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releases/0.6.1-2
zrepl/platformtest/tests/sendArgsValidation.go
Christian Schwarz 2d8c3692ec 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:

- 6c3c5fcfbe/module/zfs/dmu_send.c (L1947-L2012)
- 6c3c5fcfbe/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
2022-09-25 17:32:02 +02:00

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package tests
import (
"fmt"
"path"
"github.com/kr/pretty"
"github.com/stretchr/testify/require"
"github.com/zrepl/zrepl/endpoint"
"github.com/zrepl/zrepl/platformtest"
"github.com/zrepl/zrepl/replication/logic"
"github.com/zrepl/zrepl/replication/logic/pdu"
"github.com/zrepl/zrepl/replication/report"
"github.com/zrepl/zrepl/util/nodefault"
"github.com/zrepl/zrepl/zfs"
)
func SendArgsValidationEncryptedSendOfUnencryptedDatasetForbidden__EncryptionSupported_true(ctx *platformtest.Context) {
sendArgsValidationEncryptedSendOfUnencryptedDatasetForbidden_impl(ctx, true)
}
func SendArgsValidationEncryptedSendOfUnencryptedDatasetForbidden__EncryptionSupported_false(ctx *platformtest.Context) {
sendArgsValidationEncryptedSendOfUnencryptedDatasetForbidden_impl(ctx, false)
}
func sendArgsValidationEncryptedSendOfUnencryptedDatasetForbidden_impl(ctx *platformtest.Context, testForEncryptionSupported bool) {
supported, err := zfs.EncryptionCLISupported(ctx)
check(err)
if supported != testForEncryptionSupported {
ctx.SkipNow()
}
noEncryptionCLISupport := !supported
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
DESTROYROOT
CREATEROOT
+ "send er"
+ "send er@a snap"
`)
fs := fmt.Sprintf("%s/send er", ctx.RootDataset)
props := mustGetFilesystemVersion(ctx, fs+"@a snap")
sendArgs, err := zfs.ZFSSendArgsUnvalidated{
FS: fs,
To: &zfs.ZFSSendArgVersion{
RelName: "@a snap",
GUID: props.Guid,
},
ZFSSendFlags: zfs.ZFSSendFlags{
Encrypted: &nodefault.Bool{B: true},
ResumeToken: "",
},
}.Validate(ctx)
var stream *zfs.SendStream
if err == nil {
stream, err = zfs.ZFSSend(ctx, sendArgs) // no shadow
if err == nil {
defer stream.Close()
}
// fallthrough
}
if noEncryptionCLISupport {
require.Error(ctx, err)
saverr, ok := err.(*zfs.ZFSSendArgsValidationError)
require.True(ctx, ok, "%T", err)
require.Equal(ctx, zfs.ZFSSendArgsEncryptedSendRequestedButFSUnencrypted, saverr.What)
return
}
require.Error(ctx, err)
ctx.Logf("send err: %T %s", err, err)
validationErr, ok := err.(*zfs.ZFSSendArgsValidationError)
require.True(ctx, ok)
require.True(ctx, validationErr.What == zfs.ZFSSendArgsEncryptedSendRequestedButFSUnencrypted)
}
func SendArgsValidationResumeTokenEncryptionMismatchForbidden(ctx *platformtest.Context) {
supported, err := zfs.EncryptionCLISupported(ctx)
check(err)
if !supported {
ctx.SkipNow()
}
supported, err = zfs.ResumeSendSupported(ctx)
check(err)
if !supported {
ctx.SkipNow()
}
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
DESTROYROOT
CREATEROOT
+ "send er" encrypted
`)
sendFS := fmt.Sprintf("%s/send er", ctx.RootDataset)
unencRecvFS := fmt.Sprintf("%s/unenc recv", ctx.RootDataset)
encRecvFS := fmt.Sprintf("%s/enc recv", ctx.RootDataset)
src := makeDummyDataSnapshots(ctx, sendFS)
unencS := makeResumeSituation(ctx, src, unencRecvFS, zfs.ZFSSendArgsUnvalidated{
FS: sendFS,
To: src.snapA,
ZFSSendFlags: zfs.ZFSSendFlags{Encrypted: &nodefault.Bool{B: false}}, // !
}, zfs.RecvOptions{
RollbackAndForceRecv: false,
SavePartialRecvState: true,
})
encS := makeResumeSituation(ctx, src, encRecvFS, zfs.ZFSSendArgsUnvalidated{
FS: sendFS,
To: src.snapA,
ZFSSendFlags: zfs.ZFSSendFlags{Encrypted: &nodefault.Bool{B: true}}, // !
}, zfs.RecvOptions{
RollbackAndForceRecv: false,
SavePartialRecvState: true,
})
// threat model: use of a crafted resume token that requests an unencrypted send
// but send args require encrypted send
{
var maliciousSend zfs.ZFSSendArgsUnvalidated = encS.sendArgs
maliciousSend.ResumeToken = unencS.recvErrDecoded.ResumeTokenRaw
_, err := maliciousSend.Validate(ctx)
validationErr, ok := err.(*zfs.ZFSSendArgsValidationError)
require.True(ctx, ok)
require.Equal(ctx, validationErr.What, zfs.ZFSSendArgsResumeTokenMismatch)
ctx.Logf("%s", validationErr)
mismatchError, ok := validationErr.Msg.(*zfs.ZFSSendArgsResumeTokenMismatchError)
require.True(ctx, ok)
require.Equal(ctx, mismatchError.What, zfs.ZFSSendArgsResumeTokenMismatchEncryptionNotSet)
}
// threat model: use of a crafted resume token that requests an encrypted send
// but send args require unencrypted send
{
var maliciousSend zfs.ZFSSendArgsUnvalidated = unencS.sendArgs
maliciousSend.ResumeToken = encS.recvErrDecoded.ResumeTokenRaw
_, err := maliciousSend.Validate(ctx)
require.Error(ctx, err)
ctx.Logf("send err: %T %s", err, err)
validationErr, ok := err.(*zfs.ZFSSendArgsValidationError)
require.True(ctx, ok)
require.Equal(ctx, validationErr.What, zfs.ZFSSendArgsResumeTokenMismatch)
ctx.Logf("%s", validationErr)
mismatchError, ok := validationErr.Msg.(*zfs.ZFSSendArgsResumeTokenMismatchError)
require.True(ctx, ok)
require.Equal(ctx, mismatchError.What, zfs.ZFSSendArgsResumeTokenMismatchEncryptionSet)
}
}
func SendArgsValidationResumeTokenDifferentFilesystemForbidden(ctx *platformtest.Context) {
supported, err := zfs.ResumeSendSupported(ctx)
check(err)
if !supported {
ctx.SkipNow()
}
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, `
DESTROYROOT
CREATEROOT
+ "send er1"
+ "send er2"
`)
sendFS1 := fmt.Sprintf("%s/send er1", ctx.RootDataset)
sendFS2 := fmt.Sprintf("%s/send er2", ctx.RootDataset)
recvFS := fmt.Sprintf("%s/unenc recv", ctx.RootDataset)
src1 := makeDummyDataSnapshots(ctx, sendFS1)
src2 := makeDummyDataSnapshots(ctx, sendFS2)
rs := makeResumeSituation(ctx, src1, recvFS, zfs.ZFSSendArgsUnvalidated{
FS: sendFS1,
To: src1.snapA,
ZFSSendFlags: zfs.ZFSSendFlags{Encrypted: &nodefault.Bool{B: false}},
}, zfs.RecvOptions{
RollbackAndForceRecv: false,
SavePartialRecvState: true,
})
// threat model: forged resume token tries to steal a full send of snapA on fs2 by
// presenting a resume token for full send of snapA on fs1
var maliciousSend zfs.ZFSSendArgsUnvalidated = zfs.ZFSSendArgsUnvalidated{
FS: sendFS2,
To: &zfs.ZFSSendArgVersion{
RelName: src2.snapA.RelName,
GUID: src2.snapA.GUID,
},
ZFSSendFlags: zfs.ZFSSendFlags{
Encrypted: &nodefault.Bool{B: false},
ResumeToken: rs.recvErrDecoded.ResumeTokenRaw,
},
}
_, err = maliciousSend.Validate(ctx)
require.Error(ctx, err)
ctx.Logf("send err: %T %s", err, err)
validationErr, ok := err.(*zfs.ZFSSendArgsValidationError)
require.True(ctx, ok)
require.Equal(ctx, validationErr.What, zfs.ZFSSendArgsResumeTokenMismatch)
ctx.Logf("%s", validationErr)
mismatchError, ok := validationErr.Msg.(*zfs.ZFSSendArgsResumeTokenMismatchError)
require.True(ctx, ok)
require.Equal(ctx, mismatchError.What, zfs.ZFSSendArgsResumeTokenMismatchFilesystem)
}
type sendArgsValidationEndToEndTestOutcome string
const (
ValidationAccepts sendArgsValidationEndToEndTestOutcome = "accept"
ValidationRejects sendArgsValidationEndToEndTestOutcome = "rejects"
)
type sendArgsValidationEndToEndTest struct {
encryptedSenderFilesystem bool
senderConfigHook func(config *endpoint.SenderConfig)
expectedOutcome sendArgsValidationEndToEndTestOutcome
outcomeRejectsInspectError func(require.TestingT, *report.FilesystemReport, bool)
inspectReceiverFSAfterSuccessfulCycle func(rfs string)
}
func implSendArgsValidationEndToEndTest(ctx *platformtest.Context, setup sendArgsValidationEndToEndTest) {
senderEncrypted := ""
if setup.encryptedSenderFilesystem {
senderEncrypted = "encrypted"
}
platformtest.Run(ctx, platformtest.PanicErr, ctx.RootDataset, fmt.Sprintf(`
CREATEROOT
+ "sender" %s
+ "receiver"
R zfs create -p "${ROOTDS}/receiver/${ROOTDS}"
`, senderEncrypted))
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)
// Two cycles. one initial replication, one incremental replication.
// Within each cycle: interrupt replication at least once.
// This exercises both the no-resume-token-present and the resume-token-present validation code paths.
initial_then_incremental:
for i := 0; i < 2; i++ {
writeDummyData(path.Join(sfsmp.Mountpoint, "dummy.data"), 2*(1<<20))
mustSnapshot(ctx, fmt.Sprintf("%s@%d", sfs, i))
rep := replicationInvocation{
sjid: sjid,
rjid: rjid,
sfs: sfs,
rfsRoot: rfsRoot,
senderConfigHook: setup.senderConfigHook,
interceptSender: func(e *endpoint.Sender) logic.Sender {
return &PartialSender{Sender: e, failAfterByteCount: 1 << 20}
},
guarantee: pdu.ReplicationConfigProtectionWithKind(pdu.ReplicationGuaranteeKind_GuaranteeResumability),
skipSendArgsValidation: false,
}
rfs := rep.ReceiveSideFilesystem()
// PartialSender interrupts after 1MiB, and we wrote 2 MiB of data
// => Give it 3 attempts to replicate. after that, we should have a stable outcome
var lastReport *report.Report
lastResumeToken := ""
interrupt_current_step:
for j := 0; j < 3; j++ {
lastReport = rep.Do(ctx)
ctx.Logf("\nreport=%s", pretty.Sprint(lastReport))
require.Len(ctx, lastReport.Attempts, 1)
require.Len(ctx, lastReport.Attempts[0].Filesystems, 1)
lastReportFS := lastReport.Attempts[0].Filesystems[0]
var rfsExists bool
rfsResumeToken, err := zfs.ZFSGetReceiveResumeTokenOrEmptyStringIfNotSupported(ctx, mustDatasetPath(rfs))
if err != nil {
_, ok := err.(*zfs.DatasetDoesNotExist) // no shadow
require.True(ctx, ok, "no other errors expected")
rfsExists = false
rfsResumeToken = ""
} else {
rfsExists = true
}
if setup.expectedOutcome == ValidationRejects {
// When expecting rejection, it should manifest immediately, before sending anything.
// This is tested in the j=0 iteration (for both initial and incremental repl (i=0, i=1)).
// But we also want to assert correct behavior in case zrepl observes resume tokens.
// Specifically, cases where the send parameters encoded in the token conflict with the
// configured encryption policy.
// Hence, for scenarios that are expected to reject, after we validated that they reject
// for the non-resuming case (j==0), fabricate a resuming scenario by temporarily disabling
// send args validation. After fabricating the scenario, proceed into j==1 to exercise
// the resume token validation.
if j == 0 {
if i == 0 {
require.False(ctx, rfsExists, "the sender should not have sent anything")
} else {
// we fabricate a scenario where rfsExists below, hence can't assert non-existence anymore
}
ctx.Logf("skipping send args validation to test resuming case")
rep.skipSendArgsValidation = true
setupResumeReport := rep.Do(ctx)
ctx.Logf("setupResumeReport=%s", pretty.Sprint(setupResumeReport))
rep.skipSendArgsValidation = false
rt, err := zfs.ZFSGetReceiveResumeTokenOrEmptyStringIfNotSupported(ctx, mustDatasetPath(rfs))
require.NoError(ctx, err)
require.NotEmpty(ctx, rt, "we disabled send args validation, so the .Do above should have resulted in a resume token on rfs")
lastResumeToken = rt
continue interrupt_current_step // next iteration will test resume case with send args validation enabled
} else { // j > 0
require.Equal(ctx, lastResumeToken, rfsResumeToken, "we expect policy to refuse replication, no progress must happen")
_, err := zfs.ZFSGetFilesystemVersion(ctx, fmt.Sprintf("%s@%d", rfs, i))
_, ok := err.(*zfs.DatasetDoesNotExist)
require.True(ctx, ok, "another check that no progress is happening")
}
setup.outcomeRejectsInspectError(ctx, lastReportFS, j == 0)
// XXX: check rejection cases for incremental replication as well
break initial_then_incremental
} else {
require.Equal(ctx, ValidationAccepts, setup.expectedOutcome)
_, err := zfs.ZFSGetFilesystemVersion(ctx, fmt.Sprintf("%s@%d", rfs, i))
_, notExist := err.(*zfs.DatasetDoesNotExist)
if notExist {
require.NotEmpty(ctx, rfsResumeToken)
continue interrupt_current_step // next iteration will resume
} else {
require.NoError(ctx, err)
// version exists
// make sure all the filesystem versions we created so far were replicated by the replication loop
for j := 0; j <= i; j++ {
_ = fsversion(ctx, rfs, fmt.Sprintf("@%d", j))
}
setup.inspectReceiverFSAfterSuccessfulCycle(rfs)
continue initial_then_incremental
}
}
}
}
}
func SendArgsValidationEE_EncryptionAndRaw(ctx *platformtest.Context) {
type TC struct {
// create sender filesystem with encryption enabled yes/no
SFSEnc bool
SndEnc bool // send flag
SndRaw bool // send flag
RFSEnc bool
Outcome sendArgsValidationEndToEndTestOutcome
RejectErrorNoResume string
RejectErrorResume string
}
tcs := []TC{
// Sender FS is unencrypted
{SFSEnc: false, SndEnc: false, SndRaw: false, RFSEnc: false, Outcome: ValidationAccepts},
{SFSEnc: false, SndEnc: false, SndRaw: true, RFSEnc: false, Outcome: ValidationAccepts}, // allow unencrypted raw sends (#503)
{SFSEnc: false, SndEnc: true, SndRaw: false, RFSEnc: false, Outcome: ValidationRejects,
RejectErrorNoResume: `encrypted send mandated by policy, but filesystem .* is not encrypted`,
RejectErrorResume: `encrypted send mandated by policy, but filesystem .* is not encrypted`,
},
{SFSEnc: false, SndEnc: true, SndRaw: true, RFSEnc: false, Outcome: ValidationRejects,
RejectErrorNoResume: `encrypted send mandated by policy, but filesystem .* is not encrypted`,
RejectErrorResume: `encrypted send mandated by policy, but filesystem .* is not encrypted`,
},
// Sender FS is encrypted
{SFSEnc: true, SndEnc: false, SndRaw: false, RFSEnc: false, Outcome: ValidationAccepts}, // passes because keys are loaded, thus can send plain.
{SFSEnc: true, SndEnc: false, SndRaw: true, RFSEnc: false, Outcome: ValidationRejects,
RejectErrorNoResume: `policy mandates raw\+unencrypted sends, but filesystem .* is encrypted`,
RejectErrorResume: `resume token has rawok=true which would result in encrypted send, but policy mandates unencrypted sends only`,
},
{SFSEnc: true, SndEnc: true, SndRaw: false, RFSEnc: true, Outcome: ValidationAccepts},
{SFSEnc: true, SndEnc: true, SndRaw: true, RFSEnc: true, Outcome: ValidationAccepts},
}
for _, tc := range tcs {
tc := tc // closure would copy by ref otherwise
ctx.QueueSubtest(fmt.Sprintf("%#v", tc), func(ctx *platformtest.Context) {
implSendArgsValidationEndToEndTest(ctx, sendArgsValidationEndToEndTest{
encryptedSenderFilesystem: tc.SFSEnc,
senderConfigHook: func(c *endpoint.SenderConfig) {
c.Encrypt = &nodefault.Bool{B: tc.SndEnc}
c.SendRaw = tc.SndRaw
},
expectedOutcome: tc.Outcome,
outcomeRejectsInspectError: func(ctx require.TestingT, fr *report.FilesystemReport, isResume bool) {
// this callback is only called for ValidationRejects
// validation should be failing during dry send => planning stage
// XXX mock out ZFS to ensure we never call a zfs send that would send data
// if we're expecting validation to fail
require.Equal(ctx, report.FilesystemPlanningErrored, fr.State)
if isResume {
require.NotEmpty(ctx, tc.RejectErrorResume)
require.Regexp(ctx, tc.RejectErrorResume, fr.PlanError)
} else {
require.NotEmpty(ctx, tc.RejectErrorNoResume)
require.Regexp(ctx, tc.RejectErrorNoResume, fr.PlanError)
}
},
inspectReceiverFSAfterSuccessfulCycle: func(rfs string) {
enabled, err := zfs.ZFSGetEncryptionEnabled(ctx, rfs)
require.NoError(ctx, err)
require.Equal(ctx, tc.RFSEnc, enabled, "receiver filesystem encryption settings unexpected")
},
})
})
}
}
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