Browse Source

get rid of everything else except the influx mod, and rename the crate influx-writer

master
Jonathan Strong 4 years ago
parent
commit
94f1e93026
9 changed files with 1323 additions and 3280 deletions
  1. +8
    -31
      Cargo.toml
  2. +30
    -0
      README.md
  3. +0
    -127
      examples/hist-interval.rs
  4. +0
    -62
      examples/precipice.rs
  5. +0
    -195
      src/hist.rs
  6. +0
    -1417
      src/influx.rs
  7. +0
    -774
      src/latency.rs
  8. +1285
    -90
      src/lib.rs
  9. +0
    -584
      src/warnings.rs

+ 8
- 31
Cargo.toml View File

@@ -1,56 +1,33 @@
[package]
name = "logging"
version = "0.5.2"
name = "influx-writer"
version = "0.6.0"
authors = ["Jonathan Strong <jonathan.strong@gmail.com>"]
edition = "2018"

[[example]]
name = "hist-interval"
path = "examples/hist-interval.rs"
[lib]
name = "influx_writer"
path = "src/lib.rs"

[dependencies]
chrono = { version = "0.4", features = ["serde"] }
hyper = "0.10"
termion = "1.4.0"
slog = "2.0.6"
slog = "2"
slog-term = "2"
uuid = { version = "0.8", features = ["serde", "v4", "slog"] }
hdrhistogram = "6"
slog-async = "2"
smallvec = "0.6"
num = "0.1"
dirs = "1"
crossbeam-channel = "0.3"
pretty_toa = "1.0.0"

sloggers = "0.3"
#sloggers = { path = "../sloggers" }

#decimal = { path = "../decimal", version = "2" }
#decimal = { git = "https://github.com/jonathanstrong/decimal", branch = "v2.3.x" }
decimal = { git = "https://github.com/jonathanstrong/decimal", branch = "v2.3.x" }
decimal-macros = { git = "https://github.com/jonathanstrong/decimal", branch = "v2.3.x" }

#windows = { path = "../windows", version = "0.2" }
money = { path = "../money", version = "0.3" }
pubsub = { path = "../pubsub", optional = true }

[features]
default = ["inlines"]
no-thrash = []
default = ["string-tags"]
trace = ["slog/release_max_level_trace", "slog/max_level_trace"]
debug = ["slog/release_max_level_debug", "slog/max_level_debug"]
test = []
localhost = []
harrison = []
washington = []
scholes = []
no-influx-buffer = []
disable-short-uuid = []
warnings = []
inlines = []
latency = ["pubsub"]
string-tags = []
unstable = []

[profile.bench]
lto = true

+ 30
- 0
README.md View File

@@ -0,0 +1,30 @@
# influx-writer

An opinionated influxdb client in rust:

- http write requests are managed by a worker thread, so "writing" to influx is wait free on the hot path
- worker thread recovers from failed writes/requests with robust retry and failure handling
- library includes `measure!`, a mini-dsl for creating and sending measurements to influxdb

## `measure!`

`measure!` is a macro that allows highly ergonomic creation and sending of `OwnedMeasurement` instances, at the cost of a bit of a learning curve.

A single letter is used to denote the type of a field, and `t` is used to denote a tag:

```rust
measure!(influx, "measurement_name", t(color, "red"), i(n, 1), tm(now()));
```

In the above example, `influx` is the identifier for a `InfluxWriter` instance. `InfluxWriter` is a handle to the worker thread that is sending data to the influxdb server.

Now for a more advanced example: if only a single argument is passed to `t`, `f`, `i`, `b`, and other field type short-hands, it creates a field or tag by that name, and uses value in a variable binding of the same name as the field or tag's value:

```rust
let color = "red";
let n = 1;
let t = now(); // in this example, now() would return integer timestamp
measure!(influx, "even_faster", t(color), i(n), tm(t));
```

In the example above, `measure!` creates a `OwnedMeasurement` instance, fills it with a tag named "color" with the value "red", an integer field "n" with the value 1, and a timestamp with the value that's in the variable `t`. Then it uses `influx` to send the measurement to the worker thread.

+ 0
- 127
examples/hist-interval.rs View File

@@ -1,127 +0,0 @@
#![allow(unused)]

extern crate logging;

use std::time::{Instant, Duration};
use std::thread;

use logging::hist::{Entry, HistLog, nanos};

const N_SECS: u64 = 30;

//const N_THREADS: usize = 48;

macro_rules! n_threads {
($n:expr) => {
const N_THREADS: usize = $n;
const NAME: &'static str = concat!("sleeptest_", stringify!($n));
}
}

n_threads!(96);

fn main() {
::std::process::exit(test_n());
}

fn test_n() -> i32 {
let start = Instant::now();
let hist = HistLog::new(NAME, "master", Duration::from_millis(100));
for _ in 0..N_THREADS {
let mut a = hist.clone_with_tag("sleep_1ns");
thread::spawn(move || {

let mut prev = Instant::now();
let mut loop_time = Instant::now();

loop {
prev = loop_time;
loop_time = Instant::now();
a.record(nanos(loop_time - prev));
a.check_send(loop_time);


if loop_time - start > Duration::from_secs(N_SECS) { break }

thread::sleep(Duration::new(0, 1));
//thread::yield_now();
}
});
}

thread::sleep(Duration::from_secs(N_SECS));

0
}

fn test_3() -> i32 {
let start = Instant::now();
let hist = HistLog::new("sleeptest", "master", Duration::from_millis(100));
let mut a = hist.clone_with_tag("yield");
let mut b = hist.clone_with_tag("sleep_0");
let mut c = hist.clone_with_tag("sleep_100ns");

thread::spawn(move || {

let mut prev = Instant::now();
let mut loop_time = Instant::now();
let mut i = 0;

loop {
prev = loop_time;
loop_time = Instant::now();
a.record(nanos(loop_time - prev));
a.check_send(loop_time);


if loop_time - start > Duration::from_secs(N_SECS) { break }

i += 1;
//if i % 100 == 0 { thread::sleep(Duration::new(0, 0)); }
//thread::sleep(Duration::new(0, 0));
thread::yield_now();
}
});

thread::spawn(move || {
let mut prev = Instant::now();
let mut loop_time = Instant::now();
let mut i = 0;

loop {
prev = loop_time;
loop_time = Instant::now();
b.record(nanos(loop_time - prev));
b.check_send(loop_time);

if loop_time - start > Duration::from_secs(N_SECS) { break }

i += 1;
//if i % 1_000 == 0 { thread::sleep(Duration::new(0, 0)); }
//if i % 100 == 0 { thread::sleep(Duration::new(0, 0)); }
thread::sleep(Duration::new(0, 0));
}
});

let mut prev = Instant::now();
let mut loop_time = Instant::now();
let mut i = 0;

loop {
prev = loop_time;
loop_time = Instant::now();
c.record(nanos(loop_time - prev));
c.check_send(loop_time);

if loop_time - start > Duration::from_secs(N_SECS) { break }

i += 1;
//if i % 100_000 == 0 { thread::sleep(Duration::from_millis(10)); }
//if i % 100 == 0 { thread::sleep(Duration::new(0, 0)); }
thread::sleep(Duration::new(0, 100));
}

0
}



+ 0
- 62
examples/precipice.rs View File

@@ -1,62 +0,0 @@
#![allow(unused_imports)]

#[macro_use]
extern crate slog;
#[macro_use]
extern crate logging;

use std::io::{self, prelude::*};
use std::thread;
use std::sync::{Arc, atomic::{AtomicBool, Ordering}};
use std::time::*;
use chrono::Utc;
use slog::Drain;
use pretty_toa::ThousandsSep;
use logging::influx::InfluxWriter;

const INTERVAL: Duration = Duration::from_micros(1); //from_millis(1);
const HB_EVERY: usize = 1_000_000;

fn main() {
let to_file = logging::truncating_file_logger("var/log/precipice.log", sloggers::types::Severity::Debug);
let decorator = slog_term::TermDecorator::new().stdout().force_color().build();
let drain = slog_term::CompactFormat::new(decorator).use_utc_timestamp().build().fuse();
let drain = slog_async::Async::new(drain).chan_size(8192).thread_name("recv".into()).build().fuse();
let drain = slog::Duplicate::new(drain, to_file).fuse();
let root = slog::Logger::root(drain, o!());
let logger = root.new(o!("thread" => "main"));
info!(logger, "initializing...");
let influx = InfluxWriter::with_logger("localhost", "precipice", 1024, root.new(o!("thread" => "InfluxWriter")));
let stop = Arc::new(AtomicBool::new(false));
let thread = {
let stop = Arc::clone(&stop);
let logger = root.new(o!("thread" => "blaster"));
let influx = influx.clone();
thread::spawn(move || {
let mut i = 0;
let mut sum = 0;
while !stop.load(Ordering::Relaxed) {
measure!(influx, xs, i(i), tm(logging::inanos(Utc::now())));
sum += i;
i += 1;
if i % HB_EVERY == 0 {
info!(logger, "sent {} measurements", i.thousands_sep());
}
thread::sleep(INTERVAL);
}
info!(logger, "exiting"; "n_sent" => i, "sum" => sum);
})
};

let mut keys = String::new();
loop {
if let Ok(_) = io::stdin().read_line(&mut keys) {
break
}
thread::sleep(Duration::from_millis(1));
}
stop.store(true, Ordering::Relaxed);
let _ = thread.join();
}



+ 0
- 195
src/hist.rs View File

@@ -1,195 +0,0 @@
use std::sync::mpsc::{Sender, Receiver, channel};
use std::sync::Arc;
use std::time::{Instant, Duration, SystemTime, UNIX_EPOCH};
use std::path::PathBuf;
use std::thread::{self, JoinHandle};
use std::io;
use std::{mem, fs};

use dirs::home_dir;
use hdrhistogram::{Histogram};
use hdrhistogram::serialization::V2DeflateSerializer;
use hdrhistogram::serialization::interval_log::{IntervalLogWriterBuilder, Tag};

pub type C = u64;

pub fn nanos(d: Duration) -> u64 {
d.as_secs() * 1_000_000_000_u64 + (d.subsec_nanos() as u64)
}

pub struct HistLog {
series: &'static str,
tag: &'static str,
freq: Duration,
last_sent: Instant,
tx: Sender<Option<Entry>>,
hist: Histogram<C>,
thread: Option<Arc<thread::JoinHandle<()>>>,
}

pub struct Entry {
pub tag: &'static str,
pub start: SystemTime,
pub end: SystemTime,
pub hist: Histogram<C>,
}

impl Clone for HistLog {
fn clone(&self) -> Self {
let thread = self.thread.as_ref().map(|x| Arc::clone(x));
Self {
series: self.series.clone(),
tag: self.tag.clone(),
freq: self.freq.clone(),
last_sent: Instant::now(),
tx: self.tx.clone(),
hist: self.hist.clone(),
thread,
}
}
}

impl HistLog {
pub fn new(series: &'static str, tag: &'static str, freq: Duration) -> Self {
let (tx, rx) = channel();
let mut dir = home_dir().expect("home_dir");
dir.push("src/market-maker/var/hist");
fs::create_dir_all(&dir).unwrap();
let thread = Some(Arc::new(Self::scribe(series, rx, dir)));
let last_sent = Instant::now();
let hist = Histogram::new(3).unwrap();
Self { series, tag, freq, last_sent, tx, hist, thread }
}

/// Create a new `HistLog` that will save results in a specified
/// directory (`path`).
pub fn with_path(
path: &str,
series: &'static str,
tag: &'static str,
freq: Duration,
) -> Self {
let (tx, rx) = channel();
let dir = PathBuf::from(path);
// let mut dir = env::home_dir().unwrap();
// dir.push("src/market-maker/var/hist");
fs::create_dir_all(&dir).ok();
let thread = Some(Arc::new(Self::scribe(series, rx, dir)));
let last_sent = Instant::now();
let hist = Histogram::new(3).unwrap();
Self { series, tag, freq, last_sent, tx, hist, thread }
}


pub fn new_with_tag(&self, tag: &'static str) -> Self {
Self::new(self.series, tag, self.freq)
}

pub fn clone_with_tag(&self, tag: &'static str) -> Self {
let thread = self.thread.as_ref().map(|x| Arc::clone(x)).unwrap();
assert!(self.thread.is_some(), "self.thread is {:?}", self.thread);
let tx = self.tx.clone();
Self {
series: self.series,
tag,
freq: self.freq,
last_sent: Instant::now(),
tx,
hist: self.hist.clone(),
thread: Some(thread),
}
}

pub fn clone_with_tag_and_freq(&self, tag: &'static str, freq: Duration) -> HistLog {
let mut clone = self.clone_with_tag(tag);
clone.freq = freq;
clone
}

pub fn record(&mut self, value: u64) {
let _ = self.hist.record(value);
}

/// If for some reason there was a pause in between using the struct,
/// this resets the internal state of both the values recorded to the
/// `Histogram` and the value of when it last sent a `Histogram` onto
/// the writing thread.
///
pub fn reset(&mut self) {
self.hist.clear();
self.last_sent = Instant::now();
}

fn send(&mut self, loop_time: Instant) {
let end = SystemTime::now();
let start = end - (loop_time - self.last_sent);
assert!(end > start, "end <= start!");
let mut next = Histogram::new_from(&self.hist);
mem::swap(&mut self.hist, &mut next);
self.tx.send(Some(Entry { tag: self.tag, start, end, hist: next })).expect("sending entry failed");
self.last_sent = loop_time;
}

pub fn check_send(&mut self, loop_time: Instant) {
//let since = loop_time - self.last_sent;
if loop_time > self.last_sent && loop_time - self.last_sent >= self.freq {
// send sets self.last_sent to loop_time fyi
self.send(loop_time);
}
}

fn scribe(
series : &'static str,
rx : Receiver<Option<Entry>>,
dir : PathBuf,
) -> JoinHandle<()> {
let mut ser = V2DeflateSerializer::new();
let start_time = SystemTime::now();
let seconds = start_time.duration_since(UNIX_EPOCH).unwrap().as_secs();
let path = dir.join(&format!("{}-interval-log-{}.v2z", series, seconds));
let file = fs::File::create(&path).unwrap();
thread::Builder::new().name(format!("mm:hist:{}", series)).spawn(move || {
let mut buf = io::LineWriter::new(file);
let mut wtr =
IntervalLogWriterBuilder::new()
.with_base_time(UNIX_EPOCH)
.with_start_time(start_time)
.begin_log_with(&mut buf, &mut ser)
.unwrap();

loop {
match rx.recv() { //.recv_timeout(Duration::from_millis(1)) {
//match rx.recv_timeout(Duration::new(1, 0)) {
Ok(Some(Entry { tag, start, end, hist })) => {
wtr.write_histogram(&hist, start.duration_since(UNIX_EPOCH).unwrap(),
end.duration_since(start).unwrap(), Tag::new(tag))
.ok();
//.map_err(|e| { println!("{:?}", e); e }).ok();
}

// `None` used as terminate signal from `Drop`
Ok(None) => break,

_ => {
thread::sleep(Duration::new(0, 0));
}
}

}
}).unwrap()
}
}

impl Drop for HistLog {
fn drop(&mut self) {
if !self.hist.is_empty() { self.send(Instant::now()) }

if let Some(arc) = self.thread.take() {
//println!("in Drop, strong count is {}", Arc::strong_count(&arc));
if let Ok(thread) = Arc::try_unwrap(arc) {
let _ = self.tx.send(None);
let _ = thread.join();
}
}
}
}

+ 0
- 1417
src/influx.rs
File diff suppressed because it is too large
View File


+ 0
- 774
src/latency.rs View File

@@ -1,774 +0,0 @@
#![allow(unused)]
use std::thread::{self, JoinHandle};
use std::sync::mpsc::{Sender, channel};
use std::fmt;
use std::time::{Instant, Duration};

use chrono::{self, DateTime, Utc};
use pub_sub::PubSub;
use sloggers::types::Severity;

//use windows::{DurationWindow, Incremental, Window};
use money::{Ticker, Side, Exchange};

use super::file_logger;
use influx::{self, OwnedMeasurement, OwnedValue};

use self::windows::Incremental;

pub type Nanos = u64;

pub const SECOND: u64 = 1e9 as u64;
pub const MINUTE: u64 = SECOND * 60;
pub const HOUR: u64 = MINUTE * 60;
pub const MILLISECOND: u64 = SECOND / 1000;
pub const MICROSECOND: u64 = MILLISECOND / 1000;

pub fn nanos(d: Duration) -> Nanos {
d.as_secs() * 1_000_000_000 + (d.subsec_nanos() as u64)
}

pub fn dt_nanos(t: DateTime<Utc>) -> i64 {
(t.timestamp() as i64) * 1_000_000_000_i64 + (t.timestamp_subsec_nanos() as i64)
}

pub fn now() -> i64 { dt_nanos(Utc::now()) }

pub fn tfmt(ns: Nanos) -> String {
match ns {
t if t <= MICROSECOND => {
format!("{}ns", t)
}

t if t > MICROSECOND && t < MILLISECOND => {
format!("{}u", t / MICROSECOND)
}
t if t > MILLISECOND && t < SECOND => {
format!("{}ms", t / MILLISECOND)
}

t => {
format!("{}.{}sec", t / SECOND, t / MILLISECOND)
}
}
}

pub fn tfmt_dur(d: Duration) -> String {
tfmt(nanos(d))
}

pub fn tfmt_dt(dt: DateTime<Utc>) -> String {
Utc::now().signed_duration_since(dt)
.to_std()
.map(|dur| {
tfmt_dur(dur)
}).unwrap_or("?".into())
}


pub fn tfmt_write(ns: Nanos, f: &mut fmt::Formatter) -> fmt::Result {
match ns {
t if t <= MICROSECOND => {
write!(f, "{}ns", t)
}

t if t > MICROSECOND && t < MILLISECOND => {
write!(f, "{}u", t / MICROSECOND)
}

t if t > MILLISECOND && t < SECOND => {
write!(f, "{}ms", t / MILLISECOND)
}

t => {
write!(f, "{}.{}sec", t / SECOND, t / MILLISECOND)
}
}
}

#[doc(hide)]
mod windows {
use super::*;
use std::ops::{Div, Mul, Sub, SubAssign, AddAssign};
use std::collections::VecDeque;
use num::Float;

const INITIAL_CAPACITY: usize = 1000;

#[derive(Clone, Debug)]
pub struct Point<T>
//where T: Default
{
time: Instant,
value: T
}

#[derive(Debug, Clone)]
pub struct Window<T>
where T: Default
{
pub size: Duration, // window size
mean: T,
ps: T,
psa: T,
var: T,
sum: T,
count: u32,
items: VecDeque<Point<T>>,
}

#[derive(Default)]
pub struct DurationWindow {
pub size: Duration,
mean: Duration,
sum: Duration,
count: u32,
items: VecDeque<Point<Duration>>
}

impl<T> Point<T>
where T: Default + Copy
{
fn new(time: Instant, value: T) -> Self {
Point { time, value }
}

fn value(&self) -> T {
self.value
}
}

impl<T> Window<T>
where T: Default + Zero
{
pub fn new(size: Duration) -> Self {
Window {
size,
mean: T::default(),
psa: T::default(),
ps: T::default(),
sum: T::default(),
count: 0,
var: T::default(),
items: VecDeque::with_capacity(INITIAL_CAPACITY),
}
}

pub fn with_size_and_capacity(size: Duration, capacity: usize) -> Self {
Window {
size,
mean: T::default(),
psa: T::default(),
ps: T::default(),
sum: T::default(),
count: 0,
var: T::default(),
items: VecDeque::with_capacity(capacity),
}
}
}

impl<T> From<Duration> for Window<T>
where T: Default + Zero
{
fn from(size: Duration) -> Self {
Window::new(size)
}
}

impl From<Duration> for DurationWindow {
fn from(size: Duration) -> Self {
DurationWindow::new(size)
}
}

pub trait Incremental<T> {
/// Purge expired items.
///
#[inline]
fn refresh(&mut self, t: Instant) -> &Self;

/// Add a new item.
///
#[inline]
fn add(&mut self, time: Instant, value: T);

/// Add a new item and purge expired items.
///
#[inline]
fn update(&mut self, time: Instant, value: T) {
self.refresh(time);
self.add(time, value);
}
}

pub trait Zero {
fn zero() -> Self;
}

pub trait One {
fn one() -> Self;
}

macro_rules! zero {
($t:ty, $body:expr) => {

impl Zero for $t {
fn zero() -> $t { $body }
}
}
}

macro_rules! one {
($t:ty, $body:expr) => {

impl One for $t {
fn one() -> $t { $body }
}
}
}

zero!(f64, 0.0);
zero!(f32, 0.0);
zero!(u128, 0);
zero!(i128, 0);
zero!(u64, 0);
zero!(i64, 0);
zero!(i32, 0);
zero!(u32, 0);
zero!(u16, 0);
one!(f64, 1.0);
one!(f32, 1.0);
one!(u128, 1);
one!(i128, 1);
one!(u64, 1);
one!(i64, 1);
one!(i32, 1);
one!(u32, 1);
one!(u16, 1);

impl<T> Incremental<T> for Window<T>
where T: Default + AddAssign<T> + SubAssign<T> + From<u32> + Div<Output = T> +
Mul<Output = T> + Sub<Output = T> + Copy
{
#[inline]
fn refresh(&mut self, t: Instant) -> &Self {
if !self.items.is_empty() {
let (n_remove, sum, ps, count) =
self.items.iter()
.take_while(|x| t - x.time > self.size)
.fold((0, self.sum, self.ps, self.count), |(n_remove, sum, ps, count), x| {
(n_remove + 1, sum - x.value, ps - x.value * x.value, count - 1)
});
self.sum = sum;
self.ps = ps;
self.count = count;
for _ in 0..n_remove {
self.items.pop_front();
}
}

if self.count > 0 {
self.mean = self.sum / self.count.into();
self.psa = self.ps / self.count.into();
let c: T = self.count.into();
self.var = (self.psa * c - c * self.mean * self.mean) / c;
}
self
}

/// Creates `Point { time, value }` and pushes to `self.items`.
///
#[inline]
fn add(&mut self, time: Instant, value: T) {
let p = Point::new(time, value);
self.sum += p.value;
self.ps += p.value * p.value;
self.count += 1;
self.items.push_back(p);
}

#[inline]
fn update(&mut self, time: Instant, value: T) {
self.add(time, value);
self.refresh(time);
}
}

impl Incremental<Duration> for DurationWindow {
#[inline]
fn refresh(&mut self, t: Instant) -> &Self {
if !self.items.is_empty() {
let (n_remove, sum, count) =
self.items.iter()
.take_while(|x| t - x.time > self.size)
.fold((0, self.sum, self.count), |(n_remove, sum, count), x| {
(n_remove + 1, sum - x.value, count - 1)
});
self.sum = sum;
self.count = count;
for _ in 0..n_remove {
self.items.pop_front();
}
}

if self.count > 0 {
self.mean = self.sum / self.count.into();
}

self
}

#[inline]
fn add(&mut self, time: Instant, value: Duration) {
let p = Point::new(time, value);
self.sum += p.value;
self.count += 1;
self.items.push_back(p);
}
}


impl<T> Window<T>
where T: Default + Copy
{
pub fn mean(&self) -> T { self.mean }
pub fn var(&self) -> T { self.var }
pub fn psa(&self) -> T { self.psa }
pub fn ps(&self) -> T { self.ps }
pub fn count(&self) -> u32 { self.count }
pub fn len(&self) -> usize { self.items.len() }
pub fn is_empty(&self) -> bool { self.items.is_empty() }

/// Returns the `Duration` between `t` and the first `Point` in `self.items`.
///
/// If there are no items, returns `Duration { secs: 0, nanos: 0 }`.
///
/// # Panics
///
/// This function will panic if `t` is earlier than the first `Point`'s `Instant`.
///
#[inline]
pub fn elapsed(&self, t: Instant) -> Duration {
self.items.front()
.map(|p| {
t - p.time
}).unwrap_or_else(|| Duration::new(0, 0))
}
}

impl<T> Window<T>
where T: Float + Default
{
#[inline]
pub fn std(&self) -> T { self.var.sqrt() }
}

impl DurationWindow {
pub fn new(size: Duration) -> Self { DurationWindow { size, ..Default::default() } }
pub fn mean(&self) -> Duration { self.mean }
pub fn count(&self) -> u32 { self.count }
pub fn len(&self) -> usize { self.items.len() }
pub fn is_empty(&self) -> bool { self.items.is_empty() }

#[inline]
pub fn nanos(d: Duration) -> u64 { d.as_secs() * 1_000_000_000 + (d.subsec_nanos() as u64) }

#[inline]
pub fn micros(d: Duration) -> Option<u32> {
if d <= Duration::new(4_294, 967_295_000) {
Some((d.as_secs() * 1_000_000) as u32 + d.subsec_nanos() / 1_000u32)
} else {
None
}
}

#[inline]
pub fn mean_nanos(&self) -> u64 { DurationWindow::nanos(self.mean()) }

#[inline]
pub fn max(&self) -> Option<Duration> {
self.items.iter()
.map(|p| p.value)
.max()
}

#[inline]
pub fn max_nanos(&self) -> Option<u64> {
self.max()
.map(|x| DurationWindow::nanos(x))
}

#[inline]
pub fn first(&self) -> Option<Duration> {
self.items
.front()
.map(|pt| pt.value())
}

/// Returns the `Duration` between `t` and the first `Point` in `self.items`.
///
/// If there are no items, returns `Duration { secs: 0, nanos: 0 }`.
///
/// # Panics
///
/// This function will panic if `t` is earlier than the first `Point`'s `Instant`.
///
#[inline]
pub fn elapsed(&self, t: Instant) -> Duration {
self.items.front()
.map(|p| {
t - p.time
}).unwrap_or_else(|| Duration::new(0, 0))
}
}
}

#[derive(Debug)]
pub enum Latency {
Ws(Exchange, Ticker, Duration),
Http(Exchange, Duration),
Trade(Exchange, Ticker, Duration),
Terminate
}

#[derive(Debug)]
pub enum ExperiencedLatency {

GdaxWebsocket(Duration),
GdaxHttpPublic(Duration),
GdaxHttpPrivate(Duration),
PlnxHttpPublic(Duration),
PlnxHttpPrivate(Duration),
PlnxOrderBook(Duration),
KrknHttpPublic(Duration),
KrknHttpPrivate(Duration),
KrknTrade(Duration, &'static str, Option<Ticker>, Option<Side>),
PlnxWs(Ticker),

Terminate
}

#[derive(Debug, Clone)]
pub struct Update {
pub gdax_ws: Nanos,
pub gdax_trade: Nanos,
pub gdax_last: DateTime<Utc>
}

impl Default for Update {
fn default() -> Self {
Update {
gdax_ws: 0,
gdax_trade: 0,
gdax_last: Utc::now(),
}
}
}

#[derive(Debug, Clone)]
pub struct LatencyUpdate {
pub gdax_ws: Nanos,
pub krkn_pub: Nanos,
pub krkn_priv: Nanos,
pub plnx_pub: Nanos,
pub plnx_priv: Nanos,
pub plnx_order: Nanos,
pub krkn_trade_30_mean: Nanos,
pub krkn_trade_30_max: Nanos,

pub krkn_trade_300_mean: Nanos,
pub krkn_trade_300_max: Nanos,

pub plnx_last: DateTime<Utc>,
pub krkn_last: DateTime<Utc>,

pub plnx_ws_count: u64,
}

impl Default for LatencyUpdate {
fn default() -> Self {
LatencyUpdate {
gdax_ws : 0,
krkn_pub : 0,
krkn_priv : 0,
plnx_pub : 0,
plnx_priv : 0,
plnx_order : 0,
krkn_trade_30_mean : 0,
krkn_trade_30_max : 0,
krkn_trade_300_mean : 0,
krkn_trade_300_max : 0,
plnx_ws_count : 0,

plnx_last : Utc::now(),
krkn_last : Utc::now(),
}
}
}

pub struct Manager {
pub tx: Sender<Latency>,
pub channel: PubSub<Update>,
thread: Option<JoinHandle<()>>,
}

pub struct LatencyManager {
pub tx: Sender<ExperiencedLatency>,
pub channel: PubSub<LatencyUpdate>,
thread: Option<JoinHandle<()>>,
}

/// returns a DateTime equal to now - `dur`
///
pub fn dt_from_dur(dur: Duration) -> DateTime<Utc> {
let old_dur = chrono::Duration::nanoseconds(nanos(dur) as i64);
Utc::now() - old_dur
}

struct Last {
broadcast: Instant,
plnx: Instant,
krkn: Instant,
gdax: Instant,
}

impl Default for Last {
fn default() -> Self {
Last {
broadcast: Instant::now(),
plnx: Instant::now(),
krkn: Instant::now(),
gdax: Instant::now(),
}
}
}

impl Manager {
pub fn new(window: Duration,
log_path: &'static str,
measurements: Sender<OwnedMeasurement>) -> Self {

let (tx, rx) = channel();
let channel = PubSub::new();
let channel_copy = channel.clone();
let logger = file_logger(log_path, Severity::Info);
info!(logger, "initializing");
let mut gdax_ws = windows::DurationWindow::new(window);
let mut gdax_trade = windows::DurationWindow::new(window);

let mut last = Last::default();

info!(logger, "entering loop");

let thread = Some(thread::spawn(move || {
loop {

let loop_time = Instant::now();

if let Ok(msg) = rx.recv_timeout(Duration::from_millis(1)) {
debug!(logger, "rcvd {:?}", msg);

match msg {
Latency::Ws(_, _, dur) => {
gdax_ws.update(loop_time, dur);
last.gdax = loop_time;
}

Latency::Trade(_, ticker, dur) => {
gdax_trade.update(loop_time, dur);
last.gdax = loop_time;
let nanos = windows::DurationWindow::nanos(dur);
measurements.send(
OwnedMeasurement::new("gdax_trade_api")
.add_tag("ticker", ticker.as_str())
.add_field("nanos", OwnedValue::Integer(nanos as i64))
.set_timestamp(influx::now())).unwrap();
}

Latency::Terminate => break,

_ => {}
}
}

if loop_time - last.broadcast > Duration::from_millis(100) {
debug!(logger, "initalizing broadcast");

let update = Update {
gdax_ws: gdax_ws.refresh(loop_time).mean_nanos(),
gdax_trade: gdax_trade.refresh(loop_time).mean_nanos(),
gdax_last: dt_from_dur(loop_time - last.gdax)
};
channel.send(update).unwrap();
last.broadcast = loop_time;
debug!(logger, "sent broadcast");
}

}
debug!(logger, "latency manager terminating");
}));

Manager {
tx,
channel: channel_copy,
thread,
}
}
}

impl Drop for LatencyManager {
fn drop(&mut self) {
for _ in 0..100 { self.tx.send(ExperiencedLatency::Terminate).unwrap(); }
if let Some(thread) = self.thread.take() {
let _ = thread.join();
}
}
}

impl Drop for Manager {
fn drop(&mut self) {
for _ in 0..100 { self.tx.send(Latency::Terminate).unwrap(); }
if let Some(thread) = self.thread.take() {
let _ = thread.join();
}
}
}

impl LatencyManager {
pub fn new(d: Duration) -> Self {
let (tx, rx) = channel();
let tx_copy = tx.clone();
let channel = PubSub::new();
let channel_copy = channel.clone();
//let w = w.clone();

let thread = Some(thread::spawn(move || {
let logger = file_logger("var/log/latency-manager.log", Severity::Info);

info!(logger, "initializing DurationWindows");
let mut gdax_ws = windows::DurationWindow::new(d);
let mut gdax_priv = windows::DurationWindow::new(d);
let mut krkn_pub = windows::DurationWindow::new(d);
let mut krkn_priv = windows::DurationWindow::new(d);
let mut plnx_pub = windows::DurationWindow::new(d);
let mut plnx_priv = windows::DurationWindow::new(d);
let mut plnx_order = windows::DurationWindow::new(d);
let mut plnx_ws_count: windows::Window<u32> = windows::Window::new(d);

// yes I am intentionally breaking from the hard-typed duration
// window ... that was a stupid idea
//
let mut krkn_trade_30 = windows::DurationWindow::new(Duration::from_secs(30));
let mut krkn_trade_300 = windows::DurationWindow::new(Duration::from_secs(300));

let mut last = Last::default();

thread::sleep(Duration::from_millis(1));

info!(logger, "entering loop");
loop {
let loop_time = Instant::now();

if let Ok(msg) = rx.recv() {
debug!(logger, "new msg: {:?}", msg);

match msg {
ExperiencedLatency::Terminate => {
crit!(logger, "terminating");
break;
}

ExperiencedLatency::GdaxWebsocket(d) => gdax_ws.update(loop_time, d),

ExperiencedLatency::GdaxHttpPrivate(d) => gdax_priv.update(loop_time, d),

ExperiencedLatency::KrknHttpPublic(d) => {
last.krkn = loop_time;
krkn_pub.update(loop_time, d)
}

ExperiencedLatency::KrknHttpPrivate(d) => {
last.krkn = loop_time;
krkn_priv.update(loop_time, d)
}

ExperiencedLatency::PlnxHttpPublic(d) => {
last.plnx = loop_time;
plnx_pub.update(loop_time, d)
}

ExperiencedLatency::PlnxHttpPrivate(d) => {
last.plnx = loop_time;
plnx_priv.update(loop_time, d)
}

ExperiencedLatency::PlnxOrderBook(d) => {
last.plnx = loop_time;
plnx_order.update(loop_time, d)
}

ExperiencedLatency::PlnxWs(_) => {
last.plnx = loop_time;
plnx_ws_count.update(loop_time, 1_u32);
}

ExperiencedLatency::KrknTrade(d, cmd, _, _) => {
debug!(logger, "new KrknTrade";
"cmd" => cmd);
last.krkn = loop_time;
krkn_trade_30.update(loop_time, d);
krkn_trade_300.update(loop_time, d);
}

other => {
warn!(logger, "unexpected msg: {:?}", other);
}
}
}

if loop_time - last.broadcast > Duration::from_millis(100) {
debug!(logger, "initalizing broadcast");
// note - because we mutated the Window instances
// above, we need a fresh Instant to avoid less than other
// panic
//
krkn_trade_30.refresh(loop_time);
krkn_trade_300.refresh(loop_time);
let update = LatencyUpdate {
gdax_ws: gdax_ws.refresh(loop_time).mean_nanos(),
krkn_pub: krkn_pub.refresh(loop_time).mean_nanos(),
krkn_priv: krkn_priv.refresh(loop_time).mean_nanos(),
plnx_pub: plnx_pub.refresh(loop_time).mean_nanos(),
plnx_priv: plnx_priv.refresh(loop_time).mean_nanos(),
plnx_order: plnx_order.refresh(loop_time).mean_nanos(),

krkn_trade_30_mean: krkn_trade_30.mean_nanos(),
krkn_trade_30_max: krkn_trade_30.max_nanos().unwrap_or(0),

krkn_trade_300_mean: krkn_trade_300.mean_nanos(),
krkn_trade_300_max: krkn_trade_300.max_nanos().unwrap_or(0),

plnx_last: dt_from_dur(loop_time - last.plnx),
krkn_last: dt_from_dur(loop_time - last.krkn),

plnx_ws_count: plnx_ws_count.refresh(loop_time).count() as u64,

};
channel.send(update).unwrap();
last.broadcast = loop_time;
debug!(logger, "sent broadcast");
}
}
crit!(logger, "goodbye");
}));

LatencyManager {
tx: tx_copy,
channel: channel_copy,
thread
}
}
}

+ 1285
- 90
src/lib.rs
File diff suppressed because it is too large
View File


+ 0
- 584
src/warnings.rs View File

@@ -1,584 +0,0 @@
//! An object to handle everyone's errors
//!

use std::thread::{self, JoinHandle};
use std::sync::{Arc, Mutex, RwLock};
use std::sync::mpsc::{Sender, channel};
use std::collections::{BTreeMap, VecDeque};
use std::fmt::{self, Display, Error as FmtError, Formatter};
use std::io::{self, Write};
use std::fs;

use chrono::{DateTime, Utc};
use termion::color::{self, Fg, Bg};
use influent::measurement::{Measurement, Value as InfluentValue};
use slog::{self, OwnedKVList, Drain, Key, KV, Level, Logger};
use sloggers::types::Severity;

use super::{nanos, file_logger};
use influx;


const N_WARNINGS: usize = 500;

#[macro_export]
macro_rules! confirmed {
($warnings:ident, $($args:tt)*) => (
{
let _ = warnings.send(Warning::Confirmed( ( format!($($args)*) ) ) ).unwrap();
}
)
}

/// logs a `Warning::Awesome` message to the `WarningsManager`
#[macro_export]
macro_rules! awesome {
($warnings:ident, $($args:tt)*) => (
{
let _ = $warnings.send(Warning::Awesome( ( format!($($args)*) ) ) ).unwrap();
}
)
}

#[macro_export]
macro_rules! critical {
($warnings:ident, $($args:tt)*) => (
{
let _ = $warnings.send(Warning::Critical( ( format!($($args)*) ) ) ).unwrap();
}
)
}

#[macro_export]
macro_rules! notice {
($warnings:ident, $($args:tt)*) => (
{
let _ = $warnings.send(Warning::Notice( ( format!($($args)*) ) ) ).unwrap();
}
)
}

#[macro_export]
macro_rules! error_w {
($warnings:ident, $($args:tt)*) => (
{
$warnings.send(Warning::Error( ( format!($($args)*) ) ) ).unwrap();
}
)
}

/// represents a non-fatal error somewhere in
/// the system to report either to the program interface
/// or in logs.
///
#[derive(Debug, Clone, PartialEq)]
pub enum Warning {
Notice(String),

Error(String),

DegradedService(String),

Critical(String),

Confirmed(String),

Awesome(String),

Log {
level: Level,
module: &'static str,
function: &'static str,
line: u32,
msg: String,
kv: MeasurementRecord,
},

Terminate
}

impl Warning {
pub fn msg(&self) -> String {
match *self {
Warning::Notice(ref s) | Warning::Error(ref s) |
Warning::DegradedService(ref s) | Warning::Critical(ref s) |
Warning::Awesome(ref s) | Warning::Confirmed(ref s) |
Warning::Log { msg: ref s, .. } =>
s.clone(),

Warning::Terminate => "".to_owned()
}
}
pub fn msg_str(&self) -> &str {
match *self {
Warning::Notice(ref s) | Warning::Error(ref s) |
Warning::DegradedService(ref s) | Warning::Critical(ref s) |
Warning::Awesome(ref s) | Warning::Confirmed(ref s) |
Warning::Log { msg: ref s, .. } =>

s.as_ref(),

Warning::Terminate => "Terminate"
}
}

pub fn category_str(&self) -> &str {
match self {
&Warning::Notice(_) => "NOTC",
&Warning::Error(_) => "ERRO",
&Warning::Critical(_) => "CRIT",
&Warning::DegradedService(_) => "DGRD",
&Warning::Confirmed(_) => "CNFD",
&Warning::Awesome(_) => "AWSM",
&Warning::Log { ref level, .. } => level.as_short_str(),
&Warning::Terminate => "TERM",
}
}

pub fn category(&self, f: &mut Formatter) -> fmt::Result {
match *self {
Warning::Notice(_) => {
write!(f, "[ Notice ]")
}

Warning::Error(_) => {
write!(f, "{yellow}[{title}]{reset}",
yellow = Fg(color::LightYellow),
title = " Error--",
reset = Fg(color::Reset))
}

Warning::Critical(_) => {
write!(f, "{bg}{fg}{title}{resetbg}{resetfg}",
bg = Bg(color::Red),
fg = Fg(color::White),
title = " CRITICAL ",
resetbg = Bg(color::Reset),
resetfg = Fg(color::Reset))
}

Warning::Awesome(_) => {
write!(f, "{color}[{title}]{reset}",
color = Fg(color::Green),
title = "Awesome!",
reset = Fg(color::Reset))
}

Warning::DegradedService(_) => {
write!(f, "{color}[{title}] {reset}",
color = Fg(color::Blue),
title = "Degraded Service ",
reset = Fg(color::Reset))
}

Warning::Confirmed(_) => {
write!(f, "{bg}{fg}{title}{resetbg}{resetfg}",
bg = Bg(color::Blue),
fg = Fg(color::White),
title = "Confirmed ",
resetbg = Bg(color::Reset),
resetfg = Fg(color::Reset))
}

_ => Ok(())
}
}
}

impl Display for Warning {
fn fmt(&self, f: &mut Formatter) -> Result<(), FmtError> {
self.category(f)?;
write!(f, " {}", self.msg())
}
}

#[derive(Debug, Clone)]
pub struct Record {
pub time: DateTime<Utc>,
pub msg: Warning
}

impl Record {
pub fn new(msg: Warning) -> Self {
let time = Utc::now();
Record { time, msg }
}

pub fn to_measurement(&self, name: &'static str) -> Measurement {
let cat = self.msg.category_str();
let body = self.msg.msg_str();
let mut m = Measurement::new(name);
m.add_tag("category", cat);
m.add_field("msg", InfluentValue::String(body));
m.set_timestamp(nanos(self.time) as i64);
m
}
}

impl Display for Record {
fn fmt(&self, f: &mut Formatter) -> Result<(), FmtError> {
write!(f, "{} | {}", self.time.format("%H:%M:%S"), self.msg)
}
}

pub type SlogResult = Result<(), slog::Error>;

#[derive(Debug, Clone, PartialEq)]
pub enum Value {
String(String),
Float(f64),
Integer(i64),
Boolean(bool)
}

impl Value {
pub fn to_influent<'a>(&'a self) -> InfluentValue<'a> {
match self {
&Value::String(ref s) => InfluentValue::String(s),
&Value::Float(n) => InfluentValue::Float(n),
&Value::Integer(i) => InfluentValue::Integer(i),
&Value::Boolean(b) => InfluentValue::Boolean(b),
}
}
}

#[derive(Debug, Clone, PartialEq)]
pub struct MeasurementRecord {
fields: Vec<(Key, Value)>,
tags: Vec<(Key, String)>,
}

impl MeasurementRecord {
pub fn new() -> Self {
MeasurementRecord {
fields: Vec::new(),
tags: Vec::new(),
}
}

pub fn add_field(&mut self, key: Key, val: Value) -> SlogResult {
self.fields.push((key, val));
Ok(())
}

pub fn add_tag(&mut self, key: Key, val: String) -> SlogResult {
match key {
"exchange" | "thread" | "ticker" | "category" => {
self.tags.push((key, val));
}

other => {
self.add_field(other, Value::String(val)).unwrap();
}
}

Ok(())
}

pub fn serialize_values(&mut self, record: &slog::Record, values: &OwnedKVList) {
let mut builder = TagBuilder { mrec: self };
let _ = values.serialize(record, &mut builder);
}

pub fn to_measurement<'a>(&'a self, name: &'a str) -> Measurement<'a> {
let fields: BTreeMap<&'a str, InfluentValue<'a>> =
self.fields.iter()
.map(|&(k, ref v)| {
(k, v.to_influent())
}).collect();

let tags: BTreeMap<&'a str, &'a str> =
self.tags.iter()
.map(|&(k, ref v)| {
(k, v.as_ref())
}).collect();

Measurement {
key: name,
timestamp: Some(nanos(Utc::now()) as i64),
fields,
tags,
}
}
}

impl slog::Serializer for MeasurementRecord {
fn emit_usize(&mut self, key: Key, val: usize) -> SlogResult { self.add_field(key, Value::Integer(val as i64)) }
fn emit_isize(&mut self, key: Key, val: isize) -> SlogResult { self.add_field(key, Value::Integer(val as i64)) }
fn emit_bool(&mut self, key: Key, val: bool) -> SlogResult { self.add_field(key, Value::Boolean(val)) }
fn emit_u8(&mut self, key: Key, val: u8) -> SlogResult { self.add_field(key, Value::Integer(val as i64)) }
fn emit_i8(&mut self, key: Key, val: i8) -> SlogResult { self.add_field(key, Value::Integer(val as i64)) }
fn emit_u16(&mut self, key: Key, val: u16) -> SlogResult { self.add_field(key, Value::Integer(val as i64)) }
fn emit_i16(&mut self, key: Key, val: i16) -> SlogResult { self.add_field(key, Value::Integer(val as i64)) }
fn emit_u32(&mut self, key: Key, val: u32) -> SlogResult { self.add_field(key, Value::Integer(val as i64)) }
fn emit_i32(&mut self, key: Key, val: i32) -> SlogResult { self.add_field(key, Value::Integer(val as i64)) }
fn emit_f32(&mut self, key: Key, val: f32) -> SlogResult { self.add_field(key, Value::Float(val as f64)) }
fn emit_u64(&mut self, key: Key, val: u64) -> SlogResult { self.add_field(key, Value::Integer(val as i64)) }
fn emit_i64(&mut self, key: Key, val: i64) -> SlogResult { self.add_field(key, Value::Integer(val)) }
fn emit_f64(&mut self, key: Key, val: f64) -> SlogResult { self.add_field(key, Value::Float(val)) }
fn emit_str(&mut self, key: Key, val: &str) -> SlogResult { self.add_field(key, Value::String(val.to_string())) }
fn emit_unit(&mut self, key: Key) -> SlogResult { self.add_field(key, Value::Boolean(true)) }
fn emit_none(&mut self, _: Key) -> SlogResult { Ok(()) } //self.add_field(key, Value::String("none".into())) }
fn emit_arguments(&mut self, key: Key, val: &fmt::Arguments) -> SlogResult { self.add_field(key, Value::String(val.to_string())) }
}

pub struct TagBuilder<'a> {
mrec: &'a mut MeasurementRecord
}

impl<'a> slog::Serializer for TagBuilder<'a> {
fn emit_str(&mut self, key: Key, val: &str) -> SlogResult {
match key {
"exchange" | "thread" | "ticker" | "category" => {
self.mrec.add_tag(key, val.to_string())
}

other => {
self.mrec.add_field(other, Value::String(val.to_string()))
}
}
}

fn emit_arguments(&mut self, key: Key, val: &fmt::Arguments) -> SlogResult {
match key {
"exchange" | "thread" | "ticker" | "category" => {
self.mrec.add_tag(key, val.to_string())
}

other => {
self.mrec.add_field(other, Value::String(val.to_string()))
}
}

}
}

pub struct WarningsDrain<D: Drain> {
level: Level,
tx: Arc<Mutex<Sender<Warning>>>,
drain: D,
to_file: Logger,
}

impl<D> WarningsDrain<D>
where D: Drain
{
pub fn new(tx: Sender<Warning>, level: Level, drain: D) -> Self {
let tx = Arc::new(Mutex::new(tx));
let to_file = file_logger("var/log/mm.log", Severity::Warning);
WarningsDrain { tx, drain, level, to_file }
}
}

impl From<Sender<Warning>> for WarningsDrain<slog::Fuse<slog::Discard>> {
fn from(tx: Sender<Warning>) -> Self {
WarningsDrain::new(tx, Level::Debug, slog::Discard.fuse())
}
}

impl<D: Drain> Drain for WarningsDrain<D> {
type Ok = ();
type Err = D::Err;

fn log(&self, record: &slog::Record, values: &OwnedKVList) -> Result<Self::Ok, Self::Err> {
if record.level() <= self.level {
let mut ser = MeasurementRecord::new();
ser.serialize_values(record, values);
let _ = record.kv().serialize(record, &mut ser);
let msg = record.msg().to_string();
if let Ok(lock) = self.tx.lock() {
let _ = lock.send(Warning::Log {
level: record.level(),
module: record.module(),
function: record.function(),
line: record.line(),
msg,
kv: ser
});
}
}
if record.level() <= Level::Warning {
let _ = self.to_file.log(record);
}
let _ = self.drain.log(record, values)?;
Ok(())
}
}

#[derive(Debug)]
pub struct WarningsManager {
pub tx: Sender<Warning>,
pub warnings: Arc<RwLock<VecDeque<Record>>>,
thread: Option<JoinHandle<()>>
}

impl Drop for WarningsManager {
fn drop(&mut self) {
let _ = self.tx.send(Warning::Terminate);
if let Some(thread) = self.thread.take() {
thread.join().unwrap();
}
}
}

const TIMESTAMP_FORMAT: &'static str = "%b %d %H:%M:%S%.3f";

/// Serializes *only* KV pair with `key == "thread"`
///
struct ThreadSer<'a>(&'a mut Vec<u8>);

impl<'a> slog::ser::Serializer for ThreadSer<'a> {
fn emit_arguments(&mut self, _: &str, _: &fmt::Arguments) -> slog::Result {
Ok(())
}

fn emit_str(&mut self, key: &str, val: &str) -> slog::Result {
if key == "thread" {
write!(self.0, " {:<20}", val)?;
}
Ok(())
}
}


/// Serializes KV pairs as ", k: v"
///
struct KvSer<'a>(&'a mut Vec<u8>);

macro_rules! s(
($s:expr, $k:expr, $v:expr) => {
try!(write!($s.0, ", {}: {}", $k, $v));
};
);

impl<'a> slog::ser::Serializer for KvSer<'a> {
fn emit_none(&mut self, key: &str) -> slog::Result {
s!(self, key, "None");
Ok(())
}
fn emit_unit(&mut self, key: &str) -> slog::Result {
s!(self, key, "()");
Ok(())
}

fn emit_bool(&mut self, key: &str, val: bool) -> slog::Result {
s!(self, key, val);
Ok(())
}

fn emit_char(&mut self, key: &str, val: char) -> slog::Result {
s!(self, key, val);
Ok(())
}

fn emit_usize(&mut self, key: &str, val: usize) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_isize(&mut self, key: &str, val: isize) -> slog::Result {
s!(self, key, val);
Ok(())
}

fn emit_u8(&mut self, key: &str, val: u8) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_i8(&mut self, key: &str, val: i8) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_u16(&mut self, key: &str, val: u16) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_i16(&mut self, key: &str, val: i16) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_u32(&mut self, key: &str, val: u32) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_i32(&mut self, key: &str, val: i32) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_f32(&mut self, key: &str, val: f32) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_u64(&mut self, key: &str, val: u64) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_i64(&mut self, key: &str, val: i64) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_f64(&mut self, key: &str, val: f64) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_str(&mut self, key: &str, val: &str) -> slog::Result {
s!(self, key, val);
Ok(())
}
fn emit_arguments(
&mut self,
key: &str,
val: &fmt::Arguments,
) -> slog::Result {
s!(self, key, val);
Ok(())
}
}

#[allow(unused_variables, unused_imports)]
#[cfg(test)]
mod tests {
use super::*;
use test::{black_box, Bencher};

#[test]
#[ignore]
fn it_creates_a_logger() {
let wm = WarningsManager::new("rust-test");
let im = influx::writer(wm.tx.clone());
let drain =
WarningsDrain {
tx: Arc::new(Mutex::new(wm.tx.clone())),
drain: slog::Discard,
to_file: Logger::root(slog::Discard, o!()),
level: Level::Trace,
};
let logger = slog::Logger::root(drain, o!());
}

#[bench]
fn it_sends_integers_with_a_sender_behind_a_mutex(b: &mut Bencher) {
let (tx, rx) = channel();
enum Msg {
Val(usize),
Terminate
}
let worker = thread::spawn(move || {
let mut xs = Vec::new();
loop {
match rx.recv().unwrap() {
Msg::Val(x) => { xs.push(x); }
Msg::Terminate => break,
}
}
xs.len()
});
let tx = Arc::new(Mutex::new(tx));
b.iter(|| {
let lock = tx.lock().unwrap();
let _ = lock.send(Msg::Val(1));
});
let _ = tx.lock().unwrap().send(Msg::Terminate);
let len = worker.join().unwrap();
//println!("{}", len);
}
}

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