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/*
* Copyright (c) 2021, Jan de Visser <jan@de-visser.net>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <cstring>
#include <AK/String.h>
#include <AK/StringBuilder.h>
#include <LibSQL/Serializer.h>
#include <LibSQL/Tuple.h>
#include <LibSQL/TupleDescriptor.h>
#include <LibSQL/Value.h>
namespace SQL {
Tuple::Tuple()
: m_descriptor(adopt_ref(*new TupleDescriptor))
, m_data()
{
}
Tuple::Tuple(NonnullRefPtr<TupleDescriptor> const& descriptor, u32 pointer)
: m_descriptor(descriptor)
, m_data()
, m_pointer(pointer)
{
for (auto& element : *descriptor) {
m_data.empend(element.type);
}
}
Tuple::Tuple(NonnullRefPtr<TupleDescriptor> const& descriptor, Serializer& serializer)
: Tuple(descriptor)
{
deserialize(serializer);
}
void Tuple::deserialize(Serializer& serializer)
{
dbgln_if(SQL_DEBUG, "deserialize tuple at offset {}", serializer.offset());
serializer.deserialize_to<u32>(m_pointer);
dbgln_if(SQL_DEBUG, "pointer: {}", m_pointer);
auto sz = serializer.deserialize<u32>();
m_data.clear();
m_descriptor->clear();
for (auto ix = 0u; ix < sz; ++ix) {
m_descriptor->append(serializer.deserialize<TupleElementDescriptor>());
m_data.append(serializer.deserialize<Value>());
}
}
void Tuple::serialize(Serializer& serializer) const
{
VERIFY(m_descriptor->size() == m_data.size());
dbgln_if(SQL_DEBUG, "Serializing tuple pointer {}", pointer());
serializer.serialize<u32>(pointer());
serializer.serialize<u32>((u32)m_descriptor->size());
for (auto ix = 0u; ix < m_descriptor->size(); ix++) {
auto& key_part = m_data[ix];
serializer.serialize<TupleElementDescriptor>((*m_descriptor)[ix]);
serializer.serialize<Value>(key_part);
}
}
Tuple::Tuple(Tuple const& other)
: m_descriptor(other.m_descriptor)
, m_data()
{
copy_from(other);
}
Tuple& Tuple::operator=(Tuple const& other)
{
if (this != &other) {
copy_from(other);
}
return *this;
}
Optional<size_t> Tuple::index_of(String name) const
{
auto n = move(name);
for (auto ix = 0u; ix < m_descriptor->size(); ix++) {
auto& part = (*m_descriptor)[ix];
if (part.name == n) {
return (int)ix;
}
}
return {};
}
Value const& Tuple::operator[](size_t ix) const
{
VERIFY(ix < m_data.size());
return m_data[ix];
}
Value& Tuple::operator[](size_t ix)
{
VERIFY(ix < m_data.size());
return m_data[ix];
}
Value const& Tuple::operator[](String const& name) const
{
auto index = index_of(name);
VERIFY(index.has_value());
return (*this)[index.value()];
}
Value& Tuple::operator[](String const& name)
{
auto index = index_of(name);
VERIFY(index.has_value());
return (*this)[index.value()];
}
void Tuple::append(const Value& value)
{
VERIFY(m_descriptor->size() == 0);
m_data.append(value);
}
Tuple& Tuple::operator+=(Value const& value)
{
append(value);
return *this;
}
bool Tuple::is_compatible(Tuple const& other) const
{
if ((m_descriptor->size() == 0) && (other.m_descriptor->size() == 0)) {
return true;
}
if (m_descriptor->size() != other.m_descriptor->size()) {
return false;
}
for (auto ix = 0u; ix < m_descriptor->size(); ix++) {
auto& my_part = (*m_descriptor)[ix];
auto& other_part = (*other.m_descriptor)[ix];
if (my_part.type != other_part.type) {
return false;
}
if (my_part.order != other_part.order) {
return false;
}
}
return true;
}
size_t Tuple::length() const
{
size_t len = 2 * sizeof(u32);
for (auto ix = 0u; ix < m_descriptor->size(); ix++) {
auto& descriptor = (*m_descriptor)[ix];
auto& value = m_data[ix];
len += descriptor.length();
len += value.length();
}
return len;
}
String Tuple::to_string() const
{
StringBuilder builder;
for (auto& part : m_data) {
if (!builder.is_empty()) {
builder.append('|');
}
builder.append(part.to_string());
}
if (pointer() != 0) {
builder.appendff(":{}", pointer());
}
return builder.build();
}
Vector<String> Tuple::to_string_vector() const
{
Vector<String> ret;
for (auto& value : m_data) {
ret.append(value.to_string());
}
return ret;
}
void Tuple::copy_from(const Tuple& other)
{
if (*m_descriptor != *other.m_descriptor) {
m_descriptor->clear();
for (TupleElementDescriptor const& part : *other.m_descriptor) {
m_descriptor->append(part);
}
}
m_data.clear();
for (auto& part : other.m_data) {
m_data.append(part);
}
m_pointer = other.pointer();
}
int Tuple::compare(const Tuple& other) const
{
auto num_values = min(m_data.size(), other.m_data.size());
VERIFY(num_values > 0);
for (auto ix = 0u; ix < num_values; ix++) {
auto ret = m_data[ix].compare(other.m_data[ix]);
if (ret != 0) {
if ((ix < m_descriptor->size()) && (*m_descriptor)[ix].order == Order::Descending)
ret = -ret;
return ret;
}
}
return 0;
}
int Tuple::match(const Tuple& other) const
{
auto other_index = 0u;
for (auto& part : *other.descriptor()) {
auto other_value = other[other_index];
if (other_value.is_null())
return 0;
auto my_index = index_of(part.name);
if (!my_index.has_value())
return -1;
auto ret = m_data[my_index.value()].compare(other_value);
if (ret != 0)
return ((*m_descriptor)[my_index.value()].order == Order::Descending) ? -ret : ret;
other_index++;
}
return 0;
}
u32 Tuple::hash() const
{
u32 ret = 0u;
for (auto& value : m_data) {
// This is an extension of the pair_int_hash function from AK/HashFunctions.h:
if (!ret)
ret = value.hash();
else
ret = int_hash((ret * 209) ^ (value.hash() * 413));
}
return ret;
}
}
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