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compound_compat.hh
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compound_compat.hh
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/*
* Copyright (C) 2015 ScyllaDB
*/
/*
* This file is part of Scylla.
*
* Scylla is free software: you can redistribute it and/or modify
* it under the terms of the GNU Affero General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* Scylla is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with Scylla. If not, see <http://www.gnu.org/licenses/>.
*/
#pragma once
#include <boost/range/algorithm/copy.hpp>
#include <boost/range/adaptor/transformed.hpp>
#include "compound.hh"
#include "schema.hh"
//
// This header provides adaptors between the representation used by our compound_type<>
// and representation used by Origin.
//
// For single-component keys the legacy representation is equivalent
// to the only component's serialized form. For composite keys it the following
// (See org.apache.cassandra.db.marshal.CompositeType):
//
// <representation> ::= ( <component> )+
// <component> ::= <length> <value> <EOC>
// <length> ::= <uint16_t>
// <EOC> ::= <uint8_t>
//
// <value> is component's value in serialized form. <EOC> is always 0 for partition key.
//
// Given a representation serialized using @CompoundType, provides a view on the
// representation of the same components as they would be serialized by Origin.
//
// The view is exposed in a form of a byte range. For example of use see to_legacy() function.
template <typename CompoundType>
class legacy_compound_view {
static_assert(!CompoundType::is_prefixable, "Legacy view not defined for prefixes");
CompoundType& _type;
bytes_view _packed;
public:
legacy_compound_view(CompoundType& c, bytes_view packed)
: _type(c)
, _packed(packed)
{ }
class iterator : public std::iterator<std::input_iterator_tag, bytes::value_type> {
bool _singular;
// Offset within virtual output space of a component.
//
// Offset: -2 -1 0 ... LEN-1 LEN
// Field: [ length MSB ] [ length LSB ] [ VALUE ] [ EOC ]
//
int32_t _offset;
typename CompoundType::iterator _i;
public:
struct end_tag {};
iterator(const legacy_compound_view& v)
: _singular(v._type.is_singular())
, _offset(_singular ? 0 : -2)
, _i(v._type.begin(v._packed))
{ }
iterator(const legacy_compound_view& v, end_tag)
: _offset(-2)
, _i(v._type.end(v._packed))
{ }
value_type operator*() const {
int32_t component_size = _i->size();
if (_offset == -2) {
return (component_size >> 8) & 0xff;
} else if (_offset == -1) {
return component_size & 0xff;
} else if (_offset < component_size) {
return (*_i)[_offset];
} else { // _offset == component_size
return 0; // EOC field
}
}
iterator& operator++() {
auto component_size = (int32_t) _i->size();
if (_offset < component_size
// When _singular, we skip the EOC byte.
&& (!_singular || _offset != (component_size - 1)))
{
++_offset;
} else {
++_i;
_offset = -2;
}
return *this;
}
bool operator==(const iterator& other) const {
return _offset == other._offset && other._i == _i;
}
bool operator!=(const iterator& other) const {
return !(*this == other);
}
};
// A trichotomic comparator defined on @CompoundType representations which
// orders them according to lexicographical ordering of their corresponding
// legacy representations.
//
// tri_comparator(t)(k1, k2)
//
// ...is equivalent to:
//
// compare_unsigned(to_legacy(t, k1), to_legacy(t, k2))
//
// ...but more efficient.
//
struct tri_comparator {
const CompoundType& _type;
tri_comparator(const CompoundType& type)
: _type(type)
{ }
// @k1 and @k2 must be serialized using @type, which was passed to the constructor.
int operator()(bytes_view k1, bytes_view k2) const {
if (_type.is_singular()) {
return compare_unsigned(*_type.begin(k1), *_type.begin(k2));
}
return lexicographical_tri_compare(
_type.begin(k1), _type.end(k1),
_type.begin(k2), _type.end(k2),
[] (const bytes_view& c1, const bytes_view& c2) -> int {
if (c1.size() != c2.size()) {
return c1.size() < c2.size() ? -1 : 1;
}
return memcmp(c1.begin(), c2.begin(), c1.size());
});
}
};
// Equivalent to std::distance(begin(), end()), but computes faster
size_t size() const {
if (_type.is_singular()) {
return _type.begin(_packed)->size();
}
size_t s = 0;
for (auto&& component : _type.components(_packed)) {
s += 2 /* length field */ + component.size() + 1 /* EOC */;
}
return s;
}
iterator begin() const {
return iterator(*this);
}
iterator end() const {
return iterator(*this, typename iterator::end_tag());
}
};
// Converts compound_type<> representation to legacy representation
// @packed is assumed to be serialized using supplied @type.
template <typename CompoundType>
static inline
bytes to_legacy(CompoundType& type, bytes_view packed) {
legacy_compound_view<CompoundType> lv(type, packed);
bytes legacy_form(bytes::initialized_later(), lv.size());
std::copy(lv.begin(), lv.end(), legacy_form.begin());
return legacy_form;
}
class composite_view;
// Represents a value serialized according to Origin's CompositeType.
// If is_compound is true, then the value is one or more components encoded as:
//
// <representation> ::= ( <component> )+
// <component> ::= <length> <value> <EOC>
// <length> ::= <uint16_t>
// <EOC> ::= <uint8_t>
//
// If false, then it encodes a single value, without a prefix length or a suffix EOC.
class composite final {
bytes _bytes;
bool _is_compound;
public:
composite(bytes&& b, bool is_compound)
: _bytes(std::move(b))
, _is_compound(is_compound)
{ }
explicit composite(bytes&& b)
: _bytes(std::move(b))
, _is_compound(true)
{ }
composite()
: _bytes()
, _is_compound(true)
{ }
using size_type = uint16_t;
using eoc_type = int8_t;
/*
* The 'end-of-component' byte should always be 0 for actual column name.
* However, it can set to 1 for query bounds. This allows to query for the
* equivalent of 'give me the full range'. That is, if a slice query is:
* start = <3><"foo".getBytes()><0>
* end = <3><"foo".getBytes()><1>
* then we'll return *all* the columns whose first component is "foo".
* If for a component, the 'end-of-component' is != 0, there should not be any
* following component. The end-of-component can also be -1 to allow
* non-inclusive query. For instance:
* end = <3><"foo".getBytes()><-1>
* allows to query everything that is smaller than <3><"foo".getBytes()>, but
* not <3><"foo".getBytes()> itself.
*/
enum class eoc : eoc_type {
start = -1,
none = 0,
end = 1
};
using component = std::pair<bytes, eoc>;
using component_view = std::pair<bytes_view, eoc>;
private:
template<typename Value, typename = std::enable_if_t<!std::is_same<const data_value, std::decay_t<Value>>::value>>
static size_t size(const Value& val) {
return val.size();
}
static size_t size(const data_value& val) {
return val.serialized_size();
}
template<typename Value, typename = std::enable_if_t<!std::is_same<data_value, std::decay_t<Value>>::value>>
static void write_value(Value&& val, bytes::iterator& out) {
out = std::copy(val.begin(), val.end(), out);
}
static void write_value(const data_value& val, bytes::iterator& out) {
val.serialize(out);
}
template<typename RangeOfSerializedComponents>
static void serialize_value(RangeOfSerializedComponents&& values, bytes::iterator& out, bool is_compound) {
if (!is_compound) {
auto it = values.begin();
write_value(std::forward<decltype(*it)>(*it), out);
return;
}
for (auto&& val : values) {
write<size_type>(out, static_cast<size_type>(size(val)));
write_value(std::forward<decltype(val)>(val), out);
// Range tombstones are not keys. For collections, only frozen
// values can be keys. Therefore, for as long as it is safe to
// assume that this code will be used to create keys, it is safe
// to assume the trailing byte is always zero.
write<eoc_type>(out, eoc_type(eoc::none));
}
}
template <typename RangeOfSerializedComponents>
static size_t serialized_size(RangeOfSerializedComponents&& values, bool is_compound) {
size_t len = 0;
auto it = values.begin();
if (it != values.end()) {
// CQL3 uses a specific prefix (0xFFFF) to encode "static columns"
// (CASSANDRA-6561). This does mean the maximum size of the first component of a
// composite is 65534, not 65535 (or we wouldn't be able to detect if the first 2
// bytes is the static prefix or not).
auto value_size = size(*it);
if (value_size > static_cast<size_type>(std::numeric_limits<size_type>::max() - uint8_t(is_compound))) {
throw std::runtime_error(sprint("First component size too large: %d > %d", value_size, std::numeric_limits<size_type>::max() - is_compound));
}
if (!is_compound) {
return value_size;
}
len += sizeof(size_type) + value_size + sizeof(eoc_type);
++it;
}
for ( ; it != values.end(); ++it) {
auto value_size = size(*it);
if (value_size > std::numeric_limits<size_type>::max()) {
throw std::runtime_error(sprint("Component size too large: %d > %d", value_size, std::numeric_limits<size_type>::max()));
}
len += sizeof(size_type) + value_size + sizeof(eoc_type);
}
return len;
}
public:
template <typename Describer>
auto describe_type(Describer f) const {
return f(const_cast<bytes&>(_bytes));
}
// marker is ignored if !is_compound
template<typename RangeOfSerializedComponents>
static composite serialize_value(RangeOfSerializedComponents&& values, bool is_compound = true, eoc marker = eoc::none) {
auto size = serialized_size(values, is_compound);
bytes b(bytes::initialized_later(), size);
auto i = b.begin();
serialize_value(std::forward<decltype(values)>(values), i, is_compound);
if (is_compound && !b.empty()) {
b.back() = eoc_type(marker);
}
return composite(std::move(b), is_compound);
}
template<typename RangeOfSerializedComponents>
static composite serialize_static(const schema& s, RangeOfSerializedComponents&& values) {
// FIXME: Optimize
auto b = bytes(size_t(2), bytes::value_type(0xff));
std::vector<bytes_view> sv(s.clustering_key_size());
b += composite::serialize_value(boost::range::join(sv, std::forward<RangeOfSerializedComponents>(values)), true).release_bytes();
return composite(std::move(b));
}
static eoc to_eoc(int8_t eoc_byte) {
return eoc_byte == 0 ? eoc::none : (eoc_byte < 0 ? eoc::start : eoc::end);
}
class iterator : public std::iterator<std::input_iterator_tag, const component_view> {
bytes_view _v;
component_view _current;
private:
void read_current() {
size_type len;
{
if (_v.empty()) {
_v = bytes_view(nullptr, 0);
return;
}
len = read_simple<size_type>(_v);
if (_v.size() < len) {
throw_with_backtrace<marshal_exception>(sprint("composite iterator - not enough bytes, expected %d, got %d", len, _v.size()));
}
}
auto value = bytes_view(_v.begin(), len);
_v.remove_prefix(len);
_current = component_view(std::move(value), to_eoc(read_simple<eoc_type>(_v)));
}
public:
struct end_iterator_tag {};
iterator(const bytes_view& v, bool is_compound, bool is_static)
: _v(v) {
if (is_static) {
_v.remove_prefix(2);
}
if (is_compound) {
read_current();
} else {
_current = component_view(_v, eoc::none);
_v.remove_prefix(_v.size());
}
}
iterator(end_iterator_tag) : _v(nullptr, 0) {}
iterator& operator++() {
read_current();
return *this;
}
iterator operator++(int) {
iterator i(*this);
++(*this);
return i;
}
const value_type& operator*() const { return _current; }
const value_type* operator->() const { return &_current; }
bool operator!=(const iterator& i) const { return _v.begin() != i._v.begin(); }
bool operator==(const iterator& i) const { return _v.begin() == i._v.begin(); }
};
iterator begin() const {
return iterator(_bytes, _is_compound, is_static());
}
iterator end() const {
return iterator(iterator::end_iterator_tag());
}
boost::iterator_range<iterator> components() const & {
return { begin(), end() };
}
auto values() const & {
return components() | boost::adaptors::transformed([](auto&& c) { return c.first; });
}
std::vector<component> components() const && {
std::vector<component> result;
std::transform(begin(), end(), std::back_inserter(result), [](auto&& p) {
return component(bytes(p.first.begin(), p.first.end()), p.second);
});
return result;
}
std::vector<bytes> values() const && {
std::vector<bytes> result;
boost::copy(components() | boost::adaptors::transformed([](auto&& c) { return to_bytes(c.first); }), std::back_inserter(result));
return result;
}
const bytes& get_bytes() const {
return _bytes;
}
bytes release_bytes() && {
return std::move(_bytes);
}
size_t size() const {
return _bytes.size();
}
bool empty() const {
return _bytes.empty();
}
static bool is_static(bytes_view bytes, bool is_compound) {
return is_compound && bytes.size() > 2 && (bytes[0] & bytes[1] & 0xff) == 0xff;
}
bool is_static() const {
return is_static(_bytes, _is_compound);
}
bool is_compound() const {
return _is_compound;
}
template <typename ClusteringElement>
static composite from_clustering_element(const schema& s, const ClusteringElement& ce) {
return serialize_value(ce.components(s), s.is_compound());
}
static composite from_exploded(const std::vector<bytes_view>& v, bool is_compound, eoc marker = eoc::none) {
if (v.size() == 0) {
return composite(bytes(size_t(1), bytes::value_type(marker)), is_compound);
}
return serialize_value(v, is_compound, marker);
}
static composite static_prefix(const schema& s) {
return serialize_static(s, std::vector<bytes_view>());
}
explicit operator bytes_view() const {
return _bytes;
}
template <typename Component>
friend inline std::ostream& operator<<(std::ostream& os, const std::pair<Component, eoc>& c) {
return os << "{value=" << c.first << "; eoc=" << sprint("0x%02x", eoc_type(c.second) & 0xff) << "}";
}
friend std::ostream& operator<<(std::ostream& os, const composite& v);
struct tri_compare {
const std::vector<data_type>& _types;
tri_compare(const std::vector<data_type>& types) : _types(types) {}
int operator()(const composite&, const composite&) const;
int operator()(composite_view, composite_view) const;
};
};
class composite_view final {
bytes_view _bytes;
bool _is_compound;
public:
composite_view(bytes_view b, bool is_compound = true)
: _bytes(b)
, _is_compound(is_compound)
{ }
composite_view(const composite& c)
: composite_view(static_cast<bytes_view>(c), c.is_compound())
{ }
composite_view()
: _bytes(nullptr, 0)
, _is_compound(true)
{ }
std::vector<bytes_view> explode() const {
if (!_is_compound) {
return { _bytes };
}
std::vector<bytes_view> ret;
ret.reserve(8);
for (auto it = begin(), e = end(); it != e; ) {
ret.push_back(it->first);
auto marker = it->second;
++it;
if (it != e && marker != composite::eoc::none) {
throw runtime_exception(sprint("non-zero component divider found (%d) mid", sprint("0x%02x", composite::eoc_type(marker) & 0xff)));
}
}
return ret;
}
composite::iterator begin() const {
return composite::iterator(_bytes, _is_compound, is_static());
}
composite::iterator end() const {
return composite::iterator(composite::iterator::end_iterator_tag());
}
boost::iterator_range<composite::iterator> components() const {
return { begin(), end() };
}
composite::eoc last_eoc() const {
if (!_is_compound || _bytes.empty()) {
return composite::eoc::none;
}
bytes_view v(_bytes);
v.remove_prefix(v.size() - 1);
return composite::to_eoc(read_simple<composite::eoc_type>(v));
}
auto values() const {
return components() | boost::adaptors::transformed([](auto&& c) { return c.first; });
}
size_t size() const {
return _bytes.size();
}
bool empty() const {
return _bytes.empty();
}
bool is_static() const {
return composite::is_static(_bytes, _is_compound);
}
explicit operator bytes_view() const {
return _bytes;
}
bool operator==(const composite_view& k) const { return k._bytes == _bytes && k._is_compound == _is_compound; }
bool operator!=(const composite_view& k) const { return !(k == *this); }
friend inline std::ostream& operator<<(std::ostream& os, composite_view v) {
return os << "{" << ::join(", ", v.components()) << ", compound=" << v._is_compound << ", static=" << v.is_static() << "}";
}
};
inline
std::ostream& operator<<(std::ostream& os, const composite& v) {
return os << composite_view(v);
}
inline
int composite::tri_compare::operator()(const composite& v1, const composite& v2) const {
return (*this)(composite_view(v1), composite_view(v2));
}
inline
int composite::tri_compare::operator()(composite_view v1, composite_view v2) const {
// See org.apache.cassandra.db.composites.AbstractCType#compare
if (v1.empty()) {
return v2.empty() ? 0 : -1;
}
if (v2.empty()) {
return 1;
}
if (v1.is_static() != v2.is_static()) {
return v1.is_static() ? -1 : 1;
}
auto a_values = v1.components();
auto b_values = v2.components();
auto cmp = [&](const data_type& t, component_view c1, component_view c2) {
// First by value, then by EOC
auto r = t->compare(c1.first, c2.first);
if (r) {
return r;
}
return static_cast<int>(c1.second) - static_cast<int>(c2.second);
};
return lexicographical_tri_compare(_types.begin(), _types.end(),
a_values.begin(), a_values.end(),
b_values.begin(), b_values.end(),
cmp);
}