denoland-deno/cli/tools/coverage/range_tree.rs

// Forked from https://github.com/demurgos/v8-coverage/tree/d0ca18da8740198681e0bc68971b0a6cdb11db3e/rust
// Copyright 2021 Charles Samborski. All rights reserved. MIT license.
// Copyright 2018-2022 the Deno authors. All rights reserved. MIT license.

use super::json_types::CoverageRange;
use std::iter::Peekable;
use typed_arena::Arena;

pub struct RangeTreeArena<'a>(Arena<RangeTree<'a>>);

impl<'a> RangeTreeArena<'a> {
  #[cfg(test)]
  pub fn new() -> Self {
    RangeTreeArena(Arena::new())
  }

  pub fn with_capacity(n: usize) -> Self {
    RangeTreeArena(Arena::with_capacity(n))
  }

  #[allow(clippy::mut_from_ref)]
  pub fn alloc(&'a self, value: RangeTree<'a>) -> &'a mut RangeTree<'a> {
    self.0.alloc(value)
  }
}

#[derive(Eq, PartialEq, Debug)]
pub struct RangeTree<'a> {
  pub start: usize,
  pub end: usize,
  pub delta: i64,
  pub children: Vec<&'a mut RangeTree<'a>>,
}

impl<'rt> RangeTree<'rt> {
  pub fn new<'a>(
    start: usize,
    end: usize,
    delta: i64,
    children: Vec<&'a mut RangeTree<'a>>,
  ) -> RangeTree<'a> {
    RangeTree {
      start,
      end,
      delta,
      children,
    }
  }

  pub fn split<'a>(
    rta: &'a RangeTreeArena<'a>,
    tree: &'a mut RangeTree<'a>,
    value: usize,
  ) -> (&'a mut RangeTree<'a>, &'a mut RangeTree<'a>) {
    let mut left_children: Vec<&'a mut RangeTree<'a>> = Vec::new();
    let mut right_children: Vec<&'a mut RangeTree<'a>> = Vec::new();
    for child in tree.children.iter_mut() {
      if child.end <= value {
        left_children.push(child);
      } else if value <= child.start {
        right_children.push(child);
      } else {
        let (left_child, right_child) = Self::split(rta, child, value);
        left_children.push(left_child);
        right_children.push(right_child);
      }
    }

    let left = RangeTree::new(tree.start, value, tree.delta, left_children);
    let right = RangeTree::new(value, tree.end, tree.delta, right_children);
    (rta.alloc(left), rta.alloc(right))
  }

  pub fn normalize<'a>(
    rta: &'a RangeTreeArena<'a>,
    tree: &'a mut RangeTree<'a>,
  ) -> &'a mut RangeTree<'a> {
    tree.children = {
      let mut children: Vec<&'a mut RangeTree<'a>> = Vec::new();
      let mut chain: Vec<&'a mut RangeTree<'a>> = Vec::new();
      for child in tree.children.drain(..) {
        let is_chain_end: bool =
          match chain.last().map(|tree| (tree.delta, tree.end)) {
            Some((delta, chain_end)) => {
              (delta, chain_end) != (child.delta, child.start)
            }
            None => false,
          };
        if is_chain_end {
          let mut chain_iter = chain.drain(..);
          let mut head: &'a mut RangeTree<'a> = chain_iter.next().unwrap();
          for tree in chain_iter {
            head.end = tree.end;
            for sub_child in tree.children.drain(..) {
              sub_child.delta += tree.delta - head.delta;
              head.children.push(sub_child);
            }
          }
          children.push(RangeTree::normalize(rta, head));
        }
        chain.push(child)
      }
      if !chain.is_empty() {
        let mut chain_iter = chain.drain(..);
        let mut head: &'a mut RangeTree<'a> = chain_iter.next().unwrap();
        for tree in chain_iter {
          head.end = tree.end;
          for sub_child in tree.children.drain(..) {
            sub_child.delta += tree.delta - head.delta;
            head.children.push(sub_child);
          }
        }
        children.push(RangeTree::normalize(rta, head));
      }

      if children.len() == 1
        && children[0].start == tree.start
        && children[0].end == tree.end
      {
        let normalized = children.remove(0);
        normalized.delta += tree.delta;
        return normalized;
      }

      children
    };

    tree
  }

  pub fn to_ranges(&self) -> Vec<CoverageRange> {
    let mut ranges: Vec<CoverageRange> = Vec::new();
    let mut stack: Vec<(&RangeTree, i64)> = vec![(self, 0)];
    while let Some((cur, parent_count)) = stack.pop() {
      let count: i64 = parent_count + cur.delta;
      ranges.push(CoverageRange {
        start_offset: cur.start,
        end_offset: cur.end,
        count,
      });
      for child in cur.children.iter().rev() {
        stack.push((child, count))
      }
    }
    ranges
  }

  pub fn from_sorted_ranges<'a>(
    rta: &'a RangeTreeArena<'a>,
    ranges: &[CoverageRange],
  ) -> Option<&'a mut RangeTree<'a>> {
    Self::from_sorted_ranges_inner(
      rta,
      &mut ranges.iter().peekable(),
      ::std::usize::MAX,
      0,
    )
  }

  fn from_sorted_ranges_inner<'a, 'b, 'c: 'b>(
    rta: &'a RangeTreeArena<'a>,
    ranges: &'b mut Peekable<impl Iterator<Item = &'c CoverageRange>>,
    parent_end: usize,
    parent_count: i64,
  ) -> Option<&'a mut RangeTree<'a>> {
    let has_range: bool = match ranges.peek() {
      None => false,
      Some(range) => range.start_offset < parent_end,
    };
    if !has_range {
      return None;
    }
    let range = ranges.next().unwrap();
    let start: usize = range.start_offset;
    let end: usize = range.end_offset;
    let count: i64 = range.count;
    let delta: i64 = count - parent_count;
    let mut children: Vec<&mut RangeTree> = Vec::new();
    while let Some(child) =
      Self::from_sorted_ranges_inner(rta, ranges, end, count)
    {
      children.push(child);
    }
    Some(rta.alloc(RangeTree::new(start, end, delta, children)))
  }
}

#[cfg(test)]
mod tests {
  use super::*;

  #[test]
  fn from_sorted_ranges_empty() {
    let rta = RangeTreeArena::new();
    let inputs: Vec<CoverageRange> = vec![CoverageRange {
      start_offset: 0,
      end_offset: 9,
      count: 1,
    }];
    let actual: Option<&mut RangeTree> =
      RangeTree::from_sorted_ranges(&rta, &inputs);
    let expected: Option<&mut RangeTree> =
      Some(rta.alloc(RangeTree::new(0, 9, 1, Vec::new())));

    assert_eq!(actual, expected);
  }
}
fix(coverage): merge coverage ranges (#13334) Covered ranges were not merged and thus it appeared that some lines might be uncovered. To fix this I used "v8-coverage" that takes care of merging the ranges properly. With this change, coverage collected from a file by multiple entrypoints is now correctly calculated. I ended up forking https://github.com/demurgos/v8-coverage and adding "cli/tools/coverage/merge.rs" and "cli/tools/coverage/range_tree.rs". 2022-01-11 15:17:25 -05:00			`// Forked from https://github.com/demurgos/v8-coverage/tree/d0ca18da8740198681e0bc68971b0a6cdb11db3e/rust`
			`// Copyright 2021 Charles Samborski. All rights reserved. MIT license.`
			`// Copyright 2018-2022 the Deno authors. All rights reserved. MIT license.`

			`use super::json_types::CoverageRange;`
			`use std::iter::Peekable;`
			`use typed_arena::Arena;`

			`pub struct RangeTreeArena<'a>(Arena<RangeTree<'a>>);`

			`impl<'a> RangeTreeArena<'a> {`
			`#[cfg(test)]`
			`pub fn new() -> Self {`
			`RangeTreeArena(Arena::new())`
			`}`

			`pub fn with_capacity(n: usize) -> Self {`
			`RangeTreeArena(Arena::with_capacity(n))`
			`}`

			`#[allow(clippy::mut_from_ref)]`
			`pub fn alloc(&'a self, value: RangeTree<'a>) -> &'a mut RangeTree<'a> {`
			`self.0.alloc(value)`
			`}`
			`}`

			`#[derive(Eq, PartialEq, Debug)]`
			`pub struct RangeTree<'a> {`
			`pub start: usize,`
			`pub end: usize,`
			`pub delta: i64,`
			`pub children: Vec<&'a mut RangeTree<'a>>,`
			`}`

			`impl<'rt> RangeTree<'rt> {`
			`pub fn new<'a>(`
			`start: usize,`
			`end: usize,`
			`delta: i64,`
			`children: Vec<&'a mut RangeTree<'a>>,`
			`) -> RangeTree<'a> {`
			`RangeTree {`
			`start,`
			`end,`
			`delta,`
			`children,`
			`}`
			`}`

			`pub fn split<'a>(`
			`rta: &'a RangeTreeArena<'a>,`
			`tree: &'a mut RangeTree<'a>,`
			`value: usize,`
			`) -> (&'a mut RangeTree<'a>, &'a mut RangeTree<'a>) {`
			`let mut left_children: Vec<&'a mut RangeTree<'a>> = Vec::new();`
			`let mut right_children: Vec<&'a mut RangeTree<'a>> = Vec::new();`
			`for child in tree.children.iter_mut() {`
			`if child.end <= value {`
			`left_children.push(child);`
			`} else if value <= child.start {`
			`right_children.push(child);`
			`} else {`
			`let (left_child, right_child) = Self::split(rta, child, value);`
			`left_children.push(left_child);`
			`right_children.push(right_child);`
			`}`
			`}`

			`let left = RangeTree::new(tree.start, value, tree.delta, left_children);`
			`let right = RangeTree::new(value, tree.end, tree.delta, right_children);`
			`(rta.alloc(left), rta.alloc(right))`
			`}`

			`pub fn normalize<'a>(`
			`rta: &'a RangeTreeArena<'a>,`
			`tree: &'a mut RangeTree<'a>,`
			`) -> &'a mut RangeTree<'a> {`
			`tree.children = {`
			`let mut children: Vec<&'a mut RangeTree<'a>> = Vec::new();`
			`let mut chain: Vec<&'a mut RangeTree<'a>> = Vec::new();`
			`for child in tree.children.drain(..) {`
			`let is_chain_end: bool =`
			`match chain.last().map(\|tree\| (tree.delta, tree.end)) {`
			`Some((delta, chain_end)) => {`
			`(delta, chain_end) != (child.delta, child.start)`
			`}`
			`None => false,`
			`};`
			`if is_chain_end {`
			`let mut chain_iter = chain.drain(..);`
			`let mut head: &'a mut RangeTree<'a> = chain_iter.next().unwrap();`
			`for tree in chain_iter {`
			`head.end = tree.end;`
			`for sub_child in tree.children.drain(..) {`
			`sub_child.delta += tree.delta - head.delta;`
			`head.children.push(sub_child);`
			`}`
			`}`
			`children.push(RangeTree::normalize(rta, head));`
			`}`
			`chain.push(child)`
			`}`
			`if !chain.is_empty() {`
			`let mut chain_iter = chain.drain(..);`
			`let mut head: &'a mut RangeTree<'a> = chain_iter.next().unwrap();`
			`for tree in chain_iter {`
			`head.end = tree.end;`
			`for sub_child in tree.children.drain(..) {`
			`sub_child.delta += tree.delta - head.delta;`
			`head.children.push(sub_child);`
			`}`
			`}`
			`children.push(RangeTree::normalize(rta, head));`
			`}`

			`if children.len() == 1`
			`&& children[0].start == tree.start`
			`&& children[0].end == tree.end`
			`{`
			`let normalized = children.remove(0);`
			`normalized.delta += tree.delta;`
			`return normalized;`
			`}`

			`children`
			`};`

			`tree`
			`}`

			`pub fn to_ranges(&self) -> Vec<CoverageRange> {`
			`let mut ranges: Vec<CoverageRange> = Vec::new();`
			`let mut stack: Vec<(&RangeTree, i64)> = vec![(self, 0)];`
			`while let Some((cur, parent_count)) = stack.pop() {`
			`let count: i64 = parent_count + cur.delta;`
			`ranges.push(CoverageRange {`
			`start_offset: cur.start,`
			`end_offset: cur.end,`
			`count,`
			`});`
			`for child in cur.children.iter().rev() {`
			`stack.push((child, count))`
			`}`
			`}`
			`ranges`
			`}`

			`pub fn from_sorted_ranges<'a>(`
			`rta: &'a RangeTreeArena<'a>,`
			`ranges: &[CoverageRange],`
			`) -> Option<&'a mut RangeTree<'a>> {`
			`Self::from_sorted_ranges_inner(`
			`rta,`
			`&mut ranges.iter().peekable(),`
			`::std::usize::MAX,`
			`0,`
			`)`
			`}`

			`fn from_sorted_ranges_inner<'a, 'b, 'c: 'b>(`
			`rta: &'a RangeTreeArena<'a>,`
			`ranges: &'b mut Peekable<impl Iterator<Item = &'c CoverageRange>>,`
			`parent_end: usize,`
			`parent_count: i64,`
			`) -> Option<&'a mut RangeTree<'a>> {`
			`let has_range: bool = match ranges.peek() {`
			`None => false,`
			`Some(range) => range.start_offset < parent_end,`
			`};`
			`if !has_range {`
			`return None;`
			`}`
			`let range = ranges.next().unwrap();`
			`let start: usize = range.start_offset;`
			`let end: usize = range.end_offset;`
			`let count: i64 = range.count;`
			`let delta: i64 = count - parent_count;`
			`let mut children: Vec<&mut RangeTree> = Vec::new();`
			`while let Some(child) =`
			`Self::from_sorted_ranges_inner(rta, ranges, end, count)`
			`{`
			`children.push(child);`
			`}`
			`Some(rta.alloc(RangeTree::new(start, end, delta, children)))`
			`}`
			`}`

			`#[cfg(test)]`
			`mod tests {`
			`use super::*;`

			`#[test]`
			`fn from_sorted_ranges_empty() {`
			`let rta = RangeTreeArena::new();`
			`let inputs: Vec<CoverageRange> = vec![CoverageRange {`
			`start_offset: 0,`
			`end_offset: 9,`
			`count: 1,`
			`}];`
			`let actual: Option<&mut RangeTree> =`
			`RangeTree::from_sorted_ranges(&rta, &inputs);`
			`let expected: Option<&mut RangeTree> =`
			`Some(rta.alloc(RangeTree::new(0, 9, 1, Vec::new())));`

			`assert_eq!(actual, expected);`
			`}`
			`}`