ClickHouse/src/Functions/geometryConverters.h

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#pragma once
#include <Core/ColumnWithTypeAndName.h>
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#include <Core/Types.h>
#include <boost/geometry/geometries/geometries.hpp>
#include <boost/geometry.hpp>
#include <boost/geometry/geometries/point_xy.hpp>
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#include <Columns/ColumnsNumber.h>
#include <Columns/ColumnArray.h>
#include <Columns/ColumnTuple.h>
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#include <Common/NaNUtils.h>
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#include <DataTypes/DataTypeArray.h>
#include <DataTypes/IDataType.h>
#include <DataTypes/DataTypeFactory.h>
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#include <IO/WriteHelpers.h>
#include <Interpreters/castColumn.h>
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#include <cmath>
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#include <base/logger_useful.h>
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namespace DB
{
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namespace ErrorCodes
{
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extern const int BAD_ARGUMENTS;
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extern const int ILLEGAL_TYPE_OF_ARGUMENT;
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}
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template <typename Point>
using Ring = boost::geometry::model::ring<Point>;
template <typename Point>
using Polygon = boost::geometry::model::polygon<Point>;
template <typename Point>
using MultiPolygon = boost::geometry::model::multi_polygon<Polygon<Point>>;
using CartesianPoint = boost::geometry::model::d2::point_xy<Float64>;
using CartesianRing = Ring<CartesianPoint>;
using CartesianPolygon = Polygon<CartesianPoint>;
using CartesianMultiPolygon = MultiPolygon<CartesianPoint>;
using SphericalPoint = boost::geometry::model::point<Float64, 2, boost::geometry::cs::spherical_equatorial<boost::geometry::degree>>;
using SphericalRing = Ring<SphericalPoint>;
using SphericalPolygon = Polygon<SphericalPoint>;
using SphericalMultiPolygon = MultiPolygon<SphericalPoint>;
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/**
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* Class which takes converts Column with type Tuple(Float64, Float64) to a vector of boost point type.
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* They are (x,y) in case of cartesian coordinated and (lon,lat) in case of Spherical.
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*/
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template <typename Point>
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struct ColumnToPointsConverter
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{
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static std::vector<Point> convert(ColumnPtr col)
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{
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const auto * tuple = typeid_cast<const ColumnTuple *>(col.get());
const auto & tuple_columns = tuple->getColumns();
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const auto * x_data = typeid_cast<const ColumnFloat64 *>(tuple_columns[0].get());
const auto * y_data = typeid_cast<const ColumnFloat64 *>(tuple_columns[1].get());
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const auto * first_container = x_data->getData().data();
const auto * second_container = y_data->getData().data();
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std::vector<Point> answer(col->size());
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for (size_t i = 0; i < col->size(); ++i)
{
const Float64 first = first_container[i];
const Float64 second = second_container[i];
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if (isNaN(first) || isNaN(second))
throw Exception("Point's component must not be NaN", ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
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if (std::isinf(first) || std::isinf(second))
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throw Exception("Point's component must not be infinite", ErrorCodes::ILLEGAL_TYPE_OF_ARGUMENT);
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answer[i] = Point(first, second);
}
return answer;
}
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};
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template <typename Point>
struct ColumnToRingsConverter
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{
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static std::vector<Ring<Point>> convert(ColumnPtr col)
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{
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const IColumn::Offsets & offsets = typeid_cast<const ColumnArray &>(*col).getOffsets();
size_t prev_offset = 0;
std::vector<Ring<Point>> answer;
answer.reserve(offsets.size());
auto tmp = ColumnToPointsConverter<Point>::convert(typeid_cast<const ColumnArray &>(*col).getDataPtr());
for (size_t offset : offsets)
{
answer.emplace_back(tmp.begin() + prev_offset, tmp.begin() + offset);
prev_offset = offset;
}
return answer;
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}
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};
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template <typename Point>
struct ColumnToPolygonsConverter
{
static std::vector<Polygon<Point>> convert(ColumnPtr col)
{
const IColumn::Offsets & offsets = typeid_cast<const ColumnArray &>(*col).getOffsets();
std::vector<Polygon<Point>> answer(offsets.size());
auto all_rings = ColumnToRingsConverter<Point>::convert(typeid_cast<const ColumnArray &>(*col).getDataPtr());
size_t prev_offset = 0;
for (size_t iter = 0; iter < offsets.size(); ++iter)
{
const auto current_array_size = offsets[iter] - prev_offset;
answer[iter].outer() = std::move(all_rings[prev_offset]);
answer[iter].inners().reserve(current_array_size);
for (size_t inner_holes = prev_offset + 1; inner_holes < offsets[iter]; ++inner_holes)
answer[iter].inners().emplace_back(std::move(all_rings[inner_holes]));
prev_offset = offsets[iter];
}
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return answer;
}
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};
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template <typename Point>
struct ColumnToMultiPolygonsConverter
{
static std::vector<MultiPolygon<Point>> convert(ColumnPtr col)
{
const IColumn::Offsets & offsets = typeid_cast<const ColumnArray &>(*col).getOffsets();
size_t prev_offset = 0;
std::vector<MultiPolygon<Point>> answer(offsets.size());
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auto all_polygons = ColumnToPolygonsConverter<Point>::convert(typeid_cast<const ColumnArray &>(*col).getDataPtr());
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for (size_t iter = 0; iter < offsets.size(); ++iter)
{
for (size_t polygon_iter = prev_offset; polygon_iter < offsets[iter]; ++polygon_iter)
answer[iter].emplace_back(std::move(all_polygons[polygon_iter]));
prev_offset = offsets[iter];
}
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return answer;
}
};
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/// To serialize Spherical or Cartesian point (a pair of numbers in both cases).
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template <typename Point>
class PointSerializer
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{
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public:
PointSerializer()
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: first(ColumnFloat64::create())
, second(ColumnFloat64::create())
, first_container(first->getData())
, second_container(second->getData())
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{}
explicit PointSerializer(size_t n)
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: first(ColumnFloat64::create(n))
, second(ColumnFloat64::create(n))
, first_container(first->getData())
, second_container(second->getData())
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{}
void add(const Point & point)
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{
first_container.emplace_back(point.template get<0>());
second_container.emplace_back(point.template get<1>());
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}
ColumnPtr finalize()
{
Columns columns(2);
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columns[0] = std::move(first);
columns[1] = std::move(second);
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return ColumnTuple::create(columns);
}
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private:
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ColumnFloat64::MutablePtr first;
ColumnFloat64::MutablePtr second;
ColumnFloat64::Container & first_container;
ColumnFloat64::Container & second_container;
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};
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/// Serialize Point, Ring as Ring
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template <typename Point>
class RingSerializer
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{
public:
RingSerializer()
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: offsets(ColumnUInt64::create())
{}
explicit RingSerializer(size_t n)
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: offsets(ColumnUInt64::create(n))
{}
void add(const Ring<Point> & ring)
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{
size += ring.size();
offsets->insertValue(size);
for (const auto & point : ring)
point_serializer.add(point);
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}
ColumnPtr finalize()
{
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return ColumnArray::create(point_serializer.finalize(), std::move(offsets));
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}
private:
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size_t size = 0;
PointSerializer<Point> point_serializer;
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ColumnUInt64::MutablePtr offsets;
};
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/// Serialize Point, Ring, Polygon as Polygon
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template <typename Point>
class PolygonSerializer
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{
public:
PolygonSerializer()
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: offsets(ColumnUInt64::create())
{}
explicit PolygonSerializer(size_t n)
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: offsets(ColumnUInt64::create(n))
{}
void add(const Ring<Point> & ring)
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{
size++;
offsets->insertValue(size);
ring_serializer.add(ring);
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}
void add(const Polygon<Point> & polygon)
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{
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/// Outer ring + all inner rings (holes).
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size += 1 + polygon.inners().size();
offsets->insertValue(size);
ring_serializer.add(polygon.outer());
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for (const auto & ring : polygon.inners())
ring_serializer.add(ring);
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}
ColumnPtr finalize()
{
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return ColumnArray::create(ring_serializer.finalize(), std::move(offsets));
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}
private:
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size_t size = 0;
RingSerializer<Point> ring_serializer;
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ColumnUInt64::MutablePtr offsets;
};
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/// Serialize Point, Ring, Polygon, MultiPolygon as MultiPolygon
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template <typename Point>
class MultiPolygonSerializer
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{
public:
MultiPolygonSerializer()
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: offsets(ColumnUInt64::create())
{}
explicit MultiPolygonSerializer(size_t n)
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: offsets(ColumnUInt64::create(n))
{}
void add(const Ring<Point> & ring)
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{
size++;
offsets->insertValue(size);
polygon_serializer.add(ring);
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}
void add(const Polygon<Point> & polygon)
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{
size++;
offsets->insertValue(size);
polygon_serializer.add(polygon);
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}
void add(const MultiPolygon<Point> & multi_polygon)
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{
size += multi_polygon.size();
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offsets->insertValue(size);
for (const auto & polygon : multi_polygon)
{
polygon_serializer.add(polygon);
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}
}
ColumnPtr finalize()
{
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return ColumnArray::create(polygon_serializer.finalize(), std::move(offsets));
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}
private:
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size_t size = 0;
PolygonSerializer<Point> polygon_serializer;
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ColumnUInt64::MutablePtr offsets;
};
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template <typename PType>
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struct ConverterType
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{
using Type = PType;
};
template <typename Point, typename F>
static void callOnGeometryDataType(DataTypePtr type, F && f)
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{
const auto & factory = DataTypeFactory::instance();
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/// There is no Point type, because for most of geometry functions it is useless.
if (factory.get("Point")->equals(*type))
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return f(ConverterType<ColumnToPointsConverter<Point>>());
else if (factory.get("Ring")->equals(*type))
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return f(ConverterType<ColumnToRingsConverter<Point>>());
else if (factory.get("Polygon")->equals(*type))
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return f(ConverterType<ColumnToPolygonsConverter<Point>>());
else if (factory.get("MultiPolygon")->equals(*type))
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return f(ConverterType<ColumnToMultiPolygonsConverter<Point>>());
throw Exception(fmt::format("Unknown geometry type {}", type->getName()), ErrorCodes::BAD_ARGUMENTS);
}
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template <typename Point, typename F>
static void callOnTwoGeometryDataTypes(DataTypePtr left_type, DataTypePtr right_type, F && func)
{
return callOnGeometryDataType<Point>(left_type, [&](const auto & left_types)
{
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using LeftConverterType = std::decay_t<decltype(left_types)>;
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return callOnGeometryDataType<Point>(right_type, [&](const auto & right_types)
{
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using RightConverterType = std::decay_t<decltype(right_types)>;
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return func(LeftConverterType(), RightConverterType());
});
});
}
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}