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// Copyright (C) 2022-2023 Luke Shumaker <lukeshu@lukeshu.com>
//
// SPDX-License-Identifier: GPL-2.0-or-later
package btrfsutil
import (
"context"
"fmt"
"sync"
"time"
"github.com/datawire/dlib/dlog"
"git.lukeshu.com/btrfs-progs-ng/lib/btrfs/btrfsitem"
"git.lukeshu.com/btrfs-progs-ng/lib/btrfs/btrfsprim"
"git.lukeshu.com/btrfs-progs-ng/lib/btrfs/btrfsvol"
"git.lukeshu.com/btrfs-progs-ng/lib/containers"
"git.lukeshu.com/btrfs-progs-ng/lib/maps"
"git.lukeshu.com/btrfs-progs-ng/lib/slices"
"git.lukeshu.com/btrfs-progs-ng/lib/textui"
)
type RebuiltTree struct {
// static
ID btrfsprim.ObjID
UUID btrfsprim.UUID
Parent *RebuiltTree
ParentGen btrfsprim.Generation // offset of this tree's root item
forrest *RebuiltForrest
// mutable
mu sync.RWMutex
Roots containers.Set[btrfsvol.LogicalAddr]
// There are 3 more mutable "members" that are protected by
// `mu`; but they live in a shared ARCache. They are all
// derived from tree.Roots, which is why it's OK if they get
// evicted.
//
// 1. tree.leafToRoots() = tree.forrest.leafs.Load(tree.ID)
// 2. tree.RebuiltItems() = tree.forrest.incItems.Load(tree.ID)
// 3. tree.RebuiltPotentialItems() = tree.forrest.excItems.Load(tree.ID)
}
// evictable member 1: .leafToRoots() //////////////////////////////////////////////////////////////////////////////////
// leafToRoots returns all leafs (lvl=0) in the filesystem that pass
// .isOwnerOK, whether or not they're in the tree.
func (tree *RebuiltTree) leafToRoots(ctx context.Context) map[btrfsvol.LogicalAddr]containers.Set[btrfsvol.LogicalAddr] {
ret := *tree.forrest.leafs.Acquire(ctx, tree.ID)
tree.forrest.leafs.Release(tree.ID)
return ret
}
func (tree *RebuiltTree) uncachedLeafToRoots(ctx context.Context) map[btrfsvol.LogicalAddr]containers.Set[btrfsvol.LogicalAddr] {
ctx = dlog.WithField(ctx, "btrfs.util.rebuilt-tree.index-nodes", fmt.Sprintf("tree=%v", tree.ID))
nodeToRoots := make(map[btrfsvol.LogicalAddr]containers.Set[btrfsvol.LogicalAddr])
var stats textui.Portion[int]
stats.D = len(tree.forrest.graph.Nodes)
progressWriter := textui.NewProgress[textui.Portion[int]](ctx, dlog.LogLevelInfo, textui.Tunable(1*time.Second))
progress := func() {
stats.N = len(nodeToRoots)
progressWriter.Set(stats)
}
progress()
for _, node := range maps.SortedKeys(tree.forrest.graph.Nodes) {
tree.indexNode(ctx, node, nodeToRoots, progress, nil)
}
progressWriter.Done()
ret := make(map[btrfsvol.LogicalAddr]containers.Set[btrfsvol.LogicalAddr])
for node, roots := range nodeToRoots {
if tree.forrest.graph.Nodes[node].Level == 0 && len(roots) > 0 {
ret[node] = roots
}
}
return ret
}
func (tree *RebuiltTree) indexNode(ctx context.Context, node btrfsvol.LogicalAddr, index map[btrfsvol.LogicalAddr]containers.Set[btrfsvol.LogicalAddr], progress func(), stack []btrfsvol.LogicalAddr) {
defer progress()
if err := ctx.Err(); err != nil {
return
}
if _, done := index[node]; done {
return
}
if slices.Contains(node, stack) {
// This is a panic because tree.forrest.graph.FinalCheck() should
// have already checked for loops.
panic("loop")
}
if !tree.isOwnerOK(tree.forrest.graph.Nodes[node].Owner, tree.forrest.graph.Nodes[node].Generation) {
index[node] = nil
return
}
// tree.leafToRoots
stack = append(stack, node)
var roots containers.Set[btrfsvol.LogicalAddr]
for _, kp := range tree.forrest.graph.EdgesTo[node] {
if !tree.isOwnerOK(tree.forrest.graph.Nodes[kp.FromNode].Owner, tree.forrest.graph.Nodes[kp.FromNode].Generation) {
continue
}
tree.indexNode(ctx, kp.FromNode, index, progress, stack)
if len(index[kp.FromNode]) > 0 {
if roots == nil {
roots = make(containers.Set[btrfsvol.LogicalAddr])
}
roots.InsertFrom(index[kp.FromNode])
}
}
if roots == nil {
roots = containers.NewSet[btrfsvol.LogicalAddr](node)
}
index[node] = roots
}
// isOwnerOK returns whether it is permissible for a node with
// .Head.Owner=owner to be in this tree.
func (tree *RebuiltTree) isOwnerOK(owner btrfsprim.ObjID, gen btrfsprim.Generation) bool {
for {
if owner == tree.ID {
return true
}
if tree.Parent == nil || gen > tree.ParentGen {
return false
}
tree = tree.Parent
}
}
// evictable members 2 and 3: .RebuiltItems() and .RebuiltPotentialItems() /////////////////////////////////////////////
// RebuiltItems returns a map of the items contained in this tree.
//
// Do not mutate the returned map; it is a pointer to the
// RebuiltTree's internal map!
func (tree *RebuiltTree) RebuiltItems(ctx context.Context) *containers.SortedMap[btrfsprim.Key, ItemPtr] {
ret := *tree.forrest.incItems.Acquire(ctx, tree.ID)
tree.forrest.incItems.Release(tree.ID)
return ret
}
// RebuiltPotentialItems returns a map of items that could be added to
// this tree with .RebuiltAddRoot().
//
// Do not mutate the returned map; it is a pointer to the
// RebuiltTree's internal map!
func (tree *RebuiltTree) RebuiltPotentialItems(ctx context.Context) *containers.SortedMap[btrfsprim.Key, ItemPtr] {
ret := *tree.forrest.excItems.Acquire(ctx, tree.ID)
tree.forrest.excItems.Release(tree.ID)
return ret
}
func (tree *RebuiltTree) uncachedIncItems(ctx context.Context) *containers.SortedMap[btrfsprim.Key, ItemPtr] {
ctx = dlog.WithField(ctx, "btrfs.util.rebuilt-tree.index-inc-items", fmt.Sprintf("tree=%v", tree.ID))
return tree.items(ctx, tree.Roots.HasAny)
}
func (tree *RebuiltTree) uncachedExcItems(ctx context.Context) *containers.SortedMap[btrfsprim.Key, ItemPtr] {
ctx = dlog.WithField(ctx, "btrfs.util.rebuilt-tree.index-exc-items", fmt.Sprintf("tree=%v", tree.ID))
return tree.items(ctx,
func(roots containers.Set[btrfsvol.LogicalAddr]) bool {
return !tree.Roots.HasAny(roots)
})
}
type itemIndex = *containers.SortedMap[btrfsprim.Key, ItemPtr]
type itemStats struct {
Leafs textui.Portion[int]
NumItems int
NumDups int
}
func (s itemStats) String() string {
return textui.Sprintf("%v (%v items, %v dups)",
s.Leafs, s.NumItems, s.NumDups)
}
func (tree *RebuiltTree) items(ctx context.Context, leafFn func(roots containers.Set[btrfsvol.LogicalAddr]) bool) *containers.SortedMap[btrfsprim.Key, ItemPtr] {
tree.mu.RLock()
defer tree.mu.RUnlock()
var leafs []btrfsvol.LogicalAddr
for leaf, roots := range tree.leafToRoots(ctx) {
if leafFn(roots) {
leafs = append(leafs, leaf)
}
}
slices.Sort(leafs)
var stats itemStats
stats.Leafs.D = len(leafs)
progressWriter := textui.NewProgress[itemStats](ctx, dlog.LogLevelInfo, textui.Tunable(1*time.Second))
index := new(containers.SortedMap[btrfsprim.Key, ItemPtr])
for i, leaf := range leafs {
stats.Leafs.N = i
progressWriter.Set(stats)
for j, itemKey := range tree.forrest.graph.Nodes[leaf].Items {
newPtr := ItemPtr{
Node: leaf,
Slot: j,
}
if oldPtr, exists := index.Load(itemKey); !exists {
index.Store(itemKey, newPtr)
stats.NumItems++
} else {
if tree.RebuiltShouldReplace(oldPtr.Node, newPtr.Node) {
index.Store(itemKey, newPtr)
}
stats.NumDups++
}
progressWriter.Set(stats)
}
}
if stats.Leafs.N > 0 {
stats.Leafs.N = len(leafs)
progressWriter.Set(stats)
progressWriter.Done()
}
return index
}
// main public API /////////////////////////////////////////////////////////////////////////////////////////////////////
func (tree *RebuiltTree) RebuiltShouldReplace(oldNode, newNode btrfsvol.LogicalAddr) bool {
oldDist, _ := tree.RebuiltCOWDistance(tree.forrest.graph.Nodes[oldNode].Owner)
newDist, _ := tree.RebuiltCOWDistance(tree.forrest.graph.Nodes[newNode].Owner)
switch {
case newDist < oldDist:
// Replace the old one with the new lower-dist one.
return true
case newDist > oldDist:
// Retain the old lower-dist one.
return false
default:
oldGen := tree.forrest.graph.Nodes[oldNode].Generation
newGen := tree.forrest.graph.Nodes[newNode].Generation
switch {
case newGen > oldGen:
// Replace the old one with the new higher-gen one.
return true
case newGen < oldGen:
// Retain the old higher-gen one.
return false
default:
// TODO: This is a panic because I'm not really sure what the
// best way to handle this is, and so if this happens I want the
// program to crash and force me to figure out how to handle it.
panic(fmt.Errorf("dup nodes in tree=%v: old=%v=%v ; new=%v=%v",
tree.ID,
oldNode, tree.forrest.graph.Nodes[oldNode],
newNode, tree.forrest.graph.Nodes[newNode]))
}
}
}
type rootStats struct {
Leafs textui.Portion[int]
AddedLeafs int
AddedItems int
}
func (s rootStats) String() string {
return textui.Sprintf("%v (added %v leafs, added %v items)",
s.Leafs, s.AddedLeafs, s.AddedItems)
}
// RebuiltAddRoot adds an additional root node to the tree. It is
// useful to call .RebuiltAddRoot() to re-attach part of the tree that
// has been broken off.
func (tree *RebuiltTree) RebuiltAddRoot(ctx context.Context, rootNode btrfsvol.LogicalAddr) {
tree.mu.Lock()
defer tree.mu.Unlock()
ctx = dlog.WithField(ctx, "btrfs.util.rebuilt-tree.add-root", fmt.Sprintf("tree=%v rootNode=%v", tree.ID, rootNode))
dlog.Info(ctx, "adding root...")
leafToRoots := tree.leafToRoots(ctx)
var stats rootStats
stats.Leafs.D = len(leafToRoots)
progressWriter := textui.NewProgress[rootStats](ctx, dlog.LogLevelInfo, textui.Tunable(1*time.Second))
for i, leaf := range maps.SortedKeys(leafToRoots) {
stats.Leafs.N = i
progressWriter.Set(stats)
if tree.Roots.HasAny(leafToRoots[leaf]) || !leafToRoots[leaf].Has(rootNode) {
continue
}
stats.AddedLeafs++
progressWriter.Set(stats)
for _, itemKey := range tree.forrest.graph.Nodes[leaf].Items {
tree.forrest.cb.AddedItem(ctx, tree.ID, itemKey)
stats.AddedItems++
progressWriter.Set(stats)
}
}
stats.Leafs.N = len(leafToRoots)
progressWriter.Set(stats)
progressWriter.Done()
tree.Roots.Insert(rootNode)
tree.forrest.incItems.Delete(tree.ID) // force re-gen
tree.forrest.excItems.Delete(tree.ID) // force re-gen
if (tree.ID == btrfsprim.ROOT_TREE_OBJECTID || tree.ID == btrfsprim.UUID_TREE_OBJECTID) && stats.AddedItems > 0 {
tree.forrest.flushNegativeCache(ctx)
}
tree.forrest.cb.AddedRoot(ctx, tree.ID, rootNode)
}
// RebuiltCOWDistance returns how many COW-snapshots down the 'tree'
// is from the 'parent'.
func (tree *RebuiltTree) RebuiltCOWDistance(parentID btrfsprim.ObjID) (dist int, ok bool) {
for {
if parentID == tree.ID {
return dist, true
}
if tree.Parent == nil {
return 0, false
}
tree = tree.Parent
dist++
}
}
// ReadItem reads an item from a tree.
func (tree *RebuiltTree) ReadItem(ctx context.Context, key btrfsprim.Key) btrfsitem.Item {
ptr, ok := tree.RebuiltItems(ctx).Load(key)
if !ok {
panic(fmt.Errorf("should not happen: btrfsutil.RebuiltTree.ReadItem called for not-included key: %v", key))
}
return tree.forrest.readItem(ctx, ptr)
}
// RebuiltLeafToRoots returns the list of potential roots (to pass to
// .RebuiltAddRoot) that include a given leaf-node.
func (tree *RebuiltTree) RebuiltLeafToRoots(ctx context.Context, leaf btrfsvol.LogicalAddr) containers.Set[btrfsvol.LogicalAddr] {
if tree.forrest.graph.Nodes[leaf].Level != 0 {
panic(fmt.Errorf("should not happen: (tree=%v).RebuiltLeafToRoots(leaf=%v): not a leaf",
tree.ID, leaf))
}
tree.mu.RLock()
defer tree.mu.RUnlock()
ret := make(containers.Set[btrfsvol.LogicalAddr])
for root := range tree.leafToRoots(ctx)[leaf] {
if tree.Roots.Has(root) {
panic(fmt.Errorf("should not happen: (tree=%v).RebuiltLeafToRoots(leaf=%v): tree contains root=%v but not leaf",
tree.ID, leaf, root))
}
ret.Insert(root)
}
if len(ret) == 0 {
return nil
}
return ret
}
|