use super::{HostMessage, Message, ResultMessage};
use ocl::{flags, Buffer, Context, Device, Kernel, Platform, Program, Queue};
use std::sync::mpsc::{Receiver, Sender};

#[derive(Debug)]
pub struct Host {
    #[allow(unused)]
    platform: Platform,
    #[allow(unused)]
    device: Device,
    #[allow(unused)]
    context: Context,
    program: Program,
    queue: Queue,
    n: u32,
    h: u32,
    w: u32,
    /// Workgroup size, set to 0 for max
    wg_size: usize,
    permutations: Buffer<u64>,
    receiver: Receiver<Message>,
    walls: Vec<Vec<u32>>,
}

impl Host {
    pub fn launch_sevice(
        permutation_masks: &[u64],
        n: u32,
        h: u32,
        w: u32,
        mut wg_size: usize,
        src: &str,
    ) -> ocl::Result<(Sender<Message>, std::thread::JoinHandle<()>)> {
        let platform = ocl::Platform::default();
        let device = ocl::Device::first(platform)?;
        let context = ocl::Context::builder()
            .platform(platform)
            .devices(device.clone())
            .build()?;
        let queue = ocl::Queue::new(&context, device, None)?;

        let program = Program::builder()
            .devices(device)
            .src(src)
            .build(&context)?;
        let buffer = ocl::Buffer::builder()
            .queue(queue.clone())
            .flags(flags::MEM_READ_WRITE)
            .copy_host_slice(permutation_masks)
            .len(permutation_masks.len())
            .build()?;

        let max_wg_size = device.max_wg_size()?;
        if wg_size == 0 {
            wg_size = max_wg_size;
        } else if wg_size > max_wg_size {
            return Err(ocl::Error::from("invalid workgroup size"));
        }

        let solver = Self {
            platform,
            device,
            context,
            program,
            queue,
            n,
            h,
            w,
            wg_size,
            permutations: buffer,
            rec_queues: receivers,
            walls: Vec::new(),
        };
        std::thread::Builder::new()
            .name("GPU Deamon".into())
            .spawn(move || {
                solver.run();
            })
            .unwrap();
        println!("started gpu thread");
        Ok(senders)
    }

    fn get_dim(&self, queue: usize) -> usize {
        let chunk = self.permutations.len() / self.n as usize;
        let dim = (queue + 1) * chunk;
        (dim + self.wg_size - 1) / self.wg_size * self.wg_size
    }
    fn get_off(&self, queue: usize) -> u64 {
        let chunk = self.permutations.len() / self.n as usize;
        let off = self.permutations.len() - chunk - self.get_dim(queue);
        if off > isize::max_value() as usize {
            panic!("workgroup size to big, offset underflow")
        }
        off as u64
    }
    fn get_res(&self, queue: usize) -> usize {
        let dim = self.get_dim(queue);
        dim * self.get_res_save_dim()
    }
    fn get_res_save_dim(&self) -> usize {
        (self.wg_size + 63) / 64
    }

    fn run(mut self) -> ! {
        let queues = self.rec_queues.len();
        let mut instruction_buffer = Vec::with_capacity((self.n - self.h) as usize);
        let mut result_buffer = Vec::with_capacity((self.n - self.h) as usize);

        for i in 0..queues {
            let buffer: Buffer<u64> = Buffer::builder()
                .queue(self.queue.clone())
                .len(self.wg_size)
                .flags(flags::MEM_READ_WRITE)
                .build()
                .unwrap();

            instruction_buffer.push(buffer);
            let results: Buffer<u64> = Buffer::builder()
                .queue(self.queue.clone())
                .len(self.get_res(i))
                .flags(flags::MEM_READ_WRITE)
                .build()
                .unwrap();
            result_buffer.push(results);
        }
        println!("finished gpu setup");
        for i in (0..self.rec_queues.len()).cycle() {
            if let Some(buffer) = self.rec_queues[i].read() {
                instruction_buffer[i].write(buffer).enq().unwrap();
                let dim = self.get_dim(i);

                //println!("dim: {}", dim);
                //println!("off: {}", self.get_off(i));
                //println!("result size: {}", self.get_res_save_dim());
                let kernel = Kernel::builder()
                    .program(&self.program)
                    .name("check")
                    .queue(self.queue.clone())
                    .global_work_size(dim)
                    .arg(&self.permutations)
                    .arg(&result_buffer[i])
                    .arg(&instruction_buffer[i])
                    .arg_local::<u64>(self.wg_size)
                    .arg(self.n)
                    .arg(self.w)
                    .arg(self.get_off(i))
                    .build()
                    .unwrap();

                unsafe {
                    kernel
                        .cmd()
                        .queue(&self.queue)
                        .global_work_offset(kernel.default_global_work_offset())
                        .global_work_size(dim)
                        .local_work_size(self.wg_size)
                        .enq()
                        .unwrap();
                }

                // (5) Read results from the device into a vector (`::block` not shown):
                let mut result = vec![0u64; self.get_res(i)];
                result_buffer[i]
                    .cmd()
                    .queue(&self.queue)
                    .offset(0)
                    .read(&mut result)
                    .enq()
                    .unwrap();
                for (j, r) in result.iter().enumerate() {
                    if j == 0 {
                        continue;
                    }
                    for b in 0..64 {
                        if r & (1 << b) != 0 {
                            let permutation =
                                j / self.get_res_save_dim() + self.get_off(i) as usize;
                            let instruction = (j % self.get_res_save_dim()) * 64 + b;
                            let mut wall = self.rec_queues[i].get_rows()[instruction].clone();
                            wall.push(permutation as u32);
                            println!("{:?}", wall);
                            self.walls.push(wall);
                        }
                    }
                }
            }
        }
        panic!();
    }
}
/*
pub fn check(permutations: &[u64], w: u32, n: u32, mask: u64, offset: usize) -> ocl::Result<()> {
    //println!("read src!");
    let src = std::fs::read_to_string("src/solvers/check.cl").expect("failed to open kernel file");

    //println!("created queue!");
    println!("offset: {}", offset);
    println!("length: {}", permutations.len() - offset);
    let pro_que = ocl::ProQue::builder()
        .src(src)
        .dims(permutations.len() - offset)
        .build()?;

    let results = pro_que.create_buffer::<i32>()?;
    let kernel = pro_que
        .kernel_builder("check")
        .arg(get_buffer())
        .arg(&results)
        .arg(mask)
        .arg(n)
        .arg(w)
        .arg(offset as u64)
        //.global_work_offset(offset)
        .build()?;

    //println!("starting calculation");
    unsafe {
        kernel.enq()?;
    }

    let mut vec = vec![0; results.len()];
    results.read(&mut vec).enq()?;

    if vec.iter().any(|x| *x != 0) {
        println!("The resuts are now '{:?}'!", vec);
    }
    Ok(())
}*/