LCOV - code coverage report
Current view: top level - pageserver/src/tenant/layer_map - layer_coverage.rs (source / functions) Coverage Total Hit
Test: b9d67f908f91f00e353a27440ba89f642a869959.info Lines: 100.0 % 111 111
Test Date: 2024-11-19 21:44:13 Functions: 100.0 % 23 23

            Line data    Source code
       1              : use std::ops::Range;
       2              : 
       3              : // NOTE the `im` crate has 20x more downloads and also has
       4              : // persistent/immutable BTree. But it's bugged so rpds is a
       5              : // better choice <https://github.com/neondatabase/neon/issues/3395>
       6              : use rpds::RedBlackTreeMapSync;
       7              : 
       8              : /// Data structure that can efficiently:
       9              : /// - find the latest layer by lsn.end at a given key
      10              : /// - iterate the latest layers in a key range
      11              : /// - insert layers in non-decreasing lsn.start order
      12              : ///
      13              : /// For a detailed explanation and justification of this approach, see:
      14              : /// <https://neon.tech/blog/persistent-structures-in-neons-wal-indexing>
      15              : ///
      16              : /// NOTE The struct is parameterized over Value for easier
      17              : ///      testing, but in practice it's some sort of layer.
      18              : pub struct LayerCoverage<Value> {
      19              :     /// For every change in coverage (as we sweep the key space)
      20              :     /// we store (lsn.end, value).
      21              :     ///
      22              :     /// NOTE We use an immutable/persistent tree so that we can keep historic
      23              :     ///      versions of this coverage without cloning the whole thing and
      24              :     ///      incurring quadratic memory cost. See HistoricLayerCoverage.
      25              :     ///
      26              :     /// NOTE We use the Sync version of the map because we want Self to
      27              :     ///      be Sync. Using nonsync might be faster, if we can work with
      28              :     ///      that.
      29              :     nodes: RedBlackTreeMapSync<i128, Option<(u64, Value)>>,
      30              : }
      31              : 
      32              : impl<T: Clone> Default for LayerCoverage<T> {
      33         1652 :     fn default() -> Self {
      34         1652 :         Self::new()
      35         1652 :     }
      36              : }
      37              : 
      38              : impl<Value: Clone> LayerCoverage<Value> {
      39         1652 :     pub fn new() -> Self {
      40         1652 :         Self {
      41         1652 :             nodes: RedBlackTreeMapSync::default(),
      42         1652 :         }
      43         1652 :     }
      44              : 
      45              :     /// Helper function to subdivide the key range without changing any values
      46              :     ///
      47              :     /// This operation has no semantic effect by itself. It only helps us pin in
      48              :     /// place the part of the coverage we don't want to change when inserting.
      49              :     ///
      50              :     /// As an analogy, think of a polygon. If you add a vertex along one of the
      51              :     /// segments, the polygon is still the same, but it behaves differently when
      52              :     /// we move or delete one of the other points.
      53              :     ///
      54              :     /// Complexity: O(log N)
      55        10136 :     fn add_node(&mut self, key: i128) {
      56        10136 :         let value = match self.nodes.range(..=key).last() {
      57         6862 :             Some((_, Some(v))) => Some(v.clone()),
      58         2682 :             Some((_, None)) => None,
      59          592 :             None => None,
      60              :         };
      61        10136 :         self.nodes.insert_mut(key, value);
      62        10136 :     }
      63              : 
      64              :     /// Insert a layer.
      65              :     ///
      66              :     /// Complexity: worst case O(N), in practice O(log N). See NOTE in implementation.
      67         5068 :     pub fn insert(&mut self, key: Range<i128>, lsn: Range<u64>, value: Value) {
      68         5068 :         // Add nodes at endpoints
      69         5068 :         //
      70         5068 :         // NOTE The order of lines is important. We add nodes at the start
      71         5068 :         // and end of the key range **before updating any nodes** in order
      72         5068 :         // to pin down the current coverage outside of the relevant key range.
      73         5068 :         // Only the coverage inside the layer's key range should change.
      74         5068 :         self.add_node(key.start);
      75         5068 :         self.add_node(key.end);
      76         5068 : 
      77         5068 :         // Raise the height where necessary
      78         5068 :         //
      79         5068 :         // NOTE This loop is worst case O(N), but amortized O(log N) in the special
      80         5068 :         // case when rectangles have no height. In practice I don't think we'll see
      81         5068 :         // the kind of layer intersections needed to trigger O(N) behavior. The worst
      82         5068 :         // case is N/2 horizontal layers overlapped with N/2 vertical layers in a
      83         5068 :         // grid pattern.
      84         5068 :         let mut to_update = Vec::new();
      85         5068 :         let mut to_remove = Vec::new();
      86         5068 :         let mut prev_covered = false;
      87         6830 :         for (k, node) in self.nodes.range(key) {
      88         6830 :             let needs_cover = match node {
      89         1108 :                 None => true,
      90         5722 :                 Some((h, _)) => h < &lsn.end,
      91              :             };
      92         6830 :             if needs_cover {
      93         6816 :                 match prev_covered {
      94         1742 :                     true => to_remove.push(*k),
      95         5074 :                     false => to_update.push(*k),
      96              :                 }
      97           14 :             }
      98         6830 :             prev_covered = needs_cover;
      99              :         }
     100              :         // TODO check if the nodes inserted at key.start and key.end are safe
     101              :         //      to remove. It's fine to keep them but they could be redundant.
     102        10142 :         for k in to_update {
     103         5074 :             self.nodes.insert_mut(k, Some((lsn.end, value.clone())));
     104         5074 :         }
     105         6810 :         for k in to_remove {
     106         1742 :             self.nodes.remove_mut(&k);
     107         1742 :         }
     108         5068 :     }
     109              : 
     110              :     /// Get the latest (by lsn.end) layer at a given key
     111              :     ///
     112              :     /// Complexity: O(log N)
     113       635152 :     pub fn query(&self, key: i128) -> Option<Value> {
     114       635152 :         self.nodes
     115       635152 :             .range(..=key)
     116       635152 :             .next_back()?
     117              :             .1
     118       541794 :             .as_ref()
     119       541794 :             .map(|(_, v)| v.clone())
     120       635152 :     }
     121              : 
     122              :     /// Iterate the changes in layer coverage in a given range. You will likely
     123              :     /// want to start with self.query(key.start), and then follow up with self.range
     124              :     ///
     125              :     /// Complexity: O(log N + result_size)
     126       491074 :     pub fn range(&self, key: Range<i128>) -> impl '_ + Iterator<Item = (i128, Option<Value>)> {
     127       491074 :         self.nodes
     128       491074 :             .range(key)
     129       491074 :             .map(|(k, v)| (*k, v.as_ref().map(|x| x.1.clone())))
     130       491074 :     }
     131              : 
     132              :     /// Returns an iterator which includes all coverage changes for layers that intersect
     133              :     /// with the provided range.
     134       491044 :     pub fn range_overlaps(
     135       491044 :         &self,
     136       491044 :         key_range: &Range<i128>,
     137       491044 :     ) -> impl Iterator<Item = (i128, Option<Value>)> + '_
     138       491044 :     where
     139       491044 :         Value: Eq,
     140       491044 :     {
     141       491044 :         let first_change = self.query(key_range.start);
     142       491044 :         match first_change {
     143       411894 :             Some(change) => {
     144       411894 :                 // If the start of the range is covered, we have to deal with two cases:
     145       411894 :                 // 1. Start of the range is aligned with the start of a layer.
     146       411894 :                 // In this case the return of `self.range` will contain the layer which aligns with the start of the key range.
     147       411894 :                 // We advance said iterator to avoid duplicating the first change.
     148       411894 :                 // 2. Start of the range is not aligned with the start of a layer.
     149       411894 :                 let range = key_range.start..key_range.end;
     150       411894 :                 let mut range_coverage = self.range(range).peekable();
     151       411894 :                 if range_coverage
     152       411894 :                     .peek()
     153       411894 :                     .is_some_and(|c| c.1.as_ref() == Some(&change))
     154         3786 :                 {
     155         3786 :                     range_coverage.next();
     156       408108 :                 }
     157       411894 :                 itertools::Either::Left(
     158       411894 :                     std::iter::once((key_range.start, Some(change))).chain(range_coverage),
     159       411894 :                 )
     160              :             }
     161              :             None => {
     162        79150 :                 let range = key_range.start..key_range.end;
     163        79150 :                 let coverage = self.range(range);
     164        79150 :                 itertools::Either::Right(coverage)
     165              :             }
     166              :         }
     167       491044 :     }
     168              :     /// O(1) clone
     169        12096 :     pub fn clone(&self) -> Self {
     170        12096 :         Self {
     171        12096 :             nodes: self.nodes.clone(),
     172        12096 :         }
     173        12096 :     }
     174              : }
     175              : 
     176              : /// Image and delta coverage at a specific LSN.
     177              : pub struct LayerCoverageTuple<Value> {
     178              :     pub image_coverage: LayerCoverage<Value>,
     179              :     pub delta_coverage: LayerCoverage<Value>,
     180              : }
     181              : 
     182              : impl<T: Clone> Default for LayerCoverageTuple<T> {
     183          826 :     fn default() -> Self {
     184          826 :         Self {
     185          826 :             image_coverage: LayerCoverage::default(),
     186          826 :             delta_coverage: LayerCoverage::default(),
     187          826 :         }
     188          826 :     }
     189              : }
     190              : 
     191              : impl<Value: Clone> LayerCoverageTuple<Value> {
     192         6048 :     pub fn clone(&self) -> Self {
     193         6048 :         Self {
     194         6048 :             image_coverage: self.image_coverage.clone(),
     195         6048 :             delta_coverage: self.delta_coverage.clone(),
     196         6048 :         }
     197         6048 :     }
     198              : }
        

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