use nix::sys::uio::*;
use nix::unistd::*;
use rand::distributions::Alphanumeric;
use rand::{thread_rng, Rng};
use std::fs::OpenOptions;
use std::io::IoSlice;
use std::os::unix::io::AsRawFd;
use std::{cmp, iter};

#[cfg(not(target_os = "redox"))]
use std::io::IoSliceMut;

use tempfile::tempdir;
#[cfg(not(target_os = "redox"))]
use tempfile::tempfile;

#[test]
fn test_writev() {
    let mut to_write = Vec::with_capacity(16 * 128);
    for _ in 0..16 {
        let s: String = thread_rng()
            .sample_iter(&Alphanumeric)
            .map(char::from)
            .take(128)
            .collect();
        let b = s.as_bytes();
        to_write.extend(b.iter().cloned());
    }
    // Allocate and fill iovecs
    let mut iovecs = Vec::new();
    let mut consumed = 0;
    while consumed < to_write.len() {
        let left = to_write.len() - consumed;
        let slice_len = if left <= 64 {
            left
        } else {
            thread_rng().gen_range(64..cmp::min(256, left))
        };
        let b = &to_write[consumed..consumed + slice_len];
        iovecs.push(IoSlice::new(b));
        consumed += slice_len;
    }
    let (reader, writer) = pipe().expect("Couldn't create pipe");
    // FileDesc will close its filedesc (reader).
    let mut read_buf: Vec<u8> = iter::repeat(0u8).take(128 * 16).collect();

    // Blocking io, should write all data.
    let write_res = writev(&writer, &iovecs);
    let written = write_res.expect("couldn't write");
    // Check whether we written all data
    assert_eq!(to_write.len(), written);
    let read_res = read(reader.as_raw_fd(), &mut read_buf[..]);
    let read = read_res.expect("couldn't read");
    // Check we have read as much as we written
    assert_eq!(read, written);
    // Check equality of written and read data
    assert_eq!(&to_write, &read_buf);
}

#[test]
#[cfg(not(target_os = "redox"))]
fn test_readv() {
    let s: String = thread_rng()
        .sample_iter(&Alphanumeric)
        .map(char::from)
        .take(128)
        .collect();
    let to_write = s.as_bytes().to_vec();
    let mut storage = Vec::new();
    let mut allocated = 0;
    while allocated < to_write.len() {
        let left = to_write.len() - allocated;
        let vec_len = if left <= 64 {
            left
        } else {
            thread_rng().gen_range(64..cmp::min(256, left))
        };
        let v: Vec<u8> = iter::repeat(0u8).take(vec_len).collect();
        storage.push(v);
        allocated += vec_len;
    }
    let mut iovecs = Vec::with_capacity(storage.len());
    for v in &mut storage {
        iovecs.push(IoSliceMut::new(&mut v[..]));
    }
    let (reader, writer) = pipe().expect("couldn't create pipe");
    // Blocking io, should write all data.
    write(writer, &to_write).expect("write failed");

    let read = readv(&reader, &mut iovecs[..]).expect("read failed");
    // Check whether we've read all data
    assert_eq!(to_write.len(), read);
    // Cccumulate data from iovecs
    let mut read_buf = Vec::with_capacity(to_write.len());
    for iovec in &iovecs {
        read_buf.extend(iovec.iter().cloned());
    }
    // Check whether iovecs contain all written data
    assert_eq!(read_buf.len(), to_write.len());
    // Check equality of written and read data
    assert_eq!(&read_buf, &to_write);
}

#[test]
#[cfg(not(target_os = "redox"))]
fn test_pwrite() {
    use std::io::Read;

    let mut file = tempfile().unwrap();
    let buf = [1u8; 8];
    assert_eq!(Ok(8), pwrite(&file, &buf, 8));
    let mut file_content = Vec::new();
    file.read_to_end(&mut file_content).unwrap();
    let mut expected = vec![0u8; 8];
    expected.extend(vec![1; 8]);
    assert_eq!(file_content, expected);
}

#[test]
fn test_pread() {
    use std::io::Write;

    let tempdir = tempdir().unwrap();

    let path = tempdir.path().join("pread_test_file");
    let mut file = OpenOptions::new()
        .write(true)
        .read(true)
        .create(true)
        .truncate(true)
        .open(path)
        .unwrap();
    let file_content: Vec<u8> = (0..64).collect();
    file.write_all(&file_content).unwrap();

    let mut buf = [0u8; 16];
    assert_eq!(Ok(16), pread(&file, &mut buf, 16));
    let expected: Vec<_> = (16..32).collect();
    assert_eq!(&buf[..], &expected[..]);
}

#[test]
#[cfg(not(any(
    target_os = "redox",
    target_os = "haiku",
    target_os = "solaris"
)))]
fn test_pwritev() {
    use std::io::Read;

    let to_write: Vec<u8> = (0..128).collect();
    let expected: Vec<u8> = [vec![0; 100], to_write.clone()].concat();

    let iovecs = [
        IoSlice::new(&to_write[0..17]),
        IoSlice::new(&to_write[17..64]),
        IoSlice::new(&to_write[64..128]),
    ];

    let tempdir = tempdir().unwrap();

    // pwritev them into a temporary file
    let path = tempdir.path().join("pwritev_test_file");
    let mut file = OpenOptions::new()
        .write(true)
        .read(true)
        .create(true)
        .truncate(true)
        .open(path)
        .unwrap();

    let written = pwritev(&file, &iovecs, 100).ok().unwrap();
    assert_eq!(written, to_write.len());

    // Read the data back and make sure it matches
    let mut contents = Vec::new();
    file.read_to_end(&mut contents).unwrap();
    assert_eq!(contents, expected);
}

#[test]
#[cfg(not(any(
    target_os = "redox",
    target_os = "haiku",
    target_os = "solaris"
)))]
fn test_preadv() {
    use std::io::Write;

    let to_write: Vec<u8> = (0..200).collect();
    let expected: Vec<u8> = (100..200).collect();

    let tempdir = tempdir().unwrap();

    let path = tempdir.path().join("preadv_test_file");

    let mut file = OpenOptions::new()
        .read(true)
        .write(true)
        .create(true)
        .truncate(true)
        .open(path)
        .unwrap();
    file.write_all(&to_write).unwrap();

    let mut buffers: Vec<Vec<u8>> = vec![vec![0; 24], vec![0; 1], vec![0; 75]];

    {
        // Borrow the buffers into IoVecs and preadv into them
        let mut iovecs: Vec<_> = buffers
            .iter_mut()
            .map(|buf| IoSliceMut::new(&mut buf[..]))
            .collect();
        assert_eq!(Ok(100), preadv(&file, &mut iovecs, 100));
    }

    let all = buffers.concat();
    assert_eq!(all, expected);
}

#[test]
#[cfg(all(target_os = "linux", not(target_env = "uclibc")))]
// uclibc doesn't implement process_vm_readv
// qemu-user doesn't implement process_vm_readv/writev on most arches
#[cfg_attr(qemu, ignore)]
fn test_process_vm_readv() {
    use crate::*;
    use nix::sys::signal::*;
    use nix::sys::wait::*;
    use nix::unistd::ForkResult::*;
    use std::os::unix::io::AsRawFd;

    require_capability!("test_process_vm_readv", CAP_SYS_PTRACE);
    let _m = crate::FORK_MTX.lock();

    // Pre-allocate memory in the child, since allocation isn't safe
    // post-fork (~= async-signal-safe)
    let mut vector = vec![1u8, 2, 3, 4, 5];

    let (r, w) = pipe().unwrap();
    match unsafe { fork() }.expect("Error: Fork Failed") {
        Parent { child } => {
            drop(w);
            // wait for child
            read(r.as_raw_fd(), &mut [0u8]).unwrap();
            drop(r);

            let ptr = vector.as_ptr() as usize;
            let remote_iov = RemoteIoVec { base: ptr, len: 5 };
            let mut buf = vec![0u8; 5];

            let ret = process_vm_readv(
                child,
                &mut [IoSliceMut::new(&mut buf)],
                &[remote_iov],
            );

            kill(child, SIGTERM).unwrap();
            waitpid(child, None).unwrap();

            assert_eq!(Ok(5), ret);
            assert_eq!(20u8, buf.iter().sum());
        }
        Child => {
            drop(r);
            for i in &mut vector {
                *i += 1;
            }
            let _ = write(w, b"\0");
            loop {
                pause();
            }
        }
    }
}