use core::{ffi::c_void, ptr::null_mut, sync::atomic::compiler_fence}; use alloc::boxed::Box; use crate::{ arch::x86_64::asm::current::current_pcb, include::bindings::bindings::{ process_control_block, CLONE_CLEAR_SIGHAND, CLONE_SIGHAND, CLONE_THREAD, ENOMEM, }, ipc::{ signal::{flush_signal_handlers, DEFAULT_SIGACTION}, signal_types::{sigaction, sighand_struct, signal_struct, SigQueue}, }, libs::{ atomic::atomic_set, ffi_convert::FFIBind2Rust, refcount::{refcount_inc, RefCount}, spinlock::{spin_lock_irqsave, spin_unlock_irqrestore}, }, }; #[no_mangle] pub extern "C" fn process_copy_sighand(clone_flags: u64, pcb: *mut process_control_block) -> i32 { // kdebug!("process_copy_sighand"); if (clone_flags & (CLONE_SIGHAND as u64)) != 0 { let r = RefCount::convert_mut(unsafe { &mut (*(current_pcb().sighand)).count }).unwrap(); refcount_inc(r); } // 在这里使用Box::leak将动态申请的内存的生命周期转换为static的 let mut sig: &mut sighand_struct = Box::leak(Box::new(sighand_struct::default())); if (sig as *mut sighand_struct) == null_mut() { return -(ENOMEM as i32); } // 将新的sighand赋值给pcb unsafe { (*pcb).sighand = sig as *mut sighand_struct as usize as *mut crate::include::bindings::bindings::sighand_struct; } // kdebug!("DEFAULT_SIGACTION.sa_flags={}", DEFAULT_SIGACTION.sa_flags); // 拷贝sigaction let mut flags: u64 = 0; spin_lock_irqsave(unsafe { &mut (*current_pcb().sighand).siglock }, &mut flags); compiler_fence(core::sync::atomic::Ordering::SeqCst); for (index, x) in unsafe { (*current_pcb().sighand).action } .iter() .enumerate() { compiler_fence(core::sync::atomic::Ordering::SeqCst); if !(x as *const crate::include::bindings::bindings::sigaction).is_null() { sig.action[index] = *sigaction::convert_ref(x as *const crate::include::bindings::bindings::sigaction) .unwrap(); } else { sig.action[index] = DEFAULT_SIGACTION; } } compiler_fence(core::sync::atomic::Ordering::SeqCst); spin_unlock_irqrestore(unsafe { &mut (*current_pcb().sighand).siglock }, &flags); compiler_fence(core::sync::atomic::Ordering::SeqCst); // 将信号的处理函数设置为default(除了那些被手动屏蔽的) if (clone_flags & (CLONE_CLEAR_SIGHAND as u64)) != 0 { compiler_fence(core::sync::atomic::Ordering::SeqCst); flush_signal_handlers(pcb, false); compiler_fence(core::sync::atomic::Ordering::SeqCst); } compiler_fence(core::sync::atomic::Ordering::SeqCst); return 0; } #[no_mangle] pub extern "C" fn process_copy_signal(clone_flags: u64, pcb: *mut process_control_block) -> i32 { // kdebug!("process_copy_signal"); // 如果克隆的是线程,则不拷贝信号(同一进程的各个线程之间共享信号) if (clone_flags & (CLONE_THREAD as u64)) != 0 { return 0; } let sig: &mut signal_struct = Box::leak(Box::new(signal_struct::default())); if (sig as *mut signal_struct) == null_mut() { return -(ENOMEM as i32); } atomic_set(&mut sig.sig_cnt, 1); // 将sig赋值给pcb中的字段 unsafe { (*pcb).signal = sig as *mut signal_struct as usize as *mut crate::include::bindings::bindings::signal_struct; } // 创建新的sig_pending->sigqueue unsafe { (*pcb).sig_pending.signal = 0; (*pcb).sig_pending.sigqueue = Box::leak(Box::new(SigQueue::default())) as *mut SigQueue as *mut c_void; } return 0; } #[no_mangle] pub extern "C" fn process_exit_signal(pcb: *mut process_control_block) { // 回收进程的信号结构体 unsafe { // 回收sighand let sighand = Box::from_raw((*pcb).sighand as *mut sighand_struct); drop(sighand); (*pcb).sighand = 0 as *mut crate::include::bindings::bindings::sighand_struct; // 回收sigqueue let queue = Box::from_raw((*pcb).sig_pending.sigqueue as *mut SigQueue); drop(queue); } } #[no_mangle] pub extern "C" fn process_exit_sighand(pcb: *mut process_control_block) { // todo: 回收进程的sighand结构体 unsafe { let sig = Box::from_raw((*pcb).signal as *mut signal_struct); drop(sig); (*pcb).signal = 0 as *mut crate::include::bindings::bindings::signal_struct; } }