ladybird/AK/ByteBuffer.h

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#pragma once
#include "Types.h"
#include "StdLibExtras.h"
#include <AK/Retainable.h>
#include <AK/RetainPtr.h>
#include <AK/kmalloc.h>
namespace AK {
class ByteBufferImpl : public Retainable<ByteBufferImpl> {
public:
static Retained<ByteBufferImpl> create_uninitialized(int size);
static Retained<ByteBufferImpl> create_zeroed(int);
static Retained<ByteBufferImpl> copy(const void*, int);
static Retained<ByteBufferImpl> wrap(void*, int);
static Retained<ByteBufferImpl> wrap(const void*, int);
static Retained<ByteBufferImpl> adopt(void*, int);
~ByteBufferImpl() { clear(); }
void clear()
{
if (!m_data)
return;
if (m_owned)
kfree(m_data);
m_data = nullptr;
}
byte& operator[](int i) { ASSERT(i < m_size); return m_data[i]; }
const byte& operator[](int i) const { ASSERT(i < m_size); return m_data[i]; }
bool is_empty() const { return !m_size; }
int size() const { return m_size; }
byte* pointer() { return m_data; }
const byte* pointer() const { return m_data; }
byte* offset_pointer(int offset) { return m_data + offset; }
const byte* offset_pointer(int offset) const { return m_data + offset; }
void* end_pointer() { return m_data + m_size; }
const void* end_pointer() const { return m_data + m_size; }
// NOTE: trim() does not reallocate.
void trim(int size)
{
ASSERT(size <= m_size);
m_size = size;
}
void grow(int size);
private:
enum ConstructionMode { Uninitialized, Copy, Wrap, Adopt };
explicit ByteBufferImpl(int); // For ConstructionMode=Uninitialized
ByteBufferImpl(const void*, int, ConstructionMode); // For ConstructionMode=Copy
ByteBufferImpl(void*, int, ConstructionMode); // For ConstructionMode=Wrap/Adopt
ByteBufferImpl() { }
byte* m_data { nullptr };
int m_size { 0 };
bool m_owned { false };
};
class ByteBuffer {
public:
ByteBuffer() { }
ByteBuffer(std::nullptr_t) { }
ByteBuffer(const ByteBuffer& other)
: m_impl(other.m_impl.copy_ref())
{
}
ByteBuffer(ByteBuffer&& other)
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: m_impl(move(other.m_impl))
{
}
ByteBuffer& operator=(ByteBuffer&& other)
{
if (this != &other)
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m_impl = move(other.m_impl);
return *this;
}
ByteBuffer& operator=(const ByteBuffer& other)
{
m_impl = other.m_impl.copy_ref();
return *this;
}
static ByteBuffer create_uninitialized(ssize_t size) { return ByteBuffer(ByteBufferImpl::create_uninitialized(size)); }
static ByteBuffer create_zeroed(ssize_t size) { return ByteBuffer(ByteBufferImpl::create_zeroed(size)); }
static ByteBuffer copy(const void* data, ssize_t size) { return ByteBuffer(ByteBufferImpl::copy(data, size)); }
static ByteBuffer wrap(const void* data, ssize_t size) { return ByteBuffer(ByteBufferImpl::wrap(data, size)); }
static ByteBuffer wrap(void* data, ssize_t size) { return ByteBuffer(ByteBufferImpl::wrap(data, size)); }
static ByteBuffer adopt(void* data, ssize_t size) { return ByteBuffer(ByteBufferImpl::adopt(data, size)); }
~ByteBuffer() { clear(); }
void clear() { m_impl = nullptr; }
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operator bool() const { return !is_null(); }
bool operator!() const { return is_null(); }
bool is_null() const { return m_impl == nullptr; }
byte& operator[](ssize_t i) { ASSERT(m_impl); return (*m_impl)[i]; }
byte operator[](ssize_t i) const { ASSERT(m_impl); return (*m_impl)[i]; }
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bool is_empty() const { return !m_impl || m_impl->is_empty(); }
ssize_t size() const { return m_impl ? m_impl->size() : 0; }
byte* data() { return pointer(); }
const byte* data() const { return pointer(); }
byte* pointer() { return m_impl ? m_impl->pointer() : nullptr; }
const byte* pointer() const { return m_impl ? m_impl->pointer() : nullptr; }
byte* offset_pointer(ssize_t offset) { return m_impl ? m_impl->offset_pointer(offset) : nullptr; }
const byte* offset_pointer(ssize_t offset) const { return m_impl ? m_impl->offset_pointer(offset) : nullptr; }
void* end_pointer() { return m_impl ? m_impl->end_pointer() : nullptr; }
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const void* end_pointer() const { return m_impl ? m_impl->end_pointer() : nullptr; }
ByteBuffer isolated_copy() const
{
if (!m_impl)
return { };
return copy(m_impl->pointer(), m_impl->size());
}
// NOTE: trim() does not reallocate.
void trim(ssize_t size)
{
if (m_impl)
m_impl->trim(size);
}
ByteBuffer slice(ssize_t offset, ssize_t size) const
{
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if (is_null())
return { };
if (offset >= this->size())
return { };
if (offset + size >= this->size())
size = this->size() - offset;
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return copy(offset_pointer(offset), size);
}
void grow(ssize_t size)
{
if (!m_impl)
m_impl = ByteBufferImpl::create_uninitialized(size);
else
m_impl->grow(size);
}
void append(const void* data, int data_size)
{
int old_size = size();
grow(size() + data_size);
memcpy(pointer() + old_size, data, data_size);
}
private:
explicit ByteBuffer(RetainPtr<ByteBufferImpl>&& impl)
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: m_impl(move(impl))
{
}
RetainPtr<ByteBufferImpl> m_impl;
};
inline ByteBufferImpl::ByteBufferImpl(int size)
: m_size(size)
{
m_data = static_cast<byte*>(kmalloc(size));
m_owned = true;
}
inline ByteBufferImpl::ByteBufferImpl(const void* data, int size, ConstructionMode mode)
: m_size(size)
{
ASSERT(mode == Copy);
m_data = static_cast<byte*>(kmalloc(size));
memcpy(m_data, data, size);
m_owned = true;
}
inline ByteBufferImpl::ByteBufferImpl(void* data, ssize_t size, ConstructionMode mode)
: m_data(static_cast<byte*>(data))
, m_size(size)
{
if (mode == Adopt) {
m_owned = true;
} else if (mode == Wrap) {
m_owned = false;
}
}
inline void ByteBufferImpl::grow(ssize_t size)
{
ASSERT(size > m_size);
ASSERT(m_owned);
byte* new_data = static_cast<byte*>(kmalloc(size));
memcpy(new_data, m_data, m_size);
byte* old_data = m_data;
m_data = new_data;
m_size = size;
kfree(old_data);
}
inline Retained<ByteBufferImpl> ByteBufferImpl::create_uninitialized(int size)
{
return ::adopt(*new ByteBufferImpl(size));
}
inline Retained<ByteBufferImpl> ByteBufferImpl::create_zeroed(int size)
{
auto buffer = ::adopt(*new ByteBufferImpl(size));
memset(buffer->pointer(), 0, size);
return buffer;
}
inline Retained<ByteBufferImpl> ByteBufferImpl::copy(const void* data, int size)
{
return ::adopt(*new ByteBufferImpl(data, size, Copy));
}
inline Retained<ByteBufferImpl> ByteBufferImpl::wrap(void* data, int size)
{
return ::adopt(*new ByteBufferImpl(data, size, Wrap));
}
inline Retained<ByteBufferImpl> ByteBufferImpl::wrap(const void* data, int size)
{
return ::adopt(*new ByteBufferImpl(const_cast<void*>(data), size, Wrap));
}
inline Retained<ByteBufferImpl> ByteBufferImpl::adopt(void* data, int size)
{
return ::adopt(*new ByteBufferImpl(data, size, Adopt));
}
}
using AK::ByteBuffer;