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303 lines
20 KiB
Plaintext
---
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slug: 2019/06/high-performance-systems
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title: "On Building High Performance Systems"
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date: 2019-06-31 12:00:00
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last_updated:
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date: 2019-09-21 12:00:00
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authors: [bspeice]
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tags: []
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---
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Prior to working in the trading industry, my assumption was that High Frequency Trading (HFT) is
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made up of people who have access to secret techniques mortal developers could only dream of. There
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had to be some secret art that could only be learned if one had an appropriately tragic backstory.
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<!-- truncate -->
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![Kung Fu fight](./kung-fu.webp)
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> How I assumed HFT people learn their secret techniques
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How else do you explain people working on systems that complete the round trip of market data in to
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orders out (a.k.a. tick-to-trade) consistently within
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[750-800 nanoseconds](https://stackoverflow.com/a/22082528/1454178)? In roughly the time it takes a
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computer to access
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[main memory 8 times](https://people.eecs.berkeley.edu/~rcs/research/interactive_latency.html),
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trading systems are capable of reading the market data packets, deciding what orders to send, doing
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risk checks, creating new packets for exchange-specific protocols, and putting those packets on the
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wire.
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Having now worked in the trading industry, I can confirm the developers aren't super-human; I've
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made some simple mistakes at the very least. Instead, what shows up in public discussions is that
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philosophy, not technique, separates high-performance systems from everything else.
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Performance-critical systems don't rely on "this one cool C++ optimization trick" to make code fast
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(though micro-optimizations have their place); there's a lot more to worry about than just the code
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written for the project.
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The framework I'd propose is this: **If you want to build high-performance systems, focus first on
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reducing performance variance** (reducing the gap between the fastest and slowest runs of the same
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code), **and only look at average latency once variance is at an acceptable level**.
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Don't get me wrong, I'm a much happier person when things are fast. Computer goes from booting in 20
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seconds down to 10 because I installed a solid-state drive? Awesome. But if every fifth day it takes
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a full minute to boot because of corrupted sectors? Not so great. Average speed over the course of a
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week is the same in each situation, but you're painfully aware of that minute when it happens. When
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it comes to code, the principal is the same: speeding up a function by an average of 10 milliseconds
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doesn't mean much if there's a 100ms difference between your fastest and slowest runs. When
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performance matters, you need to respond quickly _every time_, not just in aggregate.
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High-performance systems should first optimize for time variance. Once you're consistent at the time
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scale you care about, then focus on improving average time.
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This focus on variance shows up all the time in industry too (emphasis added in all quotes below):
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- In [marketing materials](https://business.nasdaq.com/market-tech/marketplaces/trading) for
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NASDAQ's matching engine, the most performance-sensitive component of the exchange, dependability
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is highlighted in addition to instantaneous metrics:
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> Able to **consistently sustain** an order rate of over 100,000 orders per second at sub-40
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> microsecond average latency
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- The [Aeron](https://github.com/real-logic/aeron) message bus has this to say about performance:
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> Performance is the key focus. Aeron is designed to be the highest throughput with the lowest and
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> **most predictable latency possible** of any messaging system
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- The company PolySync, which is working on autonomous vehicles,
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[mentions why](https://polysync.io/blog/session-types-for-hearty-codecs/) they picked their
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specific messaging format:
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> In general, high performance is almost always desirable for serialization. But in the world of
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> autonomous vehicles, **steady timing performance is even more important** than peak throughput.
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> This is because safe operation is sensitive to timing outliers. Nobody wants the system that
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> decides when to slam on the brakes to occasionally take 100 times longer than usual to encode
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> its commands.
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- [Solarflare](https://solarflare.com/), which makes highly-specialized network hardware, points out
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variance (jitter) as a big concern for
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[electronic trading](https://solarflare.com/electronic-trading/):
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> The high stakes world of electronic trading, investment banks, market makers, hedge funds and
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> exchanges demand the **lowest possible latency and jitter** while utilizing the highest
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> bandwidth and return on their investment.
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And to further clarify: we're not discussing _total run-time_, but variance of total run-time. There
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are situations where it's not reasonably possible to make things faster, and you'd much rather be
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consistent. For example, trading firms use
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[wireless networks](https://sniperinmahwah.wordpress.com/2017/06/07/network-effects-part-i/) because
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the speed of light through air is faster than through fiber-optic cables. There's still at _absolute
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minimum_ a [~33.76 millisecond](http://tinyurl.com/y2vd7tn8) delay required to send data between,
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say,
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[Chicago and Tokyo](https://www.theice.com/market-data/connectivity-and-feeds/wireless/tokyo-chicago).
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If a trading system in Chicago calls the function for "send order to Tokyo" and waits to see if a
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trade occurs, there's a physical limit to how long that will take. In this situation, the focus is
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on keeping variance of _additional processing_ to a minimum, since speed of light is the limiting
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factor.
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So how does one go about looking for and eliminating performance variance? To tell the truth, I
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don't think a systematic answer or flow-chart exists. There's no substitute for (A) building a deep
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understanding of the entire technology stack, and (B) actually measuring system performance (though
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(C) watching a lot of [CppCon](https://www.youtube.com/channel/UCMlGfpWw-RUdWX_JbLCukXg) videos for
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inspiration never hurt). Even then, every project cares about performance to a different degree; you
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may need to build an entire
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[replica production system](https://www.youtube.com/watch?v=NH1Tta7purM&feature=youtu.be&t=3015) to
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accurately benchmark at nanosecond precision, or you may be content to simply
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[avoid garbage collection](https://www.youtube.com/watch?v=BD9cRbxWQx8&feature=youtu.be&t=1335) in
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your Java code.
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Even though everyone has different needs, there are still common things to look for when trying to
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isolate and eliminate variance. In no particular order, these are my focus areas when thinking about
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high-performance systems:
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**Update 2019-09-21**: Added notes on `isolcpus` and `systemd` affinity.
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## Language-specific
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**Garbage Collection**: How often does garbage collection happen? When is it triggered? What are the
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impacts?
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- [In Python](https://rushter.com/blog/python-garbage-collector/), individual objects are collected
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if the reference count reaches 0, and each generation is collected if
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`num_alloc - num_dealloc > gc_threshold` whenever an allocation happens. The GIL is acquired for
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the duration of generational collection.
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- Java has
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[many](https://docs.oracle.com/en/java/javase/12/gctuning/parallel-collector1.html#GUID-DCDD6E46-0406-41D1-AB49-FB96A50EB9CE)
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[different](https://docs.oracle.com/en/java/javase/12/gctuning/garbage-first-garbage-collector.html#GUID-ED3AB6D3-FD9B-4447-9EDF-983ED2F7A573)
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[collection](https://docs.oracle.com/en/java/javase/12/gctuning/garbage-first-garbage-collector-tuning.html#GUID-90E30ACA-8040-432E-B3A0-1E0440AB556A)
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[algorithms](https://docs.oracle.com/en/java/javase/12/gctuning/z-garbage-collector1.html#GUID-A5A42691-095E-47BA-B6DC-FB4E5FAA43D0)
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to choose from, each with different characteristics. The default algorithms (Parallel GC in Java
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8, G1 in Java 9) freeze the JVM while collecting, while more recent algorithms
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([ZGC](https://wiki.openjdk.java.net/display/zgc) and
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[Shenandoah](https://wiki.openjdk.java.net/display/shenandoah)) are designed to keep "stop the
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world" to a minimum by doing collection work in parallel.
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**Allocation**: Every language has a different way of interacting with "heap" memory, but the
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principle is the same: running the allocator to allocate/deallocate memory takes time that can often
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be put to better use. Understanding when your language interacts with the allocator is crucial, and
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not always obvious. For example: C++ and Rust don't allocate heap memory for iterators, but Java
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does (meaning potential GC pauses). Take time to understand heap behavior (I made a
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[a guide for Rust](/2019/02/understanding-allocations-in-rust.html)), and look into alternative
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allocators ([jemalloc](http://jemalloc.net/),
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[tcmalloc](https://gperftools.github.io/gperftools/tcmalloc.html)) that might run faster than the
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operating system default.
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**Data Layout**: How your data is arranged in memory matters;
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[data-oriented design](https://www.youtube.com/watch?v=yy8jQgmhbAU) and
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[cache locality](https://www.youtube.com/watch?v=2EWejmkKlxs&feature=youtu.be&t=1185) can have huge
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impacts on performance. The C family of languages (C, value types in C#, C++) and Rust all have
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guarantees about the shape every object takes in memory that others (e.g. Java and Python) can't
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make. [Cachegrind](http://valgrind.org/docs/manual/cg-manual.html) and kernel
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[perf](https://perf.wiki.kernel.org/index.php/Main_Page) counters are both great for understanding
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how performance relates to memory layout.
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**Just-In-Time Compilation**: Languages that are compiled on the fly (LuaJIT, C#, Java, PyPy) are
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great because they optimize your program for how it's actually being used, rather than how a
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compiler expects it to be used. However, there's a variance problem if the program stops executing
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while waiting for translation from VM bytecode to native code. As a remedy, many languages support
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ahead-of-time compilation in addition to the JIT versions
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([CoreRT](https://github.com/dotnet/corert) in C# and [GraalVM](https://www.graalvm.org/) in Java).
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On the other hand, LLVM supports
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[Profile Guided Optimization](https://clang.llvm.org/docs/UsersManual.html#profile-guided-optimization),
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which theoretically brings JIT benefits to non-JIT languages. Finally, be careful to avoid comparing
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apples and oranges during benchmarks; you don't want your code to suddenly speed up because the JIT
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compiler kicked in.
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**Programming Tricks**: These won't make or break performance, but can be useful in specific
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circumstances. For example, C++ can use
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[templates instead of branches](https://www.youtube.com/watch?v=NH1Tta7purM&feature=youtu.be&t=1206)
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in critical sections.
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## Kernel
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Code you wrote is almost certainly not the _only_ code running on your hardware. There are many ways
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the operating system interacts with your program, from interrupts to system calls, that are
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important to watch for. These are written from a Linux perspective, but Windows does typically have
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equivalent functionality.
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**Scheduling**: The kernel is normally free to schedule any process on any core, so it's important
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to reserve CPU cores exclusively for the important programs. There are a few parts to this: first,
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limit the CPU cores that non-critical processes are allowed to run on by excluding cores from
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scheduling
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([`isolcpus`](https://www.linuxtopia.org/online_books/linux_kernel/kernel_configuration/re46.html)
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kernel command-line option), or by setting the `init` process CPU affinity
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([`systemd` example](https://access.redhat.com/solutions/2884991)). Second, set critical processes
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to run on the isolated cores by setting the
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[processor affinity](https://en.wikipedia.org/wiki/Processor_affinity) using
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[taskset](https://linux.die.net/man/1/taskset). Finally, use
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[`NO_HZ`](https://github.com/torvalds/linux/blob/master/Documentation/timers/NO_HZ.txt) or
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[`chrt`](https://linux.die.net/man/1/chrt) to disable scheduling interrupts. Turning off
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hyper-threading is also likely beneficial.
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**System calls**: Reading from a UNIX socket? Writing to a file? In addition to not knowing how long
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the I/O operation takes, these all trigger expensive
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[system calls (syscalls)](https://en.wikipedia.org/wiki/System_call). To handle these, the CPU must
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[context switch](https://en.wikipedia.org/wiki/Context_switch) to the kernel, let the kernel
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operation complete, then context switch back to your program. We'd rather keep these
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[to a minimum](https://www.destroyallsoftware.com/talks/the-birth-and-death-of-javascript) (see
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timestamp 18:20). [Strace](https://linux.die.net/man/1/strace) is your friend for understanding when
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and where syscalls happen.
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**Signal Handling**: Far less likely to be an issue, but signals do trigger a context switch if your
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code has a handler registered. This will be highly dependent on the application, but you can
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[block signals](https://www.linuxprogrammingblog.com/all-about-linux-signals?page=show#Blocking_signals)
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if it's an issue.
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**Interrupts**: System interrupts are how devices connected to your computer notify the CPU that
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something has happened. The CPU will then choose a processor core to pause and context switch to the
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OS to handle the interrupt. Make sure that
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[SMP affinity](http://www.alexonlinux.com/smp-affinity-and-proper-interrupt-handling-in-linux) is
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set so that interrupts are handled on a CPU core not running the program you care about.
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**[NUMA](https://www.kernel.org/doc/html/latest/vm/numa.html)**: While NUMA is good at making
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multi-cell systems transparent, there are variance implications; if the kernel moves a process
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across nodes, future memory accesses must wait for the controller on the original node. Use
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[numactl](https://linux.die.net/man/8/numactl) to handle memory-/cpu-cell pinning so this doesn't
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happen.
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## Hardware
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**CPU Pipelining/Speculation**: Speculative execution in modern processors gave us vulnerabilities
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like Spectre, but it also gave us performance improvements like
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[branch prediction](https://stackoverflow.com/a/11227902/1454178). And if the CPU mis-speculates
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your code, there's variance associated with rewind and replay. While the compiler knows a lot about
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how your CPU [pipelines instructions](https://youtu.be/nAbCKa0FzjQ?t=4467), code can be
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[structured to help](https://www.youtube.com/watch?v=NH1Tta7purM&feature=youtu.be&t=755) the branch
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predictor.
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**Paging**: For most systems, virtual memory is incredible. Applications live in their own worlds,
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and the CPU/[MMU](https://en.wikipedia.org/wiki/Memory_management_unit) figures out the details.
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However, there's a variance penalty associated with memory paging and caching; if you access more
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memory pages than the [TLB](https://en.wikipedia.org/wiki/Translation_lookaside_buffer) can store,
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you'll have to wait for the page walk. Kernel perf tools are necessary to figure out if this is an
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issue, but using [huge pages](https://blog.pythian.com/performance-tuning-hugepages-in-linux/) can
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reduce TLB burdens. Alternately, running applications in a hypervisor like
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[Jailhouse](https://github.com/siemens/jailhouse) allows one to skip virtual memory entirely, but
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this is probably more work than the benefits are worth.
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**Network Interfaces**: When more than one computer is involved, variance can go up dramatically.
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Tuning kernel
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[network parameters](https://github.com/leandromoreira/linux-network-performance-parameters) may be
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helpful, but modern systems more frequently opt to skip the kernel altogether with a technique
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called [kernel bypass](https://blog.cloudflare.com/kernel-bypass/). This typically requires
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specialized hardware and [drivers](https://www.openonload.org/), but even industries like
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[telecom](https://www.bbc.co.uk/rd/blog/2018-04-high-speed-networking-open-source-kernel-bypass) are
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finding the benefits.
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## Networks
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**Routing**: There's a reason financial firms are willing to pay
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[millions of euros](https://sniperinmahwah.wordpress.com/2019/03/26/4-les-moeres-english-version/)
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for rights to a small plot of land - having a straight-line connection from point A to point B means
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the path their data takes is the shortest possible. In contrast, there are currently 6 computers in
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between me and Google, but that may change at any moment if my ISP realizes a
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[more efficient route](https://en.wikipedia.org/wiki/Border_Gateway_Protocol) is available. Whether
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it's using
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[research-quality equipment](https://sniperinmahwah.wordpress.com/2018/05/07/shortwave-trading-part-i-the-west-chicago-tower-mystery/)
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for shortwave radio, or just making sure there's no data inadvertently going between data centers,
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routing matters.
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**Protocol**: TCP as a network protocol is awesome: guaranteed and in-order delivery, flow control,
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and congestion control all built in. But these attributes make the most sense when networking
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infrastructure is lossy; for systems that expect nearly all packets to be delivered correctly, the
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setup handshaking and packet acknowledgment are just overhead. Using UDP (unicast or multicast) may
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make sense in these contexts as it avoids the chatter needed to track connection state, and
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[gap-fill](https://iextrading.com/docs/IEX%20Transport%20Specification.pdf)
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[strategies](http://www.nasdaqtrader.com/content/technicalsupport/specifications/dataproducts/moldudp64.pdf)
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can handle the rest.
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**Switching**: Many routers/switches handle packets using "store-and-forward" behavior: wait for the
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whole packet, validate checksums, and then send to the next device. In variance terms, the time
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needed to move data between two nodes is proportional to the size of that data; the switch must
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"store" all data before it can calculate checksums and "forward" to the next node. With
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["cut-through"](https://www.networkworld.com/article/2241573/latency-and-jitter--cut-through-design-pays-off-for-arista--blade.html)
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designs, switches will begin forwarding data as soon as they know where the destination is,
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checksums be damned. This means there's a fixed cost (at the switch) for network traffic, no matter
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the size.
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## Final Thoughts
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High-performance systems, regardless of industry, are not magical. They do require extreme precision
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and attention to detail, but they're designed, built, and operated by regular people, using a lot of
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tools that are publicly available. Interested in seeing how context switching affects performance of
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your benchmarks? `taskset` should be installed in all modern Linux distributions, and can be used to
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make sure the OS never migrates your process. Curious how often garbage collection triggers during a
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crucial operation? Your language of choice will typically expose details of its operations
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([Python](https://docs.python.org/3/library/gc.html),
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[Java](https://www.oracle.com/technetwork/java/javase/tech/vmoptions-jsp-140102.html#DebuggingOptions)).
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Want to know how hard your program is stressing the TLB? Use `perf record` and look for
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`dtlb_load_misses.miss_causes_a_walk`.
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Two final guiding questions, then: first, before attempting to apply some of the technology above to
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your own systems, can you first identify
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[where/when you care](http://wiki.c2.com/?PrematureOptimization) about "high-performance"? As an
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example, if parts of a system rely on humans pushing buttons, CPU pinning won't have any measurable
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effect. Humans are already far too slow to react in time. Second, if you're using benchmarks, are
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they being designed in a way that's actually helpful? Tools like
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[Criterion](http://www.serpentine.com/criterion/) (also in
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[Rust](https://github.com/bheisler/criterion.rs)) and Google's
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[Benchmark](https://github.com/google/benchmark) output not only average run time, but variance as
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well; your benchmarking environment is subject to the same concerns your production environment is.
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Finally, I believe high-performance systems are a matter of philosophy, not necessarily technique.
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Rigorous focus on variance is the first step, and there are plenty of ways to measure and mitigate
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it; once that's at an acceptable level, then optimize for speed.
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