singrdk/base/Services/Fat/Fs/BlockWriter.sg

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2008-03-05 09:52:00 -05:00
///////////////////////////////////////////////////////////////////////////////
//
// Microsoft Research Singularity
//
// Copyright (c) Microsoft Corporation. All rights reserved.
//
// File: BlockWriter.sg
//
// Note:
//
using Microsoft.SingSharp;
using Microsoft.Singularity.Channels;
using System;
using System.Threading;
namespace Microsoft.Singularity.Services.Fat.Fs
{
public interface IBlockWriterUser
{
/// <remarks>
/// This method is called immediately before the
/// BlockWriter attempts to write the data to disk. The
/// receiver must give up the associated buffer.
/// </remarks>
byte[]! in ExHeap GetDataForWrite(ulong sectorId,
int cookie);
/// <remarks>
/// This method is called by the BlockWriter when the data
/// has been written to the disk.
/// </remarks>
void WriteComplete(ulong sectorId,
[Claims] byte[]! in ExHeap buffer,
int cookie);
}
internal sealed class RequestQueue
{
private struct Request
{
IBlockWriterUser! user;
ulong sectorId;
int userCookie;
public Request(IBlockWriterUser! theUser,
ulong theSectorId,
int theUserCookie)
{
this.user = theUser;
this.sectorId = theSectorId;
this.userCookie = theUserCookie;
}
public IBlockWriterUser! User { get { return user; } }
public ulong SectorId { get { return sectorId; } }
public int UserCookie { get { return userCookie; } }
}
///////////////////////////////////////////////////////////////////////
// Fields
Request[] requests;
int head;
int length;
///////////////////////////////////////////////////////////////////////
// Invariants
// invariant head >= 0 && head <= requests.Length;
// invariant length >= 0 && length <= requests.Length;
///////////////////////////////////////////////////////////////////////
// Methods
internal RequestQueue(uint maxLength)
requires maxLength >= 0;
{
requests = new Request[maxLength];
head = 0;
length = 0;
}
internal int MaxLength
{
get { return requests.Length; }
}
internal int Length
{
get { return length; }
}
internal bool Full
{
get { return length == requests.Length; }
}
internal bool Empty
{
get { return length == 0; }
}
internal void Enqueue(IBlockWriterUser! user,
ulong theSectorId,
int userCookie)
requires (Full == false);
ensures (Length == old(Length) + 1);
{
int index = (head + length) % requests.Length;
requests[index] = new Request(user, theSectorId, userCookie);
length++;
}
internal void Dequeue(out IBlockWriterUser user,
out ulong sectorId,
out int userCookie)
requires Length != 0;
ensures Length == old(Length) - 1;
{
user = requests[head].User;
sectorId = requests[head].SectorId;
userCookie = requests[head].UserCookie;
head = (head + 1) % MaxLength;
length = length - 1;
}
}
/// <summary>
/// Block writer is responsible for writing blocks to disk.
/// It may operate synchronously or asynchronously. When
/// synchronous, all writes occur immediately. When
/// asynchronous they are performed when the request queue
/// over flows or when the periodic worker thread is woken
/// up.
/// </summary>
internal sealed class BlockWriter
{
///////////////////////////////////////////////////////////////////////
// Constants
private const int MinimumSleepSecs = 5;
private const int MaximumSleepSecs = 15;
private const int RangeSleepSecs = MaximumSleepSecs - MinimumSleepSecs;
///////////////////////////////////////////////////////////////////////
// Fields
AutoResetEvent wakeEvent;
volatile bool shutdown;
Disk disk;
RequestQueue requestQueue;
Thread worker;
bool writesAllowed; // Sanity check for RO mount
bool diskDirtied; // Data written to disk
///////////////////////////////////////////////////////////////////////
// Methods
[ Microsoft.Contracts.NotDelayed ]
internal BlockWriter(Disk theDisk,
uint maxQueueLength, // Synchronous if zero
bool areWritesAllowed)
{
this.wakeEvent = new AutoResetEvent(false);
this.shutdown = false;
this.disk = theDisk;
this.diskDirtied = false;
this.requestQueue = new RequestQueue(maxQueueLength);
this.writesAllowed = areWritesAllowed;
if (requestQueue.MaxLength > 0) {
worker = new Thread(new ThreadStart(WorkerMain));
worker.Start();
}
}
internal void Shutdown()
{
lock (this) {
shutdown = true;
}
if (worker != null) {
wakeEvent.Set();
worker.Join();
worker = null;
}
if (this.diskDirtied) {
assert FatVolume.Fat.CleanShutdown == false;
if (FatVolume.FatVersion == FatVersion.Fat32) {
Fat32 fat32 = (Fat32)FatVolume.Fat;
fat32.UpdateFsInfo32();
}
// The following method sets the appropriate bit
// in the FAT(s), which will ripple down as a
// dirty blocks in the cache for FAT16 and FAT32
// (FAT12 does not record clean shutdown)
FatVolume.Fat.CleanShutdown = true;
// Synchronously flush the queue as the worker
// thread has exited.
int done = this.FlushQueue();
assert done >= 1 || FatVolume.FatVersion == FatVersion.Fat12;
}
}
private void WorkerMain()
{
Random rng = new Random();
while (shutdown == false) {
int secs = MinimumSleepSecs + (rng.Next() % RangeSleepSecs);
wakeEvent.WaitOne(TimeSpan.FromSeconds(secs));
Tracing.Log(Tracing.Debug, "BlockWriter worker flushing.");
if (this.diskDirtied &&
FatVolume.FatVersion == FatVersion.Fat32) {
// Update free space estimate. This might be done
// more conditionally, ie check whether free space has
// changed.
Fat32 fat32 = (Fat32)FatVolume.Fat;
fat32.UpdateFsInfo32();
}
FlushQueue();
}
}
private int FlushQueue()
{
int done = 0;
for (;;) {
IBlockWriterUser user = null;
ulong sectorId;
int userCookie;
lock (this) {
// We might want to be
// smart and re-order write requests here or
// add ordering to requests made to disk.
//
// We also want to look at changing
// the disk driver interface to support scatter-gather
// writes so we can write consecutive blocks back-to-back
// and avoid unnecessary seeks.
if (requestQueue.Empty)
break;
requestQueue.Dequeue(out user, out sectorId, out userCookie);
}
if (user != null) {
WriteBlock(user, sectorId, userCookie);
done++;
}
}
return done;
}
private void WriteBlock(IBlockWriterUser! user,
ulong sectorId,
int cookie)
{
assert writesAllowed == true;
if (this.diskDirtied == false) {
FatVolume.Fat.CleanShutdown = false;
this.diskDirtied = true;
}
// DebugStub.Print("Writing sector {0}\n",
// __arglist(sectorId));
byte[]! in ExHeap data = user.GetDataForWrite(sectorId, cookie);
byte[] in ExHeap doneData = disk.Write(sectorId, data);
user.WriteComplete(sectorId, (!) doneData, cookie);
}
internal bool Enqueue(IBlockWriterUser! user,
ulong sectorId,
int userCookie)
{
assert writesAllowed == true;
IBlockWriterUser pushUser = null;
ulong pushSectorId = 0;
int pushUserCookie = 0;
if (requestQueue.MaxLength == 0) {
// Queue has no capacity so we're synchronous and
// will need to push this write to disk
pushUser = user;
pushSectorId = sectorId;
pushUserCookie = userCookie;
}
else {
lock (this) {
// We're async, and need to push head from queue if
// queue overflows.
if (requestQueue.Full) {
requestQueue.Dequeue(out pushUser,
out pushSectorId,
out pushUserCookie);
}
requestQueue.Enqueue(user, sectorId, userCookie);
}
}
if (pushUser != null) {
Tracing.Log(Tracing.Audit,
"Request enqueue pushed block to disk.");
WriteBlock(pushUser, pushSectorId, pushUserCookie);
}
return true;
}
internal void WakeUp()
{
wakeEvent.Set();
}
}
}