Ejemplo n.º 1
0
func (h Handler) Touch(cmd common.TouchRequest) error {
	// read metadata
	// for 0 to metadata.numChunks
	//  touch item
	// touch metadata

	// We get the metadata and not GAT it in case the key is *just* about to expire.
	// In this case if a chunk expires during the operation, we fail the touch instead of
	// leaving a key in an inconsistent state where the metadata lives on and the data is
	// incomplete. The metadata is touched last to make sure the data exists first.
	metaKey, metaData, err := getMetadata(h.rw, cmd.Key)

	if err != nil {
		if err == common.ErrKeyNotFound {
			metrics.IncCounter(MetricCmdTouchMissesMeta)
		}

		return err
	}

	// First touch all the chunks as a batch
	for i := 0; i < int(metaData.NumChunks); i++ {
		chunkKey := chunkKey(cmd.Key, i)
		if err := binprot.WriteTouchCmd(h.rw.Writer, chunkKey, cmd.Exptime); err != nil {
			return err
		}
	}

	if err := h.rw.Flush(); err != nil {
		return err
	}

	miss := false
	for i := 0; i < int(metaData.NumChunks); i++ {
		if err := simpleCmdLocal(h.rw, false); err != nil {
			if err == common.ErrKeyNotFound && !miss {
				metrics.IncCounter(MetricCmdTouchMissesChunk)
				miss = true
			}
		}
	}

	if miss {
		return common.ErrKeyNotFound
	}

	// Then touch the metadata
	if err := binprot.WriteTouchCmd(h.rw.Writer, metaKey, cmd.Exptime); err != nil {
		return err
	}
	if err := simpleCmdLocal(h.rw, true); err != nil {
		if err == common.ErrKeyNotFound {
			metrics.IncCounter(MetricCmdTouchMissesMeta)
		}
		return err
	}

	return nil
}
Ejemplo n.º 2
0
func (h Handler) Delete(cmd common.DeleteRequest) error {
	// read metadata
	// delete metadata
	// for 0 to metadata.numChunks
	//  delete item

	metaKey, metaData, err := getMetadata(h.rw, cmd.Key)

	if err != nil {
		if err == common.ErrKeyNotFound {
			metrics.IncCounter(MetricCmdDeleteMissesMeta)
		}
		return err
	}

	// Delete metadata first
	if err := binprot.WriteDeleteCmd(h.rw.Writer, metaKey); err != nil {
		return err
	}
	if err := simpleCmdLocal(h.rw, true); err != nil {
		if err == common.ErrKeyNotFound {
			metrics.IncCounter(MetricCmdDeleteMissesMeta)
		}
		return err
	}

	// Then delete data chunks
	for i := 0; i < int(metaData.NumChunks); i++ {
		chunkKey := chunkKey(cmd.Key, i)
		if err := binprot.WriteDeleteCmd(h.rw.Writer, chunkKey); err != nil {
			return err
		}
	}

	if err := h.rw.Flush(); err != nil {
		return err
	}

	miss := false
	for i := 0; i < int(metaData.NumChunks); i++ {
		if err := simpleCmdLocal(h.rw, false); err != nil {
			if err == common.ErrKeyNotFound && !miss {
				metrics.IncCounter(MetricCmdDeleteMissesChunk)
				miss = true
			}
		}
	}

	if miss {
		return common.ErrKeyNotFound
	}

	return nil
}
Ejemplo n.º 3
0
func (l *L1OnlyOrca) Gat(req common.GATRequest) error {
	metrics.IncCounter(MetricCmdGat)
	//log.Println("gat", string(req.Key))

	metrics.IncCounter(MetricCmdGatL1)
	res, err := l.l1.GAT(req)

	if err == nil {
		if res.Miss {
			metrics.IncCounter(MetricCmdGatMissesL1)
			// TODO: Account for L2
			metrics.IncCounter(MetricCmdGatMisses)
		} else {
			metrics.IncCounter(MetricCmdGatHits)
			metrics.IncCounter(MetricCmdGatHitsL1)
		}
		l.res.GAT(res)
		// There is no GetEnd call required here since this is only ever
		// done in the binary protocol, where there's no END marker.
		// Calling l.res.GetEnd was a no-op here and is just useless.
		//l.res.GetEnd(0, false)
	} else {
		metrics.IncCounter(MetricCmdGatErrors)
		metrics.IncCounter(MetricCmdGatErrorsL1)
	}

	return err
}
Ejemplo n.º 4
0
func (l *L1OnlyOrca) Get(req common.GetRequest) error {
	metrics.IncCounter(MetricCmdGet)
	metrics.IncCounterBy(MetricCmdGetKeys, uint64(len(req.Keys)))
	//debugString := "get"
	//for _, k := range req.Keys {
	//	debugString += " "
	//	debugString += string(k)
	//}
	//println(debugString)

	metrics.IncCounter(MetricCmdGetL1)
	metrics.IncCounterBy(MetricCmdGetKeysL1, uint64(len(req.Keys)))
	resChan, errChan := l.l1.Get(req)

	var err error

	// Read all the responses back from l.l1.
	// The contract is that the resChan will have GetResponse's for get hits and misses,
	// and the errChan will have any other errors, such as an out of memory error from
	// memcached. If any receive happens from errChan, there will be no more responses
	// from resChan.
	for {
		select {
		case res, ok := <-resChan:
			if !ok {
				resChan = nil
			} else {
				if res.Miss {
					metrics.IncCounter(MetricCmdGetMissesL1)
					metrics.IncCounter(MetricCmdGetMisses)
				} else {
					metrics.IncCounter(MetricCmdGetHits)
					metrics.IncCounter(MetricCmdGetHitsL1)
				}
				l.res.Get(res)
			}

		case getErr, ok := <-errChan:
			if !ok {
				errChan = nil
			} else {
				metrics.IncCounter(MetricCmdGetErrors)
				metrics.IncCounter(MetricCmdGetErrorsL1)
				err = getErr
			}
		}

		if resChan == nil && errChan == nil {
			break
		}
	}

	if err == nil {
		l.res.GetEnd(req.NoopOpaque, req.NoopEnd)
	}

	return err
}
Ejemplo n.º 5
0
Archivo: l1l2.go Proyecto: Netflix/rend
func (l *L1L2Orca) Set(req common.SetRequest) error {
	//log.Println("set", string(req.Key))

	// Try L2 first
	metrics.IncCounter(MetricCmdSetL2)
	start := timer.Now()

	err := l.l2.Set(req)

	metrics.ObserveHist(HistSetL2, timer.Since(start))

	// If we fail to set in L2, don't set in L1
	if err != nil {
		metrics.IncCounter(MetricCmdSetErrorsL2)
		metrics.IncCounter(MetricCmdSetErrors)
		return err
	}
	metrics.IncCounter(MetricCmdSetSuccessL2)

	// Now set in L1. If L1 fails, we log the error and fail the request.
	// If a user was writing a new piece of information, the error would be OK,
	// since the next GET would be able to put the L2 information back into L1.
	// In the case that the user was overwriting information, a failed set in L1
	// and successful one in L2 would leave us inconsistent. If the response was
	// positive in this situation, it would look like the server successfully
	// processed the request but didn't store the information. Clients will
	// retry failed writes. In this case L2 will get two writes for the same key
	// but this is better because it is more correct overall, though less
	// efficient. Note there are no retries at this level.
	//
	// It should be noted that errors on a straight set are nearly always fatal
	// for the connection. It's likely that if this branch is taken that the
	// connections to everyone will be severed (for this one client connection)
	// and that the client will reconnect to try again.
	metrics.IncCounter(MetricCmdSetL1)
	start = timer.Now()

	err = l.l1.Set(req)

	metrics.ObserveHist(HistSetL1, timer.Since(start))

	if err != nil {
		metrics.IncCounter(MetricCmdSetErrorsL1)
		metrics.IncCounter(MetricCmdSetErrors)
		return err
	}

	metrics.IncCounter(MetricCmdSetSuccessL1)
	metrics.IncCounter(MetricCmdSetSuccess)

	return l.res.Set(req.Opaque, req.Quiet)
}
Ejemplo n.º 6
0
func (l *L1OnlyOrca) Replace(req common.SetRequest) error {
	//log.Println("replace", string(req.Key))

	metrics.IncCounter(MetricCmdReplaceL1)
	start := timer.Now()

	err := l.l1.Replace(req)

	metrics.ObserveHist(HistReplaceL1, timer.Since(start))

	if err == nil {
		metrics.IncCounter(MetricCmdReplaceStoredL1)
		metrics.IncCounter(MetricCmdReplaceStored)

		err = l.res.Replace(req.Opaque, req.Quiet)

	} else if err == common.ErrKeyNotFound {
		metrics.IncCounter(MetricCmdReplaceNotStoredL1)
		metrics.IncCounter(MetricCmdReplaceNotStored)
	} else {
		metrics.IncCounter(MetricCmdReplaceErrorsL1)
		metrics.IncCounter(MetricCmdReplaceErrors)
	}

	return err
}
Ejemplo n.º 7
0
func (l *L1L2BatchOrca) Set(req common.SetRequest) error {
	//log.Println("set", string(req.Key))

	// Try L2 first
	metrics.IncCounter(MetricCmdSetL2)
	start := timer.Now()

	err := l.l2.Set(req)

	metrics.ObserveHist(HistSetL2, timer.Since(start))

	// If we fail to set in L2, don't do anything in L1
	if err != nil {
		metrics.IncCounter(MetricCmdSetErrorsL2)
		metrics.IncCounter(MetricCmdSetErrors)
		return err
	}
	metrics.IncCounter(MetricCmdSetSuccessL2)

	// Replace the entry in L1.
	metrics.IncCounter(MetricCmdSetReplaceL1)
	start = timer.Now()

	err = l.l1.Replace(req)

	metrics.ObserveHist(HistReplaceL1, timer.Since(start))

	if err != nil {
		if err == common.ErrKeyNotFound {
			// For a replace not stored in L1, there's no problem.
			// There is no hot data to replace
			metrics.IncCounter(MetricCmdSetReplaceNotStoredL1)
		} else {
			metrics.IncCounter(MetricCmdSetReplaceErrorsL1)
			metrics.IncCounter(MetricCmdSetErrors)
			return err
		}
	} else {
		metrics.IncCounter(MetricCmdSetReplaceStoredL1)
	}

	metrics.IncCounter(MetricCmdSetSuccess)

	return l.res.Set(req.Opaque, req.Quiet)
}
Ejemplo n.º 8
0
func (l *L1OnlyOrca) Delete(req common.DeleteRequest) error {
	//log.Println("delete", string(req.Key))

	metrics.IncCounter(MetricCmdDeleteL1)
	start := timer.Now()

	err := l.l1.Delete(req)

	metrics.ObserveHist(HistDeleteL1, timer.Since(start))

	if err == nil {
		metrics.IncCounter(MetricCmdDeleteHits)
		metrics.IncCounter(MetricCmdDeleteHitsL1)

		l.res.Delete(req.Opaque)

	} else if err == common.ErrKeyNotFound {
		metrics.IncCounter(MetricCmdDeleteMissesL1)
		metrics.IncCounter(MetricCmdDeleteMisses)
	} else {
		metrics.IncCounter(MetricCmdDeleteErrorsL1)
		metrics.IncCounter(MetricCmdDeleteErrors)
	}

	return err
}
Ejemplo n.º 9
0
func (l *L1OnlyOrca) Touch(req common.TouchRequest) error {
	//log.Println("touch", string(req.Key))

	metrics.IncCounter(MetricCmdTouchL1)
	start := timer.Now()

	err := l.l1.Touch(req)

	metrics.ObserveHist(HistTouchL1, timer.Since(start))

	if err == nil {
		metrics.IncCounter(MetricCmdTouchHitsL1)
		metrics.IncCounter(MetricCmdTouchHits)

		l.res.Touch(req.Opaque)

	} else if err == common.ErrKeyNotFound {
		metrics.IncCounter(MetricCmdTouchMissesL1)
		metrics.IncCounter(MetricCmdTouchMisses)
	} else {
		metrics.IncCounter(MetricCmdTouchMissesL1)
		metrics.IncCounter(MetricCmdTouchMisses)
	}

	return err
}
Ejemplo n.º 10
0
func (l *L1OnlyOrca) Add(req common.SetRequest) error {
	//log.Println("add", string(req.Key))

	metrics.IncCounter(MetricCmdAddL1)
	start := timer.Now()

	err := l.l1.Add(req)

	metrics.ObserveHist(HistAddL1, timer.Since(start))

	if err == nil {
		metrics.IncCounter(MetricCmdAddStoredL1)
		metrics.IncCounter(MetricCmdAddStored)

		err = l.res.Add(req.Opaque, req.Quiet)

	} else if err == common.ErrKeyExists {
		metrics.IncCounter(MetricCmdAddNotStoredL1)
		metrics.IncCounter(MetricCmdAddNotStored)
	} else {
		metrics.IncCounter(MetricCmdAddErrorsL1)
		metrics.IncCounter(MetricCmdAddErrors)
	}

	return err
}
Ejemplo n.º 11
0
func readRequestHeader(r io.Reader) (RequestHeader, error) {
	buf := bufPool.Get().([]byte)

	br, err := io.ReadAtLeast(r, buf, ReqHeaderLen)
	metrics.IncCounterBy(common.MetricBytesReadRemote, uint64(br))
	if err != nil {
		bufPool.Put(buf)
		return emptyReqHeader, err
	}

	if buf[0] != MagicRequest {
		bufPool.Put(buf)
		metrics.IncCounter(MetricBinaryRequestHeadersBadMagic)
		return emptyReqHeader, ErrBadMagic
	}

	rh := reqHeadPool.Get().(RequestHeader)
	rh.Magic = buf[0]
	rh.Opcode = buf[1]
	rh.KeyLength = binary.BigEndian.Uint16(buf[2:4])
	rh.ExtraLength = buf[4]
	// ignore DataType, unused
	//rh.DataType = buf[5]
	rh.DataType = 0
	// ignore VBucket, unused
	//rh.VBucket = binary.BigEndian.Uint16(buf[6:8])
	rh.VBucket = 0
	rh.TotalBodyLength = binary.BigEndian.Uint32(buf[8:12])
	rh.OpaqueToken = binary.BigEndian.Uint32(buf[12:16])
	// ignore CAS, unused in rend
	//rh.CASToken = binary.BigEndian.Uint64(buf[16:24])
	rh.CASToken = 0

	bufPool.Put(buf)
	metrics.IncCounter(MetricBinaryRequestHeadersParsed)

	return rh, nil
}
Ejemplo n.º 12
0
func (l *L1OnlyOrca) Set(req common.SetRequest) error {
	//log.Println("set", string(req.Key))

	metrics.IncCounter(MetricCmdSetL1)
	start := timer.Now()

	err := l.l1.Set(req)

	metrics.ObserveHist(HistSetL1, timer.Since(start))

	if err == nil {
		metrics.IncCounter(MetricCmdSetSuccessL1)
		metrics.IncCounter(MetricCmdSetSuccess)

		err = l.res.Set(req.Opaque, req.Quiet)

	} else {
		metrics.IncCounter(MetricCmdSetErrorsL1)
		metrics.IncCounter(MetricCmdSetErrors)
	}

	return err
}
Ejemplo n.º 13
0
func (l *L1OnlyOrca) Touch(req common.TouchRequest) error {
	metrics.IncCounter(MetricCmdTouch)
	//log.Println("touch", string(req.Key))

	metrics.IncCounter(MetricCmdTouchL1)
	err := l.l1.Touch(req)

	if err == nil {
		metrics.IncCounter(MetricCmdTouchHitsL1)
		metrics.IncCounter(MetricCmdTouchHits)

		l.res.Touch(req.Opaque)

	} else if err == common.ErrKeyNotFound {
		metrics.IncCounter(MetricCmdTouchMissesL1)
		metrics.IncCounter(MetricCmdTouchMisses)
	} else {
		metrics.IncCounter(MetricCmdTouchMissesL1)
		metrics.IncCounter(MetricCmdTouchMisses)
	}

	return err
}
Ejemplo n.º 14
0
func (l *L1OnlyOrca) Add(req common.SetRequest) error {
	metrics.IncCounter(MetricCmdAdd)
	//log.Println("add", string(req.Key))

	metrics.IncCounter(MetricCmdAddL1)
	err := l.l1.Add(req)

	if err == nil {
		metrics.IncCounter(MetricCmdAddStoredL1)
		metrics.IncCounter(MetricCmdAddStored)

		err = l.res.Add(req.Opaque, req.Quiet)

	} else if err == common.ErrKeyExists {
		metrics.IncCounter(MetricCmdAddNotStoredL1)
		metrics.IncCounter(MetricCmdAddNotStored)
	} else {
		metrics.IncCounter(MetricCmdAddErrorsL1)
		metrics.IncCounter(MetricCmdAddErrors)
	}

	return err
}
Ejemplo n.º 15
0
func (l *L1OnlyOrca) Replace(req common.SetRequest) error {
	metrics.IncCounter(MetricCmdReplace)
	//log.Println("replace", string(req.Key))

	metrics.IncCounter(MetricCmdReplaceL1)
	err := l.l1.Replace(req)

	if err == nil {
		metrics.IncCounter(MetricCmdReplaceStoredL1)
		metrics.IncCounter(MetricCmdReplaceStored)

		err = l.res.Replace(req.Opaque, req.Quiet)

	} else if err == common.ErrKeyNotFound {
		metrics.IncCounter(MetricCmdReplaceNotStoredL1)
		metrics.IncCounter(MetricCmdReplaceNotStored)
	} else {
		metrics.IncCounter(MetricCmdReplaceErrorsL1)
		metrics.IncCounter(MetricCmdReplaceErrors)
	}

	return err
}
Ejemplo n.º 16
0
func (l *L1OnlyOrca) Delete(req common.DeleteRequest) error {
	metrics.IncCounter(MetricCmdDelete)
	//log.Println("delete", string(req.Key))

	metrics.IncCounter(MetricCmdDeleteL1)
	err := l.l1.Delete(req)

	if err == nil {
		metrics.IncCounter(MetricCmdDeleteHits)
		metrics.IncCounter(MetricCmdDeleteHitsL1)

		l.res.Delete(req.Opaque)

	} else if err == common.ErrKeyNotFound {
		metrics.IncCounter(MetricCmdDeleteMissesL1)
		metrics.IncCounter(MetricCmdDeleteMisses)
	} else {
		metrics.IncCounter(MetricCmdDeleteErrorsL1)
		metrics.IncCounter(MetricCmdDeleteErrors)
	}

	return err
}
Ejemplo n.º 17
0
func (l *L1OnlyOrca) Set(req common.SetRequest) error {
	metrics.IncCounter(MetricCmdSet)
	//log.Println("set", string(req.Key))

	metrics.IncCounter(MetricCmdSetL1)
	err := l.l1.Set(req)

	if err == nil {
		metrics.IncCounter(MetricCmdSetSuccessL1)
		metrics.IncCounter(MetricCmdSetSuccess)

		err = l.res.Set(req.Opaque, req.Quiet)

	} else {
		metrics.IncCounter(MetricCmdSetErrorsL1)
		metrics.IncCounter(MetricCmdSetErrors)
	}

	return err
}
Ejemplo n.º 18
0
func (l *L1L2Orca) Gat(req common.GATRequest) error {
	metrics.IncCounter(MetricCmdGat)
	//log.Println("gat", string(req.Key))

	// Try L1 first, since it'll be faster if it succeeds
	metrics.IncCounter(MetricCmdGatL1)
	res, err := l.l1.GAT(req)

	// Errors here are genrally fatal to the connection, as something has gone
	// seriously wrong. Bail out early.
	// I should note that this is different than the other commands, where there
	// are some benevolent "errors" that include KeyNotFound or KeyExists. In
	// both Get and GAT the mini-internal-protocol is different because the Get
	// command uses a channel to send results back and an error channel to signal
	// some kind of fatal problem. The result signals non-fatal "errors"; in this
	// case it's ErrKeyNotFound --> res.Miss is true.
	if err != nil {
		metrics.IncCounter(MetricCmdGatErrorsL1)
		metrics.IncCounter(MetricCmdGatErrors)
		return err
	}

	if res.Miss {
		// If we miss here, we have to GAT L2 to get the data, then put it back
		// into L1 with the new TTL.
		metrics.IncCounter(MetricCmdGatMissesL1)

		metrics.IncCounter(MetricCmdGatL2)
		res, err = l.l2.GAT(req)

		// fatal error
		if err != nil {
			metrics.IncCounter(MetricCmdGatErrorsL2)
			metrics.IncCounter(MetricCmdGatErrors)
			return err
		}

		// A miss on L2 after L1 is a true miss
		if res.Miss {
			metrics.IncCounter(MetricCmdGatMissesL2)
			metrics.IncCounter(MetricCmdGatMisses)
			return l.res.GAT(res)
		}

		// Take the data from the L2 GAT and set into L1 with the new TTL.
		// There's several problems that could arise from interleaving of other
		// operations. Another GAT isn't a problem.
		//
		// Intermediate sets might get clobbered in L1 but remain in L2 if we
		// used Set, but since we use Add we should not overwrite a Set that
		// happens between the L2 GAT hit and subsequent L1 reconciliation.
		//
		// Deletes would be a possible problem since a delete hit in L2 and miss
		// in L1 would interleave to have data in L1 not in L2. This is a risk
		// that is understood and accepted. The typical use cases at Netflix
		// will not use deletes concurrently with GATs.
		setreq := common.SetRequest{
			Key:     req.Key,
			Exptime: req.Exptime,
			Flags:   res.Flags,
			Data:    res.Data,
		}

		metrics.IncCounter(MetricCmdGatAddL1)
		if err := l.l1.Add(setreq); err != nil {
			// we were trampled in the middle of performing the GAT operation
			// In this case, it's fine; no error for the overall op. We still
			// want to track this with a metric, though, and return success.
			if err == common.ErrKeyExists {
				metrics.IncCounter(MetricCmdGatAddNotStoredL1)
			} else {
				metrics.IncCounter(MetricCmdGatAddErrorsL1)
				// Gat errors here and not Add. The metrics for L1/L2 correspond to
				// direct interaction with the two. THe overall metrics correspond
				// to the more abstract orchestrator operation.
				metrics.IncCounter(MetricCmdGatErrors)
				return err
			}
		} else {
			metrics.IncCounter(MetricCmdGatAddStoredL1)
		}

		// the overall operation succeeded
		metrics.IncCounter(MetricCmdGatHits)

	} else {
		metrics.IncCounter(MetricCmdGatHitsL1)

		// Set in L2 to play to the L2's strengths (fast writes) and avoid some
		// pitfalls (slow touches and replaces, which require reads)
		//
		// The first possibility is a Set. A set into L2 would possibly cause a
		// concurrent delete to not take, meaning the delete could say it was
		// successful and then a subsequent get call would show the old data
		// that was just deleted.
		//
		// Another option is to just send a touch, which allows us to send less
		// data but gives the possibility of a touch miss on L2, which will be a
		// problematic situation. If we get a touch miss, then we know we are
		// inconsistent but we don't affect concurrent deletes.
		//
		// A third option is to use Replace, which could be helpful to avoid
		// overriding concurrent deletes. This also might cause problems with
		// othr sets at the same time, as it might overwrite a set that just
		// finished.
		//
		// Many heavy users of EVCache at Netflix use GAT commands to lengthen
		// TTLs of their data in use and to shorten the TTL of data they will
		// not be using which is then async TTL'd out. I am explicitly
		// discounting the concurrent delete situation here and accepting that
		// they might not be exactly correct.
		setreq := common.SetRequest{
			Key:     req.Key,
			Exptime: req.Exptime,
			Flags:   res.Flags,
			Data:    res.Data,
		}

		metrics.IncCounter(MetricCmdGatSetL2)
		err := l.l2.Set(setreq)

		if err != nil {
			// set error? Return it as our error. Yes, the GAT succeeded in L1
			// but if L2 didn't get the set, then likely something is seriously
			// wrong.
			metrics.IncCounter(MetricCmdGatSetErrorsL2)
			metrics.IncCounter(MetricCmdGatErrors)
			return err
		}
		metrics.IncCounter(MetricCmdGatSetSuccessL2)

		// overall operation succeeded
		metrics.IncCounter(MetricCmdGatHits)
	}

	return l.res.GAT(res)
}
Ejemplo n.º 19
0
func (l *L1OnlyOrca) GetE(req common.GetRequest) error {
	// For an L1 only orchestrator, this will fail if the backend is memcached.
	// It should be talking to another rend-based server, such as the L2 for the
	// EVCache server project.
	metrics.IncCounterBy(MetricCmdGetEKeys, uint64(len(req.Keys)))
	//debugString := "gete"
	//for _, k := range req.Keys {
	//	debugString += " "
	//	debugString += string(k)
	//}
	//println(debugString)

	metrics.IncCounter(MetricCmdGetEL1)
	metrics.IncCounterBy(MetricCmdGetEKeysL1, uint64(len(req.Keys)))
	start := timer.Now()

	resChan, errChan := l.l1.GetE(req)

	var err error

	// Read all the responses back from l.l1.
	// The contract is that the resChan will have GetEResponse's for get hits and misses,
	// and the errChan will have any other errors, such as an out of memory error from
	// memcached. If any receive happens from errChan, there will be no more responses
	// from resChan.
	for {
		select {
		case res, ok := <-resChan:
			if !ok {
				resChan = nil
			} else {
				if res.Miss {
					metrics.IncCounter(MetricCmdGetEMissesL1)
					metrics.IncCounter(MetricCmdGetEMisses)
				} else {
					metrics.IncCounter(MetricCmdGetEHits)
					metrics.IncCounter(MetricCmdGetEHitsL1)
				}
				l.res.GetE(res)
			}

		case getErr, ok := <-errChan:
			if !ok {
				errChan = nil
			} else {
				metrics.IncCounter(MetricCmdGetEErrors)
				metrics.IncCounter(MetricCmdGetEErrorsL1)
				err = getErr
			}
		}

		if resChan == nil && errChan == nil {
			break
		}
	}

	metrics.ObserveHist(HistGetEL1, timer.Since(start))

	if err == nil {
		l.res.GetEnd(req.NoopOpaque, req.NoopEnd)
	}

	return err
}
Ejemplo n.º 20
0
func (l *L1L2Orca) Replace(req common.SetRequest) error {
	metrics.IncCounter(MetricCmdReplace)
	//log.Println("replace", string(req.Key))

	// Add in L2 first, since it has the larger state
	metrics.IncCounter(MetricCmdReplaceL2)
	err := l.l2.Replace(req)

	if err != nil {
		// A key already existing is not an error per se, it's a part of the
		// functionality of the replace command to respond with a "not stored"
		// in the form of an ErrKeyNotFound. Hence no error metrics.
		if err == common.ErrKeyNotFound {
			metrics.IncCounter(MetricCmdReplaceNotStoredL2)
			metrics.IncCounter(MetricCmdReplaceNotStored)
			return err
		}

		// otherwise we have a real error on our hands
		metrics.IncCounter(MetricCmdReplaceErrorsL2)
		metrics.IncCounter(MetricCmdReplaceErrors)
		return err
	}

	metrics.IncCounter(MetricCmdReplaceStoredL2)

	// Now on to L1. For a replace, the L2 succeeding means that the key is
	// successfully replaced in L2, but in the middle here "anything can happen"
	// so we have to think about concurrent operations. In a concurrent set
	// situation, both L2 and L1 might have the same value from the set. In this
	// case an add will fail and cause correct behavior. In a concurrent delete
	// that hits in L2 (for the newly replaced data) and hits in L1 (for the
	// data that was about to be replaced) then an add will cause a consistency
	// problem by setting a key that shouldn't exist in L1 because it's not in
	// L2. set and replace have the opposite problem, since they might overwrite
	// a legitimate set that happened concurrently in the middle of the two
	// operations. There is no one operation that solves these, so:
	//
	// The use of replace here explicitly assumes there is no concurrent set for
	// the same key.
	//
	// The other risk here is a concurrent replace for the same key, which will
	// possibly interleave to produce inconsistency in L2 and L1.
	metrics.IncCounter(MetricCmdReplaceL1)
	err = l.l1.Replace(req)

	if err != nil {
		// In this case, the replace worked fine, and we don't worry about it not
		// being replaced in L1 because it did not exist. In this case, L2 has
		// the data and L1 is empty. This is still correct, and the next get
		// would place the data back into L1. Hence, we do not return the error.
		if err == common.ErrKeyNotFound {
			metrics.IncCounter(MetricCmdReplaceNotStoredL1)
			metrics.IncCounter(MetricCmdReplaceNotStored)
			return l.res.Replace(req.Opaque, req.Quiet)
		}

		// otherwise we have a real error on our hands
		metrics.IncCounter(MetricCmdReplaceErrorsL1)
		metrics.IncCounter(MetricCmdReplaceErrors)
		return err
	}

	metrics.IncCounter(MetricCmdReplaceStoredL1)
	metrics.IncCounter(MetricCmdReplaceStored)

	return l.res.Replace(req.Opaque, req.Quiet)
}
Ejemplo n.º 21
0
func (l *L1L2Orca) Add(req common.SetRequest) error {
	metrics.IncCounter(MetricCmdAdd)
	//log.Println("add", string(req.Key))

	// Add in L2 first, since it has the larger state
	metrics.IncCounter(MetricCmdAddL2)
	err := l.l2.Add(req)

	if err != nil {
		// A key already existing is not an error per se, it's a part of the
		// functionality of the add command to respond with a "not stored" in
		// the form of a ErrKeyExists. Hence no error metrics.
		if err == common.ErrKeyExists {
			metrics.IncCounter(MetricCmdAddNotStoredL2)
			metrics.IncCounter(MetricCmdAddNotStored)
			return err
		}

		// otherwise we have a real error on our hands
		metrics.IncCounter(MetricCmdAddErrorsL2)
		metrics.IncCounter(MetricCmdAddErrors)
		return err
	}

	metrics.IncCounter(MetricCmdAddStoredL2)

	// Now on to L1. For L1 we also do an add operation to protect (partially)
	// against concurrent operations modifying the same key. For concurrent sets
	// that complete between the two stages, this will fail, leaving the cache
	// consistent.
	//
	// There is a possibility in add that concurrent deletes will cause an
	// inconsistent state. A concurrent delete could hit in L2 and miss in
	// L1 between the two add operations, causing the L2 to be deleted and
	// the L1 to have the data.
	metrics.IncCounter(MetricCmdAddL1)
	err = l.l1.Add(req)

	if err != nil {
		// This is kind of a problem. What has happened here is that the L2
		// cache has successfully added the key but L1 did not. In this case
		// we have to fail with a ErrKeyExists/Not Stored because the overall
		// operation failed. If we assume a retry on the client, then it will
		// likely fail again at the L2 step.
		//
		// One possible scenario here is that an add started and completed L2,
		// then a set ran to full completion, overwriting the data in L2 then
		// writing into L1, then the second step here ran and got an error.
		if err == common.ErrKeyExists {
			metrics.IncCounter(MetricCmdAddNotStoredL1)
			metrics.IncCounter(MetricCmdAddNotStored)
			return err
		}

		// otherwise we have a real error on our hands
		metrics.IncCounter(MetricCmdAddErrorsL1)
		metrics.IncCounter(MetricCmdAddErrors)
		return err
	}

	metrics.IncCounter(MetricCmdAddStoredL1)
	metrics.IncCounter(MetricCmdAddStored)

	return l.res.Add(req.Opaque, req.Quiet)
}
Ejemplo n.º 22
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func (l *L1L2Orca) Unknown(req common.Request) error {
	metrics.IncCounter(MetricCmdUnknown)
	return common.ErrUnknownCmd
}
Ejemplo n.º 23
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func (l *L1L2Orca) Version(req common.VersionRequest) error {
	metrics.IncCounter(MetricCmdVersion)
	return l.res.Version(req.Opaque)
}
Ejemplo n.º 24
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func (l *L1L2Orca) Quit(req common.QuitRequest) error {
	metrics.IncCounter(MetricCmdQuit)
	return l.res.Quit(req.Opaque, req.Quiet)
}
Ejemplo n.º 25
0
func (l *L1L2Orca) Delete(req common.DeleteRequest) error {
	metrics.IncCounter(MetricCmdDelete)
	//log.Println("delete", string(req.Key))

	// Try L2 first
	metrics.IncCounter(MetricCmdDeleteL2)
	err := l.l2.Delete(req)

	if err != nil {
		// On a delete miss in L2 don't bother deleting in L1. There might be no
		// key at all, or another request may be deleting the same key. In that
		// case the other will finish up. Returning a key not found will trigger
		// error handling to send back an error response.
		if err == common.ErrKeyNotFound {
			metrics.IncCounter(MetricCmdDeleteMissesL2)
			metrics.IncCounter(MetricCmdDeleteMisses)
			return err
		}

		// If we fail to delete in L2, don't delete in L1. This can leave us in
		// an inconsistent state if the request succeeded in L2 but some
		// communication error caused the problem. In the typical deployment of
		// rend, the L1 and L2 caches are both on the same box with
		// communication happening over a unix domain socket. In this case, the
		// likelihood of this error path happening is very small.
		metrics.IncCounter(MetricCmdDeleteErrorsL2)
		metrics.IncCounter(MetricCmdDeleteErrors)
		return err
	}
	metrics.IncCounter(MetricCmdDeleteHitsL2)

	// Now delete in L1. This means we're temporarily inconsistent, but also
	// eliminated the interleaving where the data is deleted from L1, read from
	// L2, set in L1, then deleted in L2. By deleting from L2 first, if L1 goes
	// missing then no other request can undo part of this request.
	metrics.IncCounter(MetricCmdDeleteL1)
	if err := l.l1.Delete(req); err != nil {
		// Delete misses in L1 are fine. If we get here, that means the delete
		// in L2 hit. This isn't a miss per se since the overall effect is a
		// delete. Concurrent deletes might interleave to produce this, or the
		// data might have TTL'd out. Both cases are still fine.
		if err == common.ErrKeyNotFound {
			metrics.IncCounter(MetricCmdDeleteMissesL1)
			metrics.IncCounter(MetricCmdDeleteHits)
			// disregard the miss, don't return the error
			return l.res.Delete(req.Opaque)
		}
		metrics.IncCounter(MetricCmdDeleteErrorsL1)
		metrics.IncCounter(MetricCmdDeleteErrors)
		return err
	}

	metrics.IncCounter(MetricCmdDeleteHitsL1)
	metrics.IncCounter(MetricCmdDeleteHits)

	return l.res.Delete(req.Opaque)
}
Ejemplo n.º 26
0
func (s *DefaultServer) Loop() {
	defer func() {
		if r := recover(); r != nil {
			if r != io.EOF {
				log.Println("Recovered from runtime panic:", r)
				log.Println("Panic location: ", identifyPanic())
			}
		}
	}()

	for {
		start := time.Now()

		request, reqType, err := s.rp.Parse()
		if err != nil {
			if err == common.ErrBadRequest ||
				err == common.ErrBadLength ||
				err == common.ErrBadFlags ||
				err == common.ErrBadExptime {
				s.orca.Error(nil, common.RequestUnknown, err)
				continue
			} else {
				// Otherwise IO error. Abort!
				abort(s.conns, err)
				return
			}
		}

		metrics.IncCounter(MetricCmdTotal)

		// TODO: handle nil
		switch reqType {
		case common.RequestSet:
			err = s.orca.Set(request.(common.SetRequest))
		case common.RequestAdd:
			err = s.orca.Add(request.(common.SetRequest))
		case common.RequestReplace:
			err = s.orca.Replace(request.(common.SetRequest))
		case common.RequestDelete:
			err = s.orca.Delete(request.(common.DeleteRequest))
		case common.RequestTouch:
			err = s.orca.Touch(request.(common.TouchRequest))
		case common.RequestGet:
			err = s.orca.Get(request.(common.GetRequest))
		case common.RequestGetE:
			err = s.orca.GetE(request.(common.GetRequest))
		case common.RequestGat:
			err = s.orca.Gat(request.(common.GATRequest))
		case common.RequestNoop:
			err = s.orca.Noop(request.(common.NoopRequest))
		case common.RequestQuit:
			s.orca.Quit(request.(common.QuitRequest))
			abort(s.conns, err)
			return
		case common.RequestVersion:
			err = s.orca.Version(request.(common.VersionRequest))
		case common.RequestUnknown:
			err = s.orca.Unknown(request)
		}

		if err != nil {
			if common.IsAppError(err) {
				if err != common.ErrKeyNotFound {
					metrics.IncCounter(MetricErrAppError)
				}
				s.orca.Error(request, reqType, err)
			} else {
				metrics.IncCounter(MetricErrUnrecoverable)
				abort(s.conns, err)
				return
			}
		}

		dur := uint64(time.Since(start))
		switch reqType {
		case common.RequestSet:
			metrics.ObserveHist(HistSet, dur)
		case common.RequestAdd:
			metrics.ObserveHist(HistAdd, dur)
		case common.RequestReplace:
			metrics.ObserveHist(HistReplace, dur)
		case common.RequestDelete:
			metrics.ObserveHist(HistDelete, dur)
		case common.RequestTouch:
			metrics.ObserveHist(HistTouch, dur)
		case common.RequestGet:
			metrics.ObserveHist(HistGet, dur)
		case common.RequestGetE:
			metrics.ObserveHist(HistGetE, dur)
		case common.RequestGat:
			metrics.ObserveHist(HistGat, dur)
		}
	}
}
Ejemplo n.º 27
0
func (l *L1L2Orca) Touch(req common.TouchRequest) error {
	metrics.IncCounter(MetricCmdTouch)
	//log.Println("touch", string(req.Key))

	// Try L2 first
	metrics.IncCounter(MetricCmdTouchL2)
	err := l.l2.Touch(req)

	if err != nil {
		// On a touch miss in L2 don't bother touch in L1. The data should be
		// TTL'd out within a second. This is yet another place where it's
		// possible to be inconsistent, but only for a short time. Any
		// concurrent requests will see the same behavior as this one. If the
		// touch misses here, any other request will see the same view.
		if err == common.ErrKeyNotFound {
			metrics.IncCounter(MetricCmdTouchMissesL2)
			metrics.IncCounter(MetricCmdTouchMisses)
			return err
		}

		// If we fail to touch in L2, don't touch in L1. If the touch succeeded
		// but for some reason the communication failed, then this is still OK
		// since L1 can TTL out while L2 still has the data. On the next get
		// request the data would still be retrievable, albeit more slowly.
		metrics.IncCounter(MetricCmdTouchErrorsL2)
		metrics.IncCounter(MetricCmdTouchErrors)
		return err
	}
	metrics.IncCounter(MetricCmdTouchHitsL2)

	// In the case of concurrent touches with different values, it's possible
	// that the touches for L1 and L2 interleave and produce an inconsistent
	// state. The L2 could be touched long, then L2 and L1 touched short on
	// another request, then L1 touched long. In this case the data in L1 would
	// outlive L2. This situation is uncommon and is therefore discounted.
	metrics.IncCounter(MetricCmdTouchL1)
	if err := l.l1.Touch(req); err != nil {
		// Touch misses in L1 after a hit in L2 are nto a big deal. The
		// touch operation here explicitly does *not* act as a pre-warm putting
		// data into L1. A miss here after a hit is the same as a hit.
		if err == common.ErrKeyNotFound {
			metrics.IncCounter(MetricCmdTouchMissesL1)
			// Note that we increment the overall hits here (not misses) on
			// purpose because L2 hit.
			metrics.IncCounter(MetricCmdTouchHits)
			return l.res.Touch(req.Opaque)
		}

		metrics.IncCounter(MetricCmdTouchErrorsL1)
		metrics.IncCounter(MetricCmdTouchErrors)
		return err
	}

	metrics.IncCounter(MetricCmdTouchHitsL1)
	metrics.IncCounter(MetricCmdTouchHits)

	return l.res.Touch(req.Opaque)
}
Ejemplo n.º 28
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func (l *L1L2Orca) Noop(req common.NoopRequest) error {
	metrics.IncCounter(MetricCmdNoop)
	return l.res.Noop(req.Opaque)
}
Ejemplo n.º 29
0
func ListenAndServe(l ListenArgs, s ServerConst, o orcas.OrcaConst, h1, h2 handlers.HandlerConst) {
	var listener net.Listener
	var err error

	switch l.Type {
	case ListenTCP:
		listener, err = net.Listen("tcp", fmt.Sprintf(":%d", l.Port))
		if err != nil {
			log.Panicf("Error binding to port %d: %v\n", l.Port, err.Error())
		}

	case ListenUnix:
		err = os.Remove(l.Path)
		if err != nil && !os.IsNotExist(err) {
			log.Panicf("Error removing previous unix socket file at %s\n", l.Path)
		}
		listener, err = net.Listen("unix", l.Path)
		if err != nil {
			log.Panicf("Error binding to unix socket at %s: %v\n", l.Path, err.Error())
		}

	default:
		log.Panicf("Unsupported server listen type: %v", l.Type)
	}

	for {
		remote, err := listener.Accept()
		if err != nil {
			log.Println("Error accepting connection from remote:", err.Error())
			remote.Close()
			continue
		}
		metrics.IncCounter(MetricConnectionsEstablishedExt)

		if l.Type == ListenTCP {
			tcpRemote := remote.(*net.TCPConn)
			tcpRemote.SetKeepAlive(true)
			tcpRemote.SetKeepAlivePeriod(30 * time.Second)
		}

		// construct L1 handler using given constructor
		l1, err := h1()
		if err != nil {
			log.Println("Error opening connection to L1:", err.Error())
			remote.Close()
			continue
		}
		metrics.IncCounter(MetricConnectionsEstablishedL1)

		// construct l2
		l2, err := h2()
		if err != nil {
			log.Println("Error opening connection to L2:", err.Error())
			l1.Close()
			remote.Close()
			continue
		}
		metrics.IncCounter(MetricConnectionsEstablishedL2)

		// spin off a goroutine here to handle determining the protocol used for the connection.
		// The server loop can't be started until the protocol is known. Another goroutine is
		// necessary here because we don't want to block accepting new connections if the current
		// new connection doesn't send data immediately.
		go func(remoteConn net.Conn) {
			remoteReader := bufio.NewReader(remoteConn)
			remoteWriter := bufio.NewWriter(remoteConn)

			var reqParser common.RequestParser
			var responder common.Responder

			// A connection is either binary protocol or text. It cannot switch between the two.
			// This is the way memcached handles protocols, so it can be as strict here.
			binary, err := isBinaryRequest(remoteReader)
			if err != nil {
				// must be an IO error. Abort!
				abort([]io.Closer{remoteConn, l1, l2}, err)
				return
			}

			if binary {
				reqParser = binprot.NewBinaryParser(remoteReader)
				responder = binprot.NewBinaryResponder(remoteWriter)
			} else {
				reqParser = textprot.NewTextParser(remoteReader)
				responder = textprot.NewTextResponder(remoteWriter)
			}

			server := s([]io.Closer{remoteConn, l1, l2}, reqParser, o(l1, l2, responder))

			go server.Loop()
		}(remote)
	}
}
Ejemplo n.º 30
0
func (l *L1L2Orca) Get(req common.GetRequest) error {
	metrics.IncCounter(MetricCmdGet)
	metrics.IncCounterBy(MetricCmdGetKeys, uint64(len(req.Keys)))
	//debugString := "get"
	//for _, k := range req.Keys {
	//	debugString += " "
	//	debugString += string(k)
	//}
	//println(debugString)

	metrics.IncCounter(MetricCmdGetL1)
	metrics.IncCounterBy(MetricCmdGetKeysL1, uint64(len(req.Keys)))
	resChan, errChan := l.l1.Get(req)

	var err error
	//var lastres common.GetResponse
	var l2keys [][]byte
	var l2opaques []uint32
	var l2quiets []bool

	// Read all the responses back from L1.
	// The contract is that the resChan will have GetResponse's for get hits and misses,
	// and the errChan will have any other errors, such as an out of memory error from
	// memcached. If any receive happens from errChan, there will be no more responses
	// from resChan.
	for {
		select {
		case res, ok := <-resChan:
			if !ok {
				resChan = nil
			} else {
				if res.Miss {
					metrics.IncCounter(MetricCmdGetMissesL1)
					l2keys = append(l2keys, res.Key)
					l2opaques = append(l2opaques, res.Opaque)
					l2quiets = append(l2quiets, res.Quiet)
				} else {
					metrics.IncCounter(MetricCmdGetHits)
					metrics.IncCounter(MetricCmdGetHitsL1)
					l.res.Get(res)
				}
			}

		case getErr, ok := <-errChan:
			if !ok {
				errChan = nil
			} else {
				metrics.IncCounter(MetricCmdGetErrors)
				metrics.IncCounter(MetricCmdGetErrorsL1)
				err = getErr
			}
		}

		if resChan == nil && errChan == nil {
			break
		}
	}

	// leave early on all hits
	if len(l2keys) == 0 {
		if err != nil {
			return err
		}
		return l.res.GetEnd(req.NoopOpaque, req.NoopEnd)
	}

	// Time for the same dance with L2
	req = common.GetRequest{
		Keys:       l2keys,
		NoopEnd:    req.NoopEnd,
		NoopOpaque: req.NoopOpaque,
		Opaques:    l2opaques,
		Quiet:      l2quiets,
	}

	metrics.IncCounter(MetricCmdGetEL2)
	metrics.IncCounterBy(MetricCmdGetEKeysL2, uint64(len(l2keys)))
	resChanE, errChan := l.l2.GetE(req)
	for {
		select {
		case res, ok := <-resChanE:
			if !ok {
				resChanE = nil
			} else {
				if res.Miss {
					metrics.IncCounter(MetricCmdGetEMissesL2)
					// Missing L2 means a true miss
					metrics.IncCounter(MetricCmdGetMisses)
				} else {
					metrics.IncCounter(MetricCmdGetEHitsL2)

					//set in l1
					metrics.IncCounter(MetricCmdGetSetL1)
					setreq := common.SetRequest{
						Key:     res.Key,
						Flags:   res.Flags,
						Exptime: res.Exptime,
						Data:    res.Data,
					}

					if err := l.l1.Set(setreq); err != nil {
						metrics.IncCounter(MetricCmdGetSetErrorsL1)
						return err
					}

					metrics.IncCounter(MetricCmdGetSetSucessL1)

					// overall operation is considered a hit
					metrics.IncCounter(MetricCmdGetHits)
				}

				getres := common.GetResponse{
					Key:    res.Key,
					Flags:  res.Flags,
					Data:   res.Data,
					Miss:   res.Miss,
					Opaque: res.Opaque,
					Quiet:  res.Quiet,
				}

				l.res.Get(getres)
			}

		case getErr, ok := <-errChan:
			if !ok {
				errChan = nil
			} else {
				metrics.IncCounter(MetricCmdGetErrors)
				metrics.IncCounter(MetricCmdGetEErrorsL2)
				err = getErr
			}
		}

		if resChanE == nil && errChan == nil {
			break
		}
	}

	if err == nil {
		return l.res.GetEnd(req.NoopOpaque, req.NoopEnd)
	}

	return err
}