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Levin Zimmermann
neoppod
Commits
fb5d9b99
Commit
fb5d9b99
authored
May 04, 2017
by
Kirill Smelkov
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parent
f1486cb0
Changes
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3 changed files
with
93 additions
and
25 deletions
+93
-25
go/neo/proto-str.go
go/neo/proto-str.go
+26
-0
go/neo/proto.go
go/neo/proto.go
+67
-24
neo/lib/protocol.py
neo/lib/protocol.py
+0
-1
No files found.
go/neo/proto-str.go
View file @
fb5d9b99
...
...
@@ -11,3 +11,29 @@ func (e *Error) Error() string {
}
return
s
}
const
nodeTypeChar
=
"MSCA4567"
func
(
nid
NodeID
)
String
()
string
{
// return ex 'S1', 'M2', ...
if
nid
==
0
{
return
"?0"
}
typ
:=
nid
>>
24
num
:=
nid
&
(
1
<<
24
-
1
)
temp
:=
typ
&
(
1
<<
7
)
!=
0
typ
&=
1
<<
7
-
1
nodeType
:=
NodeType
(
typ
>>
4
)
s
:=
fmt
.
Sprintf
(
"%c%d"
,
nodeTypeChar
[
nodeType
],
num
)
// 's1', 'm2', for temporary nids
if
temp
{
s
=
strings
.
Lower
(
s
)
}
return
s
}
go/neo/proto.go
View file @
fb5d9b99
...
...
@@ -43,13 +43,34 @@ const (
type
ClusterState
int32
const
(
// NOTE cluster states descriptions is in protocol.py
// Once the primary master is elected, the cluster has a state, which is
// initially RECOVERING, during which the master:
// - first recovers its own data by reading it from storage nodes;
// - waits for the partition table be operational;
// - automatically switch to VERIFYING if the cluster can be safely started.
// Whenever the partition table becomes non-operational again, the cluster
// goes back to this state.
RECOVERING
ClusterState
=
iota
// Transient state, used to:
// - replay the transaction log, in case of unclean shutdown;
// - and actually truncate the DB if the user asked to do so.
// Then, the cluster either goes to RUNNING or STARTING_BACKUP state.
VERIFYING
// Normal operation. The DB is read-writable by clients.
CLUSTER_RUNNING
// XXX conflict with NodeState.RUNNING
// Transient state to shutdown the whole cluster.
STOPPING
// Transient state, during which the master (re)connect to the upstream
// master.
STARTING_BACKUP
// Backup operation. The master is notified of new transactions thanks to
// invalidations and orders storage nodes to fetch them from upstream.
// Because cells are synchronized independently, the DB is often
// inconsistent.
BACKINGUP
// Transient state, when the user decides to go back to RUNNING state.
// The master stays in this state until the DB is consistent again.
// In case of failure, the cluster will go back to backup mode.
STOPPING_BACKUP
)
...
...
@@ -74,18 +95,40 @@ const (
type
CellState
int32
const
(
// N
OTE cell states description is in protocol.py
// N
ormal state: cell is writable/readable, and it isn't planned to drop it.
UP_TO_DATE
CellState
=
iota
//short: U // XXX tag prefix name ?
// Write-only cell. Last transactions are missing because storage is/was down
// for a while, or because it is new for the partition. It usually becomes
// UP_TO_DATE when replication is done.
OUT_OF_DATE
//short: O
// Same as UP_TO_DATE, except that it will be discarded as soon as another
// node finishes to replicate it. It means a partition is moved from 1 node
// to another.
FEEDING
//short: F
// Not really a state: only used in network packets to tell storages to drop
// partitions.
DISCARDED
//short: D
// A check revealed that data differs from other replicas. Cell is neither
// readable nor writable.
CORRUPTED
//short: C
)
// An UUID (node identifier, 4-bytes signed integer)
type
UUID
int32
// NodeID is a node identifier, 4-bytes signed integer
//
// High-order byte:
// 7 6 5 4 3 2 1 0
// | | | | +-+-+-+-- reserved (0)
// | +-+-+---------- node type
// +---------------- temporary if negative
// UUID namespaces are required to prevent conflicts when the master generate
// new uuid before it knows uuid of existing storage nodes. So only the high
// order bit is really important and the 31 other bits could be random.
// Extra namespace information and non-randomness of 3 LOB help to read logs.
//
// XXX was UUID in py
type
NodeID
int32
// TODO
UUID_NAMESPACES
// TODO
NodeType -> base NodeID
var
ErrDecodeOverflow
=
errors
.
New
(
"decode: bufer overflow"
)
...
...
@@ -183,14 +226,14 @@ func float64_NEODecode(b []byte) float64 {
type
NodeInfo
struct
{
NodeType
Address
UU
ID
Node
ID
NodeState
IdTimestamp
float64
}
//type CellList []struct {
type
CellInfo
struct
{
UU
ID
Node
ID
CellState
}
...
...
@@ -246,7 +289,7 @@ type CloseClient struct {
type
RequestIdentification
struct
{
ProtocolVersion
uint32
// TODO py.PProtocol upon decoding checks for != PROTOCOL_VERSION
NodeType
NodeType
// XXX name
UUID
UU
ID
NodeID
Node
ID
Address
Address
// where requesting node is also accepting connections
Name
string
IdTimestamp
float64
...
...
@@ -255,14 +298,14 @@ type RequestIdentification struct {
// XXX -> ReplyIdentification? RequestIdentification.Answer somehow ?
type
AcceptIdentification
struct
{
NodeType
NodeType
// XXX name
My
UUID
UU
ID
My
NodeID
Node
ID
NumPartitions
uint32
// PNumber
NumReplicas
uint32
// PNumber
Your
UUID
UU
ID
Your
NodeID
Node
ID
Primary
Address
KnownMasterList
[]
struct
{
Address
UUID
UU
ID
NodeID
Node
ID
}
}
...
...
@@ -271,7 +314,7 @@ type PrimaryMaster struct {
}
type
AnswerPrimary
struct
{
Primary
UUID
UU
ID
Primary
NodeID
Node
ID
}
// Announce a primary master node election. PM -> SM.
...
...
@@ -326,7 +369,7 @@ type PartitionChanges struct {
CellList
[]
struct
{
// XXX does below correlate with Cell inside top-level CellList ?
Offset
uint32
// PNumber
UUID
UU
ID
NodeID
Node
ID
CellState
CellState
}
}
...
...
@@ -399,7 +442,7 @@ type AnswerBeginTransaction struct {
// True is returned if it's still possible to finish the transaction.
type
FailedVote
struct
{
Tid
zodb
.
Tid
UUIDList
[]
UU
ID
NodeList
[]
Node
ID
// XXX _answer = Error
}
...
...
@@ -514,7 +557,7 @@ type AnswerStoreObject struct {
// Abort a transaction. C -> S and C -> PM -> S.
type
AbortTransaction
struct
{
Tid
zodb
.
Tid
UUIDList
[]
UU
ID
// unused for * -> S
NodeList
[]
Node
ID
// unused for * -> S
}
// Ask to store a transaction. C -> S.
...
...
@@ -623,7 +666,7 @@ type AnswerObjectHistory struct {
type
PartitionList
struct
{
MinOffset
uint32
// PNumber
MaxOffset
uint32
// PNumber
UUID
UU
ID
NodeID
Node
ID
}
type
AnswerPartitionList
struct
{
...
...
@@ -643,7 +686,7 @@ type AnswerNodeList struct {
// Set the node state
type
SetNodeState
struct
{
UU
ID
Node
ID
NodeState
// XXX _answer = Error ?
...
...
@@ -651,14 +694,14 @@ type SetNodeState struct {
// Ask the primary to include some pending node in the partition table
type
AddPendingNodes
struct
{
UUIDList
[]
UU
ID
NodeList
[]
Node
ID
// XXX _answer = Error
}
// Ask the primary to optimize the partition table. A -> PM.
type
TweakPartitionTable
struct
{
UUIDList
[]
UU
ID
NodeList
[]
Node
ID
// XXX _answer = Error
}
...
...
@@ -691,7 +734,7 @@ type repairFlags struct {
// Ask storage nodes to repair their databases. ctl -> A -> M
type
Repair
struct
{
UUIDList
[]
UU
ID
NodeList
[]
Node
ID
repairFlags
}
...
...
@@ -779,7 +822,7 @@ type AnswerPack struct {
// ctl -> A
// A -> M
type
CheckReplicas
struct
{
PartitionDict
map
[
uint32
]
UU
ID
// partition -> source (PNumber)
PartitionDict
map
[
uint32
]
Node
ID
// partition -> source (PNumber)
MinTID
zodb
.
Tid
MaxTID
zodb
.
Tid
...
...
@@ -846,7 +889,7 @@ type AnswerCheckSerialRange struct {
// S -> M
type
PartitionCorrupted
struct
{
Partition
uint32
// PNumber
CellList
[]
UU
ID
CellList
[]
Node
ID
}
...
...
neo/lib/protocol.py
View file @
fb5d9b99
...
...
@@ -104,7 +104,6 @@ def ClusterStates():
# invalidations and orders storage nodes to fetch them from upstream.
# Because cells are synchronized independently, the DB is often
# inconsistent.
# TODO: allow clients to connect for read-only operations
BACKINGUP
# Transient state, when the user decides to go back to RUNNING state.
# The master stays in this state until the DB is consistent again.
...
...
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