use core::{ ffi::{c_int, c_void}, sync::atomic::compiler_fence, }; use system_error::SystemError; use crate::{ arch::{ ipc::signal::{SigCode, SigFlags, SigSet, Signal}, MMArch, }, filesystem::vfs::{ file::{File, FileMode}, FilePrivateData, }, ipc::shm::{shm_manager_lock, IPC_PRIVATE}, kerror, kwarn, libs::align::page_align_up, libs::spinlock::SpinLock, mm::{ allocator::page_frame::{PageFrameCount, PhysPageFrame, VirtPageFrame}, page::{page_manager_lock_irqsave, PageFlags, PageFlushAll}, syscall::ProtFlags, ucontext::{AddressSpace, VMA}, VirtAddr, VmFlags, }, process::{Pid, ProcessManager}, syscall::{ user_access::{UserBufferReader, UserBufferWriter}, Syscall, }, }; use super::{ pipe::{LockedPipeInode, PipeFsPrivateData}, shm::{ShmCtlCmd, ShmFlags, ShmId, ShmKey}, signal_types::{ SaHandlerType, SigInfo, SigType, Sigaction, SigactionType, UserSigaction, USER_SIG_DFL, USER_SIG_ERR, USER_SIG_IGN, }, }; impl Syscall { /// # 创建带参数的匿名管道 /// /// ## 参数 /// /// - `fd`: 用于返回文件描述符的数组 /// - `flags`:设置管道的参数 pub fn pipe2(fd: *mut i32, flags: FileMode) -> Result { if !flags .difference(FileMode::O_CLOEXEC | FileMode::O_NONBLOCK | FileMode::O_DIRECT) .is_empty() { return Err(SystemError::EINVAL); } let mut user_buffer = UserBufferWriter::new(fd, core::mem::size_of::<[c_int; 2]>(), true)?; let fd = user_buffer.buffer::(0)?; let pipe_ptr = LockedPipeInode::new(); let mut read_file = File::new( pipe_ptr.clone(), FileMode::O_RDONLY | (flags & FileMode::O_NONBLOCK), )?; read_file.private_data = SpinLock::new(FilePrivateData::Pipefs(PipeFsPrivateData::new( FileMode::O_RDONLY, ))); let mut write_file = File::new( pipe_ptr.clone(), FileMode::O_WRONLY | (flags & (FileMode::O_NONBLOCK | FileMode::O_DIRECT)), )?; write_file.private_data = SpinLock::new(FilePrivateData::Pipefs(PipeFsPrivateData::new( FileMode::O_WRONLY | (flags & (FileMode::O_NONBLOCK | FileMode::O_DIRECT)), ))); if flags.contains(FileMode::O_CLOEXEC) { read_file.set_close_on_exec(true); write_file.set_close_on_exec(true); } let fd_table_ptr = ProcessManager::current_pcb().fd_table(); let mut fd_table_guard = fd_table_ptr.write(); let read_fd = fd_table_guard.alloc_fd(read_file, None)?; let write_fd = fd_table_guard.alloc_fd(write_file, None)?; drop(fd_table_guard); fd[0] = read_fd; fd[1] = write_fd; Ok(0) } pub fn kill(pid: Pid, sig: c_int) -> Result { let sig = Signal::from(sig); if sig == Signal::INVALID { // 传入的signal数值不合法 kwarn!("Not a valid signal number"); return Err(SystemError::EINVAL); } // 初始化signal info let mut info = SigInfo::new(sig, 0, SigCode::User, SigType::Kill(pid)); compiler_fence(core::sync::atomic::Ordering::SeqCst); let retval = sig .send_signal_info(Some(&mut info), pid) .map(|x| x as usize); compiler_fence(core::sync::atomic::Ordering::SeqCst); return retval; } /// 通用信号注册函数 /// /// ## 参数 /// /// - `sig` 信号的值 /// - `act` 用户空间传入的 Sigaction 指针 /// - `old_act` 用户空间传入的用来保存旧 Sigaction 的指针 /// - `from_user` 用来标识这个函数调用是否来自用户空间 /// /// @return int 错误码 #[no_mangle] pub fn sigaction( sig: c_int, new_act: usize, old_act: usize, from_user: bool, ) -> Result { // 请注意:用户态传进来的user_sigaction结构体类型,请注意,这个结构体与内核实际的不一样 let act: *mut UserSigaction = new_act as *mut UserSigaction; let old_act = old_act as *mut UserSigaction; let mut new_ka: Sigaction = Default::default(); let mut old_sigaction: Sigaction = Default::default(); // 如果传入的,新的sigaction不为空 if !act.is_null() { // 如果参数的范围不在用户空间,则返回错误 let r = UserBufferWriter::new(act, core::mem::size_of::(), from_user); if r.is_err() { return Err(SystemError::EFAULT); } let mask: SigSet = unsafe { (*act).mask }; let input_sighandler = unsafe { (*act).handler as u64 }; match input_sighandler { USER_SIG_DFL => { new_ka = Sigaction::DEFAULT_SIGACTION; *new_ka.flags_mut() = unsafe { (*act).flags }; new_ka.set_restorer(None); } USER_SIG_IGN => { new_ka = Sigaction::DEFAULT_SIGACTION_IGNORE; *new_ka.flags_mut() = unsafe { (*act).flags }; new_ka.set_restorer(None); } _ => { // 从用户空间获得sigaction结构体 // TODO mask是default还是用户空间传入 new_ka = Sigaction::new( SigactionType::SaHandler(SaHandlerType::Customized(unsafe { VirtAddr::new((*act).handler as usize) })), unsafe { (*act).flags }, SigSet::default(), unsafe { Some(VirtAddr::new((*act).restorer as usize)) }, ); } } // TODO 如果为空,赋默认值? // kdebug!("new_ka={:?}", new_ka); // 如果用户手动给了sa_restorer,那么就置位SA_FLAG_RESTORER,否则报错。(用户必须手动指定restorer) if new_ka.restorer().is_some() { new_ka.flags_mut().insert(SigFlags::SA_RESTORER); } else if new_ka.action().is_customized() { kerror!( "pid:{:?}: in sys_sigaction: User must manually sprcify a sa_restorer for signal {}.", ProcessManager::current_pcb().pid(), sig ); return Err(SystemError::EINVAL); } *new_ka.mask_mut() = mask; } let sig = Signal::from(sig); // 如果给出的信号值不合法 if sig == Signal::INVALID { return Err(SystemError::EINVAL); } let retval = super::signal::do_sigaction( sig, if act.is_null() { None } else { Some(&mut new_ka) }, if old_act.is_null() { None } else { Some(&mut old_sigaction) }, ); // if (retval == Ok(())) && (!old_act.is_null()) { let r = UserBufferWriter::new(old_act, core::mem::size_of::(), from_user); if r.is_err() { return Err(SystemError::EFAULT); } let sigaction_handler = match old_sigaction.action() { SigactionType::SaHandler(handler) => { if let SaHandlerType::Customized(hand) = handler { hand } else if handler.is_sig_ignore() { VirtAddr::new(USER_SIG_IGN as usize) } else if handler.is_sig_error() { VirtAddr::new(USER_SIG_ERR as usize) } else { VirtAddr::new(USER_SIG_DFL as usize) } } SigactionType::SaSigaction(_) => { kerror!("unsupported type: SaSigaction"); VirtAddr::new(USER_SIG_DFL as usize) } }; unsafe { (*old_act).handler = sigaction_handler.data() as *mut c_void; (*old_act).flags = old_sigaction.flags(); (*old_act).mask = old_sigaction.mask(); if old_sigaction.restorer().is_some() { (*old_act).restorer = old_sigaction.restorer().unwrap().data() as *mut c_void; } } } return retval.map(|_| 0); } /// # SYS_SHMGET系统调用函数,用于获取共享内存 /// /// ## 参数 /// /// - `key`: 共享内存键值 /// - `size`: 共享内存大小(bytes) /// - `shmflg`: 共享内存标志 /// /// ## 返回值 /// /// 成功:共享内存id /// 失败:错误码 pub fn shmget(key: ShmKey, size: usize, shmflg: ShmFlags) -> Result { // 暂不支持巨页 if shmflg.contains(ShmFlags::SHM_HUGETLB) { kerror!("shmget: not support huge page"); return Err(SystemError::EOPNOTSUPP_OR_ENOTSUP); } let mut shm_manager_guard = shm_manager_lock(); match key { // 创建共享内存段 IPC_PRIVATE => shm_manager_guard.add(key, size, shmflg), _ => { // 查找key对应的共享内存段是否存在 let id = shm_manager_guard.contains_key(&key); if let Some(id) = id { // 不能重复创建 if shmflg.contains(ShmFlags::IPC_CREAT | ShmFlags::IPC_EXCL) { return Err(SystemError::EEXIST); } // key值存在,说明有对应共享内存,返回该共享内存id return Ok(id.data()); } else { // key不存在且shm_flags不包含IPC_CREAT创建IPC对象标志,则返回错误码 if !shmflg.contains(ShmFlags::IPC_CREAT) { return Err(SystemError::ENOENT); } // 存在创建IPC对象标志 return shm_manager_guard.add(key, size, shmflg); } } } } /// # SYS_SHMAT系统调用函数,用于连接共享内存段 /// /// ## 参数 /// /// - `id`: 共享内存id /// - `vaddr`: 连接共享内存的进程虚拟内存区域起始地址 /// - `shmflg`: 共享内存标志 /// /// ## 返回值 /// /// 成功:映射到共享内存的虚拟内存区域起始地址 /// 失败:错误码 pub fn shmat(id: ShmId, vaddr: VirtAddr, shmflg: ShmFlags) -> Result { let mut shm_manager_guard = shm_manager_lock(); let current_address_space = AddressSpace::current()?; let mut address_write_guard = current_address_space.write(); let kernel_shm = shm_manager_guard.get_mut(&id).ok_or(SystemError::EINVAL)?; let size = page_align_up(kernel_shm.size()); let mut phys = PhysPageFrame::new(kernel_shm.start_paddr()); let count = PageFrameCount::from_bytes(size).unwrap(); let r = match vaddr.data() { // 找到空闲区域并映射到共享内存 0 => { // 找到空闲区域 let region = address_write_guard .mappings .find_free(vaddr, size) .ok_or(SystemError::EINVAL)?; let vm_flags = VmFlags::from(shmflg); let destination = VirtPageFrame::new(region.start()); let page_flags: PageFlags = PageFlags::from_prot_flags(ProtFlags::from(vm_flags), true); let flusher: PageFlushAll = PageFlushAll::new(); // 将共享内存映射到对应虚拟区域 let vma = VMA::physmap( phys, destination, count, vm_flags, page_flags, &mut address_write_guard.user_mapper.utable, flusher, )?; // 将VMA加入到当前进程的VMA列表中 address_write_guard.mappings.insert_vma(vma); region.start().data() } // 指定虚拟地址 _ => { // 获取对应vma let vma = address_write_guard .mappings .contains(vaddr) .ok_or(SystemError::EINVAL)?; if vma.lock().region().start() != vaddr { return Err(SystemError::EINVAL); } // 验证用户虚拟内存区域是否有效 let _ = UserBufferReader::new(vaddr.data() as *const u8, size, true)?; // 必须在取消映射前获取到PageFlags let page_flags = address_write_guard .user_mapper .utable .translate(vaddr) .ok_or(SystemError::EINVAL)? .1; // 取消原映射 let flusher: PageFlushAll = PageFlushAll::new(); vma.unmap(&mut address_write_guard.user_mapper.utable, flusher); // 将该虚拟内存区域映射到共享内存区域 let mut page_manager_guard = page_manager_lock_irqsave(); let mut virt = VirtPageFrame::new(vaddr); for _ in 0..count.data() { let r = unsafe { address_write_guard.user_mapper.utable.map_phys( virt.virt_address(), phys.phys_address(), page_flags, ) } .expect("Failed to map zero, may be OOM error"); r.flush(); // 将vma加入到对应Page的anon_vma page_manager_guard .get_mut(&phys.phys_address()) .insert_vma(vma.clone()); phys = phys.next(); virt = virt.next(); } // 更新vma的映射状态 vma.lock().set_mapped(true); vaddr.data() } }; // 更新最后一次连接时间 kernel_shm.update_atim(); Ok(r) } /// # SYS_SHMDT系统调用函数,用于取消对共享内存的连接 /// /// ## 参数 /// /// - `vaddr`: 需要取消映射的虚拟内存区域起始地址 /// /// ## 返回值 /// /// 成功:0 /// 失败:错误码 pub fn shmdt(vaddr: VirtAddr) -> Result { let current_address_space = AddressSpace::current()?; let mut address_write_guard = current_address_space.write(); // 获取vma let vma = address_write_guard .mappings .contains(vaddr) .ok_or(SystemError::EINVAL)?; // 判断vaddr是否为起始地址 if vma.lock().region().start() != vaddr { return Err(SystemError::EINVAL); } // 获取映射的物理地址 let paddr = address_write_guard .user_mapper .utable .translate(vaddr) .ok_or(SystemError::EINVAL)? .0; // 如果物理页的shm_id为None,代表不是共享页 let page_manager_guard = page_manager_lock_irqsave(); let page = page_manager_guard.get(&paddr).ok_or(SystemError::EINVAL)?; let shm_id = page.shm_id().ok_or(SystemError::EINVAL)?; drop(page_manager_guard); // 获取对应共享页管理信息 let mut shm_manager_guard = shm_manager_lock(); let kernel_shm = shm_manager_guard .get_mut(&shm_id) .ok_or(SystemError::EINVAL)?; // 更新最后一次断开连接时间 kernel_shm.update_dtim(); drop(shm_manager_guard); // 取消映射 let flusher: PageFlushAll = PageFlushAll::new(); vma.unmap(&mut address_write_guard.user_mapper.utable, flusher); return Ok(0); } /// # SYS_SHMCTL系统调用函数,用于管理共享内存段 /// /// ## 参数 /// /// - `id`: 共享内存id /// - `cmd`: 操作码 /// - `user_buf`: 用户缓冲区 /// - `from_user`: buf_vaddr是否来自用户地址空间 /// /// ## 返回值 /// /// 成功:0 /// 失败:错误码 pub fn shmctl( id: ShmId, cmd: ShmCtlCmd, user_buf: *const u8, from_user: bool, ) -> Result { let mut shm_manager_guard = shm_manager_lock(); match cmd { // 查看共享内存元信息 ShmCtlCmd::IpcInfo => shm_manager_guard.ipc_info(user_buf, from_user), // 查看共享内存使用信息 ShmCtlCmd::ShmInfo => shm_manager_guard.shm_info(user_buf, from_user), // 查看id对应的共享内存信息 ShmCtlCmd::ShmStat | ShmCtlCmd::ShmtStatAny | ShmCtlCmd::IpcStat => { shm_manager_guard.shm_stat(id, cmd, user_buf, from_user) } // 设置KernIpcPerm ShmCtlCmd::IpcSet => shm_manager_guard.ipc_set(id, user_buf, from_user), // 将共享内存段设置为可回收状态 ShmCtlCmd::IpcRmid => shm_manager_guard.ipc_rmid(id), // 锁住共享内存段,不允许内存置换 ShmCtlCmd::ShmLock => shm_manager_guard.shm_lock(id), // 解锁共享内存段,允许内存置换 ShmCtlCmd::ShmUnlock => shm_manager_guard.shm_unlock(id), // 无效操作码 ShmCtlCmd::Default => Err(SystemError::EINVAL), } } }