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use crate::fs::{open_file, OpenFlags};
use crate::mm::{translated_ref, translated_refmut, translated_str};
use crate::task::{
    add_task, current_task, current_user_token, exit_current_and_run_next, pid2task,
    suspend_current_and_run_next, SignalFlags, SignalAction, MAX_SIG,
};
use crate::timer::get_time_ms;
use alloc::string::String;
use alloc::sync::Arc;
use alloc::vec::Vec;

pub fn sys_exit(exit_code: i32) -> ! {
    exit_current_and_run_next(exit_code);
    panic!("Unreachable in sys_exit!");
}

pub fn sys_yield() -> isize {
    suspend_current_and_run_next();
    0
}

pub fn sys_get_time() -> isize {
    get_time_ms() as isize
}

pub fn sys_getpid() -> isize {
    current_task().unwrap().pid.0 as isize
}

pub fn sys_fork() -> isize {
    let current_task = current_task().unwrap();
    let new_task = current_task.fork();
    let new_pid = new_task.pid.0;
    // modify trap context of new_task, because it returns immediately after switching
    let trap_cx = new_task.inner_exclusive_access().get_trap_cx();
    // we do not have to move to next instruction since we have done it before
    // for child process, fork returns 0
    trap_cx.x[10] = 0;
    // add new task to scheduler
    add_task(new_task);
    new_pid as isize
}

pub fn sys_exec(path: *const u8, mut args: *const usize) -> isize {
    let token = current_user_token();
    let path = translated_str(token, path);
    let mut args_vec: Vec<String> = Vec::new();
    loop {
        let arg_str_ptr = *translated_ref(token, args);
        if arg_str_ptr == 0 {
            break;
        }
        args_vec.push(translated_str(token, arg_str_ptr as *const u8));
        unsafe {
            args = args.add(1);
        }
    }
    if let Some(app_inode) = open_file(path.as_str(), OpenFlags::RDONLY) {
        let all_data = app_inode.read_all();
        let task = current_task().unwrap();
        let argc = args_vec.len();
        task.exec(all_data.as_slice(), args_vec);
        // return argc because cx.x[10] will be covered with it later
        argc as isize
    } else {
        -1
    }
}

/// If there is not a child process whose pid is same as given, return -1.
/// Else if there is a child process but it is still running, return -2.
pub fn sys_waitpid(pid: isize, exit_code_ptr: *mut i32) -> isize {
    let task = current_task().unwrap();
    // find a child process

    // ---- access current PCB exclusively
    let mut inner = task.inner_exclusive_access();
    if !inner
        .children
        .iter()
        .any(|p| pid == -1 || pid as usize == p.getpid())
    {
        return -1;
        // ---- release current PCB
    }
    let pair = inner.children.iter().enumerate().find(|(_, p)| {
        // ++++ temporarily access child PCB exclusively
        p.inner_exclusive_access().is_zombie() && (pid == -1 || pid as usize == p.getpid())
        // ++++ release child PCB
    });
    if let Some((idx, _)) = pair {
        let child = inner.children.remove(idx);
        // confirm that child will be deallocated after being removed from children list
        assert_eq!(Arc::strong_count(&child), 1);
        let found_pid = child.getpid();
        // ++++ temporarily access child PCB exclusively
        let exit_code = child.inner_exclusive_access().exit_code;
        // ++++ release child PCB
        *translated_refmut(inner.memory_set.token(), exit_code_ptr) = exit_code;
        found_pid as isize
    } else {
        -2
    }
    // ---- release current PCB automatically
}

pub fn sys_kill(pid: usize, signum: i32) -> isize {
    if let Some(task) = pid2task(pid) {
        if let Some(flag) = SignalFlags::from_bits(1 << signum) {
            // insert the signal if legal
            let mut task_ref = task.inner_exclusive_access();
            if task_ref.signals.contains(flag) {
                return -1;
            }
            task_ref.signals.insert(flag);
            0
        } else {
            -1
        }
    } else {
        -1
    }
}

pub fn sys_sigprocmask(mask: u32) -> isize {
    if let Some(task) = current_task() {
        let mut inner = task.inner_exclusive_access();
        let old_mask = inner.signal_mask;
        if let Some(flag) = SignalFlags::from_bits(mask) {
            inner.signal_mask = flag;
            old_mask.bits() as isize
        } else {
            -1
        }
    } else {
        -1
    }
}

pub fn sys_sigretrun() -> isize {
    if let Some(task) = current_task() {
        let mut inner = task.inner_exclusive_access();
        inner.handling_sig = -1;
        // restore the trap context
        let trap_ctx = inner.get_trap_cx();
        *trap_ctx = inner.trap_ctx_backup.unwrap();
        0
    } else {
        -1
    }
}

fn check_sigaction_error(signal: SignalFlags, action: usize, old_action: usize) -> bool {
    if action == 0 || old_action == 0 || signal == SignalFlags::SIGKILL ||
        signal == SignalFlags::SIGSTOP {
        true
    } else {
        false
    }
}

pub fn sys_sigaction(signum: i32, action: *const SignalAction, old_action: *mut SignalAction) -> isize {
    let token = current_user_token();
    if let Some(task) = current_task() {
        let mut inner = task.inner_exclusive_access();
        if signum as usize > MAX_SIG {
            return -1;
        }
        if let Some(flag) = SignalFlags::from_bits(1 << signum) {
            if check_sigaction_error(flag, action as usize, old_action as usize) {
                return -1;
            }
            let old_kernel_action = inner.signal_actions.table[signum as usize];
            if old_kernel_action.mask != SignalFlags::from_bits(40).unwrap() {
                *translated_refmut(token, old_action) = old_kernel_action;
            } else {
                let mut ref_old_action = *translated_refmut(token, old_action);
                ref_old_action.handler = old_kernel_action.handler;
            }
            let ref_action = translated_ref(token, action);
            inner.signal_actions.table[signum as usize] = *ref_action;
            return 0;
        }
    }
    -1
}