arg_size = arg_segment.size;
memset(uthread + 1, 0, aux.uthread_size - sizeof(struct uthread));
memset(regs, 0, sizeof(*regs));
#if defined(__i386__)
regs->eax = argc;
regs->ebx = (size_t) target_argv;
regs->edx = envc;
regs->ecx = (size_t) target_envp;
regs->eip = entry;
regs->esp = (stack_segment.addr + stack_segment.size) & ~15UL;
regs->ebp = regs->esp;
regs->cs = UCS | URPL;
regs->ds = UDS | URPL;
regs->ss = UDS | URPL;
regs->eflags = FLAGS_RESERVED1 | FLAGS_INTERRUPT | FLAGS_ID;
regs->signal_pending = 0;
regs->gsbase = (uint32_t) uthread;
regs->cr3 = addrspace;
regs->kernel_stack = GDT::GetKernelStack();
memcpy(regs->fpuenv, Float::fpu_initialized_regs, 512);
#elif defined(__x86_64__)
regs->rdi = argc;
regs->rsi = (size_t) target_argv;
regs->rdx = envc;
regs->rcx = (size_t) target_envp;
regs->rip = entry;
regs->rsp = (stack_segment.addr + stack_segment.size) & ~15UL;
regs->rbp = regs->rsp;
regs->cs = UCS | URPL;
regs->ds = UDS | URPL;
regs->ss = UDS | URPL;
regs->rflags = FLAGS_RESERVED1 | FLAGS_INTERRUPT | FLAGS_ID;
regs->signal_pending = 0;
regs->fsbase = (uint64_t) uthread;
regs->cr3 = addrspace;
regs->kernel_stack = GDT::GetKernelStack();
memcpy(regs->fpuenv, Float::fpu_initialized_regs, 512);
#else
#warning "You need to implement initializing the first thread after execute"
#endif
uint8_t* auxcode = (uint8_t*) auxcode_segment.addr;
#if defined(__i386__)
sigreturn = (void (*)(void)) &auxcode[0];
auxcode[0] = 0xCD; /* int .... */
auxcode[1] = 0x83; /* ... $131 */
#elif defined(__x86_64__)
sigreturn = (void (*)(void)) &auxcode[0];
auxcode[0] = 0xCD; /* int .... */
auxcode[1] = 0x83; /* ... $131 */
#else
(void) auxcode;
#warning "You need to initialize auxcode with a sigreturn routine"
#endif
Memory::ProtectMemory(this, auxcode_segment.addr, auxcode_segment.size, auxcode_prot);
kthread_mutex_unlock(&segment_lock);
kthread_mutex_unlock(&segment_write_lock);
dtable->OnExecute();
return 0;
}
static
const char* shebang_lookup_environment(const char* name, char* const* envp)
{
size_t equalpos = strcspn(name, "=");
if ( name[equalpos] == '=' )
return NULL;
size_t namelen = equalpos;
for ( size_t i = 0; envp[i]; i++ )
{
if ( strncmp(name, envp[i], namelen) )
continue;
if ( envp[i][namelen] != '=' )
continue;
return envp[i] + namelen + 1;
}
return NULL;
}
static char* shebang_tokenize(char** saved)
{
char* data = *saved;
if ( !data )
return *saved = NULL;
while ( data[0] && isspace((unsigned char) data[0]) )
data++;
if ( !data[0] )
return *saved = NULL;
size_t input = 0;
size_t output = 0;
bool singly = false;
bool doubly = false;
bool escaped = false;
for ( ; data[input]; input++ )
{
char c = data[input];
if ( !escaped && !singly && !doubly && isspace((unsigned char) c) )
break;
if ( !escaped && !doubly && c == '\'' )
{
singly = !singly;
continue;
}
if ( !escaped && !singly && c == '"' )
{
doubly = !doubly;
continue;
}
if ( !singly && !escaped && c == '\\' )
{
escaped = true;
continue;
}
if ( escaped )
{
switch ( c )
{
case 'a': c = '\a'; break;
case 'b': c = '\b'; break;
case 'e': c = '\e'; break;
case 'f': c = '\f'; break;
case 'n': c = '\n'; break;
case 'r': c = '\r'; break;
case 't': c = '\t'; break;
case 'v': c = '\v'; break;
default: break;
};
}
escaped = false;
data[output++] = c;
}
if ( data[input] )
*saved = data + input + 1;
else
*saved = NULL;
data[output] = '\0';
return data;
}
static size_t shebang_count_arguments(char* line)
{
size_t result = 0;
while ( shebang_tokenize(&line) )
result++;
return result;
}
// NOTE: The PATH-searching logic is repeated multiple places. Until this logic
// can be shared somehow, you need to keep this comment in sync as well
// as the logic in these files:
// * kernel/process.cpp
// * libc/unistd/execvpe.c
// * utils/which.c
// NOTE: See comments in execvpe() for algorithmic commentary.
static bool sys_execve_alloc(addralloc_t* alloc, size_t size)
{
if ( !AllocateKernelAddress(alloc, size) )
return false;
if ( !Memory::MapRange(alloc->from, alloc->size, PROT_KREAD | PROT_KWRITE, PAGE_USAGE_EXECUTE) )
return FreeKernelAddress(alloc), false;
Memory::Flush();
return true;
}
static void sys_execve_free(addralloc_t* alloc)
{
Memory::UnmapRange(alloc->from, alloc->size, PAGE_USAGE_EXECUTE);
Memory::Flush();
FreeKernelAddress(alloc);
}
static
int sys_execve_kernel(const char* filename,
int argc,
char* const* argv,
int envc,
char* const* envp,
struct thread_registers* regs)
{
Process* process = CurrentProcess();
ioctx_t ctx;
SetupKernelIOCtx(&ctx);
Ref<Descriptor> from = filename[0] == '/' ? process->GetRoot() : process->GetCWD();
Ref<Descriptor> desc = from->open(&ctx, filename, O_EXEC | O_READ, 0);
if ( !desc )
return -1;
from.Reset();
struct stat st;
if ( desc->stat(&ctx, &st) )
return -1;
if ( !(st.st_mode & 0111) )
return errno = EACCES, -1;
if ( st.st_size < 0 )
return errno = EINVAL, -1;
if ( (uintmax_t) SIZE_MAX < (uintmax_t) st.st_size )
return errno = EFBIG, -1;
size_t filesize = (size_t) st.st_size;
addralloc_t buffer_alloc;
if ( !sys_execve_alloc(&buffer_alloc, filesize) )
return -1;
uint8_t* buffer = (uint8_t*) buffer_alloc.from;
for ( size_t sofar = 0; sofar < filesize; )
{
ssize_t amount = desc->read(&ctx, buffer + sofar, filesize - sofar);
if ( amount < 0 )
return sys_execve_free(&buffer_alloc), -1;
if ( amount == 0 )
return sys_execve_free(&buffer_alloc), errno = EEOF, -1;
sofar += amount;
}
desc.Reset();
int result = process->Execute(filename, buffer, filesize, argc, argv, envc, envp, regs);
if ( result == 0 || errno != ENOEXEC ||
filesize < 2 || buffer[0] != '#' || buffer[1] != '!' )
return sys_execve_free(&buffer_alloc), result;
size_t line_length = 0;
while ( 2 + line_length < filesize && buffer[2 + line_length] != '\n' )
line_length++;
if ( line_length == filesize )
return sys_execve_free(&buffer_alloc), errno = ENOEXEC, -1;
char* line = new char[line_length+1];
if ( !line )
return sys_execve_free(&buffer_alloc), -1;
memcpy(line, buffer + 2, line_length);
line[line_length] = '\0';
sys_execve_free(&buffer_alloc);
char* line_clone = String::Clone(line);
if ( !line_clone )
return delete[] line, -1;
size_t argument_count = shebang_count_arguments(line_clone);
delete[] line_clone;
if ( !argument_count || INT_MAX < argument_count )
return delete[] line, errno = ENOEXEC, -1;
int sb_argc = (int) argument_count;
char** sb_argv = new char*[sb_argc];
if ( !sb_argv )
return delete[] line, -1;
char* sb_saved = line;
for ( int i = 0; i < sb_argc; i++ )
sb_argv[i] = shebang_tokenize(&sb_saved);
if ( INT_MAX - argc <= sb_argc )
return delete[] sb_argv, delete[] line, errno = EOVERFLOW, -1;
if ( !sb_argv[0] || !sb_argv[0][0] )
return delete[] sb_argv, delete[] line, errno = ENOENT, -1;
int new_argc = sb_argc + argc;
char** new_argv = new char*[new_argc + 1];
if ( !new_argv )
return delete[] sb_argv, delete[] line, -1;
for ( int i = 0; i < sb_argc; i++ )
new_argv[i] = sb_argv[i];
new_argv[sb_argc + 0] = (char*) filename;
for ( int i = 1; i < argc; i++ )
new_argv[sb_argc + i] = argv[i];
new_argv[new_argc] = (char*) NULL;
result = -1;
// (See the above comment block before editing this searching logic)
const char* path = shebang_lookup_environment("PATH", envp);
bool search_path = !strchr(sb_argv[0], '/') && path;
bool any_tries = false;
bool any_eacces = false;
const char* new_argv0 = sb_argv[0];
while ( search_path && *path )
{
size_t len = strcspn(path, ":");
if ( !len )
{
path++;
continue;
}
any_tries = true;
char* dirpath = strndup(path, len);
if ( !dirpath )
return -1;
if ( (path += len)[0] == ':' )
path++;
while ( len && dirpath[len - 1] == '/' )
dirpath[--len] = '\0';
char* fullpath;
if ( asprintf(&fullpath, "%s/%s", dirpath, sb_argv[0]) < 0 )
return free(dirpath), -1;
result = sys_execve_kernel(fullpath, new_argc, new_argv, envc, envp, regs);
free(fullpath);
free(dirpath);
if ( result == 0 )
break;
if ( errno == ENOENT )
continue;
if ( errno == ELOOP ||
errno == EISDIR ||
errno == ENAMETOOLONG ||
errno == ENOTDIR )
continue;
if ( errno == EACCES )
{
any_eacces = true;
continue;
}
if ( errno == EACCES )
{
any_eacces = true;
continue;
}
break;
}
if ( !any_tries )
result = sys_execve_kernel(new_argv0, new_argc, new_argv, envc, envp, regs);
if ( result < 0 && any_eacces )
errno = EACCES;
delete[] new_argv;
delete[] sb_argv;
delete[] line;
return result;
}
int sys_execve(const char* user_filename,
char* const* user_argv,
char* const* user_envp)
{
char* filename;
int argc;
int envc;
char** argv;
char** envp;
int result = -1;
struct thread_registers regs;
memset(&regs, 0, sizeof(regs));
if ( !user_filename || !user_argv || !user_envp )
return errno = EFAULT, -1;
if ( !(filename = GetStringFromUser(user_filename)) )
goto cleanup_done;
argc = 0;
while ( true )
{
const char* user_arg;
if ( !CopyFromUser(&user_arg, user_argv + argc, sizeof(user_arg)) )
goto cleanup_filename;
if ( !user_arg )
break;
if ( ++argc == INT_MAX )
{
errno = E2BIG;
goto cleanup_filename;
}
}
argv = new char*[argc+1];
if ( !argv )
goto cleanup_filename;
memset(argv, 0, sizeof(char*) * (argc+1));
for ( int i = 0; i < argc; i++ )
{
const char* user_arg;
if ( !CopyFromUser(&user_arg, user_argv + i, sizeof(user_arg)) )
goto cleanup_argv;
if ( !(argv[i] = GetStringFromUser(user_arg)) )
goto cleanup_argv;
}
envc = 0;
while ( true )
{
const char* user_env;
if ( !CopyFromUser(&user_env, user_envp + envc, sizeof(user_env)) )
goto cleanup_argv;
if ( !user_env )
break;
if ( ++envc == INT_MAX )
{
errno = E2BIG;
goto cleanup_argv;
}
}
envp = new char*[envc+1];
if ( !envp )
goto cleanup_argv;
memset(envp, 0, sizeof(char*) * (envc+1));
for ( int i = 0; i < envc; i++ )
{
const char* user_env;
if ( !CopyFromUser(&user_env, user_envp + i, sizeof(user_env)) )
goto cleanup_envp;
if ( !(envp[i] = GetStringFromUser(user_envp[i])) )
goto cleanup_envp;
}
result = sys_execve_kernel(filename, argc, argv, envc, envp, &regs);
cleanup_envp:
for ( int i = 0; i < envc; i++)
delete[] envp[i];
delete[] envp;
cleanup_argv:
for ( int i = 0; i < argc; i++)
delete[] argv[i];
delete[] argv;
cleanup_filename:
delete[] filename;
cleanup_done:
if ( result == 0 )
LoadRegisters(&regs);
return result;
}
pid_t sys_tfork(int flags, struct tfork* user_regs)
{
struct tfork regs;
if ( !CopyFromUser(&regs, user_regs, sizeof(regs)) )
return -1;
if ( Signal::IsPending() )
return errno = EINTR, -1;
bool making_process = flags == SFFORK;
bool making_thread = (flags & (SFPROC | SFPID | SFFD | SFMEM | SFCWD | SFROOT)) == SFPROC;
// TODO: Properly support tfork(2).
if ( !(making_thread || making_process) )
return errno = ENOSYS, -1;
if ( regs.altstack.ss_flags & ~__SS_SUPPORTED_FLAGS )
return errno = EINVAL, -1;
size_t stack_alignment = 16;
// TODO: Is it a hack to create a new kernel stack here?
Thread* curthread = CurrentThread();
size_t newkernelstacksize = curthread->kernelstacksize;
uint8_t* newkernelstack = new uint8_t[newkernelstacksize + stack_alignment];
if ( !newkernelstack )
return -1;
uintptr_t stack_aligned = (uintptr_t) newkernelstack;
size_t stack_aligned_size = newkernelstacksize;
if ( ((uintptr_t) stack_aligned) & (stack_alignment-1) )
stack_aligned = (stack_aligned + 16) & ~(stack_alignment-1);
stack_aligned_size &= 0xFFFFFFF0;
Process* child_process;
if ( making_thread )
child_process = CurrentProcess();
else if ( !(child_process = CurrentProcess()->Fork()) )
{
delete[] newkernelstack;
return -1;
}
struct thread_registers cpuregs;
memset(&cpuregs, 0, sizeof(cpuregs));
#if defined(__i386__)
cpuregs.eip = regs.eip;
cpuregs.esp = regs.esp;
cpuregs.eax = regs.eax;
cpuregs.ebx = regs.ebx;
cpuregs.ecx = regs.ecx;
cpuregs.edx = regs.edx;
cpuregs.edi = regs.edi;
cpuregs.esi = regs.esi;
cpuregs.ebp = regs.ebp;
cpuregs.cs = UCS | URPL;
cpuregs.ds = UDS | URPL;
cpuregs.ss = UDS | URPL;
cpuregs.eflags = FLAGS_RESERVED1 | FLAGS_INTERRUPT | FLAGS_ID;
cpuregs.fsbase = regs.fsbase;
cpuregs.gsbase = regs.gsbase;
cpuregs.cr3 = child_process->addrspace;
cpuregs.kernel_stack = stack_aligned + stack_aligned_size;
memcpy(&cpuregs.fpuenv, Float::fpu_initialized_regs, 512);
#elif defined(__x86_64__)
cpuregs.rip = regs.rip;
cpuregs.rsp = regs.rsp;
cpuregs.rax = regs.rax;
cpuregs.rbx = regs.rbx;
cpuregs.rcx = regs.rcx;
cpuregs.rdx = regs.rdx;
cpuregs.rdi = regs.rdi;
cpuregs.rsi = regs.rsi;
cpuregs.rbp = regs.rbp;
cpuregs.r8 = regs.r8;
cpuregs.r9 = regs.r9;
cpuregs.r10 = regs.r10;
cpuregs.r11 = regs.r11;
cpuregs.r12 = regs.r12;
cpuregs.r13 = regs.r13;
cpuregs.r14 = regs.r14;
cpuregs.r15 = regs.r15;
cpuregs.cs = UCS | URPL;
cpuregs.ds = UDS | URPL;
cpuregs.ss = UDS | URPL;
cpuregs.rflags = FLAGS_RESERVED1 | FLAGS_INTERRUPT | FLAGS_ID;
cpuregs.fsbase = regs.fsbase;
cpuregs.gsbase = regs.gsbase;
cpuregs.cr3 = child_process->addrspace;
cpuregs.kernel_stack = stack_aligned + stack_aligned_size;
memcpy(&cpuregs.fpuenv, Float::fpu_initialized_regs, 512);
#else
#warning "You need to implement initializing the registers of the new thread"
#endif
// Forbid the creation of new threads if init has exited.
ScopedLock process_family_lock_lock(&process_family_lock);
if ( is_init_exiting )
return errno = EPERM, -1;
// If the thread could not be created, make the process commit suicide
// in a manner such that we don't wait for its zombie.
Thread* thread = CreateKernelThread(child_process, &cpuregs,
making_process ? "main" : "second");
process_family_lock_lock.Reset();
if ( !thread )
{
if ( making_process )
child_process->AbortConstruction();
return -1;
}
thread->kernelstackpos = (addr_t) newkernelstack;
thread->kernelstacksize = newkernelstacksize;
thread->kernelstackmalloced = true;
memcpy(&thread->signal_mask, &regs.sigmask, sizeof(sigset_t));
memcpy(&thread->signal_stack, &regs.altstack, sizeof(stack_t));
StartKernelThread(thread);
return child_process->pid;
}
pid_t sys_getpid(void)
{
return CurrentProcess()->pid;
}
pid_t sys_getppid(void)
{
Process* process = CurrentProcess();
ScopedLock lock(&process_family_lock);
if ( !process->parent )
return 0;
return process->parent->pid;
}
pid_t sys_getpgid(pid_t pid)
{
ScopedLock lock(&process_family_lock);
Process* process = !pid ? CurrentProcess() : CurrentProcess()->GetPTable()->Get(pid);
if ( !process )
return errno = ESRCH, -1;
if ( !process->group )
return errno = ESRCH, -1;
return process->group->pid;
}
pid_t sys_getsid(pid_t pid)
{
ScopedLock lock(&process_family_lock);
Process* process = !pid ? CurrentProcess() : CurrentProcess()->GetPTable()->Get(pid);
if ( !process )
return errno = ESRCH, -1;
if ( !process->session )
return errno = ESRCH, -1;
return process->session->pid;
}
int sys_setpgid(pid_t pid, pid_t pgid)
{
if ( pid < 0 || pgid < 0 )
return errno = EINVAL, -1;
// TODO: Either prevent changing the process group after an exec or provide
// a version of this system call with a flags parameter that lets you
// decide if you want this behavior. This will fix a race condition
// where the shell spawns a child and both parent and child sets the
// process group, but the child sets the process group and execve's
// and the new program image exploits this 'bug' and also changes the
// process group, and then the shell gets around to change the process
// group. This probably unlikely, but correctness over all!
Process* current_process = CurrentProcess();
ScopedLock lock(&process_family_lock);
// Find the processes in question.
Process* process = !pid ? CurrentProcess() : CurrentProcess()->GetPTable()->Get(pid);
if ( !process )
return errno = ESRCH, -1;
Process* group = !pgid ? process : CurrentProcess()->GetPTable()->Get(pgid);
if ( !group )
return errno = ESRCH, -1;
// The process must be this one or a direct child.
if ( process != current_process && process->parent != current_process )
return errno = EPERM, -1;
// The process must be in this session.
if ( process->session != current_process->session )
return errno = EPERM, -1;
// The new group must be in the same session as the process.
if ( group->session != process->session )
return errno = EPERM, -1;
// The process must not be a process group leader.
// TODO: Maybe POSIX actually allows this.
if ( process->groupfirst )
return errno = EPERM, -1;
// The process must not be a session leader.
if ( process->sessionfirst )
return errno = EPERM, -1;
// The group must either exist or be the process itself.
if ( !group->groupfirst && group != process )
return errno = EPERM, -1;
// Exit early if this is a noop.
if ( process->group == group )
return 0;
// Remove the process from its current process group.
if ( process->group )
process->group->GroupRemoveMember(process);
// Insert the process into its new process group.
process->groupprev = NULL;
process->groupnext = group->groupfirst;
if ( group->groupfirst )
group->groupfirst->groupprev = process;
group->groupfirst = process;
process->group = group;
return 0;
}
pid_t sys_setsid(void)
{
Process* process = CurrentProcess();
ScopedLock lock(&process_family_lock);
// Test if already a process group leader.
if ( process->group == process )
return errno = EPERM, -1;
// Remove the process from its current process group.
if ( process->group )
process->group->GroupRemoveMember(process);
// Remove the process from its current session.
if ( process->session )
process->session->SessionRemoveMember(process);
// Insert the process into its new session.
process->sessionprev = NULL;
process->sessionnext = NULL;
process->sessionfirst = process;
process->session = process;
// Insert the process into its new process group.
process->groupprev = NULL;
process->groupnext = NULL;
process->groupfirst = process;
process->group = process;
return process->pid;
}
size_t sys_getpagesize(void)
{
return Page::Size();
}
mode_t sys_umask(mode_t newmask)
{
Process* process = CurrentProcess();
ScopedLock lock(&process->idlock);
mode_t oldmask = process->umask;
process->umask = newmask & 0666;
return oldmask;
}
mode_t sys_getumask(void)
{
Process* process = CurrentProcess();
ScopedLock lock(&process->idlock);
return process->umask;
}
static void GetAssertInfo(struct scram_assert* info,
const void* user_info_ptr)
{
memset(info, 0, sizeof(*info));
struct scram_assert user_info;
if ( !CopyFromUser(&user_info, user_info_ptr, sizeof(user_info)) )
return;
info->filename = GetStringFromUser(user_info.filename);
info->line = user_info.line;
info->function = GetStringFromUser(user_info.function);
info->expression = GetStringFromUser(user_info.expression);
}
static void FreeAssertInfo(struct scram_assert* info)
{
delete[] (char*) info->filename;
delete[] (char*) info->function;
delete[] (char*) info->expression;
}
static
void GetUndefinedBehaviorInfo(struct scram_undefined_behavior* info,
const void* user_info_ptr)
{
memset(info, 0, sizeof(*info));
struct scram_undefined_behavior user_info;
if ( !CopyFromUser(&user_info, user_info_ptr, sizeof(user_info)) )
return;
info->filename = GetStringFromUser(user_info.filename);
info->line = user_info.line;
info->column = user_info.column;
info->violation = GetStringFromUser(user_info.violation);
}
static void FreeUndefinedBehaviorInfo(struct scram_undefined_behavior* info)
{
delete[] info->filename;
delete[] info->violation;
}
__attribute__((noreturn))
void sys_scram(int event, const void* user_info)
{
Process* process = CurrentProcess();
// TODO: Prohibit execve such that program_image_path is protected.
process->ExitThroughSignal(SIGABRT);
if ( event == SCRAM_ASSERT )
{
struct scram_assert info;
GetAssertInfo(&info, user_info);
Log::PrintF("%s[%ji]: Assertion failure: %s:%lu: %s: %s\n",
process->program_image_path,
(intmax_t) process->pid,
info.filename ? info.filename : "<unknown>",
info.line,
info.function ? info.function : "<unknown>",
info.expression ? info.expression : "<unknown>");
FreeAssertInfo(&info);
}
else if ( event == SCRAM_STACK_SMASH )
{
Log::PrintF("%s[%ji]: Stack smashing detected\n",
process->program_image_path,
(intmax_t) process->pid);
}
else if ( event == SCRAM_UNDEFINED_BEHAVIOR )
{
struct scram_undefined_behavior info;
GetUndefinedBehaviorInfo(&info, user_info);
Log::PrintF("%s[%ji]: Undefined behavior: %s at %s:%lu:%lu\n",
process->program_image_path,
(intmax_t) process->pid,
info.violation ? info.violation : "<unknown>",
info.filename ? info.filename : "<unknown>",
info.line,
info.column);
FreeUndefinedBehaviorInfo(&info);
}
else
{
Log::PrintF("%s[%ji]: Unknown scram event %i\n",
process->program_image_path,
(intmax_t) process->pid,
event);
}
// TODO: Allow debugging this event (and see signal.cpp sigreturn).
kthread_exit();
}
} // namespace Sortix