mirror of
https://github.com/zrepl/zrepl.git
synced 2024-11-24 17:35:01 +01:00
ac147b5a6f
- `BlockedOn` prop in JSON report - Bring back the `*` in front of the filesystem report as an activity indicator. fixes https://github.com/zrepl/zrepl/issues/505
842 lines
24 KiB
Go
842 lines
24 KiB
Go
package driver
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import (
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"context"
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"fmt"
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"net"
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"sort"
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"strings"
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"sync"
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"time"
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"github.com/go-playground/validator"
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"github.com/kr/pretty"
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"github.com/pkg/errors"
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"google.golang.org/grpc/codes"
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"google.golang.org/grpc/status"
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"github.com/zrepl/zrepl/daemon/logging/trace"
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"github.com/zrepl/zrepl/zfs"
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"github.com/zrepl/zrepl/replication/report"
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"github.com/zrepl/zrepl/util/chainlock"
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)
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type interval struct {
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begin time.Time
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end time.Time
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}
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func (w *interval) SetZero() {
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w.begin = time.Time{}
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w.end = time.Time{}
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}
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// Duration of 0 means indefinite length
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func (w *interval) Set(begin time.Time, duration time.Duration) {
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if begin.IsZero() {
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panic("zero begin time now allowed")
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}
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w.begin = begin
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w.end = begin.Add(duration)
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}
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// Returns the End of the interval if it has a defined length.
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// For indefinite lengths, returns the zero value.
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func (w *interval) End() time.Time {
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return w.end
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}
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// Return a context with a deadline at the interval's end.
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// If the interval has indefinite length (duration 0 on Set), return ctx as is.
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// The returned context.CancelFunc can be called either way.
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func (w *interval) ContextWithDeadlineAtEnd(ctx context.Context) (context.Context, context.CancelFunc) {
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if w.begin.IsZero() {
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panic("must call Set before ContextWIthDeadlineAtEnd")
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}
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if w.end.IsZero() {
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// indefinite length, just return context as is
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return ctx, func() {}
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} else {
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return context.WithDeadline(ctx, w.end)
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}
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}
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type run struct {
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l *chainlock.L
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startedAt, finishedAt time.Time
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waitReconnect interval
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waitReconnectError *timedError
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// the attempts attempted so far:
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// All but the last in this slice must have finished with some errors.
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// The last attempt may not be finished and may not have errors.
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attempts []*attempt
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}
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type Planner interface {
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Plan(context.Context) ([]FS, error)
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WaitForConnectivity(context.Context) error
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}
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// an attempt represents a single planning & execution of fs replications
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type attempt struct {
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planner Planner
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config Config
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l *chainlock.L
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startedAt, finishedAt time.Time
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// after Planner.Plan was called, planErr and fss are mutually exclusive with regards to nil-ness
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// if both are nil, it must be assumed that Planner.Plan is active
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planErr *timedError
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fss []*fs
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}
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type timedError struct {
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Err error
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Time time.Time
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}
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func newTimedError(err error, t time.Time) *timedError {
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if err == nil {
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panic("error must be non-nil")
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}
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if t.IsZero() {
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panic("t must be non-zero")
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}
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return &timedError{err, t}
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}
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func (e *timedError) IntoReportError() *report.TimedError {
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if e == nil {
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return nil
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}
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return report.NewTimedError(e.Err.Error(), e.Time)
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}
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type FS interface {
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// Returns true if this FS and fs refer to the same filesystem returned
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// by Planner.Plan in a previous attempt.
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EqualToPreviousAttempt(fs FS) bool
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// The returned steps are assumed to be dependent on exactly
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// their direct predecessors in the returned list.
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PlanFS(context.Context) ([]Step, error)
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ReportInfo() *report.FilesystemInfo
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}
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type Step interface {
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// Returns true iff the target snapshot is the same for this Step and other.
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// We do not use TargetDate to avoid problems with wrong system time on
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// snapshot creation.
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//
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// Implementations can assume that `other` is a step of the same filesystem,
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// although maybe from a previous attempt.
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// (`same` as defined by FS.EqualToPreviousAttempt)
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//
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// Note that TargetEquals should return true in a situation with one
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// originally sent snapshot and a subsequent attempt's step that uses
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// resumable send & recv.
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TargetEquals(other Step) bool
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TargetDate() time.Time
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Step(context.Context) error
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ReportInfo() *report.StepInfo
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}
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type fs struct {
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fs FS
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l *chainlock.L
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blockedOn report.FsBlockedOn
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// ordering relationship that must be maintained for initial replication
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initialRepOrd struct {
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parents, children []*fs
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parentDidUpdate chan struct{}
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}
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planning struct {
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waitingForStepQueue bool
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done bool
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err *timedError
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}
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// valid iff planning.done && planning.err == nil
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planned struct {
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// valid iff planning.done && planning.err == nil
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stepErr *timedError
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// all steps, in the order in which they must be completed
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steps []*step
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// index into steps, pointing at the step that is currently executing
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// if step >= len(steps), no more work needs to be done
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step int
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}
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}
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type step struct {
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l *chainlock.L
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step Step
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}
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type ReportFunc func() *report.Report
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type WaitFunc func(block bool) (done bool)
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type Config struct {
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StepQueueConcurrency int `validate:"gte=1"`
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MaxAttempts int `validate:"eq=-1|gt=0"`
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ReconnectHardFailTimeout time.Duration `validate:"gt=0"`
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}
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var validate = validator.New()
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func (c Config) Validate() error {
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return validate.Struct(c)
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}
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// caller must ensure config.Validate() == nil
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func Do(ctx context.Context, config Config, planner Planner) (ReportFunc, WaitFunc) {
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if err := config.Validate(); err != nil {
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panic(err)
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}
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log := getLog(ctx)
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l := chainlock.New()
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run := &run{
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l: l,
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startedAt: time.Now(),
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}
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done := make(chan struct{})
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go func() {
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defer close(done)
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defer run.l.Lock().Unlock()
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log.Debug("begin run")
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defer log.Debug("run ended")
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var prev *attempt
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mainLog := log
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for ano := 0; ano < int(config.MaxAttempts); ano++ {
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log := mainLog.WithField("attempt_number", ano)
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log.Debug("start attempt")
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run.waitReconnect.SetZero()
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run.waitReconnectError = nil
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// do current attempt
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cur := &attempt{
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l: l,
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startedAt: time.Now(),
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planner: planner,
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config: config,
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}
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run.attempts = append(run.attempts, cur)
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run.l.DropWhile(func() {
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cur.do(ctx, prev)
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})
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prev = cur
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if ctx.Err() != nil {
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log.WithError(ctx.Err()).Info("context error")
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return
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}
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// error classification, bail out if done / permanent error
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rep := cur.report()
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log.WithField("attempt_state", rep.State).Debug("attempt state")
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errRep := cur.errorReport()
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if rep.State == report.AttemptDone {
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if len(rep.Filesystems) == 0 {
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log.Warn("no filesystems were considered for replication")
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}
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log.Debug("attempt completed")
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break
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}
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mostRecentErr, mostRecentErrClass := errRep.MostRecent()
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log.WithField("most_recent_err", mostRecentErr).WithField("most_recent_err_class", mostRecentErrClass).Debug("most recent error used for re-connect decision")
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if mostRecentErr == nil {
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// inconsistent reporting, let's bail out
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log.WithField("attempt_state", rep.State).Warn("attempt does not report done but error report does not report errors, aborting run")
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break
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}
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log.WithError(mostRecentErr.Err).Error("most recent error in this attempt")
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shouldReconnect := mostRecentErrClass == errorClassTemporaryConnectivityRelated
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log.WithField("reconnect_decision", shouldReconnect).Debug("reconnect decision made")
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if shouldReconnect {
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run.waitReconnect.Set(time.Now(), config.ReconnectHardFailTimeout)
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log.WithField("deadline", run.waitReconnect.End()).Error("temporary connectivity-related error identified, start waiting for reconnect")
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var connectErr error
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var connectErrTime time.Time
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run.l.DropWhile(func() {
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ctx, cancel := run.waitReconnect.ContextWithDeadlineAtEnd(ctx)
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defer cancel()
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connectErr = planner.WaitForConnectivity(ctx)
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connectErrTime = time.Now()
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})
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if connectErr == nil {
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log.Error("reconnect successful") // same level as 'begin with reconnect' message above
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continue
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} else {
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run.waitReconnectError = newTimedError(connectErr, connectErrTime)
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log.WithError(connectErr).Error("reconnecting failed, aborting run")
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break
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}
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} else {
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log.Error("most recent error cannot be solved by reconnecting, aborting run")
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return
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}
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}
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}()
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wait := func(block bool) bool {
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if block {
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<-done
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}
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select {
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case <-done:
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return true
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default:
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return false
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}
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}
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report := func() *report.Report {
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defer run.l.Lock().Unlock()
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return run.report()
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}
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return report, wait
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}
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func (a *attempt) do(ctx context.Context, prev *attempt) {
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prevs := a.doGlobalPlanning(ctx, prev)
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if prevs == nil {
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return
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}
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a.doFilesystems(ctx, prevs)
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}
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// if no error occurs, returns a map that maps this attempt's a.fss to `prev`'s a.fss
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func (a *attempt) doGlobalPlanning(ctx context.Context, prev *attempt) map[*fs]*fs {
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ctx, endSpan := trace.WithSpan(ctx, "plan")
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defer endSpan()
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pfss, err := a.planner.Plan(ctx)
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errTime := time.Now()
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defer a.l.Lock().Unlock()
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if err != nil {
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a.planErr = newTimedError(err, errTime)
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a.fss = nil
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a.finishedAt = time.Now()
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return nil
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}
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// a.fss != nil indicates that there was no planning error (see doc comment)
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a.fss = make([]*fs, 0)
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for _, pfs := range pfss {
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fs := &fs{
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fs: pfs,
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l: a.l,
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blockedOn: report.FsBlockedOnNothing,
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}
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fs.initialRepOrd.parentDidUpdate = make(chan struct{}, 1)
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a.fss = append(a.fss, fs)
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}
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prevs := make(map[*fs]*fs)
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{
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prevFSs := make(map[*fs][]*fs, len(pfss))
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if prev != nil {
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debug("previous attempt has %d fss", len(a.fss))
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for _, fs := range a.fss {
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for _, prevFS := range prev.fss {
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if fs.fs.EqualToPreviousAttempt(prevFS.fs) {
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l := prevFSs[fs]
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l = append(l, prevFS)
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prevFSs[fs] = l
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}
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}
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}
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}
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type inconsistency struct {
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cur *fs
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prevs []*fs
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}
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var inconsistencies []inconsistency
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for cur, fss := range prevFSs {
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if len(fss) > 1 {
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inconsistencies = append(inconsistencies, inconsistency{cur, fss})
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}
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}
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sort.SliceStable(inconsistencies, func(i, j int) bool {
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return inconsistencies[i].cur.fs.ReportInfo().Name < inconsistencies[j].cur.fs.ReportInfo().Name
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})
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if len(inconsistencies) > 0 {
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var msg strings.Builder
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msg.WriteString("cannot determine filesystem correspondences between different attempts:\n")
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var inconsistencyLines []string
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for _, i := range inconsistencies {
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var prevNames []string
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for _, prev := range i.prevs {
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prevNames = append(prevNames, prev.fs.ReportInfo().Name)
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}
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l := fmt.Sprintf(" %s => %v", i.cur.fs.ReportInfo().Name, prevNames)
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inconsistencyLines = append(inconsistencyLines, l)
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}
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fmt.Fprint(&msg, strings.Join(inconsistencyLines, "\n"))
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now := time.Now()
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a.planErr = newTimedError(errors.New(msg.String()), now)
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a.fss = nil
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a.finishedAt = now
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return nil
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}
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for cur, fss := range prevFSs {
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if len(fss) > 0 {
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prevs[cur] = fss[0]
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}
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}
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}
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// invariant: prevs contains an entry for each unambiguous correspondence
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// build up parent-child relationship (FIXME (O(n^2), but who's going to have that many filesystems...))
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mustDatasetPathOrPlanFail := func(fs string) *zfs.DatasetPath {
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dp, err := zfs.NewDatasetPath(fs)
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if err != nil {
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now := time.Now()
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a.planErr = newTimedError(errors.Wrapf(err, "%q", fs), now)
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a.fss = nil
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a.finishedAt = now
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return nil
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}
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return dp
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}
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for _, f1 := range a.fss {
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fs1 := mustDatasetPathOrPlanFail(f1.fs.ReportInfo().Name)
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if fs1 == nil {
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return nil
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}
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for _, f2 := range a.fss {
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fs2 := mustDatasetPathOrPlanFail(f2.fs.ReportInfo().Name)
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if fs2 == nil {
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return nil
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}
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if fs1.HasPrefix(fs2) && !fs1.Equal(fs2) {
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f1.initialRepOrd.parents = append(f1.initialRepOrd.parents, f2)
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f2.initialRepOrd.children = append(f2.initialRepOrd.children, f1)
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}
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}
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}
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return prevs
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}
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func (a *attempt) doFilesystems(ctx context.Context, prevs map[*fs]*fs) {
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ctx, endSpan := trace.WithSpan(ctx, "do-repl")
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defer endSpan()
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defer a.l.Lock().Unlock()
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stepQueue := newStepQueue()
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defer stepQueue.Start(a.config.StepQueueConcurrency)()
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var fssesDone sync.WaitGroup
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for _, f := range a.fss {
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fssesDone.Add(1)
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go func(f *fs) {
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defer fssesDone.Done()
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// avoid explosion of tasks with name f.report().Info.Name
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ctx, endTask := trace.WithTaskAndSpan(ctx, "repl-fs", f.report().Info.Name)
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defer endTask()
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f.do(ctx, stepQueue, prevs[f])
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f.l.HoldWhile(func() {
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// every return from f means it's unblocked...
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f.blockedOn = report.FsBlockedOnNothing
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})
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}(f)
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}
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a.l.DropWhile(func() {
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fssesDone.Wait()
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})
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a.finishedAt = time.Now()
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}
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func (f *fs) debug(format string, args ...interface{}) {
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debugPrefix("fs=%s", f.fs.ReportInfo().Name)(format, args...)
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}
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// wake up children that watch for f.{planning.{err,done},planned.{step,stepErr}}
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func (f *fs) initialRepOrdWakeupChildren() {
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var children []string
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for _, c := range f.initialRepOrd.children {
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// no locking required, c.fs does not change
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children = append(children, c.fs.ReportInfo().Name)
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}
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f.debug("wakeup children %s", children)
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for _, child := range f.initialRepOrd.children {
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select {
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// no locking required, child.initialRepOrd does not change
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case child.initialRepOrd.parentDidUpdate <- struct{}{}:
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default:
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}
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}
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}
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func (f *fs) do(ctx context.Context, pq *stepQueue, prev *fs) {
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defer f.l.Lock().Unlock()
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defer f.initialRepOrdWakeupChildren()
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// get planned steps from replication logic
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var psteps []Step
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var errTime time.Time
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var err error
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f.blockedOn = report.FsBlockedOnPlanningStepQueue
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f.l.DropWhile(func() {
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// TODO hacky
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// choose target time that is earlier than any snapshot, so fs planning is always prioritized
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targetDate := time.Unix(0, 0)
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defer pq.WaitReady(ctx, f, targetDate)()
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f.l.HoldWhile(func() {
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// transition before we call PlanFS
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f.blockedOn = report.FsBlockedOnNothing
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})
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psteps, err = f.fs.PlanFS(ctx) // no shadow
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errTime = time.Now() // no shadow
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})
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if err != nil {
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f.planning.err = newTimedError(err, errTime)
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return
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}
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for _, pstep := range psteps {
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step := &step{
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l: f.l,
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step: pstep,
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}
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f.planned.steps = append(f.planned.steps, step)
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}
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// we're not done planning yet, f.planned.steps might still be changed by next block
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// => don't set f.planning.done just yet
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f.debug("initial len(fs.planned.steps) = %d", len(f.planned.steps))
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// for not-first attempts that succeeded in planning, only allow fs.planned.steps
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// up to and including the originally planned target snapshot
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if prev != nil && prev.planning.done && prev.planning.err == nil {
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f.debug("attempting to correlate plan with previous attempt to find out what is left to do")
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// find the highest of the previously uncompleted steps for which we can also find a step
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// in our current plan
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prevUncompleted := prev.planned.steps[prev.planned.step:]
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var target struct{ prev, cur int }
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target.prev = -1
|
|
target.cur = -1
|
|
out:
|
|
for p := len(prevUncompleted) - 1; p >= 0; p-- {
|
|
for q := len(f.planned.steps) - 1; q >= 0; q-- {
|
|
if prevUncompleted[p].step.TargetEquals(f.planned.steps[q].step) {
|
|
target.prev = p
|
|
target.cur = q
|
|
break out
|
|
}
|
|
}
|
|
}
|
|
if target.prev == -1 || target.cur == -1 {
|
|
f.debug("no correlation possible between previous attempt and this attempt's plan")
|
|
f.planning.err = newTimedError(fmt.Errorf("cannot correlate previously failed attempt to current plan"), time.Now())
|
|
return
|
|
}
|
|
|
|
f.planned.steps = f.planned.steps[0:target.cur]
|
|
f.debug("found correlation, new steps are len(fs.planned.steps) = %d", len(f.planned.steps))
|
|
} else {
|
|
f.debug("previous attempt does not exist or did not finish planning, no correlation possible, taking this attempt's plan as is")
|
|
}
|
|
|
|
// now we are done planning (f.planned.steps won't change from now on)
|
|
f.planning.done = true
|
|
|
|
// wait for parents' initial replication
|
|
f.blockedOn = report.FsBlockedOnParentInitialRepl
|
|
var parents []string
|
|
for _, p := range f.initialRepOrd.parents {
|
|
parents = append(parents, p.fs.ReportInfo().Name)
|
|
}
|
|
f.debug("wait for parents %s", parents)
|
|
for {
|
|
var initialReplicatingParentsWithErrors []string
|
|
allParentsPresentOnReceiver := true
|
|
f.l.DropWhile(func() {
|
|
for _, p := range f.initialRepOrd.parents {
|
|
p.l.HoldWhile(func() {
|
|
// (get the preconditions that allow us to inspect p.planned)
|
|
parentHasPlanningDone := p.planning.done && p.planning.err == nil
|
|
if !parentHasPlanningDone {
|
|
// if the parent couldn't be planned, we cannot know whether it needs initial replication
|
|
// or incremental replication => be conservative and assume it was initial replication
|
|
allParentsPresentOnReceiver = false
|
|
if p.planning.err != nil {
|
|
initialReplicatingParentsWithErrors = append(initialReplicatingParentsWithErrors, p.fs.ReportInfo().Name)
|
|
}
|
|
return
|
|
}
|
|
// now allowed to inspect p.planned
|
|
|
|
// if there are no steps to be done, the filesystem must exist on the receiving side
|
|
// (otherwise we'd replicate it, and there would be a step for that)
|
|
// (FIXME hardcoded initial replication policy, assuming the policy will always do _some_ initial replication)
|
|
parentHasNoSteps := len(p.planned.steps) == 0
|
|
|
|
// OR if it has completed at least one step
|
|
// (remember that .step points to the next step to be done)
|
|
// (TODO technically, we could make this step ready in the moment the recv-side
|
|
// dataset exists, i.e. after the first few megabytes of transferred data, but we'd have to ask the receiver for that -> poll ListFilesystems RPC)
|
|
parentHasTakenAtLeastOneSuccessfulStep := !parentHasNoSteps && p.planned.step >= 1
|
|
|
|
parentFirstStepIsIncremental := // no need to lock for .report() because step.l == it's fs.l
|
|
len(p.planned.steps) > 0 && p.planned.steps[0].report().IsIncremental()
|
|
|
|
f.debug("parentHasNoSteps=%v parentFirstStepIsIncremental=%v parentHasTakenAtLeastOneSuccessfulStep=%v",
|
|
parentHasNoSteps, parentFirstStepIsIncremental, parentHasTakenAtLeastOneSuccessfulStep)
|
|
|
|
parentPresentOnReceiver := parentHasNoSteps || parentFirstStepIsIncremental || parentHasTakenAtLeastOneSuccessfulStep
|
|
|
|
allParentsPresentOnReceiver = allParentsPresentOnReceiver && parentPresentOnReceiver // no shadow
|
|
|
|
if !parentPresentOnReceiver && p.planned.stepErr != nil {
|
|
initialReplicatingParentsWithErrors = append(initialReplicatingParentsWithErrors, p.fs.ReportInfo().Name)
|
|
}
|
|
|
|
})
|
|
}
|
|
})
|
|
|
|
if len(initialReplicatingParentsWithErrors) > 0 {
|
|
f.planned.stepErr = newTimedError(fmt.Errorf("parent(s) failed during initial replication: %s", initialReplicatingParentsWithErrors), time.Now())
|
|
return
|
|
}
|
|
|
|
if allParentsPresentOnReceiver {
|
|
break // good to go
|
|
}
|
|
|
|
// wait for wakeups from parents, then check again
|
|
// lock must not be held while waiting in order for reporting to work
|
|
f.l.DropWhile(func() {
|
|
select {
|
|
case <-ctx.Done():
|
|
f.planned.stepErr = newTimedError(ctx.Err(), time.Now())
|
|
case <-f.initialRepOrd.parentDidUpdate:
|
|
// loop
|
|
}
|
|
})
|
|
if f.planned.stepErr != nil {
|
|
return
|
|
}
|
|
}
|
|
|
|
f.debug("all parents ready, start replication %s", parents)
|
|
|
|
// do our steps
|
|
for i, s := range f.planned.steps {
|
|
// lock must not be held while executing step in order for reporting to work
|
|
f.l.DropWhile(func() {
|
|
// wait for parallel replication
|
|
targetDate := s.step.TargetDate()
|
|
f.l.HoldWhile(func() { f.blockedOn = report.FsBlockedOnReplStepQueue })
|
|
defer pq.WaitReady(ctx, f, targetDate)()
|
|
f.l.HoldWhile(func() { f.blockedOn = report.FsBlockedOnNothing })
|
|
// do the step
|
|
ctx, endSpan := trace.WithSpan(ctx, fmt.Sprintf("%#v", s.step.ReportInfo()))
|
|
defer endSpan()
|
|
err, errTime = s.step.Step(ctx), time.Now() // no shadow
|
|
})
|
|
|
|
if err != nil {
|
|
f.planned.stepErr = newTimedError(err, errTime)
|
|
break
|
|
}
|
|
f.planned.step = i + 1 // fs.planned.step must be == len(fs.planned.steps) if all went OK
|
|
|
|
f.initialRepOrdWakeupChildren()
|
|
}
|
|
|
|
}
|
|
|
|
// caller must hold lock l
|
|
func (r *run) report() *report.Report {
|
|
report := &report.Report{
|
|
Attempts: make([]*report.AttemptReport, len(r.attempts)),
|
|
StartAt: r.startedAt,
|
|
FinishAt: r.finishedAt,
|
|
WaitReconnectSince: r.waitReconnect.begin,
|
|
WaitReconnectUntil: r.waitReconnect.end,
|
|
WaitReconnectError: r.waitReconnectError.IntoReportError(),
|
|
}
|
|
for i := range report.Attempts {
|
|
report.Attempts[i] = r.attempts[i].report()
|
|
}
|
|
return report
|
|
}
|
|
|
|
// caller must hold lock l
|
|
func (a *attempt) report() *report.AttemptReport {
|
|
|
|
r := &report.AttemptReport{
|
|
// State is set below
|
|
Filesystems: make([]*report.FilesystemReport, len(a.fss)),
|
|
StartAt: a.startedAt,
|
|
FinishAt: a.finishedAt,
|
|
PlanError: a.planErr.IntoReportError(),
|
|
}
|
|
|
|
for i := range r.Filesystems {
|
|
r.Filesystems[i] = a.fss[i].report()
|
|
}
|
|
|
|
var state report.AttemptState
|
|
if a.planErr == nil && a.fss == nil {
|
|
state = report.AttemptPlanning
|
|
} else if a.planErr != nil && a.fss == nil {
|
|
state = report.AttemptPlanningError
|
|
} else if a.planErr == nil && a.fss != nil {
|
|
if a.finishedAt.IsZero() {
|
|
state = report.AttemptFanOutFSs
|
|
} else {
|
|
fsWithError := false
|
|
for _, s := range r.Filesystems {
|
|
fsWithError = fsWithError || s.Error() != nil
|
|
}
|
|
state = report.AttemptDone
|
|
if fsWithError {
|
|
state = report.AttemptFanOutError
|
|
}
|
|
}
|
|
} else {
|
|
panic(fmt.Sprintf("attempt.planErr and attempt.fss must not both be != nil:\n%s\n%s", pretty.Sprint(a.planErr), pretty.Sprint(a.fss)))
|
|
}
|
|
r.State = state
|
|
|
|
return r
|
|
}
|
|
|
|
// caller must hold lock l
|
|
func (f *fs) report() *report.FilesystemReport {
|
|
state := report.FilesystemPlanningErrored
|
|
if f.planning.err == nil {
|
|
if f.planning.done {
|
|
if f.planned.stepErr != nil {
|
|
state = report.FilesystemSteppingErrored
|
|
} else if f.planned.step < len(f.planned.steps) {
|
|
state = report.FilesystemStepping
|
|
} else {
|
|
state = report.FilesystemDone
|
|
}
|
|
} else {
|
|
state = report.FilesystemPlanning
|
|
}
|
|
}
|
|
r := &report.FilesystemReport{
|
|
Info: f.fs.ReportInfo(),
|
|
State: state,
|
|
BlockedOn: f.blockedOn,
|
|
PlanError: f.planning.err.IntoReportError(),
|
|
StepError: f.planned.stepErr.IntoReportError(),
|
|
Steps: make([]*report.StepReport, len(f.planned.steps)),
|
|
CurrentStep: f.planned.step,
|
|
}
|
|
for i := range r.Steps {
|
|
r.Steps[i] = f.planned.steps[i].report()
|
|
}
|
|
return r
|
|
}
|
|
|
|
// caller must hold lock l
|
|
func (s *step) report() *report.StepReport {
|
|
r := &report.StepReport{
|
|
Info: s.step.ReportInfo(),
|
|
}
|
|
return r
|
|
}
|
|
|
|
//go:generate enumer -type=errorClass
|
|
type errorClass int
|
|
|
|
const (
|
|
errorClassPermanent errorClass = iota
|
|
errorClassTemporaryConnectivityRelated
|
|
)
|
|
|
|
type errorReport struct {
|
|
flattened []*timedError
|
|
// sorted DESCending by err time
|
|
byClass map[errorClass][]*timedError
|
|
}
|
|
|
|
// caller must hold lock l
|
|
func (a *attempt) errorReport() *errorReport {
|
|
r := &errorReport{}
|
|
if a.planErr != nil {
|
|
r.flattened = append(r.flattened, a.planErr)
|
|
}
|
|
for _, fs := range a.fss {
|
|
if fs.planning.done && fs.planning.err != nil {
|
|
r.flattened = append(r.flattened, fs.planning.err)
|
|
} else if fs.planning.done && fs.planned.stepErr != nil {
|
|
r.flattened = append(r.flattened, fs.planned.stepErr)
|
|
}
|
|
}
|
|
|
|
// build byClass
|
|
{
|
|
r.byClass = make(map[errorClass][]*timedError)
|
|
putClass := func(err *timedError, class errorClass) {
|
|
errs := r.byClass[class]
|
|
errs = append(errs, err)
|
|
r.byClass[class] = errs
|
|
}
|
|
for _, err := range r.flattened {
|
|
if neterr, ok := err.Err.(net.Error); ok && neterr.Temporary() {
|
|
putClass(err, errorClassTemporaryConnectivityRelated)
|
|
continue
|
|
}
|
|
if st, ok := status.FromError(err.Err); ok && st.Code() == codes.Unavailable {
|
|
// technically, codes.Unavailable could be returned by the gRPC endpoint, indicating overload, etc.
|
|
// for now, let's assume it only happens for connectivity issues, as specified in
|
|
// https://grpc.io/grpc/core/md_doc_statuscodes.html
|
|
putClass(err, errorClassTemporaryConnectivityRelated)
|
|
continue
|
|
}
|
|
putClass(err, errorClassPermanent)
|
|
}
|
|
for _, errs := range r.byClass {
|
|
sort.Slice(errs, func(i, j int) bool {
|
|
return errs[i].Time.After(errs[j].Time) // sort descendingly
|
|
})
|
|
}
|
|
}
|
|
|
|
return r
|
|
}
|
|
|
|
func (r *errorReport) AnyError() *timedError {
|
|
for _, err := range r.flattened {
|
|
if err != nil {
|
|
return err
|
|
}
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func (r *errorReport) MostRecent() (err *timedError, errClass errorClass) {
|
|
for class, errs := range r.byClass {
|
|
// errs are sorted descendingly during construction
|
|
if len(errs) > 0 && (err == nil || errs[0].Time.After(err.Time)) {
|
|
err = errs[0]
|
|
errClass = class
|
|
}
|
|
}
|
|
return
|
|
}
|