/* * Copyright (c) 2018-2020, Andreas Kling * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include namespace Kernel { KResultOr Process::sys$sigprocmask(int how, Userspace set, Userspace old_set) { REQUIRE_PROMISE(sigaction); auto current_thread = Thread::current(); u32 previous_signal_mask; if (set) { sigset_t set_value; if (!copy_from_user(&set_value, set)) return EFAULT; switch (how) { case SIG_BLOCK: previous_signal_mask = current_thread->signal_mask_block(set_value, true); break; case SIG_UNBLOCK: previous_signal_mask = current_thread->signal_mask_block(set_value, false); break; case SIG_SETMASK: previous_signal_mask = current_thread->update_signal_mask(set_value); break; default: return EINVAL; } } else { previous_signal_mask = current_thread->signal_mask(); } if (old_set && !copy_to_user(old_set, &previous_signal_mask)) return EFAULT; return 0; } KResultOr Process::sys$sigpending(Userspace set) { REQUIRE_PROMISE(stdio); auto pending_signals = Thread::current()->pending_signals(); if (!copy_to_user(set, &pending_signals)) return EFAULT; return 0; } KResultOr Process::sys$sigaction(int signum, Userspace user_act, Userspace user_old_act) { REQUIRE_PROMISE(sigaction); if (signum < 1 || signum >= 32 || signum == SIGKILL || signum == SIGSTOP) return EINVAL; InterruptDisabler disabler; // FIXME: This should use a narrower lock. Maybe a way to ignore signals temporarily? auto& action = Thread::current()->m_signal_action_data[signum]; if (user_old_act) { sigaction old_act {}; old_act.sa_flags = action.flags; old_act.sa_sigaction = reinterpret_cast(action.handler_or_sigaction.as_ptr()); if (!copy_to_user(user_old_act, &old_act)) return EFAULT; } if (user_act) { sigaction act {}; if (!copy_from_user(&act, user_act)) return EFAULT; action.flags = act.sa_flags; action.handler_or_sigaction = VirtualAddress { reinterpret_cast(act.sa_sigaction) }; } return 0; } KResultOr Process::sys$sigreturn([[maybe_unused]] RegisterState& registers) { REQUIRE_PROMISE(stdio); SmapDisabler disabler; #if ARCH(I386) //Here, we restore the state pushed by dispatch signal and asm_signal_trampoline. u32* stack_ptr = (u32*)registers.userspace_esp; u32 smuggled_eax = *stack_ptr; //pop the stored eax, ebp, return address, handler and signal code stack_ptr += 5; Thread::current()->m_signal_mask = *stack_ptr; stack_ptr++; //pop edi, esi, ebp, esp, ebx, edx, ecx and eax memcpy(®isters.edi, stack_ptr, 8 * sizeof(FlatPtr)); stack_ptr += 8; registers.eip = *stack_ptr; stack_ptr++; registers.eflags = (registers.eflags & ~safe_eflags_mask) | (*stack_ptr & safe_eflags_mask); stack_ptr++; registers.userspace_esp = registers.esp; return smuggled_eax; #else //Here, we restore the state pushed by dispatch signal and asm_signal_trampoline. FlatPtr* stack_ptr = (FlatPtr*)registers.userspace_rsp; FlatPtr smuggled_rax = *stack_ptr; //pop the stored rax, rbp, return address, handler and signal code stack_ptr += 5; Thread::current()->m_signal_mask = *stack_ptr; stack_ptr++; //pop rdi, rsi, rbp, rsp, rbx, rdx, rcx, rax, r8, r9, r10, r11, r12, r13, r14 and r15 memcpy(®isters.rdi, stack_ptr, 16 * sizeof(FlatPtr)); stack_ptr += 16; registers.rip = *stack_ptr; stack_ptr++; registers.rflags = (registers.rflags & ~safe_eflags_mask) | (*stack_ptr & safe_eflags_mask); stack_ptr++; registers.userspace_rsp = registers.rsp; return smuggled_rax; #endif } }