zrepl/platformtest/tests/replication.go

1397 lines
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package tests
import (
"context"
"fmt"
"io"
"os"
"path"
"sort"
"strings"
"time"
"github.com/kr/pretty"
"github.com/stretchr/testify/require"
"github.com/zrepl/zrepl/daemon/filters"
"github.com/zrepl/zrepl/endpoint"
"github.com/zrepl/zrepl/platformtest"
"github.com/zrepl/zrepl/replication"
"github.com/zrepl/zrepl/replication/driver"
"github.com/zrepl/zrepl/replication/logic"
"github.com/zrepl/zrepl/replication/logic/pdu"
"github.com/zrepl/zrepl/replication/report"
"github.com/zrepl/zrepl/util/bandwidthlimit"
"github.com/zrepl/zrepl/util/limitio"
"github.com/zrepl/zrepl/util/nodefault"
"github.com/zrepl/zrepl/zfs"
zfsprop "github.com/zrepl/zrepl/zfs/property"
)
// mimics the replication invocations of an active-side job
// for a single sender-receiver filesystem pair
//
// each invocation of method Do results in the construction
// of a new sender and receiver instance and one blocking invocation
// of the replication engine without encryption
type replicationInvocation struct {
rework resume token validation to allow resuming from raw sends of unencrypted datasets Before this change, resuming from an unencrypted dataset with send.raw=true specified wouldn't work with zrepl due to overly restrictive resume token checking. An initial PR to fix this was made in https://github.com/zrepl/zrepl/pull/503 but it didn't address the core of the problem. The core of the problem was that zrepl assumed that if a resume token contained `rawok=true, compressok=true`, the resulting send would be encrypted. But if the sender dataset was unencrypted, such a resume would actually result in an unencrypted send. Which could be totally legitimate but zrepl failed to recognize that. BACKGROUND ========== The following snippets of OpenZFS code are insightful regarding how the various ${X}ok values in the resume token are handled: - https://github.com/openzfs/zfs/blob/6c3c5fcfbe27d9193cd131753cc7e47ee2784621/module/zfs/dmu_send.c#L1947-L2012 - https://github.com/openzfs/zfs/blob/6c3c5fcfbe27d9193cd131753cc7e47ee2784621/module/zfs/dmu_recv.c#L877-L891 - https://github.com/openzfs/zfs/blob/6c3c5fc/lib/libzfs/libzfs_sendrecv.c#L1663-L1672 Basically, some zfs send flags make the DMU send code set some DMU send stream featureflags, although it's not a pure mapping, i.e, which DMU send stream flags are used depends somewhat on the dataset (e.g., is it encrypted or not, or, does it use zstd or not). Then, the receiver looks at some (but not all) feature flags and maps them to ${X}ok dataset zap attributes. These are funnelled back to the sender 1:1 through the resume_token. And the sender turns them into lzc flags. As an example, let's look at zfs send --raw. if the sender requests a raw send on an unencrypted dataset, the send stream (and hence the resume token) will not have the raw stream featureflag set, and hence the resume token will not have the rawok field set. Instead, it will have compressok, embedok, and depending on whether large blocks are present in the dataset, largeblockok set. WHAT'S ZREPL'S ROLE IN THIS? ============================ zrepl provides a virtual encrypted sendflag that is like `raw`, but further ensures that we only send encrypted datasets. For any other resume token stuff, it shoudn't do any checking, because it's a futile effort to keep up with ZFS send/recv features that are orthogonal to encryption. CHANGES MADE IN THIS COMMIT =========================== - Rip out a bunch of needless checking that zrepl would do during planning. These checks were there to give better error messages, but actually, the error messages created by the endpoint.Sender.Send RPC upon send args validation failure are good enough. - Add platformtests to validate all combinations of (Unencrypted/Encrypted FS) x (send.encrypted = true | false) x (send.raw = true | false) for cases both non-resuming and resuming send. Additional manual testing done: 1. With zrepl 0.5, setup with unencrypted dataset, send.raw=true specified, no send.encrypted specified. 2. Observe that regular non-resuming send works, but resuming doesn't work. 3. Upgrade zrepl to this change. 4. Observe that both regular and resuming send works. closes https://github.com/zrepl/zrepl/pull/613
2022-07-10 14:56:35 +02:00
sjid, rjid endpoint.JobID
sfs string
sfilter *filters.DatasetMapFilter
rfsRoot string
interceptSender func(e *endpoint.Sender) logic.Sender
interceptReceiver func(e *endpoint.Receiver) logic.Receiver
guarantee *pdu.ReplicationConfigProtection
senderConfigHook func(*endpoint.SenderConfig)
receiverConfigHook func(*endpoint.ReceiverConfig)
plannerPolicyHook func(*logic.PlannerPolicy)
skipSendArgsValidation bool
}
func (i replicationInvocation) Do(ctx *platformtest.Context) *report.Report {
if i.interceptSender == nil {
i.interceptSender = func(e *endpoint.Sender) logic.Sender { return e }
}
if i.interceptReceiver == nil {
i.interceptReceiver = func(e *endpoint.Receiver) logic.Receiver { return e }
}
if i.sfs != "" && i.sfilter != nil || i.sfs == "" && i.sfilter == nil {
panic("either sfs or sfilter must be set")
}
if i.sfilter == nil {
i.sfilter = filters.NewDatasetMapFilter(1, true)
err := i.sfilter.Add(i.sfs, "ok")
require.NoError(ctx, err)
}
senderConfig := endpoint.SenderConfig{
FSF: i.sfilter.AsFilter(),
Encrypt: &nodefault.Bool{B: false},
JobID: i.sjid,
BandwidthLimit: bandwidthlimit.NoLimitConfig(),
}
if i.senderConfigHook != nil {
i.senderConfigHook(&senderConfig)
}
receiverConfig := endpoint.ReceiverConfig{
JobID: i.rjid,
AppendClientIdentity: false,
RootWithoutClientComponent: mustDatasetPath(i.rfsRoot),
BandwidthLimit: bandwidthlimit.NoLimitConfig(),
PlaceholderEncryption: endpoint.PlaceholderCreationEncryptionPropertyUnspecified,
}
if i.receiverConfigHook != nil {
i.receiverConfigHook(&receiverConfig)
}
require.Equal(ctx, senderConfig.JobID, i.sjid)
require.Equal(ctx, receiverConfig.JobID, i.rjid)
sender := i.interceptSender(endpoint.NewSender(senderConfig))
receiver := i.interceptReceiver(endpoint.NewReceiver(receiverConfig))
plannerPolicy := logic.PlannerPolicy{
ReplicationConfig: &pdu.ReplicationConfig{
Protection: i.guarantee,
},
ConflictResolution: &logic.ConflictResolution{
InitialReplication: logic.InitialReplicationAutoResolutionMostRecent,
},
SizeEstimationConcurrency: 1,
}
if i.plannerPolicyHook != nil {
i.plannerPolicyHook(&plannerPolicy)
}
rework resume token validation to allow resuming from raw sends of unencrypted datasets Before this change, resuming from an unencrypted dataset with send.raw=true specified wouldn't work with zrepl due to overly restrictive resume token checking. An initial PR to fix this was made in https://github.com/zrepl/zrepl/pull/503 but it didn't address the core of the problem. The core of the problem was that zrepl assumed that if a resume token contained `rawok=true, compressok=true`, the resulting send would be encrypted. But if the sender dataset was unencrypted, such a resume would actually result in an unencrypted send. Which could be totally legitimate but zrepl failed to recognize that. BACKGROUND ========== The following snippets of OpenZFS code are insightful regarding how the various ${X}ok values in the resume token are handled: - https://github.com/openzfs/zfs/blob/6c3c5fcfbe27d9193cd131753cc7e47ee2784621/module/zfs/dmu_send.c#L1947-L2012 - https://github.com/openzfs/zfs/blob/6c3c5fcfbe27d9193cd131753cc7e47ee2784621/module/zfs/dmu_recv.c#L877-L891 - https://github.com/openzfs/zfs/blob/6c3c5fc/lib/libzfs/libzfs_sendrecv.c#L1663-L1672 Basically, some zfs send flags make the DMU send code set some DMU send stream featureflags, although it's not a pure mapping, i.e, which DMU send stream flags are used depends somewhat on the dataset (e.g., is it encrypted or not, or, does it use zstd or not). Then, the receiver looks at some (but not all) feature flags and maps them to ${X}ok dataset zap attributes. These are funnelled back to the sender 1:1 through the resume_token. And the sender turns them into lzc flags. As an example, let's look at zfs send --raw. if the sender requests a raw send on an unencrypted dataset, the send stream (and hence the resume token) will not have the raw stream featureflag set, and hence the resume token will not have the rawok field set. Instead, it will have compressok, embedok, and depending on whether large blocks are present in the dataset, largeblockok set. WHAT'S ZREPL'S ROLE IN THIS? ============================ zrepl provides a virtual encrypted sendflag that is like `raw`, but further ensures that we only send encrypted datasets. For any other resume token stuff, it shoudn't do any checking, because it's a futile effort to keep up with ZFS send/recv features that are orthogonal to encryption. CHANGES MADE IN THIS COMMIT =========================== - Rip out a bunch of needless checking that zrepl would do during planning. These checks were there to give better error messages, but actually, the error messages created by the endpoint.Sender.Send RPC upon send args validation failure are good enough. - Add platformtests to validate all combinations of (Unencrypted/Encrypted FS) x (send.encrypted = true | false) x (send.raw = true | false) for cases both non-resuming and resuming send. Additional manual testing done: 1. With zrepl 0.5, setup with unencrypted dataset, send.raw=true specified, no send.encrypted specified. 2. Observe that regular non-resuming send works, but resuming doesn't work. 3. Upgrade zrepl to this change. 4. Observe that both regular and resuming send works. closes https://github.com/zrepl/zrepl/pull/613
2022-07-10 14:56:35 +02:00
var doCtx context.Context = ctx
if i.skipSendArgsValidation {
doCtx = zfs.ZFSSendArgsSkipValidation(ctx)
}
report, wait := replication.Do(
rework resume token validation to allow resuming from raw sends of unencrypted datasets Before this change, resuming from an unencrypted dataset with send.raw=true specified wouldn't work with zrepl due to overly restrictive resume token checking. An initial PR to fix this was made in https://github.com/zrepl/zrepl/pull/503 but it didn't address the core of the problem. The core of the problem was that zrepl assumed that if a resume token contained `rawok=true, compressok=true`, the resulting send would be encrypted. But if the sender dataset was unencrypted, such a resume would actually result in an unencrypted send. Which could be totally legitimate but zrepl failed to recognize that. BACKGROUND ========== The following snippets of OpenZFS code are insightful regarding how the various ${X}ok values in the resume token are handled: - https://github.com/openzfs/zfs/blob/6c3c5fcfbe27d9193cd131753cc7e47ee2784621/module/zfs/dmu_send.c#L1947-L2012 - https://github.com/openzfs/zfs/blob/6c3c5fcfbe27d9193cd131753cc7e47ee2784621/module/zfs/dmu_recv.c#L877-L891 - https://github.com/openzfs/zfs/blob/6c3c5fc/lib/libzfs/libzfs_sendrecv.c#L1663-L1672 Basically, some zfs send flags make the DMU send code set some DMU send stream featureflags, although it's not a pure mapping, i.e, which DMU send stream flags are used depends somewhat on the dataset (e.g., is it encrypted or not, or, does it use zstd or not). Then, the receiver looks at some (but not all) feature flags and maps them to ${X}ok dataset zap attributes. These are funnelled back to the sender 1:1 through the resume_token. And the sender turns them into lzc flags. As an example, let's look at zfs send --raw. if the sender requests a raw send on an unencrypted dataset, the send stream (and hence the resume token) will not have the raw stream featureflag set, and hence the resume token will not have the rawok field set. Instead, it will have compressok, embedok, and depending on whether large blocks are present in the dataset, largeblockok set. WHAT'S ZREPL'S ROLE IN THIS? ============================ zrepl provides a virtual encrypted sendflag that is like `raw`, but further ensures that we only send encrypted datasets. For any other resume token stuff, it shoudn't do any checking, because it's a futile effort to keep up with ZFS send/recv features that are orthogonal to encryption. CHANGES MADE IN THIS COMMIT =========================== - Rip out a bunch of needless checking that zrepl would do during planning. These checks were there to give better error messages, but actually, the error messages created by the endpoint.Sender.Send RPC upon send args validation failure are good enough. - Add platformtests to validate all combinations of (Unencrypted/Encrypted FS) x (send.encrypted = true | false) x (send.raw = true | false) for cases both non-resuming and resuming send. Additional manual testing done: 1. With zrepl 0.5, setup with unencrypted dataset, send.raw=true specified, no send.encrypted specified. 2. Observe that regular non-resuming send works, but resuming doesn't work. 3. Upgrade zrepl to this change. 4. Observe that both regular and resuming send works. closes https://github.com/zrepl/zrepl/pull/613
2022-07-10 14:56:35 +02:00
doCtx,
driver.Config{
MaxAttempts: 1,
StepQueueConcurrency: 1,
ReconnectHardFailTimeout: 1 * time.Second,
},
logic.NewPlanner(nil, nil, sender, receiver, plannerPolicy),
)
wait(true)
return report()
}
func (i replicationInvocation) ReceiveSideFilesystem() string {
return path.Join(i.rfsRoot, i.sfs)
}
func ReplicationIncrementalIsPossibleIfCommonSnapshotIsDestroyed(ctx *platformtest.Context) {
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "sender"
+ "sender@1"
+ "receiver"
R zfs create -p "${ROOTDS}/receiver/${ROOTDS}"
`)
sjid := endpoint.MustMakeJobID("sender-job")
rjid := endpoint.MustMakeJobID("receiver-job")
sfs := ctx.RootDataset + "/sender"
rfsRoot := ctx.RootDataset + "/receiver"
snap1 := fsversion(ctx, sfs, "@1")
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeResumability),
}
rfs := rep.ReceiveSideFilesystem()
// first replication
report := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(report))
// assert @1 exists on receiver
_ = fsversion(ctx, rfs, "@1")
// cut off the common base between sender and receiver
// (replication engine guarantees resumability through bookmarks)
err := zfs.ZFSDestroy(ctx, snap1.FullPath(sfs))
require.NoError(ctx, err)
// assert that the replication cursor has been created
snap1CursorName, err := endpoint.ReplicationCursorBookmarkName(sfs, snap1.Guid, sjid)
require.NoError(ctx, err)
snap1CursorInfo, err := zfs.ZFSGetFilesystemVersion(ctx, sfs+"#"+snap1CursorName)
require.NoError(ctx, err)
require.True(ctx, snap1CursorInfo.IsBookmark())
// second replication of a new snapshot, should use the cursor
mustSnapshot(ctx, sfs+"@2")
report = rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(report))
_ = fsversion(ctx, rfs, "@2")
}
func ReplicationIncrementalCleansUpStaleAbstractionsWithCacheOnSecondReplication(ctx *platformtest.Context) {
implReplicationIncrementalCleansUpStaleAbstractions(ctx, true)
}
func ReplicationIncrementalCleansUpStaleAbstractionsWithoutCacheOnSecondReplication(ctx *platformtest.Context) {
implReplicationIncrementalCleansUpStaleAbstractions(ctx, false)
}
func implReplicationIncrementalCleansUpStaleAbstractions(ctx *platformtest.Context, invalidateCacheBeforeSecondReplication bool) {
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "sender"
+ "sender@1"
+ "sender@2"
+ "sender#2" "sender@2"
+ "sender@3"
+ "receiver"
R zfs create -p "${ROOTDS}/receiver/${ROOTDS}"
`)
sjid := endpoint.MustMakeJobID("sender-job")
ojid := endpoint.MustMakeJobID("other-job")
rjid := endpoint.MustMakeJobID("receiver-job")
sfs := ctx.RootDataset + "/sender"
rfsRoot := ctx.RootDataset + "/receiver"
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeResumability),
}
rfs := rep.ReceiveSideFilesystem()
// first replication
report := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(report))
// assert most recent send-side version @3 exists on receiver (=replication succeeded)
rSnap3 := fsversion(ctx, rfs, "@3")
// assert the source-side versions not managed by zrepl still exist
snap1 := fsversion(ctx, sfs, "@1")
snap2 := fsversion(ctx, sfs, "@2")
_ = fsversion(ctx, sfs, "#2") // non-replicationc-cursor bookmarks should not be affected
snap3 := fsversion(ctx, sfs, "@3")
// assert a replication cursor is in place
snap3CursorName, err := endpoint.ReplicationCursorBookmarkName(sfs, snap3.Guid, sjid)
require.NoError(ctx, err)
_ = fsversion(ctx, sfs, "#"+snap3CursorName)
// assert a last-received hold is in place
expectRjidHoldTag, err := endpoint.LastReceivedHoldTag(rjid)
require.NoError(ctx, err)
holds, err := zfs.ZFSHolds(ctx, rfs, rSnap3.Name)
require.NoError(ctx, err)
require.Contains(ctx, holds, expectRjidHoldTag)
// create artifical stale replication cursors & step holds
createArtificalStaleAbstractions := func(jobId endpoint.JobID) []endpoint.Abstraction {
snap2Cursor, err := endpoint.CreateReplicationCursor(ctx, sfs, snap2, jobId) // no shadow
require.NoError(ctx, err)
// create artifical stale step holds jobId
snap1Hold, err := endpoint.HoldStep(ctx, sfs, snap1, jobId) // no shadow
require.NoError(ctx, err)
snap2Hold, err := endpoint.HoldStep(ctx, sfs, snap2, jobId) // no shadow
require.NoError(ctx, err)
return []endpoint.Abstraction{snap2Cursor, snap1Hold, snap2Hold}
}
createArtificalStaleAbstractions(sjid)
ojidSendAbstractions := createArtificalStaleAbstractions(ojid)
snap3ojidLastReceivedHold, err := endpoint.CreateLastReceivedHold(ctx, rfs, fsversion(ctx, rfs, "@3"), ojid)
require.NoError(ctx, err)
require.True(ctx, zfs.FilesystemVersionEqualIdentity(fsversion(ctx, rfs, "@3"), snap3ojidLastReceivedHold.GetFilesystemVersion()))
// take another 2 snapshots
mustSnapshot(ctx, sfs+"@4")
mustSnapshot(ctx, sfs+"@5")
snap5 := fsversion(ctx, sfs, "@5")
if invalidateCacheBeforeSecondReplication {
endpoint.AbstractionsCacheInvalidate(sfs)
}
// do another replication
// - ojid's abstractions should not be affected on either side
// - stale abstractions of sjid and rjid should be cleaned up
// - 1 replication cursors and 1 last-received hold should be present
checkOjidAbstractionsExist := func() {
var expectedOjidAbstractions []endpoint.Abstraction
expectedOjidAbstractions = append(expectedOjidAbstractions, ojidSendAbstractions...)
expectedOjidAbstractions = append(expectedOjidAbstractions, snap3ojidLastReceivedHold)
sfsAndRfsFilter := filters.NewDatasetMapFilter(2, true)
require.NoError(ctx, sfsAndRfsFilter.Add(sfs, "ok"))
require.NoError(ctx, sfsAndRfsFilter.Add(rfs, "ok"))
rAbs, rAbsErrs, err := endpoint.ListAbstractions(ctx, endpoint.ListZFSHoldsAndBookmarksQuery{
FS: endpoint.ListZFSHoldsAndBookmarksQueryFilesystemFilter{Filter: sfsAndRfsFilter},
JobID: &ojid,
What: endpoint.AbstractionTypesAll,
Concurrency: 1,
})
require.NoError(ctx, err)
require.Len(ctx, rAbsErrs, 0)
ctx.Logf("rAbs=%s", rAbs)
ctx.Logf("expectedOjidAbstractions=%s", expectedOjidAbstractions)
require.Equal(ctx, len(expectedOjidAbstractions), len(rAbs))
for _, ea := range expectedOjidAbstractions {
ctx.Logf("looking for %s %#v", ea, ea.GetFilesystemVersion())
found := false
for _, a := range rAbs {
eq := endpoint.AbstractionEquals(ea, a)
ctx.Logf("comp=%v for %s %#v", eq, a, a.GetFilesystemVersion())
found = found || eq
}
require.True(ctx, found, "%s", ea)
}
}
checkOjidAbstractionsExist()
report = rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(report))
checkOjidAbstractionsExist()
_ = fsversion(ctx, sfs, "@1")
_ = fsversion(ctx, sfs, "@2")
_ = fsversion(ctx, sfs, "#2")
_ = fsversion(ctx, sfs, "@3")
_ = fsversion(ctx, sfs, "@4")
_ = fsversion(ctx, sfs, "@5")
_ = fsversion(ctx, rfs, "@3")
_ = fsversion(ctx, rfs, "@4")
_ = fsversion(ctx, rfs, "@5")
// check bookmark situation
{
sBms, err := zfs.ZFSListFilesystemVersions(ctx, mustDatasetPath(sfs), zfs.ListFilesystemVersionsOptions{
Types: zfs.Bookmarks,
})
ctx.Logf("sbms=%s", sBms)
require.NoError(ctx, err)
snap5SjidCursorName, err := endpoint.ReplicationCursorBookmarkName(sfs, snap5.Guid, sjid)
require.NoError(ctx, err)
snap2SjidCursorName, err := endpoint.ReplicationCursorBookmarkName(sfs, snap2.Guid, sjid)
require.NoError(ctx, err)
snap2OjidCursorName, err := endpoint.ReplicationCursorBookmarkName(sfs, snap2.Guid, ojid)
require.NoError(ctx, err)
var bmNames []string
for _, bm := range sBms {
bmNames = append(bmNames, bm.Name)
}
if invalidateCacheBeforeSecondReplication {
require.Len(ctx, sBms, 3)
require.Contains(ctx, bmNames, snap5SjidCursorName)
require.Contains(ctx, bmNames, snap2OjidCursorName)
require.Contains(ctx, bmNames, "2")
} else {
require.Len(ctx, sBms, 4)
require.Contains(ctx, bmNames, snap5SjidCursorName)
require.Contains(ctx, bmNames, snap2SjidCursorName)
require.Contains(ctx, bmNames, snap2OjidCursorName)
require.Contains(ctx, bmNames, "2")
}
}
// check last-received hold moved
{
rAbs, rAbsErrs, err := endpoint.ListAbstractions(ctx, endpoint.ListZFSHoldsAndBookmarksQuery{
FS: endpoint.ListZFSHoldsAndBookmarksQueryFilesystemFilter{FS: &rfs},
JobID: &rjid,
What: endpoint.AbstractionTypesAll,
Concurrency: 1,
})
require.NoError(ctx, err)
require.Len(ctx, rAbsErrs, 0)
require.Len(ctx, rAbs, 1)
require.Equal(ctx, rAbs[0].GetType(), endpoint.AbstractionLastReceivedHold)
require.Equal(ctx, *rAbs[0].GetJobID(), rjid)
require.Equal(ctx, rAbs[0].GetFilesystemVersion().GetGuid(), snap5.GetGuid())
}
}
type PartialSender struct {
*endpoint.Sender
failAfterByteCount int64
}
var _ logic.Sender = (*PartialSender)(nil)
func (s *PartialSender) Send(ctx context.Context, r *pdu.SendReq) (r1 *pdu.SendRes, r2 io.ReadCloser, r3 error) {
r1, r2, r3 = s.Sender.Send(ctx, r)
r2 = limitio.ReadCloser(r2, s.failAfterByteCount)
return r1, r2, r3
}
func ReplicationIsResumableFullSend__both_GuaranteeResumability(ctx *platformtest.Context) {
setup := replicationIsResumableFullSendSetup{
protection: &pdu.ReplicationConfigProtection{
Initial: pdu.ReplicationGuaranteeKind_GuaranteeResumability,
Incremental: pdu.ReplicationGuaranteeKind_GuaranteeResumability,
},
expectDatasetIsBusyErrorWhenDestroySnapshotWhilePartiallyReplicated: true,
expectAllThreeSnapshotsToThreeBePresentAfterLoop: true,
expectNoSnapshotsOnReceiverAfterLoop: false,
}
implReplicationIsResumableFullSend(ctx, setup)
}
func ReplicationIsResumableFullSend__initial_GuaranteeResumability_incremental_GuaranteeIncrementalReplication(ctx *platformtest.Context) {
setup := replicationIsResumableFullSendSetup{
protection: &pdu.ReplicationConfigProtection{
Initial: pdu.ReplicationGuaranteeKind_GuaranteeResumability,
Incremental: pdu.ReplicationGuaranteeKind_GuaranteeIncrementalReplication,
},
expectDatasetIsBusyErrorWhenDestroySnapshotWhilePartiallyReplicated: true,
expectAllThreeSnapshotsToThreeBePresentAfterLoop: true,
expectNoSnapshotsOnReceiverAfterLoop: false,
}
implReplicationIsResumableFullSend(ctx, setup)
}
func ReplicationIsResumableFullSend__initial_GuaranteeIncrementalReplication_incremental_GuaranteeIncrementalReplication(ctx *platformtest.Context) {
setup := replicationIsResumableFullSendSetup{
protection: &pdu.ReplicationConfigProtection{
Initial: pdu.ReplicationGuaranteeKind_GuaranteeIncrementalReplication,
Incremental: pdu.ReplicationGuaranteeKind_GuaranteeIncrementalReplication,
},
expectDatasetIsBusyErrorWhenDestroySnapshotWhilePartiallyReplicated: false,
expectAllThreeSnapshotsToThreeBePresentAfterLoop: false,
expectNoSnapshotsOnReceiverAfterLoop: true,
}
implReplicationIsResumableFullSend(ctx, setup)
}
type replicationIsResumableFullSendSetup struct {
protection *pdu.ReplicationConfigProtection
expectDatasetIsBusyErrorWhenDestroySnapshotWhilePartiallyReplicated bool
expectAllThreeSnapshotsToThreeBePresentAfterLoop bool
expectNoSnapshotsOnReceiverAfterLoop bool
}
func implReplicationIsResumableFullSend(ctx *platformtest.Context, setup replicationIsResumableFullSendSetup) {
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "sender"
+ "receiver"
R zfs create -p "${ROOTDS}/receiver/${ROOTDS}"
`)
sjid := endpoint.MustMakeJobID("sender-job")
rjid := endpoint.MustMakeJobID("receiver-job")
sfs := ctx.RootDataset + "/sender"
rfsRoot := ctx.RootDataset + "/receiver"
sfsmp, err := zfs.ZFSGetMountpoint(ctx, sfs)
require.NoError(ctx, err)
require.True(ctx, sfsmp.Mounted)
writeDummyData(path.Join(sfsmp.Mountpoint, "dummy.data"), 1<<22)
mustSnapshot(ctx, sfs+"@1")
snap1 := fsversion(ctx, sfs, "@1")
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
interceptSender: func(e *endpoint.Sender) logic.Sender {
return &PartialSender{Sender: e, failAfterByteCount: 1 << 20}
},
guarantee: setup.protection,
}
rfs := rep.ReceiveSideFilesystem()
for i := 2; i < 10; i++ {
report := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(report))
// always attempt to destroy the incremental source
err := zfs.ZFSDestroy(ctx, snap1.FullPath(sfs))
if i < 4 {
// we configured the PartialSender to fail after 1<<20 bytes
// and we wrote dummy data 1<<22 bytes, thus at least
// for the first 4 times this should not be possible
// due to step holds
if setup.expectDatasetIsBusyErrorWhenDestroySnapshotWhilePartiallyReplicated {
ctx.Logf("i=%v", i)
require.Error(ctx, err)
require.Contains(ctx, err.Error(), "dataset is busy")
}
}
// and create some additional snapshots that could
// confuse a naive implementation that doesn't take into
// account resume state when planning replication
if i == 2 || i == 3 {
// no significant size to avoid making this test run longer than necessary
mustSnapshot(ctx, fmt.Sprintf("%s@%d", sfs, i))
}
require.Len(ctx, report.Attempts, 1)
require.Nil(ctx, report.Attempts[0].PlanError)
require.Len(ctx, report.Attempts[0].Filesystems, 1)
if len(report.Attempts[0].Filesystems[0].Steps) == 0 {
break
}
}
if setup.expectAllThreeSnapshotsToThreeBePresentAfterLoop {
// make sure all the filesystem versions we created
// were replicated by the replication loop
_ = fsversion(ctx, rfs, "@1")
_ = fsversion(ctx, rfs, "@2")
_ = fsversion(ctx, rfs, "@3")
}
if setup.expectNoSnapshotsOnReceiverAfterLoop {
versions, err := zfs.ZFSListFilesystemVersions(ctx, mustDatasetPath(rfs), zfs.ListFilesystemVersionsOptions{})
require.NoError(ctx, err)
require.Empty(ctx, versions)
}
}
func ReplicationIncrementalDestroysStepHoldsIffIncrementalStepHoldsAreDisabledButStepHoldsExist(ctx *platformtest.Context) {
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "sender"
+ "receiver"
R zfs create -p "${ROOTDS}/receiver/${ROOTDS}"
`)
sjid := endpoint.MustMakeJobID("sender-job")
rjid := endpoint.MustMakeJobID("receiver-job")
sfs := ctx.RootDataset + "/sender"
rfsRoot := ctx.RootDataset + "/receiver"
// fully replicate snapshots @1
{
mustSnapshot(ctx, sfs+"@1")
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeResumability),
}
rfs := rep.ReceiveSideFilesystem()
report := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(report))
// assert this worked (not the main subject of the test)
_ = fsversion(ctx, rfs, "@1")
}
// create a large snapshot @2
{
sfsmp, err := zfs.ZFSGetMountpoint(ctx, sfs)
require.NoError(ctx, err)
require.True(ctx, sfsmp.Mounted)
writeDummyData(path.Join(sfsmp.Mountpoint, "dummy.data"), 1<<22)
mustSnapshot(ctx, sfs+"@2")
}
snap2sfs := fsversion(ctx, sfs, "@2")
// partially replicate snapshots @2 with step holds enabled
// to effect a step-holds situation
{
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeResumability), // !
interceptSender: func(e *endpoint.Sender) logic.Sender {
return &PartialSender{Sender: e, failAfterByteCount: 1 << 20}
},
}
rfs := rep.ReceiveSideFilesystem()
report := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(report))
// assert this partial receive worked
_, err := zfs.ZFSGetFilesystemVersion(ctx, rfs+"@2")
ctx.Logf("%T %s", err, err)
_, notFullyReceived := err.(*zfs.DatasetDoesNotExist)
require.True(ctx, notFullyReceived)
// assert step holds are in place
abs, absErrs, err := endpoint.ListAbstractions(ctx, endpoint.ListZFSHoldsAndBookmarksQuery{
FS: endpoint.ListZFSHoldsAndBookmarksQueryFilesystemFilter{
FS: &sfs,
},
Concurrency: 1,
JobID: &sjid,
What: endpoint.AbstractionTypeSet{endpoint.AbstractionStepHold: true},
})
require.NoError(ctx, err)
require.Empty(ctx, absErrs)
require.Len(ctx, abs, 2)
sort.Slice(abs, func(i, j int) bool {
return abs[i].GetCreateTXG() < abs[j].GetCreateTXG()
})
require.True(ctx, zfs.FilesystemVersionEqualIdentity(abs[0].GetFilesystemVersion(), fsversion(ctx, sfs, "@1")))
require.True(ctx, zfs.FilesystemVersionEqualIdentity(abs[1].GetFilesystemVersion(), fsversion(ctx, sfs, "@2")))
}
//
// end of test setup
//
// retry replication with incremental step holds disabled (set to bookmarks-only in this case)
// - replication should not fail due to holds-related stuff
// - replication should fail intermittently due to partial sender being fully read
// - the partial sender is 1/4th the length of the stream, thus expect
// successful replication after 5 more attempts
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeIncrementalReplication), // !
interceptSender: func(e *endpoint.Sender) logic.Sender {
return &PartialSender{Sender: e, failAfterByteCount: 1 << 20}
},
}
rfs := rep.ReceiveSideFilesystem()
for i := 0; ; i++ {
require.True(ctx, i < 5)
report := rep.Do(ctx)
ctx.Logf("retry run=%v\n%s", i, pretty.Sprint(report))
_, err := zfs.ZFSGetFilesystemVersion(ctx, rfs+"@2")
if err == nil {
break
}
}
// assert replication worked
fsversion(ctx, rfs, "@2")
// assert no step holds exist
abs, absErrs, err := endpoint.ListAbstractions(ctx, endpoint.ListZFSHoldsAndBookmarksQuery{
FS: endpoint.ListZFSHoldsAndBookmarksQueryFilesystemFilter{
FS: &sfs,
},
Concurrency: 1,
JobID: &sjid,
What: endpoint.AbstractionTypeSet{endpoint.AbstractionStepHold: true},
})
require.NoError(ctx, err)
require.Empty(ctx, absErrs)
require.Len(ctx, abs, 0)
// assert that the replication cursor bookmark exists
abs, absErrs, err = endpoint.ListAbstractions(ctx, endpoint.ListZFSHoldsAndBookmarksQuery{
FS: endpoint.ListZFSHoldsAndBookmarksQueryFilesystemFilter{
FS: &sfs,
},
Concurrency: 1,
JobID: &sjid,
What: endpoint.AbstractionTypeSet{endpoint.AbstractionReplicationCursorBookmarkV2: true},
})
require.NoError(ctx, err)
require.Empty(ctx, absErrs)
require.Len(ctx, abs, 1)
require.True(ctx, zfs.FilesystemVersionEqualIdentity(abs[0].GetFilesystemVersion(), snap2sfs))
}
func ReplicationStepCompletedLostBehavior__GuaranteeResumability(ctx *platformtest.Context) {
scenario := replicationStepCompletedLostBehavior_impl(ctx, pdu.ReplicationGuaranteeKind_GuaranteeResumability)
require.Error(ctx, scenario.deleteSfs1Err, "protected by holds")
require.Contains(ctx, scenario.deleteSfs1Err.Error(), "dataset is busy")
require.Error(ctx, scenario.deleteSfs2Err, "protected by holds")
require.Contains(ctx, scenario.deleteSfs2Err.Error(), "dataset is busy")
require.Nil(ctx, scenario.finalReport.Error())
_ = fsversion(ctx, scenario.rfs, "@3") // @3 ade it to the other side
}
func ReplicationStepCompletedLostBehavior__GuaranteeIncrementalReplication(ctx *platformtest.Context) {
scenario := replicationStepCompletedLostBehavior_impl(ctx, pdu.ReplicationGuaranteeKind_GuaranteeIncrementalReplication)
require.NoError(ctx, scenario.deleteSfs1Err, "not protected by holds")
require.NoError(ctx, scenario.deleteSfs2Err, "not protected by holds")
// step bookmarks should protect against loss of StepCompleted message
require.Nil(ctx, scenario.finalReport.Error())
_ = fsversion(ctx, scenario.rfs, "@3") // @3 ade it to the other side
}
type FailSendCompletedSender struct {
*endpoint.Sender
}
var _ logic.Sender = (*FailSendCompletedSender)(nil)
func (p *FailSendCompletedSender) SendCompleted(ctx context.Context, r *pdu.SendCompletedReq) (*pdu.SendCompletedRes, error) {
return nil, fmt.Errorf("[mock] SendCompleted not delivered to actual endpoint")
}
type replicationStepCompletedLost_scenario struct {
rfs string
deleteSfs1Err, deleteSfs2Err error
finalReport *report.FilesystemReport
}
func replicationStepCompletedLostBehavior_impl(ctx *platformtest.Context, guaranteeKind pdu.ReplicationGuaranteeKind) *replicationStepCompletedLost_scenario {
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "sender"
+ "receiver"
R zfs create -p "${ROOTDS}/receiver/${ROOTDS}"
`)
sjid := endpoint.MustMakeJobID("sender-job")
rjid := endpoint.MustMakeJobID("receiver-job")
sfs := ctx.RootDataset + "/sender"
rfsRoot := ctx.RootDataset + "/receiver"
// fully replicate snapshots @1
{
mustSnapshot(ctx, sfs+"@1")
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(guaranteeKind),
}
rfs := rep.ReceiveSideFilesystem()
report := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(report))
// assert this worked (not the main subject of the test)
_ = fsversion(ctx, rfs, "@1")
}
// create a second snapshot @2
mustSnapshot(ctx, sfs+"@2")
// fake loss of stepcompleted message
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(guaranteeKind),
interceptSender: func(e *endpoint.Sender) logic.Sender {
return &FailSendCompletedSender{e}
},
}
rfs := rep.ReceiveSideFilesystem()
report := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(report))
// assert the replication worked
_ = fsversion(ctx, rfs, "@2")
// and that we hold it using a last-received-hold
abs, absErrs, err := endpoint.ListAbstractions(ctx, endpoint.ListZFSHoldsAndBookmarksQuery{
FS: endpoint.ListZFSHoldsAndBookmarksQueryFilesystemFilter{
FS: &rfs,
},
Concurrency: 1,
JobID: &rjid,
What: endpoint.AbstractionTypeSet{endpoint.AbstractionLastReceivedHold: true},
})
require.NoError(ctx, err)
require.Empty(ctx, absErrs)
require.Len(ctx, abs, 1)
require.True(ctx, zfs.FilesystemVersionEqualIdentity(abs[0].GetFilesystemVersion(), fsversion(ctx, rfs, "@2")))
// now try to delete @2 on the sender, this should work because don't have step holds on it
deleteSfs2Err := zfs.ZFSDestroy(ctx, sfs+"@2")
// defer check to caller
// and create a new snapshot on the sender
mustSnapshot(ctx, sfs+"@3")
// now we have: sender @1, @3
// recver @1, @2
// delete @1 on both sides to demonstrate that, if we didn't have bookmarks, we would be out of sync
deleteSfs1Err := zfs.ZFSDestroy(ctx, sfs+"@1")
// defer check to caller
err = zfs.ZFSDestroy(ctx, rfs+"@1")
require.NoError(ctx, err)
// attempt replication and return the filesystem report report
{
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(guaranteeKind),
}
report := rep.Do(ctx)
ctx.Logf("expecting failure:\n%s", pretty.Sprint(report))
require.Len(ctx, report.Attempts, 1)
require.Len(ctx, report.Attempts[0].Filesystems, 1)
return &replicationStepCompletedLost_scenario{
rfs: rfs,
deleteSfs1Err: deleteSfs1Err,
deleteSfs2Err: deleteSfs2Err,
finalReport: report.Attempts[0].Filesystems[0],
}
}
}
type ErroringReceiver struct {
recvErr error
*endpoint.Receiver
}
func (r *ErroringReceiver) Receive(ctx context.Context, req *pdu.ReceiveReq, stream io.ReadCloser) (*pdu.ReceiveRes, error) {
return nil, r.recvErr
}
type NeverEndingSender struct {
*endpoint.Sender
}
func (s *NeverEndingSender) SendDry(ctx context.Context, req *pdu.SendReq) (r *pdu.SendRes, err error) {
r, _, err = s.sendImpl(ctx, req, true)
return r, err
}
func (s *NeverEndingSender) Send(ctx context.Context, req *pdu.SendReq) (r *pdu.SendRes, stream io.ReadCloser, _ error) {
return s.sendImpl(ctx, req, false)
}
func (s *NeverEndingSender) sendImpl(ctx context.Context, req *pdu.SendReq, dry bool) (r *pdu.SendRes, stream io.ReadCloser, _ error) {
stream = nil
r = &pdu.SendRes{
UsedResumeToken: false,
ExpectedSize: 1 << 30,
}
if dry {
return r, stream, nil
}
dz, err := os.Open("/dev/zero")
if err != nil {
panic(err)
}
return r, dz, nil
}
func ReplicationReceiverErrorWhileStillSending(ctx *platformtest.Context) {
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "sender"
+ "sender@1"
+ "receiver"
R zfs create -p "${ROOTDS}/receiver/${ROOTDS}"
`)
sjid := endpoint.MustMakeJobID("sender-job")
rjid := endpoint.MustMakeJobID("receiver-job")
sfs := ctx.RootDataset + "/sender"
rfsRoot := ctx.RootDataset + "/receiver"
mockRecvErr := fmt.Errorf("YiezahK3thie8ahKiel5sah2uugei2ize1yi8feivuu7musoat")
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeNothing),
interceptReceiver: func(r *endpoint.Receiver) logic.Receiver {
return &ErroringReceiver{recvErr: mockRecvErr, Receiver: r}
},
interceptSender: func(s *endpoint.Sender) logic.Sender {
return &NeverEndingSender{s}
},
}
// first replication
report := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(report))
require.Len(ctx, report.Attempts, 1)
attempt := report.Attempts[0]
require.Nil(ctx, attempt.PlanError)
require.Len(ctx, attempt.Filesystems, 1)
afs := attempt.Filesystems[0]
require.Nil(ctx, afs.PlanError)
require.Len(ctx, afs.Steps, 1)
require.Nil(ctx, afs.PlanError)
require.NotNil(ctx, afs.StepError)
require.Contains(ctx, afs.StepError.Err, mockRecvErr.Error())
}
func ReplicationFailingInitialParentProhibitsChildReplication(ctx *platformtest.Context) {
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "sender"
+ "sender/a"
+ "sender/a/child"
+ "sender/aa"
+ "receiver"
R zfs create -p "${ROOTDS}/receiver/${ROOTDS}"
R zfs snapshot -r ${ROOTDS}/sender@initial
`)
sjid := endpoint.MustMakeJobID("sender-job")
rjid := endpoint.MustMakeJobID("receiver-job")
fsA := ctx.RootDataset + "/sender/a"
fsAChild := ctx.RootDataset + "/sender/a/child"
fsAA := ctx.RootDataset + "/sender/aa"
sfilter := filters.NewDatasetMapFilter(3, true)
mustAddToSFilter(ctx, sfilter, fsA)
mustAddToSFilter(ctx, sfilter, fsAChild)
mustAddToSFilter(ctx, sfilter, fsAA)
rfsRoot := ctx.RootDataset + "/receiver"
mockRecvErr := fmt.Errorf("yifae4ohPhaquaes0hohghiep9oufie4roo7quoWooluaj2ee8")
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfilter: sfilter,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeNothing),
interceptReceiver: func(r *endpoint.Receiver) logic.Receiver {
return &ErroringReceiver{recvErr: mockRecvErr, Receiver: r}
},
}
r := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(r))
require.Len(ctx, r.Attempts, 1)
attempt := r.Attempts[0]
require.Nil(ctx, attempt.PlanError)
require.Len(ctx, attempt.Filesystems, 3)
fsByName := make(map[string]*report.FilesystemReport, len(attempt.Filesystems))
for _, fs := range attempt.Filesystems {
fsByName[fs.Info.Name] = fs
}
require.Contains(ctx, fsByName, fsA)
require.Contains(ctx, fsByName, fsAChild)
require.Contains(ctx, fsByName, fsAA)
checkFS := func(fs string, expectErrMsg string) {
rep := fsByName[fs]
require.Len(ctx, rep.Steps, 1)
require.Nil(ctx, rep.PlanError)
require.NotNil(ctx, rep.StepError)
require.Contains(ctx, rep.StepError.Err, expectErrMsg)
}
checkFS(fsA, mockRecvErr.Error())
checkFS(fsAChild, "parent(s) failed during initial replication")
checkFS(fsAA, mockRecvErr.Error()) // fsAA is not treated as a child of fsA
}
func ReplicationPropertyReplicationWorks(ctx *platformtest.Context) {
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "sender"
+ "sender/a"
+ "sender/a@1"
+ "sender/a/child"
+ "sender/a/child@1"
+ "receiver"
R zfs create -p "${ROOTDS}/receiver/${ROOTDS}/sender"
`)
sjid := endpoint.MustMakeJobID("sender-job")
rjid := endpoint.MustMakeJobID("receiver-job")
fsA := ctx.RootDataset + "/sender/a"
fsAChild := ctx.RootDataset + "/sender/a/child"
sfilter := filters.NewDatasetMapFilter(2, true)
mustAddToSFilter(ctx, sfilter, fsA)
mustAddToSFilter(ctx, sfilter, fsAChild)
rfsRoot := ctx.RootDataset + "/receiver"
type testPropExpectation struct {
Exists bool
Source zfs.PropertySource
ExpectSpecialValue string
}
type testProp struct {
Name string
SetOnSender map[string]bool
ExpectReceiver map[string]testPropExpectation
}
testProps := []testProp{
{
Name: "zrepl:ignored",
SetOnSender: map[string]bool{fsA: true, fsAChild: true},
ExpectReceiver: map[string]testPropExpectation{
fsA: {
Exists: false,
},
fsAChild: {
Exists: false,
},
},
},
{
Name: "zrepl:replicate",
SetOnSender: map[string]bool{fsA: true, fsAChild: true},
ExpectReceiver: map[string]testPropExpectation{
fsA: {Exists: true, Source: zfs.SourceReceived},
fsAChild: {Exists: true, Source: zfs.SourceReceived},
},
},
{
Name: "zrepl:overridden",
SetOnSender: map[string]bool{fsA: false, fsAChild: true},
ExpectReceiver: map[string]testPropExpectation{
fsA: {Exists: true, Source: zfs.SourceLocal, ExpectSpecialValue: "overridden value"},
fsAChild: {Exists: true, Source: zfs.SourceLocal, ExpectSpecialValue: "overridden value"},
},
},
}
for _, prop := range testProps {
for fs := range prop.SetOnSender {
err := zfs.ZFSSet(ctx, mustDatasetPath(fs), map[string]string{prop.Name: prop.Name})
require.NoError(ctx, err)
}
}
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfilter: sfilter,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeNothing),
receiverConfigHook: func(c *endpoint.ReceiverConfig) {
c.InheritProperties = []zfsprop.Property{"zrepl:ignored"}
c.OverrideProperties = map[zfsprop.Property]string{
"zrepl:overridden": "overridden value",
}
},
senderConfigHook: func(c *endpoint.SenderConfig) {
c.SendProperties = true // TODO: do another tier with SendBackupProperties
},
}
r := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(r))
require.Len(ctx, r.Attempts, 1)
attempt := r.Attempts[0]
require.Nil(ctx, attempt.PlanError)
require.Len(ctx, attempt.Filesystems, 2)
fsByName := make(map[string]*report.FilesystemReport, len(attempt.Filesystems))
for _, fs := range attempt.Filesystems {
fsByName[fs.Info.Name] = fs
}
require.Contains(ctx, fsByName, fsA)
require.Contains(ctx, fsByName, fsAChild)
require.Len(ctx, fsByName, 2)
requireFSReportSucceeded := func(fs string) *zfs.DatasetPath {
rep := fsByName[fs]
require.Len(ctx, rep.Steps, 1)
require.Nil(ctx, rep.PlanError)
if rep.StepError != nil && strings.Contains(rep.StepError.Error(), "invalid option 'x'") {
ctx.SkipNow() // XXX feature detection
}
require.Nil(ctx, rep.StepError)
require.Len(ctx, rep.Steps, 1)
require.Equal(ctx, 1, rep.CurrentStep)
return mustDatasetPath(path.Join(rfsRoot, fs))
}
rfsA := requireFSReportSucceeded(fsA)
rfsAChild := requireFSReportSucceeded(fsAChild)
rfsmap := map[string]*zfs.DatasetPath{
fsA: rfsA,
fsAChild: rfsAChild,
}
for fs, rfs := range rfsmap {
for _, tp := range testProps {
r_, err := zfs.ZFSGet(ctx, rfs, []string{tp.Name})
require.NoError(ctx, err)
r := r_.GetDetails(tp.Name)
expect := tp.ExpectReceiver[fs]
if !expect.Exists {
require.Equal(ctx, zfs.SourceNone, r.Source)
} else {
require.Equal(ctx, expect.Source, r.Source)
if expect.ExpectSpecialValue != "" {
require.Equal(ctx, expect.ExpectSpecialValue, r.Value)
} else {
require.Equal(ctx, tp.Name, r.Value)
}
}
}
}
}
func ReplicationPlaceholderEncryption__UnspecifiedLeadsToFailureAtRuntimeWhenCreatingPlaceholders(ctx *platformtest.Context) {
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "sender"
+ "sender/a"
+ "sender/a/child"
+ "receiver"
R zfs snapshot -r ${ROOTDS}/sender@initial
`)
sjid := endpoint.MustMakeJobID("sender-job")
rjid := endpoint.MustMakeJobID("receiver-job")
childfs := ctx.RootDataset + "/sender/a/child"
sfilter := filters.NewDatasetMapFilter(3, true)
mustAddToSFilter(ctx, sfilter, childfs)
rfsRoot := ctx.RootDataset + "/receiver"
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfilter: sfilter,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeResumability),
receiverConfigHook: func(rc *endpoint.ReceiverConfig) {
rc.PlaceholderEncryption = endpoint.PlaceholderCreationEncryptionPropertyUnspecified
},
}
r := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(r))
require.Len(ctx, r.Attempts, 1)
attempt := r.Attempts[0]
require.Nil(ctx, attempt.PlanError)
require.Len(ctx, attempt.Filesystems, 1)
afs := attempt.Filesystems[0]
require.Equal(ctx, childfs, afs.Info.Name)
require.Equal(ctx, 1, len(afs.Steps))
require.Equal(ctx, 0, afs.CurrentStep)
require.Equal(ctx, report.FilesystemSteppingErrored, afs.State)
childfsFirstComponent := strings.Split(childfs, "/")[0]
require.Contains(ctx, afs.StepError.Err, "cannot create placeholder filesystem "+rfsRoot+"/"+childfsFirstComponent+": placeholder filesystem encryption handling is unspecified in receiver config")
}
type ClientIdentityReceiver struct {
clientIdentity string
*endpoint.Receiver
}
func (r *ClientIdentityReceiver) Receive(ctx context.Context, req *pdu.ReceiveReq, stream io.ReadCloser) (*pdu.ReceiveRes, error) {
ctx = context.WithValue(ctx, endpoint.ClientIdentityKey, r.clientIdentity)
return r.Receiver.Receive(ctx, req, stream)
}
func ReplicationPlaceholderEncryption__UnspecifiedIsOkForClientIdentityPlaceholder(ctx *platformtest.Context) {
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "receiver"
`)
sjid := endpoint.MustMakeJobID("sender-job")
rjid := endpoint.MustMakeJobID("receiver-job")
sfilter := filters.NewDatasetMapFilter(1, true)
// hacky...
comps := strings.Split(ctx.RootDataset, "/")
require.GreaterOrEqual(ctx, len(comps), 2)
pool := comps[0]
require.Contains(ctx, pool, "zreplplatformtest", "don't want to cause accidents")
poolchild := pool + "/" + comps[1]
err := zfs.ZFSSnapshot(ctx, mustDatasetPath(pool), "testsnap", false)
require.NoError(ctx, err)
err = zfs.ZFSSnapshot(ctx, mustDatasetPath(poolchild), "testsnap", false)
require.NoError(ctx, err)
mustAddToSFilter(ctx, sfilter, pool)
mustAddToSFilter(ctx, sfilter, poolchild)
clientIdentity := "testclientid"
rfsRoot := ctx.RootDataset + "/receiver"
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfilter: sfilter,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeResumability),
receiverConfigHook: func(rc *endpoint.ReceiverConfig) {
rc.PlaceholderEncryption = endpoint.PlaceholderCreationEncryptionPropertyUnspecified
rc.AppendClientIdentity = true
},
interceptReceiver: func(r *endpoint.Receiver) logic.Receiver {
r.Test_OverrideClientIdentityFunc = func() string { return clientIdentity }
return r
},
}
r := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(r))
require.Len(ctx, r.Attempts, 1)
attempt := r.Attempts[0]
require.Nil(ctx, attempt.PlanError)
require.Len(ctx, attempt.Filesystems, 2)
filesystemsByName := make(map[string]*report.FilesystemReport)
for _, fs := range attempt.Filesystems {
filesystemsByName[fs.Info.Name] = fs
}
require.Len(ctx, filesystemsByName, len(attempt.Filesystems))
afs, ok := filesystemsByName[pool]
require.True(ctx, ok)
require.Nil(ctx, afs.PlanError)
require.Nil(ctx, afs.StepError)
require.Equal(ctx, report.FilesystemDone, afs.State)
afs, ok = filesystemsByName[poolchild]
require.True(ctx, ok)
require.Nil(ctx, afs.PlanError)
require.Nil(ctx, afs.StepError)
require.Equal(ctx, report.FilesystemDone, afs.State)
mustGetFilesystemVersion(ctx, rfsRoot+"/"+clientIdentity+"/"+pool+"@testsnap")
mustGetFilesystemVersion(ctx, rfsRoot+"/"+clientIdentity+"/"+poolchild+"@testsnap")
}
func replicationPlaceholderEncryption__EncryptOnReceiverUseCase__impl(ctx *platformtest.Context, placeholderEncryption endpoint.PlaceholderCreationEncryptionProperty) {
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "sender"
+ "sender/a"
+ "sender/a/child"
+ "receiver" encrypted
R zfs snapshot -r ${ROOTDS}/sender@initial
`)
sjid := endpoint.MustMakeJobID("sender-job")
rjid := endpoint.MustMakeJobID("receiver-job")
childfs := ctx.RootDataset + "/sender/a/child"
sfilter := filters.NewDatasetMapFilter(3, true)
mustAddToSFilter(ctx, sfilter, childfs)
rfsRoot := ctx.RootDataset + "/receiver"
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfilter: sfilter,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeResumability),
receiverConfigHook: func(rc *endpoint.ReceiverConfig) {
rc.PlaceholderEncryption = placeholderEncryption
rc.AppendClientIdentity = false
},
}
r := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(r))
require.Len(ctx, r.Attempts, 1)
attempt := r.Attempts[0]
require.Equal(ctx, report.AttemptDone, attempt.State)
require.Len(ctx, attempt.Filesystems, 1)
afs := attempt.Filesystems[0]
require.Equal(ctx, childfs, afs.Info.Name)
require.Equal(ctx, 1, len(afs.Steps))
rfs := mustDatasetPath(rfsRoot + "/" + childfs)
mustGetFilesystemVersion(ctx, rfs.ToString()+"@initial")
}
func ReplicationPlaceholderEncryption__EncryptOnReceiverUseCase__WorksIfConfiguredWithInherit(ctx *platformtest.Context) {
placeholderEncryption := endpoint.PlaceholderCreationEncryptionPropertyInherit
replicationPlaceholderEncryption__EncryptOnReceiverUseCase__impl(ctx, placeholderEncryption)
childfs := ctx.RootDataset + "/sender/a/child"
rfsRoot := ctx.RootDataset + "/receiver"
rfs := mustDatasetPath(rfsRoot + "/" + childfs)
// The leaf child dataset should be inhering from rfsRoot.
// If we had replicated with PlaceholderCreationEncryptionPropertyOff
// then it would be unencrypted and inherit from the placeholder.
props, err := zfs.ZFSGet(ctx, rfs, []string{"encryptionroot"})
require.NoError(ctx, err)
require.Equal(ctx, rfsRoot, props.Get("encryptionroot"))
}
func replicationInitialImpl(ctx *platformtest.Context, iras logic.InitialReplicationAutoResolution, expectExactRfsSnaps []string) *report.Report {
// reverse order for snap names to expose sorting assumptions
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
CREATEROOT
+ "sender"
+ "sender@3"
+ "sender@2"
+ "sender@1"
+ "receiver"
R zfs create -p "${ROOTDS}/receiver/${ROOTDS}"
`)
sjid := endpoint.MustMakeJobID("sender-job")
rjid := endpoint.MustMakeJobID("receiver-job")
sfs := ctx.RootDataset + "/sender"
rfsRoot := ctx.RootDataset + "/receiver"
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeResumability),
plannerPolicyHook: func(pp *logic.PlannerPolicy) {
pp.ConflictResolution.InitialReplication = iras
},
}
rfs := rep.ReceiveSideFilesystem()
// first replication
report := rep.Do(ctx)
ctx.Logf("\n%s", pretty.Sprint(report))
versions, err := zfs.ZFSListFilesystemVersions(ctx, mustDatasetPath(rfs), zfs.ListFilesystemVersionsOptions{Types: zfs.Snapshots})
if _, ok := err.(*zfs.DatasetDoesNotExist); ok {
versions = nil
} else {
require.NoError(ctx, err)
}
bySnapName := make(map[string]int)
for _, v := range versions {
bySnapName[v.GetName()] += 1
}
for _, v := range expectExactRfsSnaps {
bySnapName[v] -= 1
}
for _, v := range bySnapName {
if v != 0 {
ctx.Logf("unexpected snaps:\n%#v", bySnapName)
ctx.FailNow()
}
}
return report
}
func ReplicationInitialAll(ctx *platformtest.Context) {
replicationInitialImpl(ctx, logic.InitialReplicationAutoResolutionAll, []string{"3", "2", "1"})
}
func ReplicationInitialMostRecent(ctx *platformtest.Context) {
replicationInitialImpl(ctx, logic.InitialReplicationAutoResolutionMostRecent, []string{"1"})
}
func ReplicationInitialFail(ctx *platformtest.Context) {
report := replicationInitialImpl(ctx, logic.InitialReplicationAutoResolutionFail, []string{})
require.Len(ctx, report.Attempts, 1)
require.Nil(ctx, report.Attempts[0].PlanError)
require.Len(ctx, report.Attempts[0].Filesystems, 1)
require.NotNil(ctx, report.Attempts[0].Filesystems[0].PlanError)
require.Contains(ctx, report.Attempts[0].Filesystems[0].PlanError.Err, "automatic conflict resolution for initial replication is disabled in config")
}