use alloc::{boxed::Box, collections::BTreeMap, collections::btree_map::Entry, string::String, sync::Arc, vec::Vec, sync::Weak}; use core::fmt; use log::*; use spin::{Mutex, RwLock}; use xmas_elf::{ElfFile, header, program::{Flags, Type}}; use smoltcp::socket::SocketHandle; use smoltcp::wire::IpEndpoint; use rcore_memory::PAGE_SIZE; use rcore_thread::Tid; use crate::arch::interrupt::{Context, TrapFrame}; use crate::memory::{ByFrame, GlobalFrameAlloc, KernelStack, MemoryAttr, MemorySet}; use crate::fs::{FileHandle, OpenOptions}; use crate::sync::Condvar; use crate::drivers::NET_DRIVERS; use super::abi::{self, ProcInitInfo}; // TODO: avoid pub pub struct Thread { pub context: Context, pub kstack: KernelStack, /// Kernel performs futex wake when thread exits. /// Ref: [http://man7.org/linux/man-pages/man2/set_tid_address.2.html] pub clear_child_tid: usize, pub proc: Arc>, } #[derive(Clone, Debug)] pub struct TcpSocketState { pub local_endpoint: Option, // save local endpoint for bind() pub is_listening: bool, } #[derive(Clone, Debug)] pub enum SocketType { Raw, Tcp(TcpSocketState), Udp, Icmp } #[derive(Debug)] pub struct SocketWrapper { pub handle: SocketHandle, pub socket_type: SocketType, } #[derive(Clone)] pub enum FileLike { File(FileHandle), Socket(SocketWrapper) } impl fmt::Debug for FileLike { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match self { FileLike::File(_) => write!(f, "File"), FileLike::Socket(wrapper) => { match wrapper.socket_type { SocketType::Raw => write!(f, "RawSocket"), SocketType::Tcp(_) => write!(f, "TcpSocket"), SocketType::Udp => write!(f, "UdpSocket"), SocketType::Icmp => write!(f, "IcmpSocket"), } }, } } } /// Pid type /// For strong type separation #[derive(Clone, PartialEq, Eq, PartialOrd, Ord)] pub struct Pid(Option); impl Pid { pub fn uninitialized() -> Self { Pid(None) } /// Return if it was uninitialized before this call /// When returning true, it usually means this is the first thread pub fn set_if_uninitialized(&mut self, tid: Tid) -> bool { if self.0 == None { self.0 = Some(tid as usize); true } else { false } } pub fn get(&self) -> usize { self.0.unwrap() } } impl fmt::Display for Pid { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { match self.0 { Some(pid) => write!(f, "{}", pid), None => write!(f, "None"), } } } pub struct Process { // resources pub memory_set: MemorySet, pub files: BTreeMap, pub cwd: String, futexes: BTreeMap>, // relationship pub pid: Pid, // i.e. tgid, usually the tid of first thread pub parent: Option>>, pub children: Vec>>, pub threads: Vec, // threads in the same process // for waiting child pub child_exit: Arc, // notified when the a child process is going to terminate pub child_exit_code: BTreeMap, // child process store its exit code here } /// Records the mapping between pid and Process struct. lazy_static! { pub static ref PROCESSES: RwLock>>> = RwLock::new(BTreeMap::new()); } /// Let `rcore_thread` can switch between our `Thread` impl rcore_thread::Context for Thread { unsafe fn switch_to(&mut self, target: &mut rcore_thread::Context) { use core::mem::transmute; let (target, _): (&mut Thread, *const ()) = transmute(target); self.context.switch(&mut target.context); } fn set_tid(&mut self, tid: Tid) { // set pid=tid if unspecified let mut proc = self.proc.lock(); if proc.pid.set_if_uninitialized(tid) { // first thread in the process // link to its ppid if let Some(parent) = &proc.parent { let mut parent = parent.lock(); parent.children.push(Arc::downgrade(&self.proc)); } } // add it to threads proc.threads.push(tid); PROCESSES.write().insert(proc.pid.get(), Arc::downgrade(&self.proc)); } } impl Thread { /// Make a struct for the init thread /// TODO: remove this, we only need `Context::null()` pub unsafe fn new_init() -> Box { Box::new(Thread { context: Context::null(), kstack: KernelStack::new(), clear_child_tid: 0, proc: Arc::new(Mutex::new(Process { memory_set: MemorySet::new(), files: BTreeMap::default(), cwd: String::from("/"), futexes: BTreeMap::default(), pid: Pid::uninitialized(), parent: None, children: Vec::new(), threads: Vec::new(), child_exit: Arc::new(Condvar::new()), child_exit_code: BTreeMap::new(), })), }) } /// Make a new kernel thread starting from `entry` with `arg` pub fn new_kernel(entry: extern fn(usize) -> !, arg: usize) -> Box { let memory_set = MemorySet::new(); let kstack = KernelStack::new(); Box::new(Thread { context: unsafe { Context::new_kernel_thread(entry, arg, kstack.top(), memory_set.token()) }, kstack, clear_child_tid: 0, // TODO: kernel thread should not have a process proc: Arc::new(Mutex::new(Process { memory_set, files: BTreeMap::default(), cwd: String::from("/"), futexes: BTreeMap::default(), pid: Pid::uninitialized(), parent: None, children: Vec::new(), threads: Vec::new(), child_exit: Arc::new(Condvar::new()), child_exit_code: BTreeMap::new() })), }) } /// Make a new user process from ELF `data` pub fn new_user<'a, Iter>(data: &[u8], args: Iter) -> Box where Iter: Iterator { // Parse elf let elf = ElfFile::new(data).expect("failed to read elf"); let is32 = match elf.header.pt2 { header::HeaderPt2::Header32(_) => true, header::HeaderPt2::Header64(_) => false, }; match elf.header.pt2.type_().as_type() { header::Type::Executable => { // #[cfg(feature = "no_mmu")] // panic!("ELF is not shared object"); }, header::Type::SharedObject => {}, _ => panic!("ELF is not executable or shared object"), } // Make page table let (mut memory_set, entry_addr) = memory_set_from(&elf); // User stack use crate::consts::{USER_STACK_OFFSET, USER_STACK_SIZE, USER32_STACK_OFFSET}; #[cfg(not(feature = "no_mmu"))] let mut ustack_top = { let (ustack_buttom, ustack_top) = match is32 { true => (USER32_STACK_OFFSET, USER32_STACK_OFFSET + USER_STACK_SIZE), false => (USER_STACK_OFFSET, USER_STACK_OFFSET + USER_STACK_SIZE), }; memory_set.push(ustack_buttom, ustack_top, MemoryAttr::default().user(), ByFrame::new(GlobalFrameAlloc), "user_stack"); ustack_top }; #[cfg(feature = "no_mmu")] let mut ustack_top = memory_set.push(USER_STACK_SIZE).as_ptr() as usize + USER_STACK_SIZE; let init_info = ProcInitInfo { args: args.map(|s| String::from(s)).collect(), envs: BTreeMap::new(), auxv: { let mut map = BTreeMap::new(); if let Some(phdr) = elf.program_iter() .find(|ph| ph.get_type() == Ok(Type::Phdr)) { // if phdr exists in program header, use it map.insert(abi::AT_PHDR, phdr.virtual_addr() as usize); } else if let Some(elf_addr) = elf.program_iter().find(|ph| ph.get_type() == Ok(Type::Load) && ph.offset() == 0) { // otherwise, check if elf is loaded from the beginning, then phdr can be inferred. map.insert(abi::AT_PHDR, elf_addr.virtual_addr() as usize + elf.header.pt2.ph_offset() as usize); } else { warn!("new_user: no phdr found, tls might not work"); } map.insert(abi::AT_PHENT, elf.header.pt2.ph_entry_size() as usize); map.insert(abi::AT_PHNUM, elf.header.pt2.ph_count() as usize); map.insert(abi::AT_PAGESZ, PAGE_SIZE); map }, }; unsafe { memory_set.with(|| { ustack_top = init_info.push_at(ustack_top) }); } trace!("{:#x?}", memory_set); let kstack = KernelStack::new(); let mut files = BTreeMap::new(); files.insert(0, FileLike::File(FileHandle::new(crate::fs::STDIN.clone(), OpenOptions { read: true, write: false, append: false }))); files.insert(1, FileLike::File(FileHandle::new(crate::fs::STDOUT.clone(), OpenOptions { read: false, write: true, append: false }))); files.insert(2, FileLike::File(FileHandle::new(crate::fs::STDOUT.clone(), OpenOptions { read: false, write: true, append: false }))); Box::new(Thread { context: unsafe { Context::new_user_thread( entry_addr, ustack_top, kstack.top(), is32, memory_set.token()) }, kstack, clear_child_tid: 0, proc: Arc::new(Mutex::new(Process { memory_set, files, cwd: String::from("/"), futexes: BTreeMap::default(), pid: Pid::uninitialized(), parent: None, children: Vec::new(), threads: Vec::new(), child_exit: Arc::new(Condvar::new()), child_exit_code: BTreeMap::new() })), }) } /// Fork a new process from current one pub fn fork(&self, tf: &TrapFrame) -> Box { // Clone memory set, make a new page table let memory_set = self.proc.lock().memory_set.clone(); let files = self.proc.lock().files.clone(); let cwd = self.proc.lock().cwd.clone(); let parent = Some(self.proc.clone()); debug!("fork: finish clone MemorySet"); // MMU: copy data to the new space // NoMMU: coping data has been done in `memory_set.clone()` #[cfg(not(feature = "no_mmu"))] for area in memory_set.iter() { let data = Vec::::from(unsafe { area.as_slice() }); unsafe { memory_set.with(|| { area.as_slice_mut().copy_from_slice(data.as_slice()) }) } } debug!("fork: temporary copy data!"); let kstack = KernelStack::new(); let iface = &*(NET_DRIVERS.read()[0]); let mut sockets = iface.sockets(); for (_fd, file) in files.iter() { if let FileLike::Socket(wrapper) = file { sockets.retain(wrapper.handle); } } Box::new(Thread { context: unsafe { Context::new_fork(tf, kstack.top(), memory_set.token()) }, kstack, clear_child_tid: 0, proc: Arc::new(Mutex::new(Process { memory_set, files, cwd, futexes: BTreeMap::default(), pid: Pid::uninitialized(), parent, children: Vec::new(), threads: Vec::new(), child_exit: Arc::new(Condvar::new()), child_exit_code: BTreeMap::new() })), }) } /// Create a new thread in the same process. pub fn clone(&self, tf: &TrapFrame, stack_top: usize, tls: usize, clear_child_tid: usize) -> Box { let kstack = KernelStack::new(); let token = self.proc.lock().memory_set.token(); Box::new(Thread { context: unsafe { Context::new_clone(tf, stack_top, kstack.top(), token, tls) }, kstack, clear_child_tid, proc: self.proc.clone(), }) } } impl Process { pub fn get_free_fd(&self) -> usize { (0..).find(|i| !self.files.contains_key(i)).unwrap() } pub fn get_futex(&mut self, uaddr: usize) -> Arc { if !self.futexes.contains_key(&uaddr) { self.futexes.insert(uaddr, Arc::new(Condvar::new())); } self.futexes.get(&uaddr).unwrap().clone() } } /// Generate a MemorySet according to the ELF file. /// Also return the real entry point address. fn memory_set_from(elf: &ElfFile<'_>) -> (MemorySet, usize) { debug!("creating MemorySet from ELF"); let mut ms = MemorySet::new(); let entry = elf.header.pt2.entry_point() as usize; // [NoMMU] Get total memory size and alloc space let va_begin = elf.program_iter() .filter(|ph| ph.get_type() == Ok(Type::Load)) .map(|ph| ph.virtual_addr()).min().unwrap() as usize; let va_end = elf.program_iter() .filter(|ph| ph.get_type() == Ok(Type::Load)) .map(|ph| ph.virtual_addr() + ph.mem_size()).max().unwrap() as usize; let va_size = va_end - va_begin; #[cfg(feature = "no_mmu")] let target = ms.push(va_size); #[cfg(feature = "no_mmu")] { entry = entry - va_begin + target.as_ptr() as usize; } #[cfg(feature = "board_k210")] { entry += 0x40000000; } for ph in elf.program_iter() { if ph.get_type() != Ok(Type::Load) { continue; } let virt_addr = ph.virtual_addr() as usize; let offset = ph.offset() as usize; let file_size = ph.file_size() as usize; let mem_size = ph.mem_size() as usize; #[cfg(target_arch = "aarch64")] assert_eq!((virt_addr >> 48), 0xffff, "Segment Fault"); // Get target slice #[cfg(feature = "no_mmu")] let target = &mut target[virt_addr - va_begin..virt_addr - va_begin + mem_size]; #[cfg(feature = "no_mmu")] debug!("area @ {:?}, size = {:#x}", target.as_ptr(), mem_size); #[cfg(not(feature = "no_mmu"))] let target = { ms.push(virt_addr, virt_addr + mem_size, ph.flags().to_attr(), ByFrame::new(GlobalFrameAlloc), ""); unsafe { ::core::slice::from_raw_parts_mut(virt_addr as *mut u8, mem_size) } }; // Copy data unsafe { ms.with(|| { if file_size != 0 { target[..file_size].copy_from_slice(&elf.input[offset..offset + file_size]); } target[file_size..].iter_mut().for_each(|x| *x = 0); }); } } (ms, entry) } trait ToMemoryAttr { fn to_attr(&self) -> MemoryAttr; } impl ToMemoryAttr for Flags { fn to_attr(&self) -> MemoryAttr { let mut flags = MemoryAttr::default().user(); // FIXME: handle readonly if self.is_execute() { flags = flags.execute(); } flags } }