// This test creates a bunch of tasks that simultaneously send to each
// other in a ring. The messages should all be basically
// independent. It's designed to hammer the global kernel lock, so
// that things will look really good once we get that lock out of the
// message path.

// This version uses semi-automatically compiled channel contracts.

// xfail-pretty

import future::future;

use std;
import std::time;

import ring::server::recv;

// This module was generated by the pipe compiler.
mod ring {
    fn init() -> (client::num, server::num) { pipes::entangle() }
    enum num { num(uint, server::num), }
    mod client {
        fn num(-pipe: num, x_0: uint) -> num {
            let (c, s) = pipes::entangle();
            let message = ring::num(x_0, s);
            pipes::send(pipe, message);
            c
        }
        type num = pipes::send_packet<ring::num>;
    }
    mod server {
        impl recv for num {
            fn recv() -> extern fn(-num) -> ring::num {
                fn recv(-pipe: num) -> ring::num {
                    option::unwrap(pipes::recv(pipe))
                }
                recv
            }
        }
        type num = pipes::recv_packet<ring::num>;
    }
}

fn macros() {
    #macro[
        [#recv[chan],
         chan.recv()(chan)]
    ];

    #macro[
        [#move[x],
         unsafe { let y <- *ptr::addr_of(x); y }]
    ];
}

fn thread_ring(i: uint,
               count: uint,
               +num_chan: ring::client::num,
               +num_port: ring::server::num) {
    let mut num_chan <- some(num_chan);
    let mut num_port <- some(num_port);
    // Send/Receive lots of messages.
    for uint::range(0u, count) {|j|
        //#error("task %?, iter %?", i, j);
        let mut num_chan2 = none;
        let mut num_port2 = none;
        num_chan2 <-> num_chan;
        num_port2 <-> num_port;
        num_chan = some(ring::client::num(option::unwrap(num_chan2), i * j));
        let port = option::unwrap(num_port2);
        alt (#recv(port)) {
          ring::num(_n, p) {
            //log(error, _n);
            num_port = some(#move(p));
          }
        }
    };
}

fn main(args: [str]/~) {
    let args = if os::getenv("RUST_BENCH").is_some() {
        ["", "100", "10000"]/~
    } else if args.len() <= 1u {
        ["", "100", "1000"]/~
    } else {
        copy args
    }; 

    let num_tasks = option::get(uint::from_str(args[1]));
    let msg_per_task = option::get(uint::from_str(args[2]));

    let (num_chan, num_port) = ring::init();
    let mut num_chan = some(num_chan);

    let start = time::precise_time_s();

    // create the ring
    let mut futures = []/~;

    for uint::range(1u, num_tasks) {|i|
        //#error("spawning %?", i);
        let (new_chan, num_port) = ring::init();
        let num_chan2 = ~mut none;
        *num_chan2 <-> num_chan;
        let num_port = ~mut some(num_port);
        futures += [future::spawn {|move num_chan2, move num_port|
            let mut num_chan = none;
            num_chan <-> *num_chan2;
            let mut num_port1 = none;
            num_port1 <-> *num_port;
            thread_ring(i, msg_per_task,
                        option::unwrap(num_chan),
                        option::unwrap(num_port1))
        }]/~;
        num_chan = some(new_chan);
    };

    // do our iteration
    thread_ring(0u, msg_per_task, option::unwrap(num_chan), num_port);

    // synchronize
    for futures.each {|f| f.get() };

    let stop = time::precise_time_s();

    // all done, report stats.
    let num_msgs = num_tasks * msg_per_task;
    let elapsed = (stop - start);
    let rate = (num_msgs as float) / elapsed;

    io::println(#fmt("Sent %? messages in %? seconds",
                     num_msgs, elapsed));
    io::println(#fmt("  %? messages / second", rate));
    io::println(#fmt("  %? μs / message", 1000000. / rate));
}