zrepl/pruning/keep_grid.go

package pruning

import (
	"fmt"
	"regexp"
	"sort"
	"time"

	"github.com/pkg/errors"

	"github.com/zrepl/zrepl/config"
	"github.com/zrepl/zrepl/pruning/retentiongrid"
)

// KeepGrid fits snapshots that match a given regex into a retentiongrid.Grid,
// uses the most recent snapshot among those that match the regex as 'now',
// and deletes all snapshots that do not fit the grid specification.
type KeepGrid struct {
	retentionGrid *retentiongrid.Grid
	re            *regexp.Regexp
}

func NewKeepGrid(in *config.PruneGrid) (p *KeepGrid, err error) {

	if in.Regex == "" {
		return nil, fmt.Errorf("Regex must not be empty")
	}
	re, err := regexp.Compile(in.Regex)
	if err != nil {
		return nil, errors.Wrap(err, "Regex is invalid")
	}

	// Assert intervals are of increasing length (not necessarily required, but indicates config mistake)
	lastDuration := time.Duration(0)
	for i := range in.Grid {

		if in.Grid[i].Length() < lastDuration {
			// If all intervals before were keep=all, this is ok
			allPrevKeepCountAll := true
			for j := i - 1; allPrevKeepCountAll && j >= 0; j-- {
				allPrevKeepCountAll = in.Grid[j].KeepCount() == config.RetentionGridKeepCountAll
			}
			if allPrevKeepCountAll {
				goto isMonotonicIncrease
			}
			err = errors.New("retention grid interval length must be monotonically increasing")
			return
		}
	isMonotonicIncrease:
		lastDuration = in.Grid[i].Length()

	}

	retentionIntervals := make([]retentiongrid.Interval, len(in.Grid))
	for i := range in.Grid {
		retentionIntervals[i] = &in.Grid[i]
	}

	return &KeepGrid{
		retentiongrid.NewGrid(retentionIntervals),
		re,
	}, nil
}

type retentionGridAdaptor struct {
	Snapshot
}

func (a retentionGridAdaptor) LessThan(b retentiongrid.Entry) bool {
	return a.Date().Before(b.Date())
}

// Prune filters snapshots with the retention grid.
func (p *KeepGrid) KeepRule(snaps []Snapshot) (destroyList []Snapshot) {

	snaps = filterSnapList(snaps, func(snapshot Snapshot) bool {
		return p.re.MatchString(snapshot.Name())
	})
	if len(snaps) == 0 {
		return nil
	}

	// Build adaptors for retention grid
	adaptors := make([]retentiongrid.Entry, 0)
	for i := range snaps {
		adaptors = append(adaptors, retentionGridAdaptor{snaps[i]})
	}

	// determine 'now' edge
	sort.SliceStable(adaptors, func(i, j int) bool {
		return adaptors[i].LessThan(adaptors[j])
	})
	now := adaptors[len(adaptors)-1].Date()

	// Evaluate retention grid
	_, removea := p.retentionGrid.FitEntries(now, adaptors)

	// Revert adaptors
	destroyList = make([]Snapshot, len(removea))
	for i := range removea {
		destroyList[i] = removea[i].(retentionGridAdaptor).Snapshot
	}
	return destroyList
}
pruning: implement 'grid' keep rule 2018-09-24 17:30:03 +02:00			`package pruning`

			`import (`
			`"fmt"`
			`"regexp"`
			`"sort"`
			`"time"`
format source tree using goimports 2019-03-22 19:41:12 +01:00
			`"github.com/pkg/errors"`

			`"github.com/zrepl/zrepl/config"`
			`"github.com/zrepl/zrepl/pruning/retentiongrid"`
pruning: implement 'grid' keep rule 2018-09-24 17:30:03 +02:00			`)`

			`// KeepGrid fits snapshots that match a given regex into a retentiongrid.Grid,`
			`// uses the most recent snapshot among those that match the regex as 'now',`
			`// and deletes all snapshots that do not fit the grid specification.`
			`type KeepGrid struct {`
			`retentionGrid *retentiongrid.Grid`
format source tree using goimports 2019-03-22 19:41:12 +01:00			`re *regexp.Regexp`
pruning: implement 'grid' keep rule 2018-09-24 17:30:03 +02:00			`}`

			`func NewKeepGrid(in config.PruneGrid) (p KeepGrid, err error) {`

			`if in.Regex == "" {`
			`return nil, fmt.Errorf("Regex must not be empty")`
			`}`
			`re, err := regexp.Compile(in.Regex)`
			`if err != nil {`
			`return nil, errors.Wrap(err, "Regex is invalid")`
			`}`

			`// Assert intervals are of increasing length (not necessarily required, but indicates config mistake)`
			`lastDuration := time.Duration(0)`
			`for i := range in.Grid {`

			`if in.Grid[i].Length() < lastDuration {`
			`// If all intervals before were keep=all, this is ok`
			`allPrevKeepCountAll := true`
			`for j := i - 1; allPrevKeepCountAll && j >= 0; j-- {`
			`allPrevKeepCountAll = in.Grid[j].KeepCount() == config.RetentionGridKeepCountAll`
			`}`
			`if allPrevKeepCountAll {`
			`goto isMonotonicIncrease`
			`}`
			`err = errors.New("retention grid interval length must be monotonically increasing")`
			`return`
			`}`
			`isMonotonicIncrease:`
			`lastDuration = in.Grid[i].Length()`

			`}`

			`retentionIntervals := make([]retentiongrid.Interval, len(in.Grid))`
			`for i := range in.Grid {`
			`retentionIntervals[i] = &in.Grid[i]`
			`}`

			`return &KeepGrid{`
			`retentiongrid.NewGrid(retentionIntervals),`
			`re,`
			`}, nil`
			`}`

			`type retentionGridAdaptor struct {`
			`Snapshot`
			`}`

			`func (a retentionGridAdaptor) LessThan(b retentiongrid.Entry) bool {`
			`return a.Date().Before(b.Date())`
			`}`

			`// Prune filters snapshots with the retention grid.`
			`func (p *KeepGrid) KeepRule(snaps []Snapshot) (destroyList []Snapshot) {`

			`snaps = filterSnapList(snaps, func(snapshot Snapshot) bool {`
			`return p.re.MatchString(snapshot.Name())`
			`})`
			`if len(snaps) == 0 {`
			`return nil`
			`}`

			`// Build adaptors for retention grid`
			`adaptors := make([]retentiongrid.Entry, 0)`
			`for i := range snaps {`
			`adaptors = append(adaptors, retentionGridAdaptor{snaps[i]})`
			`}`

			`// determine 'now' edge`
			`sort.SliceStable(adaptors, func(i, j int) bool {`
			`return adaptors[i].LessThan(adaptors[j])`
			`})`
			`now := adaptors[len(adaptors)-1].Date()`

			`// Evaluate retention grid`
			`_, removea := p.retentionGrid.FitEntries(now, adaptors)`

			`// Revert adaptors`
			`destroyList = make([]Snapshot, len(removea))`
			`for i := range removea {`
			`destroyList[i] = removea[i].(retentionGridAdaptor).Snapshot`
			`}`
			`return destroyList`
			`}`