Wednesday, October 16, 2024

Coroutines in RonDB,

 A while ago C++ standard added a new feature to C++ 20 called coroutines. I thought it was an interesting thing to try out for RonDB and used some time this summer to read more about it. My findings was that C++ coroutines can only be used for special tasks that require no stacks. The problem is that a coroutine cannot save the stack.

My hope was to find that I could have a single thread that could work using fibers where the fiber belongs to one thread and the thread could switch between different fibers. The main goal of fibers would be to improve throughput by doing work instead of blocking the CPU on cache misses. However fibers can also be a tool to allow a scalable server where the process runs in a single thread when the load is low, and scale up to hundreds of threads (if the process has access to that many CPUs) when required. This will provide better power efficiency, better latency at low loads. Also if we ever get VMs that can dynamically scale up and down the number of CPUs we can use fibers to scale up and down the number of threads in this case.

My read up on C++ 20 coroutines was that it could not deliver on this.

However my read up found an intriguingly simple and elegant solution to the problem. See this blog for a description and here is the GitHub tree with the code. So a small header file of around 300 lines solves the problem elegantly for x86_64 both on Macs and on Linux and similarly for ARM64. Thus all the platforms RonDB supports. The header file can also be used on Windows (Windows supports fibers).

I developed a small test program to see the code in action:

#include <iostream>

#include "tiny_fiber.h"


/**

 * A very simple test program checking how fibers and threads interact.

 * The program will printout the following:

hello from fibermain

hello from main

hello from fibermain 2

hello from main 2

 */


tiny_fiber::FiberHandle thread_fiber;

tiny_fiber::FiberHandle fiber;


void fibermain(void* arg) {

  tiny_fiber::FiberHandle fiber =

  *reinterpret_cast<tiny_fiber::FiberHandle*>(arg);

  std::cout<<"hello from fibermain"<<std::endl;

  tiny_fiber::SwitchFiber(fiber, thread_fiber);

  std::cout<<"hello from fibermain 2"<<std::endl;

  tiny_fiber::SwitchFiber(fiber, thread_fiber);

}


int main(int argc, char** argv) {

  const int stack_size = 1024 * 16;

  thread_fiber = tiny_fiber::CreateFiberFromThread();

  fiber = tiny_fiber::CreateFiber(stack_size, fibermain, &fiber);

  tiny_fiber::SwitchFiber(thread_fiber, fiber);

  std::cout<<"hello from main"<<std::endl;

  tiny_fiber::SwitchFiber(thread_fiber, fiber);

  std::cout<<"hello from main 2"<<std::endl;

  return 0;

}

Equipped with this I have the tools I need to develop an experiment and see how fibers works with RonDB. Good news is that I need no learn any complex C++ syntax to do this. It is all low level system programming. I have learnt through long experience that it is not a certain success if you have a theory. A computer is sufficiently complex to not understand the impact of changes that one does. So I am excited to see how this particular new idea works out.

The concept of fibers fits very nicely into the RonDB runtime scheduler and the division of work between threads. It even provides the ability for a thread to be turned into a fiber and moved to another OS thread and it can be returned to its original thread again as well.

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