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# include <DataTypes/DataTypesNumber.h>
# include <Columns/ColumnsNumber.h>
# include <Columns/ColumnConst.h>
# include <Common/typeid_cast.h>
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# include <Common/assert_cast.h>
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# include <Functions/IFunctionImpl.h>
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# include <Functions/FunctionHelpers.h>
# include <Functions/FunctionFactory.h>
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# include <Functions/TargetSpecific.h>
# include <Functions/PerformanceAdaptors.h>
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# include <ext/range.h>
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# include <cmath>
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namespace DB
{
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namespace ErrorCodes
{
extern const int ILLEGAL_TYPE_OF_ARGUMENT ;
}
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/** Calculates the distance between two geographical locations.
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* There are three variants :
* greatCircleAngle : calculates the distance on a sphere in degrees : https : //en.wikipedia.org/wiki/Great-circle_distance
* greatCircleDistance : calculates the distance on a sphere in meters .
* geoDistance : calculates the distance on WGS - 84 ellipsoid in meters .
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*
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* The function calculates distance between two points on Earth specified by longitude and latitude in degrees .
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*
* Latitude must be in [ - 90 , 90 ] , longitude must be [ - 180 , 180 ] .
*
* Original code of this implementation of this function is here :
* https : //github.com/sphinxsearch/sphinx/blob/409f2c2b5b2ff70b04e38f92b6b1a890326bad65/src/sphinxexpr.cpp#L3825.
* Andrey Aksenov , the author of original code , permitted to use this code in ClickHouse under the Apache 2.0 license .
* Presentation about this code from Highload + + Siberia 2019 is here https : //github.com/ClickHouse/ClickHouse/files/3324740/1_._._GEODIST_._.pdf
* The main idea of this implementation is optimisations based on Taylor series , trigonometric identity
* and calculated constants once for cosine , arcsine ( sqrt ) and look up table .
*/
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namespace
{
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constexpr double PI = 3.14159265358979323846 ;
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constexpr float RAD_IN_DEG = static_cast < float > ( PI / 180.0 ) ;
constexpr float RAD_IN_DEG_HALF = static_cast < float > ( PI / 360.0 ) ;
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constexpr size_t COS_LUT_SIZE = 1024 ; // maxerr 0.00063%
constexpr size_t ASIN_SQRT_LUT_SIZE = 512 ;
constexpr size_t METRIC_LUT_SIZE = 1024 ;
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/** Earth radius in meters using WGS84 authalic radius.
* We use this value to be consistent with H3 library .
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*/
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constexpr float EARTH_RADIUS = 6371007.180918475 ;
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constexpr float EARTH_DIAMETER = 2 * EARTH_RADIUS ;
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float cos_lut [ COS_LUT_SIZE + 1 ] ; /// cos(x) table
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float asin_sqrt_lut [ ASIN_SQRT_LUT_SIZE + 1 ] ; /// asin(sqrt(x)) * earth_diameter table
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float sphere_metric_lut [ METRIC_LUT_SIZE + 1 ] ; /// sphere metric, unitless: the distance in degrees for one degree across longitude depending on latitude
float sphere_metric_meters_lut [ METRIC_LUT_SIZE + 1 ] ; /// sphere metric: the distance in meters for one degree across longitude depending on latitude
float wgs84_metric_meters_lut [ 2 * ( METRIC_LUT_SIZE + 1 ) ] ; /// ellipsoid metric: the distance in meters across one degree latitude/longitude depending on latitude
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inline double sqr ( double v )
{
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return v * v ;
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}
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inline float sqrf ( float v )
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{
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return v * v ;
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}
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void geodistInit ( )
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{
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for ( size_t i = 0 ; i < = COS_LUT_SIZE ; + + i )
cos_lut [ i ] = static_cast < float > ( cos ( 2 * PI * i / COS_LUT_SIZE ) ) ; // [0, 2 * pi] -> [0, COS_LUT_SIZE]
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for ( size_t i = 0 ; i < = ASIN_SQRT_LUT_SIZE ; + + i )
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asin_sqrt_lut [ i ] = static_cast < float > ( asin (
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sqrt ( static_cast < double > ( i ) / ASIN_SQRT_LUT_SIZE ) ) ) ; // [0, 1] -> [0, ASIN_SQRT_LUT_SIZE]
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for ( size_t i = 0 ; i < = METRIC_LUT_SIZE ; + + i )
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{
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double latitude = i * ( PI / METRIC_LUT_SIZE ) - PI * 0.5 ; // [-pi / 2, pi / 2] -> [0, METRIC_LUT_SIZE]
/// Squared metric coefficients (for the distance in meters) on a tangent plane, for latitude and longitude (in degrees),
/// depending on the latitude (in radians).
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/// https://github.com/mapbox/cheap-ruler/blob/master/index.js#L67
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wgs84_metric_meters_lut [ i * 2 ] = static_cast < float > ( sqr ( 111132.09 - 566.05 * cos ( 2 * latitude ) + 1.20 * cos ( 4 * latitude ) ) ) ;
wgs84_metric_meters_lut [ i * 2 + 1 ] = static_cast < float > ( sqr ( 111415.13 * cos ( latitude ) - 94.55 * cos ( 3 * latitude ) + 0.12 * cos ( 5 * latitude ) ) ) ;
sphere_metric_meters_lut [ i ] = static_cast < float > ( sqr ( ( EARTH_DIAMETER * PI / 360 ) * cos ( latitude ) ) ) ;
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sphere_metric_lut [ i ] = cosf ( latitude ) ;
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}
}
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inline NO_SANITIZE_UNDEFINED size_t floatToIndex ( float x )
{
/// Implementation specific behaviour on overflow or infinite value.
return static_cast < size_t > ( x ) ;
}
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inline float geodistDegDiff ( float f )
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{
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f = fabsf ( f ) ;
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if ( f > 180 )
f = 360 - f ;
return f ;
}
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inline float geodistFastCos ( float x )
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{
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float y = fabsf ( x ) * ( COS_LUT_SIZE / PI / 2 ) ;
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size_t i = floatToIndex ( y ) ;
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y - = i ;
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i & = ( COS_LUT_SIZE - 1 ) ;
return cos_lut [ i ] + ( cos_lut [ i + 1 ] - cos_lut [ i ] ) * y ;
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}
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inline float geodistFastSin ( float x )
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{
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float y = fabsf ( x ) * ( COS_LUT_SIZE / PI / 2 ) ;
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size_t i = floatToIndex ( y ) ;
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y - = i ;
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i = ( i - COS_LUT_SIZE / 4 ) & ( COS_LUT_SIZE - 1 ) ; // cos(x - pi / 2) = sin(x), costable / 4 = pi / 2
return cos_lut [ i ] + ( cos_lut [ i + 1 ] - cos_lut [ i ] ) * y ;
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}
/// fast implementation of asin(sqrt(x))
/// max error in floats 0.00369%, in doubles 0.00072%
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inline float geodistFastAsinSqrt ( float x )
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{
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if ( x < 0.122f )
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{
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// distance under 4546 km, Taylor error under 0.00072%
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float y = sqrtf ( x ) ;
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return y + x * y * 0.166666666666666f + x * x * y * 0.075f + x * x * x * y * 0.044642857142857f ;
}
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if ( x < 0.948f )
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{
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// distance under 17083 km, 512-entry LUT error under 0.00072%
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x * = ASIN_SQRT_LUT_SIZE ;
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size_t i = floatToIndex ( x ) ;
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return asin_sqrt_lut [ i ] + ( asin_sqrt_lut [ i + 1 ] - asin_sqrt_lut [ i ] ) * ( x - i ) ;
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}
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return asinf ( sqrtf ( x ) ) ; // distance over 17083 km, just compute exact
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}
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enum class Method
{
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SPHERE_DEGREES ,
SPHERE_METERS ,
WGS84_METERS ,
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} ;
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}
DECLARE_MULTITARGET_CODE (
namespace
{
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template < Method method >
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float distance ( float lon1deg , float lat1deg , float lon2deg , float lat2deg )
{
float lat_diff = geodistDegDiff ( lat1deg - lat2deg ) ;
float lon_diff = geodistDegDiff ( lon1deg - lon2deg ) ;
if ( lon_diff < 13 )
{
// points are close enough; use flat ellipsoid model
// interpolate metric coefficients using latitudes midpoint
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/// Why comparing only difference in longitude?
/// If longitudes are different enough, there is a big difference between great circle line and a line with constant latitude.
/// (Remember how a plane flies from Moscow to New York)
/// But if longitude is close but latitude is different enough, there is no difference between meridian and great circle line.
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float latitude_midpoint = ( lat1deg + lat2deg + 180 ) * METRIC_LUT_SIZE / 360 ; // [-90, 90] degrees -> [0, KTABLE] indexes
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size_t latitude_midpoint_index = floatToIndex ( latitude_midpoint ) & ( METRIC_LUT_SIZE - 1 ) ;
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/// This is linear interpolation between two table items at index "latitude_midpoint_index" and "latitude_midpoint_index + 1".
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float k_lat ;
float k_lon ;
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if constexpr ( method = = Method : : SPHERE_DEGREES )
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{
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k_lat = 1 ;
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k_lon = sphere_metric_lut [ latitude_midpoint_index ]
+ ( sphere_metric_lut [ latitude_midpoint_index + 1 ] - sphere_metric_lut [ latitude_midpoint_index ] ) * ( latitude_midpoint - latitude_midpoint_index ) ;
}
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else if constexpr ( method = = Method : : SPHERE_METERS )
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{
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k_lat = sqr ( EARTH_DIAMETER * PI / 360 ) ;
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k_lon = sphere_metric_meters_lut [ latitude_midpoint_index ]
+ ( sphere_metric_meters_lut [ latitude_midpoint_index + 1 ] - sphere_metric_meters_lut [ latitude_midpoint_index ] ) * ( latitude_midpoint - latitude_midpoint_index ) ;
}
else if constexpr ( method = = Method : : WGS84_METERS )
{
k_lat = wgs84_metric_meters_lut [ latitude_midpoint_index * 2 ]
+ ( wgs84_metric_meters_lut [ ( latitude_midpoint_index + 1 ) * 2 ] - wgs84_metric_meters_lut [ latitude_midpoint_index * 2 ] ) * ( latitude_midpoint - latitude_midpoint_index ) ;
k_lon = wgs84_metric_meters_lut [ latitude_midpoint_index * 2 + 1 ]
+ ( wgs84_metric_meters_lut [ ( latitude_midpoint_index + 1 ) * 2 + 1 ] - wgs84_metric_meters_lut [ latitude_midpoint_index * 2 + 1 ] ) * ( latitude_midpoint - latitude_midpoint_index ) ;
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}
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/// Metric on a tangent plane: it differs from Euclidean metric only by scale of coordinates.
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return sqrtf ( k_lat * lat_diff * lat_diff + k_lon * lon_diff * lon_diff ) ;
}
else
{
// points too far away; use haversine
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float a = sqrf ( geodistFastSin ( lat_diff * RAD_IN_DEG_HALF ) )
+ geodistFastCos ( lat1deg * RAD_IN_DEG ) * geodistFastCos ( lat2deg * RAD_IN_DEG ) * sqrf ( geodistFastSin ( lon_diff * RAD_IN_DEG_HALF ) ) ;
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if constexpr ( method = = Method : : SPHERE_DEGREES )
return ( 360.0f / PI ) * geodistFastAsinSqrt ( a ) ;
else
return EARTH_DIAMETER * geodistFastAsinSqrt ( a ) ;
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}
}
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}
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template < Method method >
class FunctionGeoDistance : public IFunction
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{
public :
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static constexpr auto name =
( method = = Method : : SPHERE_DEGREES ) ? " greatCircleAngle "
: ( ( method = = Method : : SPHERE_METERS ) ? " greatCircleDistance "
: " geoDistance " ) ;
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private :
String getName ( ) const override { return name ; }
size_t getNumberOfArguments ( ) const override { return 4 ; }
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bool useDefaultImplementationForConstants ( ) const override { return true ; }
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DataTypePtr getReturnTypeImpl ( const DataTypes & arguments ) const override
{
for ( const auto arg_idx : ext : : range ( 0 , arguments . size ( ) ) )
{
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const auto * arg = arguments [ arg_idx ] . get ( ) ;
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if ( ! isNumber ( WhichDataType ( arg ) ) )
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throw Exception (
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" Illegal type " + arg - > getName ( ) + " of argument " + std : : to_string ( arg_idx + 1 ) + " of function " + getName ( ) + " . Must be numeric " ,
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ErrorCodes : : ILLEGAL_TYPE_OF_ARGUMENT ) ;
}
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return std : : make_shared < DataTypeFloat32 > ( ) ;
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}
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ColumnPtr executeImpl ( const ColumnsWithTypeAndName & arguments , const DataTypePtr & , size_t input_rows_count ) const override
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{
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auto dst = ColumnVector < Float32 > : : create ( ) ;
auto & dst_data = dst - > getData ( ) ;
dst_data . resize ( input_rows_count ) ;
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const IColumn & col_lon1 = * arguments [ 0 ] . column ;
const IColumn & col_lat1 = * arguments [ 1 ] . column ;
const IColumn & col_lon2 = * arguments [ 2 ] . column ;
const IColumn & col_lat2 = * arguments [ 3 ] . column ;
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for ( size_t row_num = 0 ; row_num < input_rows_count ; + + row_num )
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dst_data [ row_num ] = distance < method > (
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col_lon1 . getFloat32 ( row_num ) , col_lat1 . getFloat32 ( row_num ) ,
col_lon2 . getFloat32 ( row_num ) , col_lat2 . getFloat32 ( row_num ) ) ;
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return dst ;
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}
} ;
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) // DECLARE_MULTITARGET_CODE
template < Method method >
class FunctionGeoDistance : public TargetSpecific : : Default : : FunctionGeoDistance < method >
{
public :
explicit FunctionGeoDistance ( const Context & context ) : selector ( context )
{
selector . registerImplementation < TargetArch : : Default ,
TargetSpecific : : Default : : FunctionGeoDistance < method > > ( ) ;
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# if USE_MULTITARGET_CODE
selector . registerImplementation < TargetArch : : AVX ,
TargetSpecific : : AVX : : FunctionGeoDistance < method > > ( ) ;
selector . registerImplementation < TargetArch : : AVX2 ,
TargetSpecific : : AVX2 : : FunctionGeoDistance < method > > ( ) ;
selector . registerImplementation < TargetArch : : AVX512F ,
TargetSpecific : : AVX512F : : FunctionGeoDistance < method > > ( ) ;
# endif
}
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ColumnPtr executeImpl ( const ColumnsWithTypeAndName & arguments , const DataTypePtr & result_type , size_t input_rows_count ) const override
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{
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return selector . selectAndExecute ( arguments , result_type , input_rows_count ) ;
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}
static FunctionPtr create ( const Context & context )
{
return std : : make_shared < FunctionGeoDistance < method > > ( context ) ;
}
private :
ImplementationSelector < IFunction > selector ;
} ;
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void registerFunctionGeoDistance ( FunctionFactory & factory )
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{
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geodistInit ( ) ;
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factory . registerFunction < FunctionGeoDistance < Method : : SPHERE_DEGREES > > ( ) ;
factory . registerFunction < FunctionGeoDistance < Method : : SPHERE_METERS > > ( ) ;
factory . registerFunction < FunctionGeoDistance < Method : : WGS84_METERS > > ( ) ;
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}
}