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4296425bd8
C++20 can automatically synthesize `operator!=` from `operator==`, so there is no point in writing such functions by hand if all they do is call through to `operator==`. This fixes a compile error with compilers that implement P2468 (Clang 16 currently). This paper restores the C++17 behavior that if both `T::operator==(U)` and `T::operator!=(U)` exist, `U == T` won't be rewritten in reverse to call `T::operator==(U)`. Removing `!=` operators makes the rewriting possible again. See https://reviews.llvm.org/D134529#3853062
332 lines
9.1 KiB
C++
332 lines
9.1 KiB
C++
/*
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* Copyright (c) 2018-2021, Andreas Kling <kling@serenityos.org>
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* Copyright (c) 2021, Gunnar Beutner <gbeutner@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/Assertions.h>
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#include <AK/Error.h>
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#include <AK/Span.h>
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#include <AK/Types.h>
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#include <AK/kmalloc.h>
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namespace AK {
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namespace Detail {
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template<size_t inline_capacity>
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class ByteBuffer {
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public:
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ByteBuffer() = default;
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~ByteBuffer()
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{
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clear();
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}
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ByteBuffer(ByteBuffer const& other)
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{
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MUST(try_resize(other.size()));
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VERIFY(m_size == other.size());
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__builtin_memcpy(data(), other.data(), other.size());
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}
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ByteBuffer(ByteBuffer&& other)
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{
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move_from(move(other));
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}
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ByteBuffer& operator=(ByteBuffer&& other)
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{
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if (this != &other) {
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if (!m_inline)
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kfree_sized(m_outline_buffer, m_outline_capacity);
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move_from(move(other));
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}
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return *this;
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}
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ByteBuffer& operator=(ByteBuffer const& other)
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{
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if (this != &other) {
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if (m_size > other.size()) {
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trim(other.size(), true);
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} else {
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MUST(try_resize(other.size()));
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}
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__builtin_memcpy(data(), other.data(), other.size());
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}
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return *this;
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}
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[[nodiscard]] static ErrorOr<ByteBuffer> create_uninitialized(size_t size)
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{
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auto buffer = ByteBuffer();
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TRY(buffer.try_resize(size));
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return { move(buffer) };
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}
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[[nodiscard]] static ErrorOr<ByteBuffer> create_zeroed(size_t size)
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{
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auto buffer = TRY(create_uninitialized(size));
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buffer.zero_fill();
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VERIFY(size == 0 || (buffer[0] == 0 && buffer[size - 1] == 0));
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return { move(buffer) };
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}
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[[nodiscard]] static ErrorOr<ByteBuffer> copy(void const* data, size_t size)
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{
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auto buffer = TRY(create_uninitialized(size));
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if (buffer.m_inline && size > inline_capacity)
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__builtin_unreachable();
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if (size != 0)
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__builtin_memcpy(buffer.data(), data, size);
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return { move(buffer) };
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}
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[[nodiscard]] static ErrorOr<ByteBuffer> copy(ReadonlyBytes bytes)
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{
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return copy(bytes.data(), bytes.size());
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}
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template<size_t other_inline_capacity>
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bool operator==(ByteBuffer<other_inline_capacity> const& other) const
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{
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if (size() != other.size())
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return false;
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// So they both have data, and the same length.
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return !__builtin_memcmp(data(), other.data(), size());
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}
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[[nodiscard]] u8& operator[](size_t i)
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{
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VERIFY(i < m_size);
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return data()[i];
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}
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[[nodiscard]] u8 const& operator[](size_t i) const
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{
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VERIFY(i < m_size);
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return data()[i];
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}
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[[nodiscard]] bool is_empty() const { return m_size == 0; }
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[[nodiscard]] size_t size() const { return m_size; }
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[[nodiscard]] u8* data() { return m_inline ? m_inline_buffer : m_outline_buffer; }
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[[nodiscard]] u8 const* data() const { return m_inline ? m_inline_buffer : m_outline_buffer; }
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[[nodiscard]] Bytes bytes() { return { data(), size() }; }
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[[nodiscard]] ReadonlyBytes bytes() const { return { data(), size() }; }
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[[nodiscard]] AK::Span<u8> span() { return { data(), size() }; }
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[[nodiscard]] AK::Span<u8 const> span() const { return { data(), size() }; }
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[[nodiscard]] u8* offset_pointer(size_t offset) { return data() + offset; }
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[[nodiscard]] u8 const* offset_pointer(size_t offset) const { return data() + offset; }
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[[nodiscard]] void* end_pointer() { return data() + m_size; }
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[[nodiscard]] void const* end_pointer() const { return data() + m_size; }
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[[nodiscard]] ErrorOr<ByteBuffer> slice(size_t offset, size_t size) const
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{
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// I cannot hand you a slice I don't have
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VERIFY(offset + size <= this->size());
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return copy(offset_pointer(offset), size);
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}
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void clear()
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{
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if (!m_inline) {
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kfree_sized(m_outline_buffer, m_outline_capacity);
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m_inline = true;
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}
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m_size = 0;
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}
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ALWAYS_INLINE void resize(size_t new_size)
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{
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MUST(try_resize(new_size));
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}
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ALWAYS_INLINE void ensure_capacity(size_t new_capacity)
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{
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MUST(try_ensure_capacity(new_capacity));
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}
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ErrorOr<void> try_resize(size_t new_size)
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{
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if (new_size <= m_size) {
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trim(new_size, false);
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return {};
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}
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TRY(try_ensure_capacity(new_size));
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m_size = new_size;
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return {};
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}
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ErrorOr<void> try_ensure_capacity(size_t new_capacity)
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{
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if (new_capacity <= capacity())
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return {};
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return try_ensure_capacity_slowpath(new_capacity);
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}
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/// Return a span of bytes past the end of this ByteBuffer for writing.
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/// Ensures that the required space is available.
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ErrorOr<Bytes> get_bytes_for_writing(size_t length)
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{
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auto const old_size = size();
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TRY(try_resize(old_size + length));
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return Bytes { data() + old_size, length };
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}
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/// Like get_bytes_for_writing, but crashes if allocation fails.
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Bytes must_get_bytes_for_writing(size_t length)
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{
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return MUST(get_bytes_for_writing(length));
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}
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void append(u8 byte)
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{
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MUST(try_append(byte));
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}
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void append(ReadonlyBytes bytes)
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{
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MUST(try_append(bytes));
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}
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void append(void const* data, size_t data_size) { append({ data, data_size }); }
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ErrorOr<void> try_append(u8 byte)
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{
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auto old_size = size();
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auto new_size = old_size + 1;
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VERIFY(new_size > old_size);
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TRY(try_resize(new_size));
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data()[old_size] = byte;
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return {};
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}
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ErrorOr<void> try_append(ReadonlyBytes bytes)
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{
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return try_append(bytes.data(), bytes.size());
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}
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ErrorOr<void> try_append(void const* data, size_t data_size)
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{
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if (data_size == 0)
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return {};
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VERIFY(data != nullptr);
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auto old_size = size();
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TRY(try_resize(size() + data_size));
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__builtin_memcpy(this->data() + old_size, data, data_size);
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return {};
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}
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void operator+=(ByteBuffer const& other)
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{
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MUST(try_append(other.data(), other.size()));
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}
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void overwrite(size_t offset, void const* data, size_t data_size)
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{
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// make sure we're not told to write past the end
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VERIFY(offset + data_size <= size());
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__builtin_memmove(this->data() + offset, data, data_size);
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}
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void zero_fill()
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{
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__builtin_memset(data(), 0, m_size);
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}
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operator Bytes() { return bytes(); }
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operator ReadonlyBytes() const { return bytes(); }
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ALWAYS_INLINE size_t capacity() const { return m_inline ? inline_capacity : m_outline_capacity; }
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private:
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void move_from(ByteBuffer&& other)
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{
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m_size = other.m_size;
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m_inline = other.m_inline;
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if (!other.m_inline) {
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m_outline_buffer = other.m_outline_buffer;
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m_outline_capacity = other.m_outline_capacity;
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} else {
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VERIFY(other.m_size <= inline_capacity);
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__builtin_memcpy(m_inline_buffer, other.m_inline_buffer, other.m_size);
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}
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other.m_size = 0;
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other.m_inline = true;
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}
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void trim(size_t size, bool may_discard_existing_data)
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{
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VERIFY(size <= m_size);
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if (!m_inline && size <= inline_capacity)
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shrink_into_inline_buffer(size, may_discard_existing_data);
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m_size = size;
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}
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NEVER_INLINE void shrink_into_inline_buffer(size_t size, bool may_discard_existing_data)
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{
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// m_inline_buffer and m_outline_buffer are part of a union, so save the pointer
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auto* outline_buffer = m_outline_buffer;
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auto outline_capacity = m_outline_capacity;
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if (!may_discard_existing_data)
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__builtin_memcpy(m_inline_buffer, outline_buffer, size);
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kfree_sized(outline_buffer, outline_capacity);
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m_inline = true;
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}
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NEVER_INLINE ErrorOr<void> try_ensure_capacity_slowpath(size_t new_capacity)
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{
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new_capacity = kmalloc_good_size(new_capacity);
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auto* new_buffer = (u8*)kmalloc(new_capacity);
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if (!new_buffer)
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return Error::from_errno(ENOMEM);
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if (m_inline) {
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__builtin_memcpy(new_buffer, data(), m_size);
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} else if (m_outline_buffer) {
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__builtin_memcpy(new_buffer, m_outline_buffer, min(new_capacity, m_outline_capacity));
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kfree_sized(m_outline_buffer, m_outline_capacity);
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}
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m_outline_buffer = new_buffer;
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m_outline_capacity = new_capacity;
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m_inline = false;
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return {};
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}
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union {
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u8 m_inline_buffer[inline_capacity];
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struct {
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u8* m_outline_buffer;
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size_t m_outline_capacity;
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};
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};
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size_t m_size { 0 };
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bool m_inline { true };
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};
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}
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template<>
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struct Traits<ByteBuffer> : public GenericTraits<ByteBuffer> {
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static unsigned hash(ByteBuffer const& byte_buffer)
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{
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return Traits<ReadonlyBytes>::hash(byte_buffer.span());
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}
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};
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}
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