// TCP large RECEIVE of results. Note that 'this' is NOT the RPC object
// that is hoping to get the received object, nor is the current thread the
// RPC thread blocking for the object. The current thread is the TCP
// reader thread.
static void tcp_ack(final AutoBuffer ab) throws IOException {
// Get the RPC we're waiting on
int task = ab.getTask();
RPC rpc = ab._h2o.taskGet(task);
// Race with canceling a large RPC fetch: Task is already dead. Do not
// bother reading from the TCP socket, just bail out & close socket.
if (rpc == null || rpc._done) {
ab.drainClose();
} else {
assert rpc._tasknum == task;
assert !rpc._done;
// Here we have the result, and we're on the correct Node but wrong
// Thread. If we just return, the TCP reader thread will close the
// remote, the remote will UDP ACK the RPC back, and back on the current
// Node but in the correct Thread, we'd wake up and realize we received a
// large result.
try {
rpc.response(ab);
} catch (AutoBuffer.AutoBufferException e) {
// If TCP fails, we will have done a short-read crushing the original
// _dt object, and be unable to resend. This is fatal right now.
// Really: an unimplemented feature; fix is to notice that a partial
// TCP read means that the server (1) got our remote_exec request, (2)
// has computed an answer and was trying to send it to us, (3) failed
// sending via TCP hence the server knows it failed and will send again
// without any further work from us. We need to disable all the resend
// & retry logic, and wait for the server to re-send our result.
// Meanwhile the _dt object is crushed with half-read crap, and cannot
// be trusted except in the base fields.
throw Log.throwErr(e._ioe);
}
}
// ACKACK the remote, telling him "we got the answer"
new AutoBuffer(ab._h2o, H2O.ACK_ACK_PRIORITY).putTask(UDP.udp.ackack.ordinal(), task).close();
}
// Got a response UDP packet, or completed a large TCP answer-receive.
// Install it as The Answer packet and wake up anybody waiting on an answer.
protected void response(AutoBuffer ab) {
assert _tasknum == ab.getTask();
if (_done) {
ab.close();
return;
} // Ignore duplicate response packet
int flag = ab.getFlag(); // Must read flag also, to advance ab
if (flag == SERVER_TCP_SEND) {
ab.close();
return;
} // Ignore UDP packet for a TCP reply
assert flag == SERVER_UDP_SEND;
synchronized (this) { // Install the answer under lock
if (_done) {
ab.close();
return;
} // Ignore duplicate response packet
_dt.read(ab); // Read the answer (under lock?)
ab.close(); // Also finish the read (under lock?)
_dt.onAck(); // One time only execute (before sending ACKACK)
_done = true;
UDPTimeOutThread.PENDING.remove(this);
TASKS.remove(_tasknum); // Flag as task-completed, even if the result is null
notifyAll(); // And notify in any case
}
}
// TCP large RECEIVE of results. Note that 'this' is NOT the RPC object
// that is hoping to get the received object, nor is the current thread the
// RPC thread blocking for the object. The current thread is the TCP
// reader thread.
static void tcp_ack(final AutoBuffer ab) {
// Get the RPC we're waiting on
int task = ab.getTask();
RPC rpc = TASKS.get(task);
// Race with canceling a large RPC fetch: Task is already dead. Do not
// bother reading from the TCP socket, just bail out & close socket.
if (rpc == null) {
ab.drainClose();
} else {
assert rpc._tasknum == task;
assert !rpc._done;
// Here we have the result, and we're on the correct Node but wrong
// Thread. If we just return, the TCP reader thread will close the
// remote, the remote will UDP ACK the RPC back, and back on the current
// Node but in the correct Thread, we'd wake up and realize we received a
// large result.
rpc.response(ab);
}
// ACKACK the remote, telling him "we got the answer"
new AutoBuffer(ab._h2o).putTask(UDP.udp.ackack.ordinal(), task).close(true);
}
// Handle TCP traffic, from a client to this server asking for work to be
// done. This is called on the TCP reader thread, not a Fork/Join worker
// thread. We want to do the bulk TCP read in the TCP reader thread.
static void tcp_exec(final AutoBuffer ab) {
final int ctrl = ab.getCtrl();
final int task = ab.getTask();
final int flag = ab.getFlag();
assert flag == CLIENT_UDP_SEND; // Client sent a request to be executed?
// Act "as if" called from the UDP packet code, by recording the task just
// like the packet we will be receiving (eventually). The presence of this
// packet is used to stop dup-actions on dup-sends. Racily inserted, keep
// only the last one.
DTask dt1 = ab._h2o.record_task(task);
assert dt1 == null || dt1 instanceof NOPTask
: "#"
+ task
+ " "
+ dt1.getClass(); // For TCP, no repeats, so 1st send is only send (except for UDP
// timeout retries)
// Make a remote instance of this dude from the stream, but only if the
// racing UDP packet did not already make one. Start the bulk TCP read.
final DTask dt = ab.get(DTask.class);
// Here I want to execute on this, but not block for completion in the
// TCP reader thread. Jam the task on some F/J thread.
UDP.udp
.UDPS[ctrl]
.pool()
.execute(
new CountedCompleter() {
public void compute() {
remexec(dt, ab._h2o, task, ab).close();
tryComplete();
}
public boolean onExceptionalCompletion(Throwable ex, CountedCompleter caller) {
ex.printStackTrace();
return true;
}
});
// All done for the TCP thread! Work continues in the FJ thread...
}
// Pretty-print bytes 1-15; byte 0 is the udp_type enum
public String print16(AutoBuffer ab) {
int flag = ab.getFlag();
String clazz = "";
if (flag == CLIENT_UDP_SEND)
clazz = new String(ab.getA1(Math.min(ab.get2(), ab.remaining())));
String fs = "";
switch (flag) {
case SERVER_UDP_SEND:
fs = "SERVER_UDP_SEND";
break;
case SERVER_TCP_SEND:
fs = "SERVER_TCP_SEND";
break;
case CLIENT_UDP_SEND:
fs = "CLIENT_UDP_SEND";
break;
case CLIENT_TCP_SEND:
fs = "CLIENT_TCP_SEND";
break;
}
return "task# " + ab.getTask() + " " + fs + " " + clazz;
}
protected AutoBuffer response(AutoBuffer ab) {
assert _tasknum == ab.getTask();
if (_done) {
if (!ab.hasTCP()) return ackack(ab, _tasknum); // Ignore duplicate response packet
ab.drainClose();
} else {
int flag = ab.getFlag(); // Must read flag also, to advance ab
if (flag == SERVER_TCP_SEND) return ackack(ab, _tasknum); // Ignore UDP packet for a TCP reply
assert flag == SERVER_UDP_SEND : "flag = " + flag;
synchronized (this) { // Install the answer under lock
if (_done) {
if (!ab.hasTCP()) return ackack(ab, _tasknum); // Ignore duplicate response packet
ab.drainClose();
} else {
// UDPTimeOutThread.PENDING.remove(_tasknum);
_dt.read(ab); // Read the answer (under lock?)
_size_rez = ab.size(); // Record received size
ab
.close(); // Also finish the read (under lock? even if canceled, since need to drain
// TCP)
if (!isCancelled()) // Can be canceled already (locally by MRTask while recieving remote
// answer)
_dt.onAck(); // One time only execute (before sending ACKACK)
_done = true; // Only read one (of many) response packets
ab._h2o.taskRemove(_tasknum); // Flag as task-completed, even if the result is null
notifyAll(); // And notify in any case
}
if (!isCancelled()) // Can be canceled already
doAllCompletions(); // Send all tasks needing completion to the work queues
}
}
// AckAck back on a fresh AutoBuffer, since actually closed() the incoming one
return new AutoBuffer(ab._h2o, H2O.ACK_ACK_PRIORITY)
.putTask(UDP.udp.ackack.ordinal(), _tasknum);
}
AutoBuffer call(AutoBuffer ab) {
return ab.getFlag() == CLIENT_UDP_SEND // UDP vs TCP send?
? remexec(ab.get(DTask.class), ab._h2o, ab.getTask(), ab)
: ab; // Else all the work is being done in the TCP thread.
}
// Handle traffic, from a client to this server asking for work to be done.
// Called from either a F/J thread (generally with a UDP packet) or from the
// TCPReceiver thread.
static void remote_exec(AutoBuffer ab) {
long lo = ab.get8(0), hi = ab._size >= 16 ? ab.get8(8) : 0;
final int task = ab.getTask();
final int flag = ab.getFlag();
assert flag == CLIENT_UDP_SEND || flag == CLIENT_TCP_SEND; // Client-side send
// Atomically record an instance of this task, one-time-only replacing a
// null with an RPCCall, a placeholder while we work on a proper response -
// and it serves to let us discard dup UDP requests.
RPCCall old = ab._h2o.has_task(task);
// This is a UDP packet requesting an answer back for a request sent via
// TCP but the UDP packet has arrived ahead of the TCP. Just drop the UDP
// and wait for the TCP to appear.
if (old == null && flag == CLIENT_TCP_SEND) {
Log.warn(
"got tcp with existing task #, FROM "
+ ab._h2o.toString()
+ " AB: " /* + UDP.printx16(lo,hi)*/);
assert !ab.hasTCP()
: "ERROR: got tcp with existing task #, FROM "
+ ab._h2o.toString()
+ " AB: " /* + UDP.printx16(lo,hi)*/; // All the resends should be UDP only
// DROP PACKET
} else if (old == null) { // New task?
RPCCall rpc;
try {
// Read the DTask Right Now. If we are the TCPReceiver thread, then we
// are reading in that thread... and thus TCP reads are single-threaded.
rpc = new RPCCall(ab.get(water.DTask.class), ab._h2o, task);
} catch (AutoBuffer.AutoBufferException e) {
// Here we assume it's a TCP fail on read - and ignore the remote_exec
// request. The caller will send it again. NOTE: this case is
// indistinguishable from a broken short-writer/long-reader bug, except
// that we'll re-send endlessly and fail endlessly.
Log.info(
"Network congestion OR short-writer/long-reader: TCP "
+ e._ioe.getMessage()
+ ", AB="
+ ab
+ ", ignoring partial send");
ab.drainClose();
return;
}
RPCCall rpc2 = ab._h2o.record_task(rpc);
if (rpc2 == null) { // Atomically insert (to avoid double-work)
if (rpc._dt instanceof MRTask && rpc._dt.logVerbose())
Log.debug("Start remote task#" + task + " " + rpc._dt.getClass() + " from " + ab._h2o);
H2O.submitTask(rpc); // And execute!
} else { // Else lost the task-insertion race
if (ab.hasTCP()) ab.drainClose();
// DROP PACKET
}
} else if (!old._computedAndReplied) {
// This packet has not been fully computed. Hence it's still a work-in-
// progress locally. We have no answer to reply but we do not want to
// re-offer the packet for repeated work. Send back a NACK, letting the
// client know we're Working On It
assert !ab.hasTCP()
: "got tcp with existing task #, FROM "
+ ab._h2o.toString()
+ " AB: "
+ UDP.printx16(lo, hi)
+ ", position = "
+ ab._bb.position();
ab.clearForWriting(udp.nack._prior).putTask(UDP.udp.nack.ordinal(), task);
// DROP PACKET
} else {
// This is an old re-send of the same thing we've answered to before.
// Send back the same old answer ACK. If we sent via TCP before, then
// we know the answer got there so just send a control-ACK back. If we
// sent via UDP, resend the whole answer.
if (ab.hasTCP()) {
Log.warn(
"got tcp with existing task #, FROM "
+ ab._h2o.toString()
+ " AB: "
+ UDP.printx16(lo, hi)); // All the resends should be UDP only
ab.drainClose();
}
if (old._dt != null) { // already ackacked
++old._ackResendCnt;
if (old._ackResendCnt % 10 == 0)
Log.err(
"Possibly broken network, can not send ack through, got "
+ old._ackResendCnt
+ " for task # "
+ old._tsknum
+ ", dt == null?"
+ (old._dt == null));
old.resend_ack();
}
}
ab.close();
}
// Pretty-print bytes 1-15; byte 0 is the udp_type enum
@Override
String print16(AutoBuffer ab) {
int flag = ab.getFlag();
String clazz = (flag == CLIENT_UDP_SEND) ? TypeMap.className(ab.getInt()) : "";
return "task# " + ab.getTask() + " " + clazz + " " + COOKIES[flag - SERVER_UDP_SEND];
}
