5

I would like to write a small in-memory database in Go. Read and write requests would be passed through a channel and processed by the db engine which would ensure the accesses are done properly.

A first idea woud be to mimic the behaviour of RWMutex. Only it would use a more idiomatic go style.

Here is a little toy (although, rather long) example of what I would like to do.

package main

import (
    "log"
    "math/rand"
    "time"
)

var source *rand.Rand

type ReqType int

const (
    READ = iota
    WRITE
)

type DbRequest struct {
    Type  int              // request type
    RespC chan *DbResponse // channel for request response
    // content here
}

type DbResponse struct {
    // response here
}

type Db struct {
    // DB here
}

func randomWait() {
    time.Sleep(time.Duration(source.Intn(1000)) * time.Millisecond)
}

func (d *Db) readsHandler(in <-chan *DbRequest) {
    for r := range in {
        id := source.Intn(4000000)
        log.Println("read ", id, " starts")
        randomWait()
        log.Println("read ", id, " ends")
        r.RespC <- &DbResponse{}
    }
}

func (d *Db) writesHandler(r *DbRequest) *DbResponse {
    id := source.Intn(4000000)
    log.Println("write ", id, " starts")
    randomWait()
    log.Println("write ", id, " ends")
    return &DbResponse{}
}

func (d *Db) Start(nReaders int) chan *DbRequest {
    in := make(chan *DbRequest, 100)
    reads := make(chan *DbRequest, nReaders)

    // launch readers
    for k := 0; k < nReaders; k++ {
        go d.readsHandler(reads)
    }

    go func() {
        for r := range in {
            switch r.Type {
            case READ:
                reads <- r
            case WRITE:
                // here we should wait for all reads to
                // be over (how ??)

                r.RespC <- d.writesHandler(r)

                // here writesHandler is blocking,
                // this ensures that no additional
                // read is added in the reads channel
                // before the write is finished
            }
        }
    }()

    return in
}

func main() {
    seed := time.Now().Unix()
    source = rand.New(rand.NewSource(seed))

    blackhole := make(chan *DbResponse, 100)

    d := Db{}
    rc := d.Start(4)
    wc := time.After(3 * time.Second)

    go func() {
        for {
            <-blackhole
        }
    }()

    for {
        select {
        case <-wc:
            return
        default:
            if source.Intn(2) == 0 {
                rc <- &DbRequest{READ, blackhole}
            } else {
                rc <- &DbRequest{WRITE, blackhole}
            }
        }
    }
}

Of course, this example shows read/write conflicts.

I feel like I'm trying to do something a bit evil: sharing memory using constructs designed to avoid it... At this point, an obvious solution would be to add RWMutex locks around the two types of requests handling but maybe there is a clever solution using only goroutines and channels.

6

Why not just use RWMutex? It's been optimized to be very efficient and it's conceptually simple. Just embed one in your Db object

type Db struct {
    sync.RWMutex
    // DB here
}

and you can call it like

db := &Db{}
...
db.Lock()
// do RW operations
db.Unlock()
...
db.RLock()
// do Read operations
db.RUnlock()

I don't know a way to get better performance using channels. You can however get better performance with lock-free techniques, but I recommend getting your RWMutex version running first.

Another concurrency issue is that fmt package writes to stdout are not thread safe and you will eventually see garbled output. Try the log package instead. You can set it to write to stdout with no logging prefix and it will ensure atomic writes.

  • Thanks, this is what I've suspected. I'll go with the RWMutex then. By the way, I'd like to know what kind of lock-free techniques you are referring to. Do you have some good references about it ? – lbonn Dec 28 '12 at 4:02
  • 2
    The best reference is Dmitry Vyukov's, 1024 Cores (1024cores.net). I'm a beginner and barely know what I'm doing but I did work one example for Rosetta Code. See rosettacode.org/wiki/Atomic_updates. Between two channel based versions, one runs 10 times faster than the other. The RWMutex version runs about 50% faster again, then the lock-free version runs twice as fast again. A 300x improvement over the most naive channel based version! – Sonia Dec 28 '12 at 10:02
  • Thanks a lot! I once landed on 1024cores.net, I will take a better look at it. – lbonn Dec 28 '12 at 10:15
0

Another possible solution, is to pass the database itself over a channel and then update it only when you hold the database. This means you don't need a lock on it since only the holder may write to it, and the memory model guarantees writes to the database, IIRC.

  • But I won't be able to do simultaneous reads in that case. Or maybe I just don't see how ? – lbonn Dec 30 '12 at 5:27
  • No, not unless the Database is persistent, so it is safe to read. – I GIVE CRAP ANSWERS Dec 31 '12 at 15:43

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