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use byteorder::{BigEndian, ByteOrder};
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/// A chunk of data to insert, delete or replace in a patch
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///
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/// A chunk is:
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/// - an insertion when `!data.is_empty() && start == end`
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/// - an deletion when `data.is_empty() && start < end`
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/// - a replacement when `!data.is_empty() && start < end`
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/// - not doing anything when `data.is_empty() && start == end`
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#[derive(Debug, Clone)]
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struct PatchFrag<'a> {
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/// The start position of the chunk of data to replace
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start: i32,
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/// The end position of the chunk of data to replace (open end interval)
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end: i32,
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/// The data replacing the chunk
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data: &'a [u8],
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}
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impl<'a> PatchFrag<'a> {
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/// Adjusted start of the chunk to replace.
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///
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/// Offset allow to take into account the growth/shrinkage of data
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/// induced by previously applied chunks.
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fn start_offseted_by(&self, offset: i32) -> i32 {
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self.start + offset
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}
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/// Adjusted end of the chunk to replace.
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///
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/// Offset allow to take into account the growth/shrinkage of data
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/// induced by previously applied chunks.
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fn end_offseted_by(&self, offset: i32) -> i32 {
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self.start_offseted_by(offset) + (self.data.len() as i32)
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}
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/// Length of the replaced chunk.
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fn replaced_len(&self) -> i32 {
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self.end - self.start
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}
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/// Length difference between the replacing data and the replaced data.
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fn len_diff(&self) -> i32 {
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(self.data.len() as i32) - self.replaced_len()
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}
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}
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/// The delta between two revisions data.
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#[derive(Debug, Clone)]
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pub struct PatchList<'a> {
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/// A collection of chunks to apply.
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///
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/// Those chunks are:
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/// - ordered from the left-most replacement to the right-most replacement
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/// - non-overlapping, meaning that two chucks can not change the same
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/// chunk of the patched data
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frags: Vec<PatchFrag<'a>>,
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}
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impl<'a> PatchList<'a> {
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/// Create a `PatchList` from bytes.
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pub fn new(data: &'a [u8]) -> Self {
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let mut frags = vec![];
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let mut data = data;
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while !data.is_empty() {
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let start = BigEndian::read_i32(&data[0..]);
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let end = BigEndian::read_i32(&data[4..]);
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let len = BigEndian::read_i32(&data[8..]);
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assert!(0 <= start && start <= end && len >= 0);
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frags.push(PatchFrag {
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start,
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end,
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data: &data[12..12 + (len as usize)],
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});
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data = &data[12 + (len as usize)..];
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}
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PatchList { frags }
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}
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/// Return the final length of data after patching
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/// given its initial length .
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fn size(&self, initial_size: i32) -> i32 {
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self.frags
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.iter()
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.fold(initial_size, |acc, frag| acc + frag.len_diff())
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}
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/// Apply the patch to some data.
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pub fn apply(&self, initial: &[u8]) -> Vec<u8> {
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let mut last: usize = 0;
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let mut vec =
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Vec::with_capacity(self.size(initial.len() as i32) as usize);
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for PatchFrag { start, end, data } in self.frags.iter() {
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vec.extend(&initial[last..(*start as usize)]);
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vec.extend(data.iter());
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last = *end as usize;
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}
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vec.extend(&initial[last..]);
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vec
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}
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/// Combine two patch lists into a single patch list.
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///
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/// Applying consecutive patches can lead to waste of time and memory
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/// as the changes introduced by one patch can be overridden by the next.
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/// Combining patches optimizes the whole patching sequence.
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fn combine(&mut self, other: &mut Self) -> Self {
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let mut frags = vec![];
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// Keep track of each growth/shrinkage resulting from applying a chunk
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// in order to adjust the start/end of subsequent chunks.
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let mut offset = 0i32;
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// Keep track of the chunk of self.chunks to process.
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let mut pos = 0;
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// For each chunk of `other`, chunks of `self` are processed
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// until they start after the end of the current chunk.
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for PatchFrag { start, end, data } in other.frags.iter() {
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// Add chunks of `self` that start before this chunk of `other`
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// without overlap.
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while pos < self.frags.len()
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&& self.frags[pos].end_offseted_by(offset) <= *start
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{
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let first = self.frags[pos].clone();
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offset += first.len_diff();
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frags.push(first);
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pos += 1;
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}
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// The current chunk of `self` starts before this chunk of `other`
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// with overlap.
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// The left-most part of data is added as an insertion chunk.
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// The right-most part data is kept in the chunk.
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if pos < self.frags.len()
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&& self.frags[pos].start_offseted_by(offset) < *start
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{
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let first = &mut self.frags[pos];
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let (data_left, data_right) = first.data.split_at(
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(*start - first.start_offseted_by(offset)) as usize,
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);
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let left = PatchFrag {
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start: first.start,
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end: first.start,
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data: data_left,
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};
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first.data = data_right;
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offset += left.len_diff();
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frags.push(left);
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// There is no index incrementation because the right-most part
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// needs further examination.
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}
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// At this point remaining chunks of `self` starts after
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// the current chunk of `other`.
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// `start_offset` will be used to adjust the start of the current
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// chunk of `other`.
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// Offset tracking continues with `end_offset` to adjust the end
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// of the current chunk of `other`.
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let mut next_offset = offset;
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// Discard the chunks of `self` that are totally overridden
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// by the current chunk of `other`
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while pos < self.frags.len()
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&& self.frags[pos].end_offseted_by(next_offset) <= *end
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{
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let first = &self.frags[pos];
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next_offset += first.len_diff();
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pos += 1;
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}
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// Truncate the left-most part of chunk of `self` that overlaps
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// the current chunk of `other`.
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if pos < self.frags.len()
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&& self.frags[pos].start_offseted_by(next_offset) < *end
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{
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let first = &mut self.frags[pos];
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let how_much_to_discard =
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*end - first.start_offseted_by(next_offset);
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first.data = &first.data[(how_much_to_discard as usize)..];
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next_offset += how_much_to_discard;
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}
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// Add the chunk of `other` with adjusted position.
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frags.push(PatchFrag {
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start: *start - offset,
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end: *end - next_offset,
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data,
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});
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// Go back to normal offset tracking for the next `o` chunk
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offset = next_offset;
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}
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// Add remaining chunks of `self`.
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for elt in &self.frags[pos..] {
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frags.push(elt.clone());
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}
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PatchList { frags }
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}
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}
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/// Combine a list of patch list into a single patch optimized patch list.
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pub fn fold_patch_lists<'a>(lists: &[PatchList<'a>]) -> PatchList<'a> {
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if lists.len() <= 1 {
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if lists.is_empty() {
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PatchList { frags: vec![] }
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} else {
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lists[0].clone()
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}
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} else {
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let (left, right) = lists.split_at(lists.len() / 2);
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let mut left_res = fold_patch_lists(left);
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let mut right_res = fold_patch_lists(right);
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left_res.combine(&mut right_res)
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}
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}
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#[cfg(test)]
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mod tests {
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use super::*;
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struct PatchDataBuilder {
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data: Vec<u8>,
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}
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impl PatchDataBuilder {
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pub fn new() -> Self {
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Self { data: vec![] }
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}
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pub fn replace(
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&mut self,
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start: usize,
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end: usize,
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data: &[u8],
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) -> &mut Self {
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assert!(start <= end);
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self.data.extend(&(start as i32).to_be_bytes());
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self.data.extend(&(end as i32).to_be_bytes());
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self.data.extend(&(data.len() as i32).to_be_bytes());
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self.data.extend(data.iter());
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self
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}
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pub fn get(&mut self) -> &[u8] {
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&self.data
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}
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}
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#[test]
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fn test_ends_before() {
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let data = vec![0u8, 0u8, 0u8];
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let mut patch1_data = PatchDataBuilder::new();
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patch1_data.replace(0, 1, &[1, 2]);
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let mut patch1 = PatchList::new(patch1_data.get());
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let mut patch2_data = PatchDataBuilder::new();
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patch2_data.replace(2, 4, &[3, 4]);
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let mut patch2 = PatchList::new(patch2_data.get());
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let patch = patch1.combine(&mut patch2);
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let result = patch.apply(&data);
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assert_eq!(result, vec![1u8, 2, 3, 4]);
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}
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#[test]
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fn test_starts_after() {
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let data = vec![0u8, 0u8, 0u8];
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let mut patch1_data = PatchDataBuilder::new();
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patch1_data.replace(2, 3, &[3]);
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let mut patch1 = PatchList::new(patch1_data.get());
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let mut patch2_data = PatchDataBuilder::new();
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patch2_data.replace(1, 2, &[1, 2]);
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let mut patch2 = PatchList::new(patch2_data.get());
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let patch = patch1.combine(&mut patch2);
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let result = patch.apply(&data);
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assert_eq!(result, vec![0u8, 1, 2, 3]);
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}
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#[test]
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fn test_overridden() {
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let data = vec![0u8, 0, 0];
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let mut patch1_data = PatchDataBuilder::new();
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patch1_data.replace(1, 2, &[3, 4]);
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let mut patch1 = PatchList::new(patch1_data.get());
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let mut patch2_data = PatchDataBuilder::new();
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patch2_data.replace(1, 4, &[1, 2, 3]);
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let mut patch2 = PatchList::new(patch2_data.get());
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let patch = patch1.combine(&mut patch2);
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let result = patch.apply(&data);
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assert_eq!(result, vec![0u8, 1, 2, 3]);
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}
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#[test]
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fn test_right_most_part_is_overridden() {
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let data = vec![0u8, 0, 0];
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let mut patch1_data = PatchDataBuilder::new();
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patch1_data.replace(0, 1, &[1, 3]);
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let mut patch1 = PatchList::new(patch1_data.get());
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let mut patch2_data = PatchDataBuilder::new();
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patch2_data.replace(1, 4, &[2, 3, 4]);
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let mut patch2 = PatchList::new(patch2_data.get());
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let patch = patch1.combine(&mut patch2);
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let result = patch.apply(&data);
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assert_eq!(result, vec![1u8, 2, 3, 4]);
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}
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#[test]
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fn test_left_most_part_is_overridden() {
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let data = vec![0u8, 0, 0];
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let mut patch1_data = PatchDataBuilder::new();
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patch1_data.replace(1, 3, &[1, 3, 4]);
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let mut patch1 = PatchList::new(patch1_data.get());
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let mut patch2_data = PatchDataBuilder::new();
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patch2_data.replace(0, 2, &[1, 2]);
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let mut patch2 = PatchList::new(patch2_data.get());
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let patch = patch1.combine(&mut patch2);
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let result = patch.apply(&data);
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assert_eq!(result, vec![1u8, 2, 3, 4]);
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}
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#[test]
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fn test_mid_is_overridden() {
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let data = vec![0u8, 0, 0];
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let mut patch1_data = PatchDataBuilder::new();
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patch1_data.replace(0, 3, &[1, 3, 3, 4]);
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let mut patch1 = PatchList::new(patch1_data.get());
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let mut patch2_data = PatchDataBuilder::new();
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patch2_data.replace(1, 3, &[2, 3]);
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let mut patch2 = PatchList::new(patch2_data.get());
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let patch = patch1.combine(&mut patch2);
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let result = patch.apply(&data);
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assert_eq!(result, vec![1u8, 2, 3, 4]);
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}
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}
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