mirror of
https://github.com/LadybirdBrowser/ladybird.git
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4758dac218
This is a raffinement of 49cbd4dcca
.
Previously, the container was scanned to compute the size in the unhappy
path. Now, using `all_of` happy and unhappy path should be fast.
395 lines
12 KiB
C++
395 lines
12 KiB
C++
/*
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* Copyright (c) 2021, Ali Mohammad Pur <mpfard@serenityos.org>
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*
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* SPDX-License-Identifier: BSD-2-Clause
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*/
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#pragma once
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#include <AK/AllOf.h>
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#include <AK/Forward.h>
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#include <AK/Span.h>
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#include <AK/StdLibExtras.h>
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namespace AK {
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template<typename ChunkType, bool IsConst>
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struct DisjointIterator {
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struct EndTag {
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};
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using ReferenceType = Conditional<IsConst, AddConst<Vector<ChunkType>>, Vector<ChunkType>>&;
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DisjointIterator(ReferenceType chunks)
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: m_chunks(chunks)
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{
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}
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DisjointIterator(ReferenceType chunks, EndTag)
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: m_chunk_index(chunks.size())
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, m_index_in_chunk(0)
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, m_chunks(chunks)
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{
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}
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DisjointIterator& operator++()
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{
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if (m_chunk_index >= m_chunks.size())
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return *this;
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auto& chunk = m_chunks[m_chunk_index];
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if (m_index_in_chunk + 1 >= chunk.size()) {
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++m_chunk_index;
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m_index_in_chunk = 0;
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} else {
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++m_index_in_chunk;
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}
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if (m_chunk_index < m_chunks.size()) {
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while (m_chunks[m_chunk_index].is_empty())
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++m_chunk_index;
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}
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return *this;
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}
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bool operator==(DisjointIterator const& other) const
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{
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return &other.m_chunks == &m_chunks && other.m_index_in_chunk == m_index_in_chunk && other.m_chunk_index == m_chunk_index;
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}
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auto& operator*() requires(!IsConst) { return m_chunks[m_chunk_index][m_index_in_chunk]; }
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auto* operator->() requires(!IsConst) { return &m_chunks[m_chunk_index][m_index_in_chunk]; }
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auto const& operator*() const { return m_chunks[m_chunk_index][m_index_in_chunk]; }
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auto const* operator->() const { return &m_chunks[m_chunk_index][m_index_in_chunk]; }
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private:
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size_t m_chunk_index { 0 };
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size_t m_index_in_chunk { 0 };
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ReferenceType m_chunks;
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};
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template<typename T>
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class DisjointSpans {
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public:
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DisjointSpans() = default;
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~DisjointSpans() = default;
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DisjointSpans(DisjointSpans const&) = default;
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DisjointSpans(DisjointSpans&&) = default;
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explicit DisjointSpans(Vector<Span<T>> spans)
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: m_spans(move(spans))
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{
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}
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DisjointSpans& operator=(DisjointSpans&&) = default;
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DisjointSpans& operator=(DisjointSpans const&) = default;
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bool operator==(DisjointSpans const& other) const
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{
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if (other.size() != size())
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return false;
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auto it = begin();
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auto other_it = other.begin();
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for (; it != end(); ++it, ++other_it) {
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if (*it != *other_it)
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return false;
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}
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return true;
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}
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T& operator[](size_t index) { return at(index); }
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T const& operator[](size_t index) const { return at(index); }
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T const& at(size_t index) const { return const_cast<DisjointSpans&>(*this).at(index); }
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T& at(size_t index)
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{
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auto value = find(index);
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VERIFY(value != nullptr);
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return *value;
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}
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T* find(size_t index)
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{
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auto span_and_offset = span_around(index);
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if (span_and_offset.offset >= span_and_offset.span.size())
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return nullptr;
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return &span_and_offset.span.at(span_and_offset.offset);
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}
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T const* find(size_t index) const
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{
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return const_cast<DisjointSpans*>(this)->find(index);
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}
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size_t size() const
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{
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size_t size = 0;
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for (auto& span : m_spans)
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size += span.size();
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return size;
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}
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bool is_empty() const
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{
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return all_of(m_spans, [](auto& span) { return span.is_empty(); });
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}
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DisjointSpans slice(size_t start, size_t length) const
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{
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DisjointSpans spans;
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for (auto& span : m_spans) {
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if (length == 0)
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break;
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if (start >= span.size()) {
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start -= span.size();
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continue;
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}
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auto sliced_length = min(length, span.size() - start);
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spans.m_spans.append(span.slice(start, sliced_length));
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start = 0;
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length -= sliced_length;
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}
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// Make sure that we weren't asked to make a slice larger than possible.
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VERIFY(length == 0);
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return spans;
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}
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DisjointSpans slice(size_t start) const { return slice(start, size() - start); }
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DisjointSpans slice_from_end(size_t length) const { return slice(size() - length, length); }
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DisjointIterator<Span<T>, false> begin() { return { m_spans }; }
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DisjointIterator<Span<T>, false> end() { return { m_spans, {} }; }
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DisjointIterator<Span<T>, true> begin() const { return { m_spans }; }
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DisjointIterator<Span<T>, true> end() const { return { m_spans, {} }; }
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private:
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struct SpanAndOffset {
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Span<T>& span;
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size_t offset;
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};
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SpanAndOffset span_around(size_t index)
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{
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size_t offset = 0;
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for (auto& span : m_spans) {
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if (span.is_empty())
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continue;
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auto next_offset = span.size() + offset;
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if (next_offset <= index) {
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offset = next_offset;
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continue;
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}
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return { span, index - offset };
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}
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return { m_spans.last(), index - (offset - m_spans.last().size()) };
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}
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Vector<Span<T>> m_spans;
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};
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template<typename T, typename ChunkType = Vector<T>>
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class DisjointChunks {
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public:
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DisjointChunks() = default;
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~DisjointChunks() = default;
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DisjointChunks(DisjointChunks const&) = default;
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DisjointChunks(DisjointChunks&&) = default;
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DisjointChunks& operator=(DisjointChunks&&) = default;
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DisjointChunks& operator=(DisjointChunks const&) = default;
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void append(ChunkType&& chunk) { m_chunks.append(chunk); }
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void extend(DisjointChunks&& chunks) { m_chunks.extend(move(chunks.m_chunks)); }
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void extend(DisjointChunks const& chunks) { m_chunks.extend(chunks.m_chunks); }
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ChunkType& first_chunk() { return m_chunks.first(); }
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ChunkType& last_chunk() { return m_chunks.last(); }
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ChunkType const& first_chunk() const { return m_chunks.first(); }
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ChunkType const& last_chunk() const { return m_chunks.last(); }
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void ensure_capacity(size_t needed_capacity)
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{
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m_chunks.ensure_capacity(needed_capacity);
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}
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void insert(size_t index, T value)
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{
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if (m_chunks.size() == 1)
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return m_chunks.first().insert(index, value);
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auto chunk_and_offset = chunk_around(index);
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if (!chunk_and_offset.chunk) {
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m_chunks.empend();
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chunk_and_offset.chunk = &m_chunks.last();
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}
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chunk_and_offset.chunk->insert(chunk_and_offset.offset, move(value));
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}
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void clear() { m_chunks.clear(); }
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T& operator[](size_t index) { return at(index); }
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T const& operator[](size_t index) const { return at(index); }
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T const& at(size_t index) const { return const_cast<DisjointChunks&>(*this).at(index); }
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T& at(size_t index)
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{
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auto value = find(index);
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VERIFY(value != nullptr);
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return *value;
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}
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T* find(size_t index)
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{
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if (m_chunks.size() == 1) {
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if (m_chunks.first().size() > index)
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return &m_chunks.first().at(index);
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return nullptr;
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}
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auto chunk_and_offset = chunk_around(index);
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if (!chunk_and_offset.chunk || chunk_and_offset.offset >= chunk_and_offset.chunk->size())
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return nullptr;
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return &chunk_and_offset.chunk->at(chunk_and_offset.offset);
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}
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T const* find(size_t index) const
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{
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return const_cast<DisjointChunks*>(this)->find(index);
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}
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size_t size() const
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{
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size_t sum = 0;
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for (auto& chunk : m_chunks)
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sum += chunk.size();
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return sum;
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}
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bool is_empty() const
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{
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return all_of(m_chunks, [](auto& chunk) { return chunk.is_empty(); });
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}
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DisjointSpans<T> spans() const&
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{
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Vector<Span<T>> spans;
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spans.ensure_capacity(m_chunks.size());
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for (auto& chunk : m_chunks)
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spans.unchecked_append(const_cast<ChunkType&>(chunk).span());
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return DisjointSpans<T> { move(spans) };
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}
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bool operator==(DisjointChunks const& other) const
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{
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if (other.size() != size())
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return false;
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auto it = begin();
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auto other_it = other.begin();
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for (; it != end(); ++it, ++other_it) {
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if (*it != *other_it)
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return false;
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}
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return true;
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}
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DisjointChunks release_slice(size_t start, size_t length) & { return move(*this).slice(start, length); }
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DisjointChunks release_slice(size_t start) & { return move(*this).slice(start); }
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DisjointChunks slice(size_t start, size_t length) &&
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{
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DisjointChunks result;
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for (auto& chunk : m_chunks) {
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if (length == 0)
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break;
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if (start >= chunk.size()) {
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start -= chunk.size();
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continue;
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}
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auto sliced_length = min(length, chunk.size() - start);
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if (start == 0 && sliced_length == chunk.size()) {
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// Happy path! move the chunk itself.
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result.m_chunks.append(move(chunk));
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} else {
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// Shatter the chunk, we were asked for only a part of it :(
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auto wanted_slice = chunk.span().slice(start, sliced_length);
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ChunkType new_chunk;
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if constexpr (IsTriviallyConstructible<T>) {
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new_chunk.resize(wanted_slice.size());
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TypedTransfer<T>::move(new_chunk.data(), wanted_slice.data(), wanted_slice.size());
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} else {
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new_chunk.ensure_capacity(wanted_slice.size());
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for (auto& entry : wanted_slice)
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new_chunk.unchecked_append(move(entry));
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}
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result.m_chunks.append(move(new_chunk));
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chunk.remove(start, sliced_length);
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}
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start = 0;
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length -= sliced_length;
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}
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m_chunks.remove_all_matching([](auto& chunk) { return chunk.is_empty(); });
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// Make sure that we weren't asked to make a slice larger than possible.
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VERIFY(length == 0);
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return result;
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}
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DisjointChunks slice(size_t start) && { return move(*this).slice(start, size() - start); }
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DisjointChunks slice_from_end(size_t length) && { return move(*this).slice(size() - length, length); }
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void flatten()
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{
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if (m_chunks.is_empty())
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return;
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auto size = this->size();
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auto& first_chunk = m_chunks.first();
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first_chunk.ensure_capacity(size);
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bool first = true;
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for (auto& chunk : m_chunks) {
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if (first) {
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first = false;
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continue;
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}
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first_chunk.extend(move(chunk));
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}
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m_chunks.remove(1, m_chunks.size() - 1);
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}
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DisjointIterator<ChunkType, false> begin() { return { m_chunks }; }
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DisjointIterator<ChunkType, false> end() { return { m_chunks, {} }; }
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DisjointIterator<ChunkType, true> begin() const { return { m_chunks }; }
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DisjointIterator<ChunkType, true> end() const { return { m_chunks, {} }; }
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private:
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struct ChunkAndOffset {
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ChunkType* chunk;
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size_t offset;
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};
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ChunkAndOffset chunk_around(size_t index)
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{
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if (m_chunks.is_empty())
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return { nullptr, index };
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size_t offset = 0;
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for (auto& chunk : m_chunks) {
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if (chunk.is_empty())
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continue;
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auto next_offset = chunk.size() + offset;
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if (next_offset <= index) {
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offset = next_offset;
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continue;
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}
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return { &chunk, index - offset };
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}
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return { &m_chunks.last(), index - (offset - m_chunks.last().size()) };
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}
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Vector<ChunkType> m_chunks;
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};
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}
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using AK::DisjointChunks;
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