LCOV - code coverage report
Current view: top level - pebble/internal/manifest - btree.go (source / functions) Hit Total Coverage
Test: 2024-07-25 08:16Z 2752abb9 - tests only.lcov Lines: 720 800 90.0 %
Date: 2024-07-25 08:17:11 Functions: 0 0 -

          Line data    Source code
       1             : // Copyright 2020 The LevelDB-Go and Pebble Authors. All rights reserved. Use
       2             : // of this source code is governed by a BSD-style license that can be found in
       3             : // the LICENSE file.
       4             : 
       5             : package manifest
       6             : 
       7             : import (
       8             :         "bytes"
       9             :         stdcmp "cmp"
      10             :         "fmt"
      11             :         "strings"
      12             :         "sync/atomic"
      13             :         "unsafe"
      14             : 
      15             :         "github.com/cockroachdb/errors"
      16             :         "github.com/cockroachdb/pebble/internal/invariants"
      17             : )
      18             : 
      19             : // The Annotator type defined below is used by other packages to lazily
      20             : // compute a value over a B-Tree. Each node of the B-Tree stores one
      21             : // `annotation` per annotator, containing the result of the computation over
      22             : // the node's subtree.
      23             : //
      24             : // An annotation is marked as valid if it's current with the current subtree
      25             : // state. Annotations are marked as invalid whenever a node will be mutated
      26             : // (in mut).  Annotators may also return `false` from `Accumulate` to signal
      27             : // that a computation for a file is not stable and may change in the future.
      28             : // Annotations that include these unstable values are also marked as invalid
      29             : // on the node, ensuring that future queries for the annotation will recompute
      30             : // the value.
      31             : 
      32             : // An Annotator defines a computation over a level's FileMetadata. If the
      33             : // computation is stable and uses inputs that are fixed for the lifetime of
      34             : // a FileMetadata, the LevelMetadata's internal data structures are annotated
      35             : // with the intermediary computations. This allows the computation to be
      36             : // computed incrementally as edits are applied to a level.
      37             : type Annotator interface {
      38             :         // Zero returns the zero value of an annotation. This value is returned
      39             :         // when a LevelMetadata is empty. The dst argument, if non-nil, is an
      40             :         // obsolete value previously returned by this Annotator and may be
      41             :         // overwritten and reused to avoid a memory allocation.
      42             :         Zero(dst interface{}) (v interface{})
      43             : 
      44             :         // Accumulate computes the annotation for a single file in a level's
      45             :         // metadata. It merges the file's value into dst and returns a bool flag
      46             :         // indicating whether or not the value is stable and okay to cache as an
      47             :         // annotation. If the file's value may change over the life of the file,
      48             :         // the annotator must return false.
      49             :         //
      50             :         // Implementations may modify dst and return it to avoid an allocation.
      51             :         Accumulate(m *FileMetadata, dst interface{}) (v interface{}, cacheOK bool)
      52             : 
      53             :         // Merge combines two values src and dst, returning the result.
      54             :         // Implementations may modify dst and return it to avoid an allocation.
      55             :         Merge(src interface{}, dst interface{}) interface{}
      56             : }
      57             : 
      58             : type btreeCmp func(*FileMetadata, *FileMetadata) int
      59             : 
      60           1 : func btreeCmpSeqNum(a, b *FileMetadata) int {
      61           1 :         return a.cmpSeqNum(b)
      62           1 : }
      63             : 
      64           1 : func btreeCmpSmallestKey(cmp Compare) btreeCmp {
      65           1 :         return func(a, b *FileMetadata) int {
      66           1 :                 return a.cmpSmallestKey(b, cmp)
      67           1 :         }
      68             : }
      69             : 
      70             : // btreeCmpSpecificOrder is used in tests to construct a B-Tree with a
      71             : // specific ordering of FileMetadata within the tree. It's typically used to
      72             : // test consistency checking code that needs to construct a malformed B-Tree.
      73           1 : func btreeCmpSpecificOrder(files []*FileMetadata) btreeCmp {
      74           1 :         m := map[*FileMetadata]int{}
      75           1 :         for i, f := range files {
      76           1 :                 m[f] = i
      77           1 :         }
      78           1 :         return func(a, b *FileMetadata) int {
      79           1 :                 ai, aok := m[a]
      80           1 :                 bi, bok := m[b]
      81           1 :                 if !aok || !bok {
      82           0 :                         panic("btreeCmpSliceOrder called with unknown files")
      83             :                 }
      84           1 :                 return stdcmp.Compare(ai, bi)
      85             :         }
      86             : }
      87             : 
      88             : const (
      89             :         degree   = 16
      90             :         maxItems = 2*degree - 1
      91             :         minItems = degree - 1
      92             : )
      93             : 
      94             : type annotation struct {
      95             :         annotator Annotator
      96             :         // v is an annotation value, the output of either
      97             :         // annotator.Value or annotator.Merge.
      98             :         v interface{}
      99             :         // valid indicates whether future reads of the annotation may use v as-is.
     100             :         // If false, v will be zeroed and recalculated.
     101             :         valid bool
     102             : }
     103             : 
     104             : type leafNode struct {
     105             :         ref   atomic.Int32
     106             :         count int16
     107             :         leaf  bool
     108             :         // subtreeCount holds the count of files in the entire subtree formed by
     109             :         // this node. For leaf nodes, subtreeCount is always equal to count. For
     110             :         // non-leaf nodes, it's the sum of count plus all the children's
     111             :         // subtreeCounts.
     112             :         //
     113             :         // NB: We could move this field to the end of the node struct, since leaf =>
     114             :         // count=subtreeCount, however the unsafe casting [leafToNode] performs make
     115             :         // it risky and cumbersome.
     116             :         subtreeCount int
     117             :         items        [maxItems]*FileMetadata
     118             :         // annot contains one annotation per annotator, merged over the entire
     119             :         // node's files (and all descendants for non-leaf nodes).
     120             :         annot []annotation
     121             : }
     122             : 
     123             : type node struct {
     124             :         leafNode
     125             :         children [maxItems + 1]*node
     126             : }
     127             : 
     128             : //go:nocheckptr casts a ptr to a smaller struct to a ptr to a larger struct.
     129           1 : func leafToNode(ln *leafNode) *node {
     130           1 :         return (*node)(unsafe.Pointer(ln))
     131           1 : }
     132             : 
     133           1 : func newLeafNode() *node {
     134           1 :         n := leafToNode(new(leafNode))
     135           1 :         n.leaf = true
     136           1 :         n.ref.Store(1)
     137           1 :         return n
     138           1 : }
     139             : 
     140           1 : func newNode() *node {
     141           1 :         n := new(node)
     142           1 :         n.ref.Store(1)
     143           1 :         return n
     144           1 : }
     145             : 
     146             : // mut creates and returns a mutable node reference. If the node is not shared
     147             : // with any other trees then it can be modified in place. Otherwise, it must be
     148             : // cloned to ensure unique ownership. In this way, we enforce a copy-on-write
     149             : // policy which transparently incorporates the idea of local mutations, like
     150             : // Clojure's transients or Haskell's ST monad, where nodes are only copied
     151             : // during the first time that they are modified between Clone operations.
     152             : //
     153             : // When a node is cloned, the provided pointer will be redirected to the new
     154             : // mutable node.
     155           1 : func mut(n **node) *node {
     156           1 :         if (*n).ref.Load() == 1 {
     157           1 :                 // Exclusive ownership. Can mutate in place.
     158           1 : 
     159           1 :                 // Whenever a node will be mutated, reset its annotations to be marked
     160           1 :                 // as uncached. This ensures any future calls to (*node).annotation
     161           1 :                 // will recompute annotations on the modified subtree.
     162           1 :                 for i := range (*n).annot {
     163           1 :                         (*n).annot[i].valid = false
     164           1 :                 }
     165           1 :                 return *n
     166             :         }
     167             :         // If we do not have unique ownership over the node then we
     168             :         // clone it to gain unique ownership. After doing so, we can
     169             :         // release our reference to the old node. We pass recursive
     170             :         // as true because even though we just observed the node's
     171             :         // reference count to be greater than 1, we might be racing
     172             :         // with another call to decRef on this node.
     173           1 :         c := (*n).clone()
     174           1 :         (*n).decRef(true /* contentsToo */, nil)
     175           1 :         *n = c
     176           1 :         // NB: We don't need to clear annotations, because (*node).clone does not
     177           1 :         // copy them.
     178           1 :         return *n
     179             : }
     180             : 
     181             : // incRef acquires a reference to the node.
     182           1 : func (n *node) incRef() {
     183           1 :         n.ref.Add(1)
     184           1 : }
     185             : 
     186             : // decRef releases a reference to the node. If requested, the method will unref
     187             : // its items and recurse into child nodes and decrease their refcounts as well.
     188             : // Some internal codepaths that manually copy the node's items or children to
     189             : // new nodes pass contentsToo=false to preserve existing reference counts during
     190             : // operations that should yield a net-zero change to descendant refcounts.
     191             : // When a node is released, its contained files are dereferenced.
     192           1 : func (n *node) decRef(contentsToo bool, obsolete *[]*FileBacking) {
     193           1 :         if n.ref.Add(-1) > 0 {
     194           1 :                 // Other references remain. Can't free.
     195           1 :                 return
     196           1 :         }
     197             : 
     198             :         // Dereference the node's metadata and release child references if
     199             :         // requested. Some internal callers may not want to propagate the deref
     200             :         // because they're manually copying the filemetadata and children to other
     201             :         // nodes, and they want to preserve the existing reference count.
     202           1 :         if contentsToo {
     203           1 :                 for _, f := range n.items[:n.count] {
     204           1 :                         if f.FileBacking.Unref() == 0 {
     205           1 :                                 // There are two sources of node dereferences: tree mutations
     206           1 :                                 // and Version dereferences. Files should only be made obsolete
     207           1 :                                 // during Version dereferences, during which `obsolete` will be
     208           1 :                                 // non-nil.
     209           1 :                                 if obsolete == nil {
     210           0 :                                         panic(fmt.Sprintf("file metadata %s dereferenced to zero during tree mutation", f.FileNum))
     211             :                                 }
     212             :                                 // Reference counting is performed on the FileBacking. In the case
     213             :                                 // of a virtual sstable, this reference counting is performed on
     214             :                                 // a FileBacking which is shared by every single virtual sstable
     215             :                                 // with the same backing sstable. If the reference count hits 0,
     216             :                                 // then we know that the FileBacking won't be required by any
     217             :                                 // sstable in Pebble, and that the backing sstable can be deleted.
     218           1 :                                 *obsolete = append(*obsolete, f.FileBacking)
     219             :                         }
     220             :                 }
     221           1 :                 if !n.leaf {
     222           1 :                         for i := int16(0); i <= n.count; i++ {
     223           1 :                                 n.children[i].decRef(true /* contentsToo */, obsolete)
     224           1 :                         }
     225             :                 }
     226             :         }
     227             : }
     228             : 
     229             : // clone creates a clone of the receiver with a single reference count.
     230           1 : func (n *node) clone() *node {
     231           1 :         var c *node
     232           1 :         if n.leaf {
     233           1 :                 c = newLeafNode()
     234           1 :         } else {
     235           1 :                 c = newNode()
     236           1 :         }
     237             :         // NB: copy field-by-field without touching n.ref to avoid
     238             :         // triggering the race detector and looking like a data race.
     239           1 :         c.count = n.count
     240           1 :         c.items = n.items
     241           1 :         c.subtreeCount = n.subtreeCount
     242           1 :         // Increase the refcount of each contained item.
     243           1 :         for _, f := range n.items[:n.count] {
     244           1 :                 f.FileBacking.Ref()
     245           1 :         }
     246           1 :         if !c.leaf {
     247           1 :                 // Copy children and increase each refcount.
     248           1 :                 c.children = n.children
     249           1 :                 for i := int16(0); i <= c.count; i++ {
     250           1 :                         c.children[i].incRef()
     251           1 :                 }
     252             :         }
     253           1 :         return c
     254             : }
     255             : 
     256             : // insertAt inserts the provided file and node at the provided index. This
     257             : // function is for use only as a helper function for internal B-Tree code.
     258             : // Clients should not invoke it directly.
     259           1 : func (n *node) insertAt(index int, item *FileMetadata, nd *node) {
     260           1 :         if index < int(n.count) {
     261           1 :                 copy(n.items[index+1:n.count+1], n.items[index:n.count])
     262           1 :                 if !n.leaf {
     263           1 :                         copy(n.children[index+2:n.count+2], n.children[index+1:n.count+1])
     264           1 :                 }
     265             :         }
     266           1 :         n.items[index] = item
     267           1 :         if !n.leaf {
     268           1 :                 n.children[index+1] = nd
     269           1 :         }
     270           1 :         n.count++
     271             : }
     272             : 
     273             : // pushBack inserts the provided file and node at the tail of the node's items.
     274             : // This function is for use only as a helper function for internal B-Tree code.
     275             : // Clients should not invoke it directly.
     276           1 : func (n *node) pushBack(item *FileMetadata, nd *node) {
     277           1 :         n.items[n.count] = item
     278           1 :         if !n.leaf {
     279           1 :                 n.children[n.count+1] = nd
     280           1 :         }
     281           1 :         n.count++
     282             : }
     283             : 
     284             : // pushFront inserts the provided file and node at the head of the
     285             : // node's items. This function is for use only as a helper function for internal B-Tree
     286             : // code. Clients should not invoke it directly.
     287           1 : func (n *node) pushFront(item *FileMetadata, nd *node) {
     288           1 :         if !n.leaf {
     289           1 :                 copy(n.children[1:n.count+2], n.children[:n.count+1])
     290           1 :                 n.children[0] = nd
     291           1 :         }
     292           1 :         copy(n.items[1:n.count+1], n.items[:n.count])
     293           1 :         n.items[0] = item
     294           1 :         n.count++
     295             : }
     296             : 
     297             : // removeAt removes a value at a given index, pulling all subsequent values
     298             : // back. This function is for use only as a helper function for internal B-Tree
     299             : // code. Clients should not invoke it directly.
     300           1 : func (n *node) removeAt(index int) (*FileMetadata, *node) {
     301           1 :         var child *node
     302           1 :         if !n.leaf {
     303           1 :                 child = n.children[index+1]
     304           1 :                 copy(n.children[index+1:n.count], n.children[index+2:n.count+1])
     305           1 :                 n.children[n.count] = nil
     306           1 :         }
     307           1 :         n.count--
     308           1 :         out := n.items[index]
     309           1 :         copy(n.items[index:n.count], n.items[index+1:n.count+1])
     310           1 :         n.items[n.count] = nil
     311           1 :         return out, child
     312             : }
     313             : 
     314             : // popBack removes and returns the last element in the list. This function is
     315             : // for use only as a helper function for internal B-Tree code. Clients should
     316             : // not invoke it directly.
     317           1 : func (n *node) popBack() (*FileMetadata, *node) {
     318           1 :         n.count--
     319           1 :         out := n.items[n.count]
     320           1 :         n.items[n.count] = nil
     321           1 :         if n.leaf {
     322           1 :                 return out, nil
     323           1 :         }
     324           1 :         child := n.children[n.count+1]
     325           1 :         n.children[n.count+1] = nil
     326           1 :         return out, child
     327             : }
     328             : 
     329             : // popFront removes and returns the first element in the list. This function is
     330             : // for use only as a helper function for internal B-Tree code. Clients should
     331             : // not invoke it directly.
     332           1 : func (n *node) popFront() (*FileMetadata, *node) {
     333           1 :         n.count--
     334           1 :         var child *node
     335           1 :         if !n.leaf {
     336           1 :                 child = n.children[0]
     337           1 :                 copy(n.children[:n.count+1], n.children[1:n.count+2])
     338           1 :                 n.children[n.count+1] = nil
     339           1 :         }
     340           1 :         out := n.items[0]
     341           1 :         copy(n.items[:n.count], n.items[1:n.count+1])
     342           1 :         n.items[n.count] = nil
     343           1 :         return out, child
     344             : }
     345             : 
     346             : // find returns the index where the given item should be inserted into this
     347             : // list. 'found' is true if the item already exists in the list at the given
     348             : // index.
     349             : //
     350             : // This function is for use only as a helper function for internal B-Tree code.
     351             : // Clients should not invoke it directly.
     352           1 : func (n *node) find(cmp btreeCmp, item *FileMetadata) (index int, found bool) {
     353           1 :         // Logic copied from sort.Search. Inlining this gave
     354           1 :         // an 11% speedup on BenchmarkBTreeDeleteInsert.
     355           1 :         i, j := 0, int(n.count)
     356           1 :         for i < j {
     357           1 :                 h := int(uint(i+j) >> 1) // avoid overflow when computing h
     358           1 :                 // i ≤ h < j
     359           1 :                 v := cmp(item, n.items[h])
     360           1 :                 if v == 0 {
     361           1 :                         return h, true
     362           1 :                 } else if v > 0 {
     363           1 :                         i = h + 1
     364           1 :                 } else {
     365           1 :                         j = h
     366           1 :                 }
     367             :         }
     368           1 :         return i, false
     369             : }
     370             : 
     371             : // split splits the given node at the given index. The current node shrinks,
     372             : // and this function returns the item that existed at that index and a new
     373             : // node containing all items/children after it.
     374             : //
     375             : // split is called when we want to perform a transformation like the one
     376             : // depicted in the following diagram.
     377             : //
     378             : //      Before:
     379             : //                             +-----------+
     380             : //                   n *node   |   x y z   |
     381             : //                             +--/-/-\-\--+
     382             : //
     383             : //      After:
     384             : //                             +-----------+
     385             : //                             |     y     |  n's parent
     386             : //                             +----/-\----+
     387             : //                                 /   \
     388             : //                                v     v
     389             : //                    +-----------+     +-----------+
     390             : //            n *node |         x |     | z         | next *node
     391             : //                    +-----------+     +-----------+
     392             : //
     393             : // split does not perform the complete transformation; the caller is responsible
     394             : // for updating the parent appropriately. split splits `n` into two nodes, `n`
     395             : // and `next`, returning `next` and the file that separates them. In the diagram
     396             : // above, `n.split` removes y and z from `n`, returning y in the first return
     397             : // value and `next` in the second return value. The caller is responsible for
     398             : // updating n's parent to now contain `y` as the separator between nodes `n` and
     399             : // `next`.
     400             : //
     401             : // This function is for use only as a helper function for internal B-Tree code.
     402             : // Clients should not invoke it directly.
     403           1 : func (n *node) split(i int) (*FileMetadata, *node) {
     404           1 :         out := n.items[i]
     405           1 :         var next *node
     406           1 :         if n.leaf {
     407           1 :                 next = newLeafNode()
     408           1 :         } else {
     409           1 :                 next = newNode()
     410           1 :         }
     411           1 :         next.count = n.count - int16(i+1)
     412           1 :         copy(next.items[:], n.items[i+1:n.count])
     413           1 :         for j := int16(i); j < n.count; j++ {
     414           1 :                 n.items[j] = nil
     415           1 :         }
     416           1 :         if !n.leaf {
     417           1 :                 copy(next.children[:], n.children[i+1:n.count+1])
     418           1 :                 descendantsMoved := 0
     419           1 :                 for j := int16(i + 1); j <= n.count; j++ {
     420           1 :                         descendantsMoved += n.children[j].subtreeCount
     421           1 :                         n.children[j] = nil
     422           1 :                 }
     423           1 :                 n.subtreeCount -= descendantsMoved
     424           1 :                 next.subtreeCount += descendantsMoved
     425             :         }
     426           1 :         n.count = int16(i)
     427           1 :         // NB: We subtract one more than `next.count` from n's subtreeCount because
     428           1 :         // the item at index `i` was removed from `n.items`. We'll return the item
     429           1 :         // at index `i`, and the caller is responsible for updating the subtree
     430           1 :         // count of whichever node adopts it.
     431           1 :         n.subtreeCount -= int(next.count) + 1
     432           1 :         next.subtreeCount += int(next.count)
     433           1 :         return out, next
     434             : }
     435             : 
     436             : // Insert inserts a item into the subtree rooted at this node, making sure no
     437             : // nodes in the subtree exceed maxItems items.
     438           1 : func (n *node) Insert(cmp btreeCmp, item *FileMetadata) error {
     439           1 :         i, found := n.find(cmp, item)
     440           1 :         if found {
     441           1 :                 // cmp provides a total ordering of the files within a level.
     442           1 :                 // If we're inserting a metadata that's equal to an existing item
     443           1 :                 // in the tree, we're inserting a file into a level twice.
     444           1 :                 return errors.Errorf("files %s and %s collided on sort keys",
     445           1 :                         errors.Safe(item.FileNum), errors.Safe(n.items[i].FileNum))
     446           1 :         }
     447           1 :         if n.leaf {
     448           1 :                 n.insertAt(i, item, nil)
     449           1 :                 n.subtreeCount++
     450           1 :                 return nil
     451           1 :         }
     452           1 :         if n.children[i].count >= maxItems {
     453           1 :                 splitLa, splitNode := mut(&n.children[i]).split(maxItems / 2)
     454           1 :                 n.insertAt(i, splitLa, splitNode)
     455           1 : 
     456           1 :                 switch cmp := cmp(item, n.items[i]); {
     457           1 :                 case cmp < 0:
     458             :                         // no change, we want first split node
     459           1 :                 case cmp > 0:
     460           1 :                         i++ // we want second split node
     461           0 :                 default:
     462           0 :                         // cmp provides a total ordering of the files within a level.
     463           0 :                         // If we're inserting a metadata that's equal to an existing item
     464           0 :                         // in the tree, we're inserting a file into a level twice.
     465           0 :                         return errors.Errorf("files %s and %s collided on sort keys",
     466           0 :                                 errors.Safe(item.FileNum), errors.Safe(n.items[i].FileNum))
     467             :                 }
     468             :         }
     469             : 
     470           1 :         err := mut(&n.children[i]).Insert(cmp, item)
     471           1 :         if err == nil {
     472           1 :                 n.subtreeCount++
     473           1 :         }
     474           1 :         return err
     475             : }
     476             : 
     477             : // removeMax removes and returns the maximum item from the subtree rooted at
     478             : // this node. This function is for use only as a helper function for internal
     479             : // B-Tree code. Clients should not invoke it directly.
     480           1 : func (n *node) removeMax() *FileMetadata {
     481           1 :         if n.leaf {
     482           1 :                 n.count--
     483           1 :                 n.subtreeCount--
     484           1 :                 out := n.items[n.count]
     485           1 :                 n.items[n.count] = nil
     486           1 :                 return out
     487           1 :         }
     488           1 :         child := mut(&n.children[n.count])
     489           1 :         if child.count <= minItems {
     490           0 :                 n.rebalanceOrMerge(int(n.count))
     491           0 :                 return n.removeMax()
     492           0 :         }
     493           1 :         n.subtreeCount--
     494           1 :         return child.removeMax()
     495             : }
     496             : 
     497             : // Remove removes a item from the subtree rooted at this node. Returns
     498             : // the item that was removed or nil if no matching item was found.
     499           1 : func (n *node) Remove(cmp btreeCmp, item *FileMetadata) (out *FileMetadata) {
     500           1 :         i, found := n.find(cmp, item)
     501           1 :         if n.leaf {
     502           1 :                 if found {
     503           1 :                         out, _ = n.removeAt(i)
     504           1 :                         n.subtreeCount--
     505           1 :                         return out
     506           1 :                 }
     507           1 :                 return nil
     508             :         }
     509           1 :         if n.children[i].count <= minItems {
     510           1 :                 // Child not large enough to remove from.
     511           1 :                 n.rebalanceOrMerge(i)
     512           1 :                 return n.Remove(cmp, item)
     513           1 :         }
     514           1 :         child := mut(&n.children[i])
     515           1 :         if found {
     516           1 :                 // Replace the item being removed with the max item in our left child.
     517           1 :                 out = n.items[i]
     518           1 :                 n.items[i] = child.removeMax()
     519           1 :                 n.subtreeCount--
     520           1 :                 return out
     521           1 :         }
     522             :         // File is not in this node and child is large enough to remove from.
     523           1 :         out = child.Remove(cmp, item)
     524           1 :         if out != nil {
     525           1 :                 n.subtreeCount--
     526           1 :         }
     527           1 :         return out
     528             : }
     529             : 
     530             : // rebalanceOrMerge grows child 'i' to ensure it has sufficient room to remove a
     531             : // item from it while keeping it at or above minItems. This function is for use
     532             : // only as a helper function for internal B-Tree code. Clients should not invoke
     533             : // it directly.
     534           1 : func (n *node) rebalanceOrMerge(i int) {
     535           1 :         switch {
     536           1 :         case i > 0 && n.children[i-1].count > minItems:
     537           1 :                 // Rebalance from left sibling.
     538           1 :                 //
     539           1 :                 //          +-----------+
     540           1 :                 //          |     y     |
     541           1 :                 //          +----/-\----+
     542           1 :                 //              /   \
     543           1 :                 //             v     v
     544           1 :                 // +-----------+     +-----------+
     545           1 :                 // |         x |     |           |
     546           1 :                 // +----------\+     +-----------+
     547           1 :                 //             \
     548           1 :                 //              v
     549           1 :                 //              a
     550           1 :                 //
     551           1 :                 // After:
     552           1 :                 //
     553           1 :                 //          +-----------+
     554           1 :                 //          |     x     |
     555           1 :                 //          +----/-\----+
     556           1 :                 //              /   \
     557           1 :                 //             v     v
     558           1 :                 // +-----------+     +-----------+
     559           1 :                 // |           |     | y         |
     560           1 :                 // +-----------+     +/----------+
     561           1 :                 //                   /
     562           1 :                 //                  v
     563           1 :                 //                  a
     564           1 :                 //
     565           1 :                 left := mut(&n.children[i-1])
     566           1 :                 child := mut(&n.children[i])
     567           1 :                 xLa, grandChild := left.popBack()
     568           1 :                 yLa := n.items[i-1]
     569           1 :                 child.pushFront(yLa, grandChild)
     570           1 :                 n.items[i-1] = xLa
     571           1 :                 child.subtreeCount++
     572           1 :                 left.subtreeCount--
     573           1 :                 if grandChild != nil {
     574           1 :                         child.subtreeCount += grandChild.subtreeCount
     575           1 :                         left.subtreeCount -= grandChild.subtreeCount
     576           1 :                 }
     577             : 
     578           1 :         case i < int(n.count) && n.children[i+1].count > minItems:
     579           1 :                 // Rebalance from right sibling.
     580           1 :                 //
     581           1 :                 //          +-----------+
     582           1 :                 //          |     y     |
     583           1 :                 //          +----/-\----+
     584           1 :                 //              /   \
     585           1 :                 //             v     v
     586           1 :                 // +-----------+     +-----------+
     587           1 :                 // |           |     | x         |
     588           1 :                 // +-----------+     +/----------+
     589           1 :                 //                   /
     590           1 :                 //                  v
     591           1 :                 //                  a
     592           1 :                 //
     593           1 :                 // After:
     594           1 :                 //
     595           1 :                 //          +-----------+
     596           1 :                 //          |     x     |
     597           1 :                 //          +----/-\----+
     598           1 :                 //              /   \
     599           1 :                 //             v     v
     600           1 :                 // +-----------+     +-----------+
     601           1 :                 // |         y |     |           |
     602           1 :                 // +----------\+     +-----------+
     603           1 :                 //             \
     604           1 :                 //              v
     605           1 :                 //              a
     606           1 :                 //
     607           1 :                 right := mut(&n.children[i+1])
     608           1 :                 child := mut(&n.children[i])
     609           1 :                 xLa, grandChild := right.popFront()
     610           1 :                 yLa := n.items[i]
     611           1 :                 child.pushBack(yLa, grandChild)
     612           1 :                 child.subtreeCount++
     613           1 :                 right.subtreeCount--
     614           1 :                 if grandChild != nil {
     615           1 :                         child.subtreeCount += grandChild.subtreeCount
     616           1 :                         right.subtreeCount -= grandChild.subtreeCount
     617           1 :                 }
     618           1 :                 n.items[i] = xLa
     619             : 
     620           1 :         default:
     621           1 :                 // Merge with either the left or right sibling.
     622           1 :                 //
     623           1 :                 //          +-----------+
     624           1 :                 //          |   u y v   |
     625           1 :                 //          +----/-\----+
     626           1 :                 //              /   \
     627           1 :                 //             v     v
     628           1 :                 // +-----------+     +-----------+
     629           1 :                 // |         x |     | z         |
     630           1 :                 // +-----------+     +-----------+
     631           1 :                 //
     632           1 :                 // After:
     633           1 :                 //
     634           1 :                 //          +-----------+
     635           1 :                 //          |    u v    |
     636           1 :                 //          +-----|-----+
     637           1 :                 //                |
     638           1 :                 //                v
     639           1 :                 //          +-----------+
     640           1 :                 //          |   x y z   |
     641           1 :                 //          +-----------+
     642           1 :                 //
     643           1 :                 if i >= int(n.count) {
     644           1 :                         i = int(n.count - 1)
     645           1 :                 }
     646           1 :                 child := mut(&n.children[i])
     647           1 :                 // Make mergeChild mutable, bumping the refcounts on its children if necessary.
     648           1 :                 _ = mut(&n.children[i+1])
     649           1 :                 mergeLa, mergeChild := n.removeAt(i)
     650           1 :                 child.items[child.count] = mergeLa
     651           1 :                 copy(child.items[child.count+1:], mergeChild.items[:mergeChild.count])
     652           1 :                 if !child.leaf {
     653           1 :                         copy(child.children[child.count+1:], mergeChild.children[:mergeChild.count+1])
     654           1 :                 }
     655           1 :                 child.count += mergeChild.count + 1
     656           1 :                 child.subtreeCount += mergeChild.subtreeCount + 1
     657           1 : 
     658           1 :                 mergeChild.decRef(false /* contentsToo */, nil)
     659             :         }
     660             : }
     661             : 
     662             : // InvalidateAnnotation removes any existing cached annotations for the provided
     663             : // annotator from this node's subtree.
     664           1 : func (n *node) InvalidateAnnotation(a Annotator) {
     665           1 :         // Find this annotator's annotation on this node.
     666           1 :         var annot *annotation
     667           1 :         for i := range n.annot {
     668           0 :                 if n.annot[i].annotator == a {
     669           0 :                         annot = &n.annot[i]
     670           0 :                 }
     671             :         }
     672             : 
     673           1 :         if annot != nil && annot.valid {
     674           0 :                 annot.valid = false
     675           0 :                 annot.v = a.Zero(annot.v)
     676           0 :         }
     677           1 :         if !n.leaf {
     678           0 :                 for i := int16(0); i <= n.count; i++ {
     679           0 :                         n.children[i].InvalidateAnnotation(a)
     680           0 :                 }
     681             :         }
     682             : }
     683             : 
     684             : // Annotation retrieves, computing if not already computed, the provided
     685             : // annotator's annotation of this node. The second return value indicates
     686             : // whether the future reads of this annotation may use the first return value
     687             : // as-is. If false, the annotation is not stable and may change on a subsequent
     688             : // computation.
     689           1 : func (n *node) Annotation(a Annotator) (interface{}, bool) {
     690           1 :         // Find this annotator's annotation on this node.
     691           1 :         var annot *annotation
     692           1 :         for i := range n.annot {
     693           1 :                 if n.annot[i].annotator == a {
     694           1 :                         annot = &n.annot[i]
     695           1 :                 }
     696             :         }
     697             : 
     698             :         // If it exists and is marked as valid, we can return it without
     699             :         // recomputing anything.
     700           1 :         if annot != nil && annot.valid {
     701           1 :                 return annot.v, true
     702           1 :         }
     703             : 
     704           1 :         if annot == nil {
     705           1 :                 // This is n's first time being annotated by a.
     706           1 :                 // Create a new zeroed annotation.
     707           1 :                 n.annot = append(n.annot, annotation{
     708           1 :                         annotator: a,
     709           1 :                         v:         a.Zero(nil),
     710           1 :                 })
     711           1 :                 annot = &n.annot[len(n.annot)-1]
     712           1 :         } else {
     713           1 :                 // There's an existing annotation that must be recomputed.
     714           1 :                 // Zero its value.
     715           1 :                 annot.v = a.Zero(annot.v)
     716           1 :         }
     717             : 
     718           1 :         annot.valid = true
     719           1 :         for i := int16(0); i <= n.count; i++ {
     720           1 :                 if !n.leaf {
     721           1 :                         v, ok := n.children[i].Annotation(a)
     722           1 :                         annot.v = a.Merge(v, annot.v)
     723           1 :                         annot.valid = annot.valid && ok
     724           1 :                 }
     725           1 :                 if i < n.count {
     726           1 :                         v, ok := a.Accumulate(n.items[i], annot.v)
     727           1 :                         annot.v = v
     728           1 :                         annot.valid = annot.valid && ok
     729           1 :                 }
     730             :         }
     731           1 :         return annot.v, annot.valid
     732             : }
     733             : 
     734           1 : func (n *node) verifyInvariants() {
     735           1 :         recomputedSubtreeCount := int(n.count)
     736           1 :         if !n.leaf {
     737           1 :                 for i := int16(0); i <= n.count; i++ {
     738           1 :                         n.children[i].verifyInvariants()
     739           1 :                         recomputedSubtreeCount += n.children[i].subtreeCount
     740           1 :                 }
     741             :         }
     742           1 :         if recomputedSubtreeCount != n.subtreeCount {
     743           0 :                 panic(fmt.Sprintf("recomputed subtree count (%d) ≠ n.subtreeCount (%d)",
     744           0 :                         recomputedSubtreeCount, n.subtreeCount))
     745             :         }
     746             : }
     747             : 
     748             : // btree is an implementation of a B-Tree.
     749             : //
     750             : // btree stores FileMetadata in an ordered structure, allowing easy insertion,
     751             : // removal, and iteration. The B-Tree stores items in order based on cmp. The
     752             : // first level of the LSM uses a cmp function that compares sequence numbers.
     753             : // All other levels compare using the FileMetadata.Smallest.
     754             : //
     755             : // Write operations are not safe for concurrent mutation by multiple
     756             : // goroutines, but Read operations are.
     757             : type btree struct {
     758             :         root *node
     759             :         cmp  btreeCmp
     760             : }
     761             : 
     762             : // Release dereferences and clears the root node of the btree, removing all
     763             : // items from the btree. In doing so, it decrements contained file counts.
     764             : // It returns a slice of newly obsolete backing files, if any.
     765           1 : func (t *btree) Release() (obsolete []*FileBacking) {
     766           1 :         if t.root != nil {
     767           1 :                 t.root.decRef(true /* contentsToo */, &obsolete)
     768           1 :                 t.root = nil
     769           1 :         }
     770           1 :         return obsolete
     771             : }
     772             : 
     773             : // Clone clones the btree, lazily. It does so in constant time.
     774           1 : func (t *btree) Clone() btree {
     775           1 :         c := *t
     776           1 :         if c.root != nil {
     777           1 :                 // Incrementing the reference count on the root node is sufficient to
     778           1 :                 // ensure that no node in the cloned tree can be mutated by an actor
     779           1 :                 // holding a reference to the original tree and vice versa. This
     780           1 :                 // property is upheld because the root node in the receiver btree and
     781           1 :                 // the returned btree will both necessarily have a reference count of at
     782           1 :                 // least 2 when this method returns. All tree mutations recursively
     783           1 :                 // acquire mutable node references (see mut) as they traverse down the
     784           1 :                 // tree. The act of acquiring a mutable node reference performs a clone
     785           1 :                 // if a node's reference count is greater than one. Cloning a node (see
     786           1 :                 // clone) increases the reference count on each of its children,
     787           1 :                 // ensuring that they have a reference count of at least 2. This, in
     788           1 :                 // turn, ensures that any of the child nodes that are modified will also
     789           1 :                 // be copied-on-write, recursively ensuring the immutability property
     790           1 :                 // over the entire tree.
     791           1 :                 c.root.incRef()
     792           1 :         }
     793           1 :         return c
     794             : }
     795             : 
     796             : // Delete removes the provided file from the tree.
     797             : // It returns true if the file now has a zero reference count.
     798           1 : func (t *btree) Delete(item *FileMetadata) (obsolete bool) {
     799           1 :         if t.root == nil || t.root.count == 0 {
     800           0 :                 return false
     801           0 :         }
     802           1 :         if out := mut(&t.root).Remove(t.cmp, item); out != nil {
     803           1 :                 obsolete = out.FileBacking.Unref() == 0
     804           1 :         }
     805           1 :         if invariants.Enabled {
     806           1 :                 t.root.verifyInvariants()
     807           1 :         }
     808           1 :         if t.root.count == 0 {
     809           1 :                 old := t.root
     810           1 :                 if t.root.leaf {
     811           1 :                         t.root = nil
     812           1 :                 } else {
     813           1 :                         t.root = t.root.children[0]
     814           1 :                 }
     815           1 :                 old.decRef(false /* contentsToo */, nil)
     816             :         }
     817           1 :         return obsolete
     818             : }
     819             : 
     820             : // Insert adds the given item to the tree. If a item in the tree already
     821             : // equals the given one, Insert panics.
     822           1 : func (t *btree) Insert(item *FileMetadata) error {
     823           1 :         if t.root == nil {
     824           1 :                 t.root = newLeafNode()
     825           1 :         } else if t.root.count >= maxItems {
     826           1 :                 splitLa, splitNode := mut(&t.root).split(maxItems / 2)
     827           1 :                 newRoot := newNode()
     828           1 :                 newRoot.count = 1
     829           1 :                 newRoot.items[0] = splitLa
     830           1 :                 newRoot.children[0] = t.root
     831           1 :                 newRoot.children[1] = splitNode
     832           1 :                 newRoot.subtreeCount = t.root.subtreeCount + splitNode.subtreeCount + 1
     833           1 :                 t.root = newRoot
     834           1 :         }
     835           1 :         item.FileBacking.Ref()
     836           1 :         err := mut(&t.root).Insert(t.cmp, item)
     837           1 :         if invariants.Enabled {
     838           1 :                 t.root.verifyInvariants()
     839           1 :         }
     840           1 :         return err
     841             : }
     842             : 
     843             : // Iter returns a new iterator object. It is not safe to continue using an
     844             : // iterator after modifications are made to the tree. If modifications are made,
     845             : // create a new iterator.
     846           1 : func (t *btree) Iter() iterator {
     847           1 :         return iterator{r: t.root, pos: -1, cmp: t.cmp}
     848           1 : }
     849             : 
     850             : // Count returns the number of files contained within the B-Tree.
     851           1 : func (t *btree) Count() int {
     852           1 :         if t.root == nil {
     853           1 :                 return 0
     854           1 :         }
     855           1 :         return t.root.subtreeCount
     856             : }
     857             : 
     858             : // String returns a string description of the tree. The format is
     859             : // similar to the https://en.wikipedia.org/wiki/Newick_format.
     860           0 : func (t *btree) String() string {
     861           0 :         if t.Count() == 0 {
     862           0 :                 return ";"
     863           0 :         }
     864           0 :         var b strings.Builder
     865           0 :         t.root.writeString(&b)
     866           0 :         return b.String()
     867             : }
     868             : 
     869           0 : func (n *node) writeString(b *strings.Builder) {
     870           0 :         if n.leaf {
     871           0 :                 for i := int16(0); i < n.count; i++ {
     872           0 :                         if i != 0 {
     873           0 :                                 b.WriteString(",")
     874           0 :                         }
     875           0 :                         b.WriteString(n.items[i].String())
     876             :                 }
     877           0 :                 return
     878             :         }
     879           0 :         for i := int16(0); i <= n.count; i++ {
     880           0 :                 b.WriteString("(")
     881           0 :                 n.children[i].writeString(b)
     882           0 :                 b.WriteString(")")
     883           0 :                 if i < n.count {
     884           0 :                         b.WriteString(n.items[i].String())
     885           0 :                 }
     886             :         }
     887             : }
     888             : 
     889             : // iterStack represents a stack of (node, pos) tuples, which captures
     890             : // iteration state as an iterator descends a btree.
     891             : type iterStack struct {
     892             :         // a contains aLen stack frames when an iterator stack is short enough.
     893             :         // If the iterator stack overflows the capacity of iterStackArr, the stack
     894             :         // is moved to s and aLen is set to -1.
     895             :         a    iterStackArr
     896             :         aLen int16 // -1 when using s
     897             :         s    []iterFrame
     898             : }
     899             : 
     900             : // Used to avoid allocations for stacks below a certain size.
     901             : type iterStackArr [3]iterFrame
     902             : 
     903             : type iterFrame struct {
     904             :         n   *node
     905             :         pos int16
     906             : }
     907             : 
     908           1 : func (is *iterStack) push(f iterFrame) {
     909           1 :         if is.aLen == -1 {
     910           1 :                 is.s = append(is.s, f)
     911           1 :         } else if int(is.aLen) == len(is.a) {
     912           1 :                 is.s = make([]iterFrame, int(is.aLen)+1, 2*int(is.aLen))
     913           1 :                 copy(is.s, is.a[:])
     914           1 :                 is.s[int(is.aLen)] = f
     915           1 :                 is.aLen = -1
     916           1 :         } else {
     917           1 :                 is.a[is.aLen] = f
     918           1 :                 is.aLen++
     919           1 :         }
     920             : }
     921             : 
     922           1 : func (is *iterStack) pop() iterFrame {
     923           1 :         if is.aLen == -1 {
     924           1 :                 f := is.s[len(is.s)-1]
     925           1 :                 is.s = is.s[:len(is.s)-1]
     926           1 :                 return f
     927           1 :         }
     928           1 :         is.aLen--
     929           1 :         return is.a[is.aLen]
     930             : }
     931             : 
     932           1 : func (is *iterStack) len() int {
     933           1 :         if is.aLen == -1 {
     934           1 :                 return len(is.s)
     935           1 :         }
     936           1 :         return int(is.aLen)
     937             : }
     938             : 
     939           1 : func (is *iterStack) clone() iterStack {
     940           1 :         // If the iterator is using the embedded iterStackArr, we only need to
     941           1 :         // copy the struct itself.
     942           1 :         if is.s == nil {
     943           1 :                 return *is
     944           1 :         }
     945           0 :         clone := *is
     946           0 :         clone.s = make([]iterFrame, len(is.s))
     947           0 :         copy(clone.s, is.s)
     948           0 :         return clone
     949             : }
     950             : 
     951           1 : func (is *iterStack) nth(n int) (f iterFrame, ok bool) {
     952           1 :         if is.aLen == -1 {
     953           0 :                 if n >= len(is.s) {
     954           0 :                         return f, false
     955           0 :                 }
     956           0 :                 return is.s[n], true
     957             :         }
     958           1 :         if int16(n) >= is.aLen {
     959           1 :                 return f, false
     960           1 :         }
     961           1 :         return is.a[n], true
     962             : }
     963             : 
     964           1 : func (is *iterStack) reset() {
     965           1 :         if is.aLen == -1 {
     966           1 :                 is.s = is.s[:0]
     967           1 :         } else {
     968           1 :                 is.aLen = 0
     969           1 :         }
     970             : }
     971             : 
     972             : // iterator is responsible for search and traversal within a btree.
     973             : type iterator struct {
     974             :         // the root node of the B-Tree.
     975             :         r *node
     976             :         // n and pos make up the current position of the iterator.
     977             :         // If valid, n.items[pos] is the current value of the iterator.
     978             :         //
     979             :         // n may be nil iff i.r is nil.
     980             :         n   *node
     981             :         pos int16
     982             :         // cmp dictates the ordering of the FileMetadata.
     983             :         cmp func(*FileMetadata, *FileMetadata) int
     984             :         // a stack of n's ancestors within the B-Tree, alongside the position
     985             :         // taken to arrive at n. If non-empty, the bottommost frame of the stack
     986             :         // will always contain the B-Tree root.
     987             :         s iterStack
     988             : }
     989             : 
     990             : // countLeft returns the count of files that are to the left of the current
     991             : // iterator position.
     992           1 : func (i *iterator) countLeft() int {
     993           1 :         if i.r == nil {
     994           0 :                 return 0
     995           0 :         }
     996             : 
     997             :         // Each iterator has a stack of frames marking the path from the root node
     998             :         // to the current iterator position. All files (n.items) and all subtrees
     999             :         // (n.children) with indexes less than [pos] are to the left of the current
    1000             :         // iterator position.
    1001             :         //
    1002             :         //     +------------------------+  -
    1003             :         //     |  Root            pos:5 |   |
    1004             :         //     +------------------------+   | stack
    1005             :         //     |  Root/5          pos:3 |   | frames
    1006             :         //     +------------------------+   | [i.s]
    1007             :         //     |  Root/5/3        pos:9 |   |
    1008             :         //     +========================+  -
    1009             :         //     |                        |
    1010             :         //     | i.n: Root/5/3/9 i.pos:2|
    1011             :         //     +------------------------+
    1012             :         //
    1013           1 :         var count int
    1014           1 :         // Walk all the ancestors in the iterator stack [i.s], tallying up all the
    1015           1 :         // files and subtrees to the left of the stack frame's position.
    1016           1 :         f, ok := i.s.nth(0)
    1017           1 :         for fi := 0; ok; fi++ {
    1018           1 :                 // There are [f.pos] files contained within [f.n.items] that sort to the
    1019           1 :                 // left of the subtree the iterator has descended.
    1020           1 :                 count += int(f.pos)
    1021           1 :                 // Any subtrees that fall before the stack frame's position are entirely
    1022           1 :                 // to the left of the iterator's current position.
    1023           1 :                 for j := int16(0); j < f.pos; j++ {
    1024           1 :                         count += f.n.children[j].subtreeCount
    1025           1 :                 }
    1026           1 :                 f, ok = i.s.nth(fi + 1)
    1027             :         }
    1028             : 
    1029             :         // The bottommost stack frame is inlined within the iterator struct. Again,
    1030             :         // [i.pos] files fall to the left of the current iterator position.
    1031           1 :         count += int(i.pos)
    1032           1 :         if !i.n.leaf {
    1033           1 :                 // NB: Unlike above, we use a `<= i.pos` comparison. The iterator is
    1034           1 :                 // positioned at item `i.n.items[i.pos]`, which sorts after everything
    1035           1 :                 // in the subtree at `i.n.children[i.pos]`.
    1036           1 :                 for j := int16(0); j <= i.pos; j++ {
    1037           1 :                         count += i.n.children[j].subtreeCount
    1038           1 :                 }
    1039             :         }
    1040           1 :         return count
    1041             : }
    1042             : 
    1043           1 : func (i *iterator) clone() iterator {
    1044           1 :         c := *i
    1045           1 :         c.s = i.s.clone()
    1046           1 :         return c
    1047           1 : }
    1048             : 
    1049           1 : func (i *iterator) reset() {
    1050           1 :         i.n = i.r
    1051           1 :         i.pos = -1
    1052           1 :         i.s.reset()
    1053           1 : }
    1054             : 
    1055           0 : func (i iterator) String() string {
    1056           0 :         var buf bytes.Buffer
    1057           0 :         for n := 0; ; n++ {
    1058           0 :                 f, ok := i.s.nth(n)
    1059           0 :                 if !ok {
    1060           0 :                         break
    1061             :                 }
    1062           0 :                 fmt.Fprintf(&buf, "%p: %02d/%02d\n", f.n, f.pos, f.n.count)
    1063             :         }
    1064           0 :         if i.r == nil {
    1065           0 :                 fmt.Fprintf(&buf, "<nil>: %02d", i.pos)
    1066           0 :         } else {
    1067           0 :                 fmt.Fprintf(&buf, "%p: %02d/%02d", i.n, i.pos, i.n.count)
    1068           0 :         }
    1069           0 :         return buf.String()
    1070             : }
    1071             : 
    1072           1 : func cmpIter(a, b iterator) int {
    1073           1 :         if a.r != b.r {
    1074           0 :                 panic("compared iterators from different btrees")
    1075             :         }
    1076             : 
    1077             :         // Each iterator has a stack of frames marking the path from the root node
    1078             :         // to the current iterator position. We walk both paths formed by the
    1079             :         // iterators' stacks simultaneously, descending from the shared root node,
    1080             :         // always comparing nodes at the same level in the tree.
    1081             :         //
    1082             :         // If the iterators' paths ever diverge and point to different nodes, the
    1083             :         // iterators are not equal and we use the node positions to evaluate the
    1084             :         // comparison.
    1085             :         //
    1086             :         // If an iterator's stack ends, we stop descending and use its current
    1087             :         // node and position for the final comparison. One iterator's stack may
    1088             :         // end before another's if one iterator is positioned deeper in the tree.
    1089             :         //
    1090             :         // a                                b
    1091             :         // +------------------------+      +--------------------------+ -
    1092             :         // |  Root            pos:5 |   =  |  Root              pos:5 |  |
    1093             :         // +------------------------+      +--------------------------+  | stack
    1094             :         // |  Root/5          pos:3 |   =  |  Root/5            pos:3 |  | frames
    1095             :         // +------------------------+      +--------------------------+  |
    1096             :         // |  Root/5/3        pos:9 |   >  |  Root/5/3          pos:1 |  |
    1097             :         // +========================+      +==========================+ -
    1098             :         // |                        |      |                          |
    1099             :         // | a.n: Root/5/3/9 a.pos:2|      | b.n: Root/5/3/1, b.pos:5 |
    1100             :         // +------------------------+      +--------------------------+
    1101             : 
    1102             :         // Initialize with the iterator's current node and position. These are
    1103             :         // conceptually the most-recent/current frame of the iterator stack.
    1104           1 :         an, apos := a.n, a.pos
    1105           1 :         bn, bpos := b.n, b.pos
    1106           1 : 
    1107           1 :         // aok, bok are set while traversing the iterator's path down the B-Tree.
    1108           1 :         // They're declared in the outer scope because they help distinguish the
    1109           1 :         // sentinel case when both iterators' first frame points to the last child
    1110           1 :         // of the root. If an iterator has no other frames in its stack, it's the
    1111           1 :         // end sentinel state which sorts after everything else.
    1112           1 :         var aok, bok bool
    1113           1 :         for i := 0; ; i++ {
    1114           1 :                 var af, bf iterFrame
    1115           1 :                 af, aok = a.s.nth(i)
    1116           1 :                 bf, bok = b.s.nth(i)
    1117           1 :                 if !aok || !bok {
    1118           1 :                         if aok {
    1119           1 :                                 // Iterator a, unlike iterator b, still has a frame. Set an,
    1120           1 :                                 // apos so we compare using the frame from the stack.
    1121           1 :                                 an, apos = af.n, af.pos
    1122           1 :                         }
    1123           1 :                         if bok {
    1124           1 :                                 // Iterator b, unlike iterator a, still has a frame. Set bn,
    1125           1 :                                 // bpos so we compare using the frame from the stack.
    1126           1 :                                 bn, bpos = bf.n, bf.pos
    1127           1 :                         }
    1128           1 :                         break
    1129             :                 }
    1130             : 
    1131             :                 // aok && bok
    1132           1 :                 if af.n != bf.n {
    1133           0 :                         panic("nonmatching nodes during btree iterator comparison")
    1134             :                 }
    1135           1 :                 if v := stdcmp.Compare(af.pos, bf.pos); v != 0 {
    1136           1 :                         return v
    1137           1 :                 }
    1138             :                 // Otherwise continue up both iterators' stacks (equivalently, down the
    1139             :                 // B-Tree away from the root).
    1140             :         }
    1141             : 
    1142           1 :         if aok && bok {
    1143           0 :                 panic("expected one or more stacks to have been exhausted")
    1144             :         }
    1145           1 :         if an != bn {
    1146           0 :                 panic("nonmatching nodes during btree iterator comparison")
    1147             :         }
    1148           1 :         if v := stdcmp.Compare(apos, bpos); v != 0 {
    1149           1 :                 return v
    1150           1 :         }
    1151           1 :         switch {
    1152           1 :         case aok:
    1153           1 :                 // a is positioned at a leaf child at this position and b is at an
    1154           1 :                 // end sentinel state.
    1155           1 :                 return -1
    1156           1 :         case bok:
    1157           1 :                 // b is positioned at a leaf child at this position and a is at an
    1158           1 :                 // end sentinel state.
    1159           1 :                 return +1
    1160           1 :         default:
    1161           1 :                 return 0
    1162             :         }
    1163             : }
    1164             : 
    1165           1 : func (i *iterator) descend(n *node, pos int16) {
    1166           1 :         i.s.push(iterFrame{n: n, pos: pos})
    1167           1 :         i.n = n.children[pos]
    1168           1 :         i.pos = 0
    1169           1 : }
    1170             : 
    1171             : // ascend ascends up to the current node's parent and resets the position
    1172             : // to the one previously set for this parent node.
    1173           1 : func (i *iterator) ascend() {
    1174           1 :         f := i.s.pop()
    1175           1 :         i.n = f.n
    1176           1 :         i.pos = f.pos
    1177           1 : }
    1178             : 
    1179             : // seek repositions the iterator over the first file for which fn returns
    1180             : // true, mirroring the semantics of the standard library's sort.Search
    1181             : // function.  Like sort.Search, seek requires the iterator's B-Tree to be
    1182             : // ordered such that fn returns false for some (possibly empty) prefix of the
    1183             : // tree's files, and then true for the (possibly empty) remainder.
    1184           1 : func (i *iterator) seek(fn func(*FileMetadata) bool) {
    1185           1 :         i.reset()
    1186           1 :         if i.r == nil {
    1187           0 :                 return
    1188           0 :         }
    1189             : 
    1190           1 :         for {
    1191           1 :                 // Logic copied from sort.Search.
    1192           1 :                 j, k := 0, int(i.n.count)
    1193           1 :                 for j < k {
    1194           1 :                         h := int(uint(j+k) >> 1) // avoid overflow when computing h
    1195           1 : 
    1196           1 :                         // j ≤ h < k
    1197           1 :                         if !fn(i.n.items[h]) {
    1198           1 :                                 j = h + 1 // preserves f(j-1) == false
    1199           1 :                         } else {
    1200           1 :                                 k = h // preserves f(k) == true
    1201           1 :                         }
    1202             :                 }
    1203             : 
    1204           1 :                 i.pos = int16(j)
    1205           1 :                 if i.n.leaf {
    1206           1 :                         if i.pos == i.n.count {
    1207           1 :                                 i.next()
    1208           1 :                         }
    1209           1 :                         return
    1210             :                 }
    1211           1 :                 i.descend(i.n, i.pos)
    1212             :         }
    1213             : }
    1214             : 
    1215             : // first seeks to the first item in the btree.
    1216           1 : func (i *iterator) first() {
    1217           1 :         i.reset()
    1218           1 :         if i.r == nil {
    1219           1 :                 return
    1220           1 :         }
    1221           1 :         for !i.n.leaf {
    1222           1 :                 i.descend(i.n, 0)
    1223           1 :         }
    1224           1 :         i.pos = 0
    1225             : }
    1226             : 
    1227             : // last seeks to the last item in the btree.
    1228           1 : func (i *iterator) last() {
    1229           1 :         i.reset()
    1230           1 :         if i.r == nil {
    1231           1 :                 return
    1232           1 :         }
    1233           1 :         for !i.n.leaf {
    1234           1 :                 i.descend(i.n, i.n.count)
    1235           1 :         }
    1236           1 :         i.pos = i.n.count - 1
    1237             : }
    1238             : 
    1239             : // next positions the iterator to the item immediately following
    1240             : // its current position.
    1241           1 : func (i *iterator) next() {
    1242           1 :         if i.r == nil {
    1243           0 :                 return
    1244           0 :         }
    1245             : 
    1246           1 :         if i.n.leaf {
    1247           1 :                 if i.pos < i.n.count {
    1248           1 :                         i.pos++
    1249           1 :                 }
    1250           1 :                 if i.pos < i.n.count {
    1251           1 :                         return
    1252           1 :                 }
    1253           1 :                 for i.s.len() > 0 && i.pos >= i.n.count {
    1254           1 :                         i.ascend()
    1255           1 :                 }
    1256           1 :                 return
    1257             :         }
    1258             : 
    1259           1 :         i.descend(i.n, i.pos+1)
    1260           1 :         for !i.n.leaf {
    1261           1 :                 i.descend(i.n, 0)
    1262           1 :         }
    1263           1 :         i.pos = 0
    1264             : }
    1265             : 
    1266             : // prev positions the iterator to the item immediately preceding
    1267             : // its current position.
    1268           1 : func (i *iterator) prev() {
    1269           1 :         if i.r == nil {
    1270           0 :                 return
    1271           0 :         }
    1272             : 
    1273           1 :         if i.n.leaf {
    1274           1 :                 i.pos--
    1275           1 :                 if i.pos >= 0 {
    1276           1 :                         return
    1277           1 :                 }
    1278           1 :                 for i.s.len() > 0 && i.pos < 0 {
    1279           1 :                         i.ascend()
    1280           1 :                         i.pos--
    1281           1 :                 }
    1282           1 :                 return
    1283             :         }
    1284             : 
    1285           1 :         i.descend(i.n, i.pos)
    1286           1 :         for !i.n.leaf {
    1287           1 :                 i.descend(i.n, i.n.count)
    1288           1 :         }
    1289           1 :         i.pos = i.n.count - 1
    1290             : }
    1291             : 
    1292             : // valid returns whether the iterator is positioned at a valid position.
    1293           1 : func (i *iterator) valid() bool {
    1294           1 :         return i.r != nil && i.pos >= 0 && i.pos < i.n.count
    1295           1 : }
    1296             : 
    1297             : // cur returns the item at the iterator's current position. It is illegal
    1298             : // to call cur if the iterator is not valid.
    1299           1 : func (i *iterator) cur() *FileMetadata {
    1300           1 :         if invariants.Enabled && !i.valid() {
    1301           0 :                 panic("btree iterator.cur invoked on invalid iterator")
    1302             :         }
    1303           1 :         return i.n.items[i.pos]
    1304             : }

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