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e34bddd3ab
ipfs-cluster/state/dsstate/datastore_test.go

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Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
package dsstate
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
import (
Issue #51: Save a backup on shutdown This adds snapshot and restore methods to state and uses the snapshot one to save a copy of the state when shutting down. Right now, this is not used for anything else. Some lines performing a migration, but this is only an idea of how it could work. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-27 16:28:41 +00:00
"bytes"
add opencensus tracing and metrics This commit adds support for OpenCensus tracing and metrics collection. This required support for context.Context propogation throughout the cluster codebase, and in particular, the ipfscluster component interfaces. The tracing propogates across RPC and HTTP boundaries. The current default tracing backend is Jaeger. The metrics currently exports the metrics exposed by the opencensus http plugin as well as the pprof metrics to a prometheus endpoint for scraping. The current default metrics backend is Prometheus. Metrics are currently exposed by default due to low overhead, can be turned off if desired, whereas tracing is off by default as it has a much higher performance overhead, though the extent of the performance hit can be adjusted with smaller sampling rates. License: MIT Signed-off-by: Adrian Lanzafame <adrianlanzafame92@gmail.com>
2018-06-27 04:03:15 +00:00
"context"
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
"testing"
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
"github.com/ipfs/ipfs-cluster/api"
"github.com/ipfs/ipfs-cluster/datastore/inmem"
ipfs-cluster-service state upgrade cli command ipfs-cluster-service now has a migration subcommand that upgrades persistant state snapshots with an out-of-date format version to the newest version of raft state. If all cluster members shutdown with consistent state, upgrade ipfs-cluster, and run the state upgrade command, the new version of cluster will be compatible with persistent storage. ipfs-cluster now validates its persistent state upon loading it and exits with a clear error in the case the state format version is not up to date. Raft snapshotting is enforced on all shutdowns and the json backup is no longer run. This commit makes use of recent changes to libp2p-raft allowing raft states to implement their own marshaling strategies. Now mapstate handles the logic for its (de)serialization. In the interest of supporting various potential upgrade formats the state serialization begins with a varint (right now one byte) describing the version. Some go tests are modified and a go test is added to cover new ipfs-cluster raft snapshot reading functions. Sharness tests are added to cover the state upgrade command.
2017-11-28 22:45:10 +00:00
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
cid "github.com/ipfs/go-cid"
Update deps along with go-libp2p-core refactor Lots of rewrites in imports...
2019-06-14 10:41:11 +00:00
peer "github.com/libp2p/go-libp2p-core/peer"
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
)
var testCid1, _ = cid.Decode("QmP63DkAFEnDYNjDYBpyNDfttu1fvUw99x1brscPzpqmmq")
var testPeerID1, _ = peer.IDB58Decode("QmXZrtE5jQwXNqCJMfHUTQkvhQ4ZAnqMnmzFMJfLewuabc")
Remove *Serial types. Use pointers for all types. This takes advantange of the latest features in go-cid, peer.ID and go-multiaddr and makes the Go types serializable by default. This means we no longer need to copy between Pin <-> PinSerial, or ID <-> IDSerial etc. We can now efficiently binary-encode these types using short field keys and without parsing/stringifying (in many cases it just a cast). We still get the same json output as before (with minor modifications for Cids). This should greatly improve Cluster performance and memory usage when dealing with large collections of items. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2019-02-27 17:04:35 +00:00
var c = &api.Pin{
testfixing License: MIT Signed-off-by: Hector Sanjuan <code@hector.link>
2018-07-23 09:14:43 +00:00
Cid: testCid1,
State: Use go-datastore to implement the state interface Since the beginning, we have used a Go map to store the shared state (pinset) in memory. The mapstate knew how to serialize itself so that libp2p-raft would know how to write to disk when it: * Saved snapshots of the state on shutdown * Sent the state to a newcomer peer hashicorp.Raft assumes an in-memory state which is snapshotted from time to time and read from disk on boot. This commit adds a `dsstate` implementation of the state interface using `go-datastore`. This allows to effortlessly switch to a disk-backed state in the future (as we will need), and also have at our disposal the different implementations and utilities of Datastore for fine-tuning (caching, batching etc.). `mapstate` has been reworked to use dsstate. Ideally, we would not even need `mapstate`, as it would suffice to initialize `dsstate` with a `MapDatastore`. BUT, we still need it separate to be able to auto-migrate to the new format. This will be the last migration with the current system. Once this has been released and users have been able to upgrade we will just remove `mapstate` as it is now. License: MIT Signed-off-by: Hector Sanjuan <code@hector.link>
2019-02-19 17:59:46 +00:00
Type: api.DataType,
testfixing License: MIT Signed-off-by: Hector Sanjuan <code@hector.link>
2018-07-23 09:14:43 +00:00
Allocations: []peer.ID{testPeerID1},
MaxDepth: -1,
PinOptions: api.PinOptions{
ReplicationFactorMax: -1,
ReplicationFactorMin: -1,
Name: "test",
},
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
}
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
func newState(t *testing.T) *State {
store := inmem.New()
ds, err := New(store, "", DefaultHandle())
if err != nil {
t.Fatal(err)
}
return ds
}
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
func TestAdd(t *testing.T) {
add opencensus tracing and metrics This commit adds support for OpenCensus tracing and metrics collection. This required support for context.Context propogation throughout the cluster codebase, and in particular, the ipfscluster component interfaces. The tracing propogates across RPC and HTTP boundaries. The current default tracing backend is Jaeger. The metrics currently exports the metrics exposed by the opencensus http plugin as well as the pprof metrics to a prometheus endpoint for scraping. The current default metrics backend is Prometheus. Metrics are currently exposed by default due to low overhead, can be turned off if desired, whereas tracing is off by default as it has a much higher performance overhead, though the extent of the performance hit can be adjusted with smaller sampling rates. License: MIT Signed-off-by: Adrian Lanzafame <adrianlanzafame92@gmail.com>
2018-06-27 04:03:15 +00:00
ctx := context.Background()
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
st := newState(t)
st.Add(ctx, c)
if ok, err := st.Has(ctx, c.Cid); !ok || err != nil {
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
t.Error("should have added it")
}
}
func TestRm(t *testing.T) {
add opencensus tracing and metrics This commit adds support for OpenCensus tracing and metrics collection. This required support for context.Context propogation throughout the cluster codebase, and in particular, the ipfscluster component interfaces. The tracing propogates across RPC and HTTP boundaries. The current default tracing backend is Jaeger. The metrics currently exports the metrics exposed by the opencensus http plugin as well as the pprof metrics to a prometheus endpoint for scraping. The current default metrics backend is Prometheus. Metrics are currently exposed by default due to low overhead, can be turned off if desired, whereas tracing is off by default as it has a much higher performance overhead, though the extent of the performance hit can be adjusted with smaller sampling rates. License: MIT Signed-off-by: Adrian Lanzafame <adrianlanzafame92@gmail.com>
2018-06-27 04:03:15 +00:00
ctx := context.Background()
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
st := newState(t)
st.Add(ctx, c)
st.Rm(ctx, c.Cid)
if ok, err := st.Has(ctx, c.Cid); ok || err != nil {
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
t.Error("should have removed it")
}
}
func TestGet(t *testing.T) {
add opencensus tracing and metrics This commit adds support for OpenCensus tracing and metrics collection. This required support for context.Context propogation throughout the cluster codebase, and in particular, the ipfscluster component interfaces. The tracing propogates across RPC and HTTP boundaries. The current default tracing backend is Jaeger. The metrics currently exports the metrics exposed by the opencensus http plugin as well as the pprof metrics to a prometheus endpoint for scraping. The current default metrics backend is Prometheus. Metrics are currently exposed by default due to low overhead, can be turned off if desired, whereas tracing is off by default as it has a much higher performance overhead, though the extent of the performance hit can be adjusted with smaller sampling rates. License: MIT Signed-off-by: Adrian Lanzafame <adrianlanzafame92@gmail.com>
2018-06-27 04:03:15 +00:00
ctx := context.Background()
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
defer func() {
if r := recover(); r != nil {
t.Fatal("paniced")
}
}()
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
st := newState(t)
st.Add(ctx, c)
get, err := st.Get(ctx, c.Cid)
if err != nil {
t.Fatal(err)
}
if get == nil {
State: Use go-datastore to implement the state interface Since the beginning, we have used a Go map to store the shared state (pinset) in memory. The mapstate knew how to serialize itself so that libp2p-raft would know how to write to disk when it: * Saved snapshots of the state on shutdown * Sent the state to a newcomer peer hashicorp.Raft assumes an in-memory state which is snapshotted from time to time and read from disk on boot. This commit adds a `dsstate` implementation of the state interface using `go-datastore`. This allows to effortlessly switch to a disk-backed state in the future (as we will need), and also have at our disposal the different implementations and utilities of Datastore for fine-tuning (caching, batching etc.). `mapstate` has been reworked to use dsstate. Ideally, we would not even need `mapstate`, as it would suffice to initialize `dsstate` with a `MapDatastore`. BUT, we still need it separate to be able to auto-migrate to the new format. This will be the last migration with the current system. Once this has been released and users have been able to upgrade we will just remove `mapstate` as it is now. License: MIT Signed-off-by: Hector Sanjuan <code@hector.link>
2019-02-19 17:59:46 +00:00
t.Fatal("not found")
}
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
State: Use go-datastore to implement the state interface Since the beginning, we have used a Go map to store the shared state (pinset) in memory. The mapstate knew how to serialize itself so that libp2p-raft would know how to write to disk when it: * Saved snapshots of the state on shutdown * Sent the state to a newcomer peer hashicorp.Raft assumes an in-memory state which is snapshotted from time to time and read from disk on boot. This commit adds a `dsstate` implementation of the state interface using `go-datastore`. This allows to effortlessly switch to a disk-backed state in the future (as we will need), and also have at our disposal the different implementations and utilities of Datastore for fine-tuning (caching, batching etc.). `mapstate` has been reworked to use dsstate. Ideally, we would not even need `mapstate`, as it would suffice to initialize `dsstate` with a `MapDatastore`. BUT, we still need it separate to be able to auto-migrate to the new format. This will be the last migration with the current system. Once this has been released and users have been able to upgrade we will just remove `mapstate` as it is now. License: MIT Signed-off-by: Hector Sanjuan <code@hector.link>
2019-02-19 17:59:46 +00:00
if get.Cid.String() != c.Cid.String() {
t.Error("bad cid decoding: ", get.Cid)
}
if get.Allocations[0] != c.Allocations[0] {
t.Error("bad allocations decoding:", get.Allocations)
}
if get.ReplicationFactorMax != c.ReplicationFactorMax ||
Fix #277: Introduce maximum and minimum replication factor This PR replaces ReplicationFactor with ReplicationFactorMax and ReplicationFactor min. This allows a CID to be pinned even though the desired replication factor (max) is not reached, and prevents triggering re-pinnings when the replication factor has not crossed the lower threshold (min). License: MIT Signed-off-by: Hector Sanjuan <code@hector.link>
2018-01-12 17:04:46 +00:00
get.ReplicationFactorMin != c.ReplicationFactorMin {
State: Use go-datastore to implement the state interface Since the beginning, we have used a Go map to store the shared state (pinset) in memory. The mapstate knew how to serialize itself so that libp2p-raft would know how to write to disk when it: * Saved snapshots of the state on shutdown * Sent the state to a newcomer peer hashicorp.Raft assumes an in-memory state which is snapshotted from time to time and read from disk on boot. This commit adds a `dsstate` implementation of the state interface using `go-datastore`. This allows to effortlessly switch to a disk-backed state in the future (as we will need), and also have at our disposal the different implementations and utilities of Datastore for fine-tuning (caching, batching etc.). `mapstate` has been reworked to use dsstate. Ideally, we would not even need `mapstate`, as it would suffice to initialize `dsstate` with a `MapDatastore`. BUT, we still need it separate to be able to auto-migrate to the new format. This will be the last migration with the current system. Once this has been released and users have been able to upgrade we will just remove `mapstate` as it is now. License: MIT Signed-off-by: Hector Sanjuan <code@hector.link>
2019-02-19 17:59:46 +00:00
t.Error("bad replication factors decoding")
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
}
}
func TestList(t *testing.T) {
add opencensus tracing and metrics This commit adds support for OpenCensus tracing and metrics collection. This required support for context.Context propogation throughout the cluster codebase, and in particular, the ipfscluster component interfaces. The tracing propogates across RPC and HTTP boundaries. The current default tracing backend is Jaeger. The metrics currently exports the metrics exposed by the opencensus http plugin as well as the pprof metrics to a prometheus endpoint for scraping. The current default metrics backend is Prometheus. Metrics are currently exposed by default due to low overhead, can be turned off if desired, whereas tracing is off by default as it has a much higher performance overhead, though the extent of the performance hit can be adjusted with smaller sampling rates. License: MIT Signed-off-by: Adrian Lanzafame <adrianlanzafame92@gmail.com>
2018-06-27 04:03:15 +00:00
ctx := context.Background()
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
defer func() {
if r := recover(); r != nil {
t.Fatal("paniced")
}
}()
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
st := newState(t)
st.Add(ctx, c)
list, err := st.List(ctx)
if err != nil {
t.Fatal(err)
}
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
if list[0].Cid.String() != c.Cid.String() ||
list[0].Allocations[0] != c.Allocations[0] ||
Fix #277: Introduce maximum and minimum replication factor This PR replaces ReplicationFactor with ReplicationFactorMax and ReplicationFactor min. This allows a CID to be pinned even though the desired replication factor (max) is not reached, and prevents triggering re-pinnings when the replication factor has not crossed the lower threshold (min). License: MIT Signed-off-by: Hector Sanjuan <code@hector.link>
2018-01-12 17:04:46 +00:00
list[0].ReplicationFactorMax != c.ReplicationFactorMax ||
list[0].ReplicationFactorMin != c.ReplicationFactorMin {
Issue #41: Add Replication factor New PeerManager, Allocator, Informer components have been added along with a new "replication_factor" configuration option. First, cluster peers collect and push metrics (Informer) to the Cluster leader regularly. The Informer is an interface that can be implemented in custom wayts to support custom metrics. Second, on a pin operation, using the information from the collected metrics, an Allocator can provide a list of preferences as to where the new pin should be assigned. The Allocator is an interface allowing to provide different allocation strategies. Both Allocator and Informer are Cluster Componenets, and have access to the RPC API. The allocations are kept in the shared state. Cluster peer failure detection is still missing and re-allocation is still missing, although re-pinning something when a node is down/metrics missing does re-allocate the pin somewhere else. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-13 15:46:53 +00:00
t.Error("returned something different")
}
}
Issue #51: Save a backup on shutdown This adds snapshot and restore methods to state and uses the snapshot one to save a copy of the state when shutting down. Right now, this is not used for anything else. Some lines performing a migration, but this is only an idea of how it could work. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-27 16:28:41 +00:00
ipfs-cluster-service state upgrade cli command ipfs-cluster-service now has a migration subcommand that upgrades persistant state snapshots with an out-of-date format version to the newest version of raft state. If all cluster members shutdown with consistent state, upgrade ipfs-cluster, and run the state upgrade command, the new version of cluster will be compatible with persistent storage. ipfs-cluster now validates its persistent state upon loading it and exits with a clear error in the case the state format version is not up to date. Raft snapshotting is enforced on all shutdowns and the json backup is no longer run. This commit makes use of recent changes to libp2p-raft allowing raft states to implement their own marshaling strategies. Now mapstate handles the logic for its (de)serialization. In the interest of supporting various potential upgrade formats the state serialization begins with a varint (right now one byte) describing the version. Some go tests are modified and a go test is added to cover new ipfs-cluster raft snapshot reading functions. Sharness tests are added to cover the state upgrade command.
2017-11-28 22:45:10 +00:00
func TestMarshalUnmarshal(t *testing.T) {
add opencensus tracing and metrics This commit adds support for OpenCensus tracing and metrics collection. This required support for context.Context propogation throughout the cluster codebase, and in particular, the ipfscluster component interfaces. The tracing propogates across RPC and HTTP boundaries. The current default tracing backend is Jaeger. The metrics currently exports the metrics exposed by the opencensus http plugin as well as the pprof metrics to a prometheus endpoint for scraping. The current default metrics backend is Prometheus. Metrics are currently exposed by default due to low overhead, can be turned off if desired, whereas tracing is off by default as it has a much higher performance overhead, though the extent of the performance hit can be adjusted with smaller sampling rates. License: MIT Signed-off-by: Adrian Lanzafame <adrianlanzafame92@gmail.com>
2018-06-27 04:03:15 +00:00
ctx := context.Background()
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
st := newState(t)
st.Add(ctx, c)
State: Use go-datastore to implement the state interface Since the beginning, we have used a Go map to store the shared state (pinset) in memory. The mapstate knew how to serialize itself so that libp2p-raft would know how to write to disk when it: * Saved snapshots of the state on shutdown * Sent the state to a newcomer peer hashicorp.Raft assumes an in-memory state which is snapshotted from time to time and read from disk on boot. This commit adds a `dsstate` implementation of the state interface using `go-datastore`. This allows to effortlessly switch to a disk-backed state in the future (as we will need), and also have at our disposal the different implementations and utilities of Datastore for fine-tuning (caching, batching etc.). `mapstate` has been reworked to use dsstate. Ideally, we would not even need `mapstate`, as it would suffice to initialize `dsstate` with a `MapDatastore`. BUT, we still need it separate to be able to auto-migrate to the new format. This will be the last migration with the current system. Once this has been released and users have been able to upgrade we will just remove `mapstate` as it is now. License: MIT Signed-off-by: Hector Sanjuan <code@hector.link>
2019-02-19 17:59:46 +00:00
buf := new(bytes.Buffer)
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
err := st.Marshal(buf)
Issue #51: Save a backup on shutdown This adds snapshot and restore methods to state and uses the snapshot one to save a copy of the state when shutting down. Right now, this is not used for anything else. Some lines performing a migration, but this is only an idea of how it could work. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-27 16:28:41 +00:00
if err != nil {
t.Fatal(err)
}
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
st2 := newState(t)
err = st2.Unmarshal(buf)
Issue #51: Save a backup on shutdown This adds snapshot and restore methods to state and uses the snapshot one to save a copy of the state when shutting down. Right now, this is not used for anything else. Some lines performing a migration, but this is only an idea of how it could work. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-27 16:28:41 +00:00
if err != nil {
t.Fatal(err)
}
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
get, err := st2.Get(ctx, c.Cid)
if err != nil {
t.Fatal(err)
ipfs-cluster-service state upgrade cli command ipfs-cluster-service now has a migration subcommand that upgrades persistant state snapshots with an out-of-date format version to the newest version of raft state. If all cluster members shutdown with consistent state, upgrade ipfs-cluster, and run the state upgrade command, the new version of cluster will be compatible with persistent storage. ipfs-cluster now validates its persistent state upon loading it and exits with a clear error in the case the state format version is not up to date. Raft snapshotting is enforced on all shutdowns and the json backup is no longer run. This commit makes use of recent changes to libp2p-raft allowing raft states to implement their own marshaling strategies. Now mapstate handles the logic for its (de)serialization. In the interest of supporting various potential upgrade formats the state serialization begins with a varint (right now one byte) describing the version. Some go tests are modified and a go test is added to cover new ipfs-cluster raft snapshot reading functions. Sharness tests are added to cover the state upgrade command.
2017-11-28 22:45:10 +00:00
}
Consensus: add new "crdt" consensus component This adds a new "crdt" consensus component using go-ds-crdt. This implies several refactors to fully make cluster consensus-component independent: * Delete mapstate and fully adopt dsstate (after people have migrated). * Return errors from state methods rather than ignoring them. * Add a new "datastore" modules so that we can configure datastores in the main configuration like other components. * Let the consensus components fully define the "state.State". Thus, they do not receive the state, they receive the storage where we put the state (a go-datastore). * Allow to customize how the monitor component obtains Peers() (the current peerset), including avoiding using the current peerset. At the moment the crdt consensus uses the monitoring component to define the current peerset. Therefore the monitor component cannot rely on the consensus component to produce a peerset. * Re-factor/re-implementation of "ipfs-cluster-service state" operations. Includes the dissapearance of the "migrate" one. The CRDT consensus component defines creates a crdt-datastore (with ipfs-lite) and uses it to intitialize a dssate. Thus the crdt-store is elegantly wrapped. Any modifications to the state get automatically replicated to other peers. We store all the CRDT DAG blocks in the local datastore. The consensus components only expose a ReadOnly state, as any modifications to the shared state should happen through them. DHT and PubSub facilities must now be created outside of Cluster and passed in so they can be re-used by different components.
2019-02-20 14:24:25 +00:00
if get == nil {
State: Use go-datastore to implement the state interface Since the beginning, we have used a Go map to store the shared state (pinset) in memory. The mapstate knew how to serialize itself so that libp2p-raft would know how to write to disk when it: * Saved snapshots of the state on shutdown * Sent the state to a newcomer peer hashicorp.Raft assumes an in-memory state which is snapshotted from time to time and read from disk on boot. This commit adds a `dsstate` implementation of the state interface using `go-datastore`. This allows to effortlessly switch to a disk-backed state in the future (as we will need), and also have at our disposal the different implementations and utilities of Datastore for fine-tuning (caching, batching etc.). `mapstate` has been reworked to use dsstate. Ideally, we would not even need `mapstate`, as it would suffice to initialize `dsstate` with a `MapDatastore`. BUT, we still need it separate to be able to auto-migrate to the new format. This will be the last migration with the current system. Once this has been released and users have been able to upgrade we will just remove `mapstate` as it is now. License: MIT Signed-off-by: Hector Sanjuan <code@hector.link>
2019-02-19 17:59:46 +00:00
t.Fatal("cannot get pin")
}
Issue #51: Save a backup on shutdown This adds snapshot and restore methods to state and uses the snapshot one to save a copy of the state when shutting down. Right now, this is not used for anything else. Some lines performing a migration, but this is only an idea of how it could work. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-27 16:28:41 +00:00
if get.Allocations[0] != testPeerID1 {
t.Error("expected different peer id")
}
State: Use go-datastore to implement the state interface Since the beginning, we have used a Go map to store the shared state (pinset) in memory. The mapstate knew how to serialize itself so that libp2p-raft would know how to write to disk when it: * Saved snapshots of the state on shutdown * Sent the state to a newcomer peer hashicorp.Raft assumes an in-memory state which is snapshotted from time to time and read from disk on boot. This commit adds a `dsstate` implementation of the state interface using `go-datastore`. This allows to effortlessly switch to a disk-backed state in the future (as we will need), and also have at our disposal the different implementations and utilities of Datastore for fine-tuning (caching, batching etc.). `mapstate` has been reworked to use dsstate. Ideally, we would not even need `mapstate`, as it would suffice to initialize `dsstate` with a `MapDatastore`. BUT, we still need it separate to be able to auto-migrate to the new format. This will be the last migration with the current system. Once this has been released and users have been able to upgrade we will just remove `mapstate` as it is now. License: MIT Signed-off-by: Hector Sanjuan <code@hector.link>
2019-02-19 17:59:46 +00:00
if !get.Cid.Equals(c.Cid) {
t.Error("expected different cid")
}
Issue #51: Save a backup on shutdown This adds snapshot and restore methods to state and uses the snapshot one to save a copy of the state when shutting down. Right now, this is not used for anything else. Some lines performing a migration, but this is only an idea of how it could work. License: MIT Signed-off-by: Hector Sanjuan <hector@protocol.ai>
2017-02-27 16:28:41 +00:00
}
Reference in New Issue Copy Permalink