ladybird/Kernel/Process.h
Andreas Kling 1e90a3a542 Kernel: Make sys$perf_register_string() generate the string ID's
Making userspace provide a global string ID was silly, and made the API
extremely difficult to use correctly in a global profiling context.

Instead, simply make the kernel do the string ID allocation for us.
This also allows us to convert the string storage to a Vector in the
kernel (and an array in the JSON profile data.)
2021-08-12 00:03:39 +02:00

956 lines
37 KiB
C++

/*
* Copyright (c) 2018-2021, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#pragma once
#include <AK/Concepts.h>
#include <AK/HashMap.h>
#include <AK/IntrusiveList.h>
#include <AK/IntrusiveListRelaxedConst.h>
#include <AK/NonnullRefPtrVector.h>
#include <AK/String.h>
#include <AK/Userspace.h>
#include <AK/WeakPtr.h>
#include <AK/Weakable.h>
#include <Kernel/API/Syscall.h>
#include <Kernel/AtomicEdgeAction.h>
#include <Kernel/FileSystem/FileDescription.h>
#include <Kernel/FileSystem/InodeMetadata.h>
#include <Kernel/FileSystem/UnveilNode.h>
#include <Kernel/Forward.h>
#include <Kernel/FutexQueue.h>
#include <Kernel/Locking/Mutex.h>
#include <Kernel/Locking/ProtectedValue.h>
#include <Kernel/Memory/AddressSpace.h>
#include <Kernel/PerformanceEventBuffer.h>
#include <Kernel/ProcessGroup.h>
#include <Kernel/StdLib.h>
#include <Kernel/Thread.h>
#include <Kernel/UnixTypes.h>
#include <LibC/elf.h>
#include <LibC/signal_numbers.h>
namespace Kernel {
ProtectedValue<String>& hostname();
Time kgettimeofday();
#define ENUMERATE_PLEDGE_PROMISES \
__ENUMERATE_PLEDGE_PROMISE(stdio) \
__ENUMERATE_PLEDGE_PROMISE(rpath) \
__ENUMERATE_PLEDGE_PROMISE(wpath) \
__ENUMERATE_PLEDGE_PROMISE(cpath) \
__ENUMERATE_PLEDGE_PROMISE(dpath) \
__ENUMERATE_PLEDGE_PROMISE(inet) \
__ENUMERATE_PLEDGE_PROMISE(id) \
__ENUMERATE_PLEDGE_PROMISE(proc) \
__ENUMERATE_PLEDGE_PROMISE(ptrace) \
__ENUMERATE_PLEDGE_PROMISE(exec) \
__ENUMERATE_PLEDGE_PROMISE(unix) \
__ENUMERATE_PLEDGE_PROMISE(recvfd) \
__ENUMERATE_PLEDGE_PROMISE(sendfd) \
__ENUMERATE_PLEDGE_PROMISE(fattr) \
__ENUMERATE_PLEDGE_PROMISE(tty) \
__ENUMERATE_PLEDGE_PROMISE(chown) \
__ENUMERATE_PLEDGE_PROMISE(chroot) \
__ENUMERATE_PLEDGE_PROMISE(thread) \
__ENUMERATE_PLEDGE_PROMISE(video) \
__ENUMERATE_PLEDGE_PROMISE(accept) \
__ENUMERATE_PLEDGE_PROMISE(settime) \
__ENUMERATE_PLEDGE_PROMISE(sigaction) \
__ENUMERATE_PLEDGE_PROMISE(setkeymap) \
__ENUMERATE_PLEDGE_PROMISE(prot_exec) \
__ENUMERATE_PLEDGE_PROMISE(map_fixed) \
__ENUMERATE_PLEDGE_PROMISE(getkeymap)
enum class Pledge : u32 {
#define __ENUMERATE_PLEDGE_PROMISE(x) x,
ENUMERATE_PLEDGE_PROMISES
#undef __ENUMERATE_PLEDGE_PROMISE
};
enum class VeilState {
None,
Dropped,
Locked,
};
typedef HashMap<FlatPtr, RefPtr<FutexQueue>> FutexQueues;
struct LoadResult;
class ProtectedProcessBase {
protected:
ProcessID m_pid { 0 };
ProcessID m_ppid { 0 };
SessionID m_sid { 0 };
uid_t m_euid { 0 };
gid_t m_egid { 0 };
uid_t m_uid { 0 };
gid_t m_gid { 0 };
uid_t m_suid { 0 };
gid_t m_sgid { 0 };
Vector<gid_t> m_extra_gids;
bool m_dumpable { false };
Atomic<bool> m_has_promises { false };
Atomic<u32> m_promises { 0 };
Atomic<bool> m_has_execpromises { false };
Atomic<u32> m_execpromises { 0 };
mode_t m_umask { 022 };
VirtualAddress m_signal_trampoline;
Atomic<u32> m_thread_count { 0 };
u8 m_termination_status { 0 };
u8 m_termination_signal { 0 };
};
class ProcessBase : public ProtectedProcessBase {
protected:
// Without the alignas specifier here the compiler places this class into
// the parent class' padding which then causes the members for the RefCounted
// class to be placed within the first page of the Process class.
alignas(ProtectedProcessBase) u8 m_process_base_padding[PAGE_SIZE - sizeof(ProtectedProcessBase)];
};
static_assert(sizeof(ProcessBase) == PAGE_SIZE);
class Process
: public ProcessBase
, public RefCounted<Process>
, public Weakable<Process> {
AK_MAKE_NONCOPYABLE(Process);
AK_MAKE_NONMOVABLE(Process);
MAKE_ALIGNED_ALLOCATED(Process, PAGE_SIZE);
friend class Thread;
friend class CoreDump;
friend class ProcFSProcessFileDescriptions;
// Helper class to temporarily unprotect a process's protected data so you can write to it.
class ProtectedDataMutationScope {
public:
explicit ProtectedDataMutationScope(Process& process)
: m_process(process)
{
m_process.unprotect_data();
}
~ProtectedDataMutationScope() { m_process.protect_data(); }
private:
Process& m_process;
};
enum class State : u8 {
Running = 0,
Dying,
Dead
};
public:
inline static Process* current()
{
auto current_thread = Processor::current_thread();
return current_thread ? &current_thread->process() : nullptr;
}
template<typename EntryFunction>
static void kernel_process_trampoline(void* data)
{
EntryFunction* func = reinterpret_cast<EntryFunction*>(data);
(*func)();
delete func;
}
enum class RegisterProcess {
No,
Yes
};
template<typename EntryFunction>
static RefPtr<Process> create_kernel_process(RefPtr<Thread>& first_thread, String&& name, EntryFunction entry, u32 affinity = THREAD_AFFINITY_DEFAULT, RegisterProcess do_register = RegisterProcess::Yes)
{
auto* entry_func = new EntryFunction(move(entry));
return create_kernel_process(first_thread, move(name), &Process::kernel_process_trampoline<EntryFunction>, entry_func, affinity, do_register);
}
static RefPtr<Process> create_kernel_process(RefPtr<Thread>& first_thread, String&& name, void (*entry)(void*), void* entry_data = nullptr, u32 affinity = THREAD_AFFINITY_DEFAULT, RegisterProcess do_register = RegisterProcess::Yes);
static RefPtr<Process> create_user_process(RefPtr<Thread>& first_thread, const String& path, uid_t, gid_t, ProcessID ppid, int& error, Vector<String>&& arguments = Vector<String>(), Vector<String>&& environment = Vector<String>(), TTY* = nullptr);
static void register_new(Process&);
~Process();
static NonnullRefPtrVector<Process> all_processes();
RefPtr<Thread> create_kernel_thread(void (*entry)(void*), void* entry_data, u32 priority, OwnPtr<KString> name, u32 affinity = THREAD_AFFINITY_DEFAULT, bool joinable = true);
bool is_profiling() const { return m_profiling; }
void set_profiling(bool profiling) { m_profiling = profiling; }
bool should_core_dump() const { return m_should_dump_core; }
void set_dump_core(bool dump_core) { m_should_dump_core = dump_core; }
bool is_dying() const { return m_state.load(AK::MemoryOrder::memory_order_acquire) != State::Running; }
bool is_dead() const { return m_state.load(AK::MemoryOrder::memory_order_acquire) == State::Dead; }
bool is_stopped() const { return m_is_stopped; }
bool set_stopped(bool stopped) { return m_is_stopped.exchange(stopped); }
bool is_kernel_process() const { return m_is_kernel_process; }
bool is_user_process() const { return !m_is_kernel_process; }
static RefPtr<Process> from_pid(ProcessID);
static SessionID get_sid_from_pgid(ProcessGroupID pgid);
const String& name() const { return m_name; }
ProcessID pid() const { return m_pid; }
SessionID sid() const { return m_sid; }
bool is_session_leader() const { return m_sid.value() == m_pid.value(); }
ProcessGroupID pgid() const { return m_pg ? m_pg->pgid() : 0; }
bool is_group_leader() const { return pgid().value() == m_pid.value(); }
const Vector<gid_t>& extra_gids() const { return m_extra_gids; }
uid_t euid() const { return m_euid; }
gid_t egid() const { return m_egid; }
uid_t uid() const { return m_uid; }
gid_t gid() const { return m_gid; }
uid_t suid() const { return m_suid; }
gid_t sgid() const { return m_sgid; }
ProcessID ppid() const { return m_ppid; }
bool is_dumpable() const { return m_dumpable; }
void set_dumpable(bool);
mode_t umask() const { return m_umask; }
bool in_group(gid_t) const;
// Breakable iteration functions
template<IteratorFunction<Process&> Callback>
static void for_each(Callback);
template<IteratorFunction<Process&> Callback>
static void for_each_in_pgrp(ProcessGroupID, Callback);
template<IteratorFunction<Process&> Callback>
void for_each_child(Callback);
template<IteratorFunction<Thread&> Callback>
IterationDecision for_each_thread(Callback);
template<IteratorFunction<Thread&> Callback>
IterationDecision for_each_thread(Callback callback) const;
// Non-breakable iteration functions
template<VoidFunction<Process&> Callback>
static void for_each(Callback);
template<VoidFunction<Process&> Callback>
static void for_each_in_pgrp(ProcessGroupID, Callback);
template<VoidFunction<Process&> Callback>
void for_each_child(Callback);
template<VoidFunction<Thread&> Callback>
IterationDecision for_each_thread(Callback);
template<VoidFunction<Thread&> Callback>
IterationDecision for_each_thread(Callback callback) const;
void die();
void finalize();
ThreadTracer* tracer() { return m_tracer.ptr(); }
bool is_traced() const { return !!m_tracer; }
KResult start_tracing_from(ProcessID tracer);
void stop_tracing();
void tracer_trap(Thread&, const RegisterState&);
KResultOr<FlatPtr> sys$emuctl();
KResultOr<FlatPtr> sys$yield();
KResultOr<FlatPtr> sys$sync();
KResultOr<FlatPtr> sys$beep();
KResultOr<FlatPtr> sys$get_process_name(Userspace<char*> buffer, size_t buffer_size);
KResultOr<FlatPtr> sys$set_process_name(Userspace<const char*> user_name, size_t user_name_length);
KResultOr<FlatPtr> sys$create_inode_watcher(u32 flags);
KResultOr<FlatPtr> sys$inode_watcher_add_watch(Userspace<const Syscall::SC_inode_watcher_add_watch_params*> user_params);
KResultOr<FlatPtr> sys$inode_watcher_remove_watch(int fd, int wd);
KResultOr<FlatPtr> sys$dbgputch(u8);
KResultOr<FlatPtr> sys$dbgputstr(Userspace<const u8*>, size_t);
KResultOr<FlatPtr> sys$dump_backtrace();
KResultOr<FlatPtr> sys$gettid();
KResultOr<FlatPtr> sys$setsid();
KResultOr<FlatPtr> sys$getsid(pid_t);
KResultOr<FlatPtr> sys$setpgid(pid_t pid, pid_t pgid);
KResultOr<FlatPtr> sys$getpgrp();
KResultOr<FlatPtr> sys$getpgid(pid_t);
KResultOr<FlatPtr> sys$getuid();
KResultOr<FlatPtr> sys$getgid();
KResultOr<FlatPtr> sys$geteuid();
KResultOr<FlatPtr> sys$getegid();
KResultOr<FlatPtr> sys$getpid();
KResultOr<FlatPtr> sys$getppid();
KResultOr<FlatPtr> sys$getresuid(Userspace<uid_t*>, Userspace<uid_t*>, Userspace<uid_t*>);
KResultOr<FlatPtr> sys$getresgid(Userspace<gid_t*>, Userspace<gid_t*>, Userspace<gid_t*>);
KResultOr<FlatPtr> sys$umask(mode_t);
KResultOr<FlatPtr> sys$open(Userspace<const Syscall::SC_open_params*>);
KResultOr<FlatPtr> sys$close(int fd);
KResultOr<FlatPtr> sys$read(int fd, Userspace<u8*>, size_t);
KResultOr<FlatPtr> sys$readv(int fd, Userspace<const struct iovec*> iov, int iov_count);
KResultOr<FlatPtr> sys$write(int fd, Userspace<const u8*>, size_t);
KResultOr<FlatPtr> sys$writev(int fd, Userspace<const struct iovec*> iov, int iov_count);
KResultOr<FlatPtr> sys$fstat(int fd, Userspace<stat*>);
KResultOr<FlatPtr> sys$stat(Userspace<const Syscall::SC_stat_params*>);
KResultOr<FlatPtr> sys$lseek(int fd, Userspace<off_t*>, int whence);
KResultOr<FlatPtr> sys$ftruncate(int fd, Userspace<off_t*>);
KResultOr<FlatPtr> sys$kill(pid_t pid_or_pgid, int sig);
[[noreturn]] void sys$exit(int status);
KResultOr<FlatPtr> sys$sigreturn(RegisterState& registers);
KResultOr<FlatPtr> sys$waitid(Userspace<const Syscall::SC_waitid_params*>);
KResultOr<FlatPtr> sys$mmap(Userspace<const Syscall::SC_mmap_params*>);
KResultOr<FlatPtr> sys$mremap(Userspace<const Syscall::SC_mremap_params*>);
KResultOr<FlatPtr> sys$munmap(Userspace<void*>, size_t);
KResultOr<FlatPtr> sys$set_mmap_name(Userspace<const Syscall::SC_set_mmap_name_params*>);
KResultOr<FlatPtr> sys$mprotect(Userspace<void*>, size_t, int prot);
KResultOr<FlatPtr> sys$madvise(Userspace<void*>, size_t, int advice);
KResultOr<FlatPtr> sys$msyscall(Userspace<void*>);
KResultOr<FlatPtr> sys$purge(int mode);
KResultOr<FlatPtr> sys$select(Userspace<const Syscall::SC_select_params*>);
KResultOr<FlatPtr> sys$poll(Userspace<const Syscall::SC_poll_params*>);
KResultOr<FlatPtr> sys$get_dir_entries(int fd, Userspace<void*>, size_t);
KResultOr<FlatPtr> sys$getcwd(Userspace<char*>, size_t);
KResultOr<FlatPtr> sys$chdir(Userspace<const char*>, size_t);
KResultOr<FlatPtr> sys$fchdir(int fd);
KResultOr<FlatPtr> sys$adjtime(Userspace<const timeval*>, Userspace<timeval*>);
KResultOr<FlatPtr> sys$clock_gettime(clockid_t, Userspace<timespec*>);
KResultOr<FlatPtr> sys$clock_settime(clockid_t, Userspace<const timespec*>);
KResultOr<FlatPtr> sys$clock_nanosleep(Userspace<const Syscall::SC_clock_nanosleep_params*>);
KResultOr<FlatPtr> sys$gethostname(Userspace<char*>, size_t);
KResultOr<FlatPtr> sys$sethostname(Userspace<const char*>, size_t);
KResultOr<FlatPtr> sys$uname(Userspace<utsname*>);
KResultOr<FlatPtr> sys$readlink(Userspace<const Syscall::SC_readlink_params*>);
KResultOr<FlatPtr> sys$ttyname(int fd, Userspace<char*>, size_t);
KResultOr<FlatPtr> sys$ptsname(int fd, Userspace<char*>, size_t);
KResultOr<FlatPtr> sys$fork(RegisterState&);
KResultOr<FlatPtr> sys$execve(Userspace<const Syscall::SC_execve_params*>);
KResultOr<FlatPtr> sys$dup2(int old_fd, int new_fd);
KResultOr<FlatPtr> sys$sigaction(int signum, Userspace<const sigaction*> act, Userspace<sigaction*> old_act);
KResultOr<FlatPtr> sys$sigprocmask(int how, Userspace<const sigset_t*> set, Userspace<sigset_t*> old_set);
KResultOr<FlatPtr> sys$sigpending(Userspace<sigset_t*>);
KResultOr<FlatPtr> sys$getgroups(size_t, Userspace<gid_t*>);
KResultOr<FlatPtr> sys$setgroups(size_t, Userspace<const gid_t*>);
KResultOr<FlatPtr> sys$pipe(int pipefd[2], int flags);
KResultOr<FlatPtr> sys$killpg(pid_t pgrp, int sig);
KResultOr<FlatPtr> sys$seteuid(uid_t);
KResultOr<FlatPtr> sys$setegid(gid_t);
KResultOr<FlatPtr> sys$setuid(uid_t);
KResultOr<FlatPtr> sys$setgid(gid_t);
KResultOr<FlatPtr> sys$setreuid(uid_t, uid_t);
KResultOr<FlatPtr> sys$setresuid(uid_t, uid_t, uid_t);
KResultOr<FlatPtr> sys$setresgid(gid_t, gid_t, gid_t);
KResultOr<FlatPtr> sys$alarm(unsigned seconds);
KResultOr<FlatPtr> sys$access(Userspace<const char*> pathname, size_t path_length, int mode);
KResultOr<FlatPtr> sys$fcntl(int fd, int cmd, u32 extra_arg);
KResultOr<FlatPtr> sys$ioctl(int fd, unsigned request, FlatPtr arg);
KResultOr<FlatPtr> sys$mkdir(Userspace<const char*> pathname, size_t path_length, mode_t mode);
KResultOr<FlatPtr> sys$times(Userspace<tms*>);
KResultOr<FlatPtr> sys$utime(Userspace<const char*> pathname, size_t path_length, Userspace<const struct utimbuf*>);
KResultOr<FlatPtr> sys$link(Userspace<const Syscall::SC_link_params*>);
KResultOr<FlatPtr> sys$unlink(Userspace<const char*> pathname, size_t path_length);
KResultOr<FlatPtr> sys$symlink(Userspace<const Syscall::SC_symlink_params*>);
KResultOr<FlatPtr> sys$rmdir(Userspace<const char*> pathname, size_t path_length);
KResultOr<FlatPtr> sys$mount(Userspace<const Syscall::SC_mount_params*>);
KResultOr<FlatPtr> sys$umount(Userspace<const char*> mountpoint, size_t mountpoint_length);
KResultOr<FlatPtr> sys$chmod(Userspace<const char*> pathname, size_t path_length, mode_t);
KResultOr<FlatPtr> sys$fchmod(int fd, mode_t);
KResultOr<FlatPtr> sys$chown(Userspace<const Syscall::SC_chown_params*>);
KResultOr<FlatPtr> sys$fchown(int fd, uid_t, gid_t);
KResultOr<FlatPtr> sys$socket(int domain, int type, int protocol);
KResultOr<FlatPtr> sys$bind(int sockfd, Userspace<const sockaddr*> addr, socklen_t);
KResultOr<FlatPtr> sys$listen(int sockfd, int backlog);
KResultOr<FlatPtr> sys$accept4(Userspace<const Syscall::SC_accept4_params*>);
KResultOr<FlatPtr> sys$connect(int sockfd, Userspace<const sockaddr*>, socklen_t);
KResultOr<FlatPtr> sys$shutdown(int sockfd, int how);
KResultOr<FlatPtr> sys$sendmsg(int sockfd, Userspace<const struct msghdr*>, int flags);
KResultOr<FlatPtr> sys$recvmsg(int sockfd, Userspace<struct msghdr*>, int flags);
KResultOr<FlatPtr> sys$getsockopt(Userspace<const Syscall::SC_getsockopt_params*>);
KResultOr<FlatPtr> sys$setsockopt(Userspace<const Syscall::SC_setsockopt_params*>);
KResultOr<FlatPtr> sys$getsockname(Userspace<const Syscall::SC_getsockname_params*>);
KResultOr<FlatPtr> sys$getpeername(Userspace<const Syscall::SC_getpeername_params*>);
KResultOr<FlatPtr> sys$socketpair(Userspace<const Syscall::SC_socketpair_params*>);
KResultOr<FlatPtr> sys$sched_setparam(pid_t pid, Userspace<const struct sched_param*>);
KResultOr<FlatPtr> sys$sched_getparam(pid_t pid, Userspace<struct sched_param*>);
KResultOr<FlatPtr> sys$create_thread(void* (*)(void*), Userspace<const Syscall::SC_create_thread_params*>);
[[noreturn]] void sys$exit_thread(Userspace<void*>, Userspace<void*>, size_t);
KResultOr<FlatPtr> sys$join_thread(pid_t tid, Userspace<void**> exit_value);
KResultOr<FlatPtr> sys$detach_thread(pid_t tid);
KResultOr<FlatPtr> sys$set_thread_name(pid_t tid, Userspace<const char*> buffer, size_t buffer_size);
KResultOr<FlatPtr> sys$get_thread_name(pid_t tid, Userspace<char*> buffer, size_t buffer_size);
KResultOr<FlatPtr> sys$kill_thread(pid_t tid, int signal);
KResultOr<FlatPtr> sys$rename(Userspace<const Syscall::SC_rename_params*>);
KResultOr<FlatPtr> sys$mknod(Userspace<const Syscall::SC_mknod_params*>);
KResultOr<FlatPtr> sys$halt();
KResultOr<FlatPtr> sys$reboot();
KResultOr<FlatPtr> sys$realpath(Userspace<const Syscall::SC_realpath_params*>);
KResultOr<FlatPtr> sys$getrandom(Userspace<void*>, size_t, unsigned int);
KResultOr<FlatPtr> sys$getkeymap(Userspace<const Syscall::SC_getkeymap_params*>);
KResultOr<FlatPtr> sys$setkeymap(Userspace<const Syscall::SC_setkeymap_params*>);
KResultOr<FlatPtr> sys$module_load(Userspace<const char*> path, size_t path_length);
KResultOr<FlatPtr> sys$module_unload(Userspace<const char*> name, size_t name_length);
KResultOr<FlatPtr> sys$profiling_enable(pid_t, u64);
KResultOr<FlatPtr> sys$profiling_disable(pid_t);
KResultOr<FlatPtr> sys$profiling_free_buffer(pid_t);
KResultOr<FlatPtr> sys$futex(Userspace<const Syscall::SC_futex_params*>);
KResultOr<FlatPtr> sys$chroot(Userspace<const char*> path, size_t path_length, int mount_flags);
KResultOr<FlatPtr> sys$pledge(Userspace<const Syscall::SC_pledge_params*>);
KResultOr<FlatPtr> sys$unveil(Userspace<const Syscall::SC_unveil_params*>);
KResultOr<FlatPtr> sys$perf_event(int type, FlatPtr arg1, FlatPtr arg2);
KResultOr<FlatPtr> sys$perf_register_string(Userspace<char const*>, size_t);
KResultOr<FlatPtr> sys$get_stack_bounds(Userspace<FlatPtr*> stack_base, Userspace<size_t*> stack_size);
KResultOr<FlatPtr> sys$ptrace(Userspace<const Syscall::SC_ptrace_params*>);
KResultOr<FlatPtr> sys$sendfd(int sockfd, int fd);
KResultOr<FlatPtr> sys$recvfd(int sockfd, int options);
KResultOr<FlatPtr> sys$sysconf(int name);
KResultOr<FlatPtr> sys$disown(ProcessID);
KResultOr<FlatPtr> sys$allocate_tls(Userspace<const char*> initial_data, size_t);
KResultOr<FlatPtr> sys$prctl(int option, FlatPtr arg1, FlatPtr arg2);
KResultOr<FlatPtr> sys$set_coredump_metadata(Userspace<const Syscall::SC_set_coredump_metadata_params*>);
KResultOr<FlatPtr> sys$anon_create(size_t, int options);
KResultOr<FlatPtr> sys$statvfs(Userspace<const Syscall::SC_statvfs_params*> user_params);
KResultOr<FlatPtr> sys$fstatvfs(int fd, statvfs* buf);
KResultOr<FlatPtr> sys$map_time_page();
template<bool sockname, typename Params>
int get_sock_or_peer_name(const Params&);
static void initialize();
[[noreturn]] void crash(int signal, FlatPtr ip, bool out_of_memory = false);
[[nodiscard]] siginfo_t wait_info();
const TTY* tty() const { return m_tty; }
void set_tty(TTY*);
u32 m_ticks_in_user { 0 };
u32 m_ticks_in_kernel { 0 };
u32 m_ticks_in_user_for_dead_children { 0 };
u32 m_ticks_in_kernel_for_dead_children { 0 };
Custody& current_directory();
Custody* executable() { return m_executable.ptr(); }
const Custody* executable() const { return m_executable.ptr(); }
const Vector<String>& arguments() const { return m_arguments; };
const Vector<String>& environment() const { return m_environment; };
KResult exec(String path, Vector<String> arguments, Vector<String> environment, int recusion_depth = 0);
KResultOr<LoadResult> load(NonnullRefPtr<FileDescription> main_program_description, RefPtr<FileDescription> interpreter_description, const ElfW(Ehdr) & main_program_header);
bool is_superuser() const { return euid() == 0; }
void terminate_due_to_signal(u8 signal);
KResult send_signal(u8 signal, Process* sender);
u8 termination_signal() const { return m_termination_signal; }
u16 thread_count() const
{
return m_thread_count.load(AK::MemoryOrder::memory_order_relaxed);
}
Mutex& big_lock() { return m_big_lock; }
Mutex& ptrace_lock() { return m_ptrace_lock; }
Custody& root_directory();
Custody& root_directory_relative_to_global_root();
void set_root_directory(const Custody&);
bool has_promises() const { return m_has_promises; }
bool has_promised(Pledge pledge) const { return m_promises & (1u << (u32)pledge); }
VeilState veil_state() const
{
return m_veil_state;
}
const UnveilNode& unveiled_paths() const
{
return m_unveiled_paths;
}
bool wait_for_tracer_at_next_execve() const
{
return m_wait_for_tracer_at_next_execve;
}
void set_wait_for_tracer_at_next_execve(bool val)
{
m_wait_for_tracer_at_next_execve = val;
}
KResultOr<u32> peek_user_data(Userspace<const u32*> address);
KResult poke_user_data(Userspace<u32*> address, u32 data);
void disowned_by_waiter(Process& process);
void unblock_waiters(Thread::WaitBlocker::UnblockFlags, u8 signal = 0);
Thread::WaitBlockCondition& wait_block_condition() { return m_wait_block_condition; }
template<typename Callback>
void for_each_coredump_property(Callback callback) const
{
for (auto& property : m_coredump_properties) {
if (property.key && property.value)
callback(*property.key, *property.value);
}
}
KResult set_coredump_property(NonnullOwnPtr<KString> key, NonnullOwnPtr<KString> value);
KResult try_set_coredump_property(StringView key, StringView value);
const NonnullRefPtrVector<Thread>& threads_for_coredump(Badge<CoreDump>) const { return m_threads_for_coredump; }
PerformanceEventBuffer* perf_events() { return m_perf_event_buffer; }
Memory::AddressSpace& address_space() { return *m_space; }
Memory::AddressSpace const& address_space() const { return *m_space; }
VirtualAddress signal_trampoline() const { return m_signal_trampoline; }
private:
friend class MemoryManager;
friend class Scheduler;
friend class Region;
friend class PerformanceManager;
bool add_thread(Thread&);
bool remove_thread(Thread&);
Process(const String& name, uid_t uid, gid_t gid, ProcessID ppid, bool is_kernel_process, RefPtr<Custody> cwd, RefPtr<Custody> executable, TTY* tty);
static RefPtr<Process> create(RefPtr<Thread>& first_thread, const String& name, uid_t, gid_t, ProcessID ppid, bool is_kernel_process, RefPtr<Custody> cwd = nullptr, RefPtr<Custody> executable = nullptr, TTY* = nullptr, Process* fork_parent = nullptr);
KResult attach_resources(RefPtr<Thread>& first_thread, Process* fork_parent);
static ProcessID allocate_pid();
void kill_threads_except_self();
void kill_all_threads();
bool dump_core();
bool dump_perfcore();
bool create_perf_events_buffer_if_needed();
void delete_perf_events_buffer();
KResult do_exec(NonnullRefPtr<FileDescription> main_program_description, Vector<String> arguments, Vector<String> environment, RefPtr<FileDescription> interpreter_description, Thread*& new_main_thread, u32& prev_flags, const ElfW(Ehdr) & main_program_header);
KResultOr<FlatPtr> do_write(FileDescription&, const UserOrKernelBuffer&, size_t);
KResultOr<FlatPtr> do_statvfs(String path, statvfs* buf);
KResultOr<RefPtr<FileDescription>> find_elf_interpreter_for_executable(const String& path, const ElfW(Ehdr) & elf_header, int nread, size_t file_size);
KResult do_kill(Process&, int signal);
KResult do_killpg(ProcessGroupID pgrp, int signal);
KResult do_killall(int signal);
KResult do_killself(int signal);
KResultOr<siginfo_t> do_waitid(idtype_t idtype, int id, int options);
KResultOr<NonnullOwnPtr<KString>> get_syscall_path_argument(const char* user_path, size_t path_length) const;
KResultOr<NonnullOwnPtr<KString>> get_syscall_path_argument(Userspace<const char*> user_path, size_t path_length) const
{
return get_syscall_path_argument(user_path.unsafe_userspace_ptr(), path_length);
}
KResultOr<NonnullOwnPtr<KString>> get_syscall_path_argument(const Syscall::StringArgument&) const;
bool has_tracee_thread(ProcessID tracer_pid);
void clear_futex_queues_on_exec();
void setup_socket_fd(int fd, NonnullRefPtr<FileDescription> description, int type);
inline PerformanceEventBuffer* current_perf_events_buffer()
{
if (g_profiling_all_threads)
return g_global_perf_events;
else if (m_profiling)
return m_perf_event_buffer.ptr();
else
return nullptr;
}
mutable IntrusiveListNode<Process> m_list_node;
String m_name;
OwnPtr<Memory::AddressSpace> m_space;
RefPtr<ProcessGroup> m_pg;
AtomicEdgeAction<u32> m_protected_data_refs;
void protect_data();
void unprotect_data();
OwnPtr<ThreadTracer> m_tracer;
public:
class FileDescriptionAndFlags {
public:
bool is_valid() const { return !m_description.is_null(); }
bool is_allocated() const { return m_is_allocated; }
void allocate()
{
VERIFY(!m_is_allocated);
VERIFY(!is_valid());
m_is_allocated = true;
}
void deallocate()
{
VERIFY(m_is_allocated);
VERIFY(!is_valid());
m_is_allocated = false;
}
FileDescription* description() { return m_description; }
const FileDescription* description() const { return m_description; }
InodeIndex global_procfs_inode_index() const { return m_global_procfs_inode_index; }
u32 flags() const { return m_flags; }
void set_flags(u32 flags) { m_flags = flags; }
void clear();
void set(NonnullRefPtr<FileDescription>&&, u32 flags = 0);
void refresh_inode_index();
private:
RefPtr<FileDescription> m_description;
bool m_is_allocated { false };
u32 m_flags { 0 };
// Note: This is needed so when we generate inodes for ProcFS, we know that
// we assigned a global Inode index to it so we can use it later
InodeIndex m_global_procfs_inode_index;
};
class ScopedDescriptionAllocation;
class FileDescriptions {
friend class Process;
public:
ALWAYS_INLINE const FileDescriptionAndFlags& operator[](size_t i) const { return at(i); }
ALWAYS_INLINE FileDescriptionAndFlags& operator[](size_t i) { return at(i); }
FileDescriptions& operator=(const Kernel::Process::FileDescriptions& other)
{
ScopedSpinLock lock(m_fds_lock);
ScopedSpinLock lock_other(other.m_fds_lock);
m_fds_metadatas = other.m_fds_metadatas;
for (auto& file_description_metadata : m_fds_metadatas) {
file_description_metadata.refresh_inode_index();
}
return *this;
}
const FileDescriptionAndFlags& at(size_t i) const;
FileDescriptionAndFlags& at(size_t i);
void enumerate(Function<void(const FileDescriptionAndFlags&)>) const;
void change_each(Function<void(FileDescriptionAndFlags&)>);
KResultOr<ScopedDescriptionAllocation> allocate(int first_candidate_fd = 0);
size_t open_count() const;
bool try_resize(size_t size) { return m_fds_metadatas.try_resize(size); }
size_t max_open() const
{
return m_max_open_file_descriptors;
}
void clear()
{
ScopedSpinLock lock(m_fds_lock);
m_fds_metadatas.clear();
}
// FIXME: Consider to remove this somehow
RefPtr<FileDescription> file_description(int fd) const;
private:
FileDescriptions() = default;
static constexpr size_t m_max_open_file_descriptors { FD_SETSIZE };
mutable SpinLock<u8> m_fds_lock;
Vector<FileDescriptionAndFlags> m_fds_metadatas;
};
class ScopedDescriptionAllocation {
AK_MAKE_NONCOPYABLE(ScopedDescriptionAllocation);
public:
ScopedDescriptionAllocation() = default;
ScopedDescriptionAllocation(int tracked_fd, FileDescriptionAndFlags* description)
: fd(tracked_fd)
, m_description(description)
{
}
ScopedDescriptionAllocation(ScopedDescriptionAllocation&& other)
: fd(other.fd)
{
// Take over the responsibility of tracking to deallocation.
swap(m_description, other.m_description);
}
~ScopedDescriptionAllocation()
{
if (m_description && m_description->is_allocated() && !m_description->is_valid()) {
m_description->deallocate();
}
}
const int fd { -1 };
private:
FileDescriptionAndFlags* m_description { nullptr };
};
FileDescriptions& fds() { return m_fds; }
const FileDescriptions& fds() const { return m_fds; }
private:
SpinLockProtectedValue<Thread::ListInProcess>& thread_list() { return m_thread_list; }
SpinLockProtectedValue<Thread::ListInProcess> const& thread_list() const { return m_thread_list; }
SpinLockProtectedValue<Thread::ListInProcess> m_thread_list;
FileDescriptions m_fds;
const bool m_is_kernel_process;
Atomic<State> m_state { State::Running };
bool m_profiling { false };
Atomic<bool, AK::MemoryOrder::memory_order_relaxed> m_is_stopped { false };
bool m_should_dump_core { false };
RefPtr<Custody> m_executable;
RefPtr<Custody> m_cwd;
RefPtr<Custody> m_root_directory;
RefPtr<Custody> m_root_directory_relative_to_global_root;
Vector<String> m_arguments;
Vector<String> m_environment;
RefPtr<TTY> m_tty;
WeakPtr<Memory::Region> m_master_tls_region;
size_t m_master_tls_size { 0 };
size_t m_master_tls_alignment { 0 };
Mutex m_big_lock { "Process" };
Mutex m_ptrace_lock { "ptrace" };
RefPtr<Timer> m_alarm_timer;
VeilState m_veil_state { VeilState::None };
UnveilNode m_unveiled_paths { "/", { .full_path = "/" } };
OwnPtr<PerformanceEventBuffer> m_perf_event_buffer;
FutexQueues m_futex_queues;
SpinLock<u8> m_futex_lock;
// This member is used in the implementation of ptrace's PT_TRACEME flag.
// If it is set to true, the process will stop at the next execve syscall
// and wait for a tracer to attach.
bool m_wait_for_tracer_at_next_execve { false };
Thread::WaitBlockCondition m_wait_block_condition;
struct CoredumpProperty {
OwnPtr<KString> key;
OwnPtr<KString> value;
};
Array<CoredumpProperty, 4> m_coredump_properties;
NonnullRefPtrVector<Thread> m_threads_for_coredump;
public:
using List = IntrusiveListRelaxedConst<Process, RawPtr<Process>, &Process::m_list_node>;
};
extern RecursiveSpinLock g_profiling_lock;
ProtectedValue<Process::List>& processes();
template<IteratorFunction<Process&> Callback>
inline void Process::for_each(Callback callback)
{
VERIFY_INTERRUPTS_DISABLED();
processes().with_shared([&](const auto& list) {
for (auto it = list.begin(); it != list.end();) {
auto& process = *it;
++it;
if (callback(process) == IterationDecision::Break)
break;
}
});
}
template<IteratorFunction<Process&> Callback>
inline void Process::for_each_child(Callback callback)
{
ProcessID my_pid = pid();
processes().with_shared([&](const auto& list) {
for (auto it = list.begin(); it != list.end();) {
auto& process = *it;
++it;
if (process.ppid() == my_pid || process.has_tracee_thread(pid())) {
if (callback(process) == IterationDecision::Break)
break;
}
}
});
}
template<IteratorFunction<Thread&> Callback>
inline IterationDecision Process::for_each_thread(Callback callback) const
{
return thread_list().with([&](auto& thread_list) -> IterationDecision {
for (auto& thread : thread_list) {
IterationDecision decision = callback(thread);
if (decision != IterationDecision::Continue)
return decision;
}
return IterationDecision::Continue;
});
}
template<IteratorFunction<Thread&> Callback>
inline IterationDecision Process::for_each_thread(Callback callback)
{
return thread_list().with([&](auto& thread_list) -> IterationDecision {
for (auto& thread : thread_list) {
IterationDecision decision = callback(thread);
if (decision != IterationDecision::Continue)
return decision;
}
return IterationDecision::Continue;
});
}
template<IteratorFunction<Process&> Callback>
inline void Process::for_each_in_pgrp(ProcessGroupID pgid, Callback callback)
{
processes().with_shared([&](const auto& list) {
for (auto it = list.begin(); it != list.end();) {
auto& process = *it;
++it;
if (!process.is_dead() && process.pgid() == pgid) {
if (callback(process) == IterationDecision::Break)
break;
}
}
});
}
template<VoidFunction<Process&> Callback>
inline void Process::for_each(Callback callback)
{
return for_each([&](auto& item) {
callback(item);
return IterationDecision::Continue;
});
}
template<VoidFunction<Process&> Callback>
inline void Process::for_each_child(Callback callback)
{
return for_each_child([&](auto& item) {
callback(item);
return IterationDecision::Continue;
});
}
template<VoidFunction<Thread&> Callback>
inline IterationDecision Process::for_each_thread(Callback callback) const
{
thread_list().with([&](auto& thread_list) {
for (auto& thread : thread_list)
callback(thread);
});
return IterationDecision::Continue;
}
template<VoidFunction<Thread&> Callback>
inline IterationDecision Process::for_each_thread(Callback callback)
{
thread_list().with([&](auto& thread_list) {
for (auto& thread : thread_list)
callback(thread);
});
return IterationDecision::Continue;
}
template<VoidFunction<Process&> Callback>
inline void Process::for_each_in_pgrp(ProcessGroupID pgid, Callback callback)
{
return for_each_in_pgrp(pgid, [&](auto& item) {
callback(item);
return IterationDecision::Continue;
});
}
inline bool InodeMetadata::may_read(const Process& process) const
{
return may_read(process.euid(), process.egid(), process.extra_gids());
}
inline bool InodeMetadata::may_write(const Process& process) const
{
return may_write(process.euid(), process.egid(), process.extra_gids());
}
inline bool InodeMetadata::may_execute(const Process& process) const
{
return may_execute(process.euid(), process.egid(), process.extra_gids());
}
inline ProcessID Thread::pid() const
{
return m_process->pid();
}
#define REQUIRE_NO_PROMISES \
do { \
if (Process::current()->has_promises()) { \
dbgln("Has made a promise"); \
Process::current()->crash(SIGABRT, 0); \
VERIFY_NOT_REACHED(); \
} \
} while (0)
#define REQUIRE_PROMISE(promise) \
do { \
if (Process::current()->has_promises() \
&& !Process::current()->has_promised(Pledge::promise)) { \
dbgln("Has not pledged {}", #promise); \
(void)Process::current()->try_set_coredump_property( \
"pledge_violation"sv, #promise); \
Process::current()->crash(SIGABRT, 0); \
VERIFY_NOT_REACHED(); \
} \
} while (0)
}
#define VERIFY_PROCESS_BIG_LOCK_ACQUIRED(process) \
VERIFY(process->big_lock().own_lock());
#define VERIFY_NO_PROCESS_BIG_LOCK(process) \
VERIFY(!process->big_lock().own_lock());
inline static String copy_string_from_user(const Kernel::Syscall::StringArgument& string)
{
return copy_string_from_user(string.characters, string.length);
}
inline static KResultOr<NonnullOwnPtr<KString>> try_copy_kstring_from_user(const Kernel::Syscall::StringArgument& string)
{
return try_copy_kstring_from_user(string.characters, string.length);
}
template<>
struct AK::Formatter<Kernel::Process> : AK::Formatter<String> {
void format(FormatBuilder& builder, const Kernel::Process& value)
{
return AK::Formatter<String>::format(builder, String::formatted("{}({})", value.name(), value.pid().value()));
}
};