singrdk/base/Services/Smb/Client/Transactor.sg

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////////////////////////////////////////////////////////////////////////////////
//
// Microsoft Research Singularity
//
// Copyright (c) Microsoft Corporation. All rights reserved.
//
// File: Services/Smb/Client/Transactor.sg
//
// Note:
//
// A "transactor" is anything that can issue requests (transactions)
// against the transport mux. These requests are issued using the
// SmbTransactor contract (in Services/Smb/PrivateContracts). The
// TransportMux thread holds the export side of the contract, and
// various other threads (DirectoryClient and FileExp service threads)
// hold the import sides.
//
// The Transactor class contains state information for each SmbTransactor
// channel, for the TransportMux class. The transport mux runs on a
// single thread; only that thread creates and uses instances of the
// Transactor class. So there is no need to synchronize access to these
// instances.
//
// TODO:
//
// * Implement fragmentation for TRANSACTION2 requests. Reassembly
// for inbound fragments is implemented, but not for outbound requests.
//
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//
// REQUESTS vs TRANSACTIONS
// ------------------------
//
// At its most basic, SMB provides a way to identify message boundaries (framing),
// and a common header for all messages exchanged. Most of those messages are
// request/response messages, where a single message sent from the client to the
// server causes the server to response with exactly one message. We will refer
// to these as "SMB requests", although that's a really horribly vague term.
//
// There are some SMB protocols that do not conform to this usage pattern.
// Notably, SMB supports "transactions", which are identified by the SMB commands
// SMB_TRANSACTION and SMB_TRANSACTION2. We will only deal with SMB_TRANSACTION2.
// These transactions add several fields to the basic request/response header,
// and they also allow the payload of the transaction to span more than one SMB
// message.
//
// First, the client sends an SMB message to the server, identifying the SMB
// transaction. There are two possibilities to consider: First, the client's
// transaction message may be small enough to fit into a single SMB message;
// this is the easy case. Otherwise, the client must fragment its transaction
// request. In either case, the client sends its first SMB message, with
// the Command field of the SMB header set to SMB_TRANSACTION2.
//
// Then the client waits for a response from the server. If the client needed
// to fragment its transaction request, then it does NOT yet send any further
// fragments. The server then decides whether or not it likes the request.
// If the primary request indicates that the client needs to send more fragments,
// then the server will respond with the "Interim Server Response". This is
// just a "go ahead" message (which means one more useless round-trip).
// The client then sends all of its fragments.
//
// The server then sends its transaction responses. If the response does not
// need to be fragmented, then there will only be a single response message.
//
//
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using System;
using System.Text;
using System.Collections;
using System.Threading;
using System.Text;
using System.Security.Protocols.Ntlm;
using System.Runtime.InteropServices;
using Microsoft.SingSharp;
using Microsoft.Singularity;
using Microsoft.Singularity.Channels;
using NetStack.Contracts;
using Smb.Protocol;
using Smb.PublicChannels;
using Smb.PrivateChannels;
using Smb.Shared;
namespace Smb.Client
{
/// <summary>
/// This class represents the mux's view of a transactor. Only the mux thread creates or manipulates
/// instances of this class. And because only a single thread ever touches these instances, locking
/// is not required.
/// </summary>
internal class Transactor
{
public Transactor(MuxTuple tuple)
{
this.Tuple = tuple;
this.State = TransactorState.Ready;
this.DebugPrefix = "Tran" + tuple.ToString() + ": ";
TrackedData data = new TrackedData();
this._datacon = new TContainer<TrackedData>(data);
}
public class TrackedData : ITracked
{
// This buffer can be null.
// This buffer is used to reassemble fragments of a TRANSACTION2 request.
public byte[] in ExHeap TransactionResponseBuffer;
public int TransactionResponseFragmentByteIndex;
public int TransactionRequestFragmentByteIndex;
public byte[] in ExHeap ResponseReassemblyBuffer;
public int Transaction_ReceivedParameterBytes;
public int Transaction_ReceivedDataBytes;
public int Transaction_ReceivedFragmentCount;
public int Transaction_DataOffset;
public int Transaction_ParameterOffset;
// In the "Ready" state, this field is null.
// In all other states, this field is non-null.
public SmbTransactor.Exp Exp;
// Contains a reference to the byte[] in ExHeap buffer that contains a message that
// needs to be transmitted to the remote SMB peer. A transactor client (a holder of
// SmbTransactor.Imp) submits these buffers by sending the Request message.
public byte[] in ExHeap RequestBuffer;
// The length of the data in _buffer. Right now, this is always equal to the length
// of the buffer itself, because the current TcpConnectionContract does not allow
// for sends that are shorter than the length of the buffer.
public int RequestLength;
public byte[] in ExHeap ExtractResponseReassemblyBuffer()
{
expose(this)
{
byte[] in ExHeap buffer = this.ResponseReassemblyBuffer;
this.ResponseReassemblyBuffer = null;
return buffer;
}
}
public SmbTransactor.Exp! AcquireEndpoint()
{
expose (this) {
SmbTransactor.Exp exp = this.Exp;
this.Exp = null;
assert exp != null;
return exp;
}
}
#if false
void ITracked.Acquire() {}
void ITracked.Release() {}
void ITracked.Expose() {}
void ITracked.UnExpose() {}
#else
public void Acquire() {}
public void Release() {}
public void Expose() {}
public void UnExpose() {}
#endif
public void Dispose()
{
delete TransactionResponseBuffer;
delete RequestBuffer;
delete Exp;
// SelfReference.Dispose();
// delete SelfReference;
delete ResponseReassemblyBuffer;
}
}
readonly TContainer<TrackedData>! _datacon;
public TrackedData! AcquireData()
{
return _datacon.Acquire();
}
public void ReleaseData([Claims]TrackedData! data)
{
_datacon.Release(data);
}
public SmbTransactor.Exp! AcquireEndpoint()
{
TrackedData! tracked = AcquireData();
SmbTransactor.Exp exp = tracked.AcquireEndpoint();
ReleaseData(tracked);
assert exp != null;
return exp;
}
public byte[] in ExHeap ExtractResponseReassemblyBuffer()
{
TrackedData! tracked = AcquireData();
byte[] in ExHeap buffer;
expose(tracked)
{
buffer = tracked.ResponseReassemblyBuffer;
tracked.ResponseReassemblyBuffer = null;
ReleaseData(tracked);
}
return buffer;
}
public readonly string! DebugPrefix;
public readonly MuxTuple Tuple;
public TransactorState State;
public bool InQueue;
public SmbFlag1 _smbFlag1;
public SmbFlag2 _smbFlag2;
public SmbCommand Command;
public void Dispose()
{
TrackedData data = AcquireData();
data.Dispose();
}
override public string! ToString()
{
string! stateText = StateToString(this.State);
return String.Format("[Transactor tuple {0} state {1}]", this.Tuple.ToString(), stateText);
}
public static string! StateToString(TransactorState tstate)
{
switch (tstate)
{
case TransactorState.Ready: return "Ready";
case TransactorState.WaitingSendRequest: return "WaitingSendRequest";
case TransactorState.WaitingSendPrimaryTransactionRequest: return "WaitingSendPrimaryTransactionRequest";
case TransactorState.WaitingSendSecondaryTransactionRequest: return "WaitingSendSecondaryTransactionRequest";
case TransactorState.WaitingReceiveResponse: return "WaitingReceiveResponse";
case TransactorState.WaitingReceivePrimaryTransactionResponse: return "WaitingReceivePrimaryTransactionResponse";
case TransactorState.WaitingReceiveSecondaryTransactionResponse: return "WaitingReceiveSecondaryTransactionResponse";
default: return "???" + ((int)tstate).ToString();
}
}
}
enum TransactorState
{
// In this state, the ExpRef has been acquired (so don't try to acquire it again), and the exp is in the
// endpoint map that is owned by the multiplexer thread. Two things can happen to this transactor:
//
// * The transactor can close its channel. In this case, the multiplexer thread removes the
// transactor state from the _transactors hash table.
//
// * The transactor can start a new request. The multiplexer thread releases the ExpRef, and
// sets Transactor.State to Queued.
Ready,
// In this state, the multiplexer has received a request from the transactor client (the imp side).
// The multiplexer has not yet transmitted the packet to the remote peer.
//
// _waitingResponseExp contains a valid pointer.
// _buffer contains a valid pointer.
//
// Events:
//
// * If the TCP connection closes or fails, then the multiplexer thread will:
// acquire _waitingResponseExp, send its a NakRequest, and then delete it.
// acquire _buffer and delete it.
// remove the Transactor from the _transactors hash table.
//
// * When the multiplexer transmits the message, it removes the
WaitingSendRequest,
// In this state, the multiplexer has transmitted the request to the remote peer, and is now waiting
// for a response.
//
// * If the TCP connection closes or fails, then the multiplexer thread will acquire the
// waiting response endpoint, will send a NakRequest, will close the channel, and then
// will remove the tuple entry from the table.
//
WaitingReceiveResponse,
WaitingSendPrimaryTransactionRequest,
WaitingReceiveInterimTransactionResponse,
WaitingSendSecondaryTransactionRequest,
WaitingReceivePrimaryTransactionResponse,
WaitingReceiveSecondaryTransactionResponse,
}
}