--- slug: /en/sql-reference/functions/geo/s2 sidebar_label: S2 Geometry --- # Functions for Working with S2 Index [S2](https://s2geometry.io/) is a geographical indexing system where all geographical data is represented on a three-dimensional sphere (similar to a globe). In the S2 library points are represented as the S2 Index - a specific number which encodes internally a point on the surface of a unit sphere, unlike traditional (latitude, longitude) pairs. To get the S2 point index for a given point specified in the format (latitude, longitude) use the [geoToS2](#geotos2) function. Also, you can use the [s2ToGeo](#s2togeo) function for getting geographical coordinates corresponding to the specified S2 point index. ## geoToS2 Returns [S2](#s2index) point index corresponding to the provided coordinates `(longitude, latitude)`. **Syntax** ``` sql geoToS2(lon, lat) ``` **Arguments** - `lon` — Longitude. [Float64](../../data-types/float.md). - `lat` — Latitude. [Float64](../../data-types/float.md). **Returned values** - S2 point index. [UInt64](../../data-types/int-uint.md). **Example** Query: ``` sql SELECT geoToS2(37.79506683, 55.71290588) AS s2Index; ``` Result: ``` text ┌─────────────s2Index─┐ │ 4704772434919038107 │ └─────────────────────┘ ``` ## s2ToGeo Returns geo coordinates `(longitude, latitude)` corresponding to the provided [S2](#s2index) point index. **Syntax** ``` sql s2ToGeo(s2index) ``` **Arguments** - `s2index` — S2 Index. [UInt64](../../data-types/int-uint.md). **Returned values** - A [tuple](../../data-types/tuple.md) consisting of two values: - `lon`. [Float64](../../data-types/float.md). - `lat`. [Float64](../../data-types/float.md). **Example** Query: ``` sql SELECT s2ToGeo(4704772434919038107) AS s2Coodrinates; ``` Result: ``` text ┌─s2Coodrinates────────────────────────┐ │ (37.79506681471008,55.7129059052841) │ └──────────────────────────────────────┘ ``` ## s2GetNeighbors Returns S2 neighbor indexes corresponding to the provided [S2](#s2index). Each cell in the S2 system is a quadrilateral bounded by four geodesics. So, each cell has 4 neighbors. **Syntax** ``` sql s2GetNeighbors(s2index) ``` **Arguments** - `s2index` — S2 Index. [UInt64](../../data-types/int-uint.md). **Returned value** - An array consisting of 4 neighbor indexes: `array[s2index1, s2index3, s2index2, s2index4]`. [Array](../../data-types/array.md)([UInt64](../../data-types/int-uint.md)). **Example** Query: ``` sql SELECT s2GetNeighbors(5074766849661468672) AS s2Neighbors; ``` Result: ``` text ┌─s2Neighbors───────────────────────────────────────────────────────────────────────┐ │ [5074766987100422144,5074766712222515200,5074767536856236032,5074767261978329088] │ └───────────────────────────────────────────────────────────────────────────────────┘ ``` ## s2CellsIntersect Determines if the two provided [S2](#s2index) cells intersect or not. **Syntax** ``` sql s2CellsIntersect(s2index1, s2index2) ``` **Arguments** - `siIndex1`, `s2index2` — S2 Index. [UInt64](../../data-types/int-uint.md). **Returned value** - `1` — If the cells intersect. [UInt8](../../data-types/int-uint.md). - `0` — If the cells don't intersect. [UInt8](../../data-types/int-uint.md). **Example** Query: ``` sql SELECT s2CellsIntersect(9926595209846587392, 9926594385212866560) AS intersect; ``` Result: ``` text ┌─intersect─┐ │ 1 │ └───────────┘ ``` ## s2CapContains Determines if a cap contains a S2 point. A cap represents a part of the sphere that has been cut off by a plane. It is defined by a point on a sphere and a radius in degrees. **Syntax** ``` sql s2CapContains(center, degrees, point) ``` **Arguments** - `center` — S2 point index corresponding to the cap. [UInt64](../../data-types/int-uint.md). - `degrees` — Radius of the cap in degrees. [Float64](../../data-types/float.md). - `point` — S2 point index. [UInt64](../../data-types/int-uint.md). **Returned value** - `1` — If the cap contains the S2 point index. [UInt8](../../data-types/int-uint.md). - `0` — If the cap doesn't contain the S2 point index. [UInt8](../../data-types/int-uint.md). **Example** Query: ``` sql SELECT s2CapContains(1157339245694594829, 1.0, 1157347770437378819) AS capContains; ``` Result: ``` text ┌─capContains─┐ │ 1 │ └─────────────┘ ``` ## s2CapUnion Determines the smallest cap that contains the given two input caps. A cap represents a portion of the sphere that has been cut off by a plane. It is defined by a point on a sphere and a radius in degrees. **Syntax** ``` sql s2CapUnion(center1, radius1, center2, radius2) ``` **Arguments** - `center1`, `center2` — S2 point indexes corresponding to the two input caps. [UInt64](../../data-types/int-uint.md). - `radius1`, `radius2` — Radius of the two input caps in degrees. [Float64](../../data-types/float.md). **Returned values** - `center` — S2 point index corresponding the center of the smallest cap containing the two input caps. [UInt64](../../data-types/int-uint.md). - `radius` — Radius of the smallest cap containing the two input caps. [Float64](../../data-types/float.md). **Example** Query: ``` sql SELECT s2CapUnion(3814912406305146967, 1.0, 1157347770437378819, 1.0) AS capUnion; ``` Result: ``` text ┌─capUnion───────────────────────────────┐ │ (4534655147792050737,60.2088283994957) │ └────────────────────────────────────────┘ ``` ## s2RectAdd Increases the size of the bounding rectangle to include the given S2 point. In the S2 system, a rectangle is represented by a type of S2Region called a `S2LatLngRect` that represents a rectangle in latitude-longitude space. **Syntax** ``` sql s2RectAdd(s2pointLow, s2pointHigh, s2Point) ``` **Arguments** - `s2PointLow` — Low S2 point index corresponding to the rectangle. [UInt64](../../data-types/int-uint.md). - `s2PointHigh` — High S2 point index corresponding to the rectangle. [UInt64](../../data-types/int-uint.md). - `s2Point` — Target S2 point index that the bound rectangle should be grown to include. [UInt64](../../data-types/int-uint.md). **Returned values** - `s2PointLow` — Low S2 cell id corresponding to the grown rectangle. [UInt64](../../data-types/int-uint.md). - `s2PointHigh` — Height S2 cell id corresponding to the grown rectangle. [UInt64](../../data-types/float.md). **Example** Query: ``` sql SELECT s2RectAdd(5178914411069187297, 5177056748191934217, 5179056748191934217) AS rectAdd; ``` Result: ``` text ┌─rectAdd───────────────────────────────────┐ │ (5179062030687166815,5177056748191934217) │ └───────────────────────────────────────────┘ ``` ## s2RectContains Determines if a given rectangle contains a S2 point. In the S2 system, a rectangle is represented by a type of S2Region called a `S2LatLngRect` that represents a rectangle in latitude-longitude space. **Syntax** ``` sql s2RectContains(s2PointLow, s2PointHi, s2Point) ``` **Arguments** - `s2PointLow` — Low S2 point index corresponding to the rectangle. [UInt64](../../data-types/int-uint.md). - `s2PointHigh` — High S2 point index corresponding to the rectangle. [UInt64](../../data-types/int-uint.md). - `s2Point` — Target S2 point index. [UInt64](../../data-types/int-uint.md). **Returned value** - `1` — If the rectangle contains the given S2 point. - `0` — If the rectangle doesn't contain the given S2 point. **Example** Query: ``` sql SELECT s2RectContains(5179062030687166815, 5177056748191934217, 5177914411069187297) AS rectContains; ``` Result: ``` text ┌─rectContains─┐ │ 0 │ └──────────────┘ ``` ## s2RectUnion Returns the smallest rectangle containing the union of this rectangle and the given rectangle. In the S2 system, a rectangle is represented by a type of S2Region called a `S2LatLngRect` that represents a rectangle in latitude-longitude space. **Syntax** ``` sql s2RectUnion(s2Rect1PointLow, s2Rect1PointHi, s2Rect2PointLow, s2Rect2PointHi) ``` **Arguments** - `s2Rect1PointLow`, `s2Rect1PointHi` — Low and High S2 point indexes corresponding to the first rectangle. [UInt64](../../data-types/int-uint.md). - `s2Rect2PointLow`, `s2Rect2PointHi` — Low and High S2 point indexes corresponding to the second rectangle. [UInt64](../../data-types/int-uint.md). **Returned values** - `s2UnionRect2PointLow` — Low S2 cell id corresponding to the union rectangle. [UInt64](../../data-types/int-uint.md). - `s2UnionRect2PointHi` — High S2 cell id corresponding to the union rectangle. [UInt64](../../data-types/int-uint.md). **Example** Query: ``` sql SELECT s2RectUnion(5178914411069187297, 5177056748191934217, 5179062030687166815, 5177056748191934217) AS rectUnion; ``` Result: ``` text ┌─rectUnion─────────────────────────────────┐ │ (5179062030687166815,5177056748191934217) │ └───────────────────────────────────────────┘ ``` ## s2RectIntersection Returns the smallest rectangle containing the intersection of this rectangle and the given rectangle. In the S2 system, a rectangle is represented by a type of S2Region called a `S2LatLngRect` that represents a rectangle in latitude-longitude space. **Syntax** ``` sql s2RectIntersection(s2Rect1PointLow, s2Rect1PointHi, s2Rect2PointLow, s2Rect2PointHi) ``` **Arguments** - `s2Rect1PointLow`, `s2Rect1PointHi` — Low and High S2 point indexes corresponding to the first rectangle. [UInt64](../../data-types/int-uint.md). - `s2Rect2PointLow`, `s2Rect2PointHi` — Low and High S2 point indexes corresponding to the second rectangle. [UInt64](../../data-types/int-uint.md). **Returned values** - `s2UnionRect2PointLow` — Low S2 cell id corresponding to the rectangle containing the intersection of the given rectangles. [UInt64](../../data-types/int-uint.md). - `s2UnionRect2PointHi` — High S2 cell id corresponding to the rectangle containing the intersection of the given rectangles. [UInt64](../../data-types/int-uint.md). **Example** Query: ``` sql SELECT s2RectIntersection(5178914411069187297, 5177056748191934217, 5179062030687166815, 5177056748191934217) AS rectIntersection; ``` Result: ``` text ┌─rectIntersection──────────────────────────┐ │ (5178914411069187297,5177056748191934217) │ └───────────────────────────────────────────┘ ```