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SQL data type rules

Applies to: check marked yes Databricks SQL check marked yes Databricks Runtime

Azure Databricks uses several rules to resolve conflicts among data types:

You can also explicitly cast between many types:

Type promotion

Type promotion is the process of casting a type into another type of the same type family which contains all possible values of the original type. Therefore type promotion is a safe operation. For example TINYINT has a range from -128 to 127. All its possible values can be safely promoted to INTEGER.

Type precedence list

The type precedence list defines whether values of a given data type can be implicitly promoted to another data type.

Data type Precedence list (from narrowest to widest)
TINYINT TINYINT -> SMALLINT -> INT -> BIGINT -> DECIMAL -> FLOAT (1) -> DOUBLE
SMALLINT SMALLINT -> INT -> BIGINT -> DECIMAL -> FLOAT (1) -> DOUBLE
INT INT -> BIGINT -> DECIMAL -> FLOAT (1) -> DOUBLE
BIGINT BIGINT -> DECIMAL -> FLOAT (1) -> DOUBLE
DECIMAL DECIMAL -> FLOAT (1) -> DOUBLE
FLOAT FLOAT (1) -> DOUBLE
DOUBLE DOUBLE
DATE DATE -> TIMESTAMP
TIMESTAMP TIMESTAMP
ARRAY ARRAY (2)
BINARY BINARY
BOOLEAN BOOLEAN
INTERVAL INTERVAL
MAP MAP (2)
STRING STRING
STRUCT STRUCT (2)
VARIANT VARIANT
OBJECT OBJECT (3)

(1) For least common type resolution FLOAT is skipped to avoid loss of precision.

(2) For a complex type the precedence rule applies recursively to its component elements.

(3) OBJECT exists only within a VARIANT.

Strings and NULL

Special rules apply for STRING and untyped NULL:

  • NULL can be promoted to any other type.
  • STRING can be promoted to BIGINT, BINARY, BOOLEAN, DATE, DOUBLE, INTERVAL, and TIMESTAMP. If the actual string value cannot be cast to least common type Azure Databricks raises a runtime error. When promoting to INTERVAL the string value must match the intervals units.

Type precedence graph

This is a graphical depiction of the precedence hierarchy, combining the type precedence list and strings and NULLs rules.

Graphical representation of precedence rules

Least common type resolution

The least common type from a set of types is the narrowest type reachable from the type precedence graph by all elements of the set of types.

The least common type resolution is used to:

  • Decide whether a function that expects a parameter of a given type can be invoked using an argument of a narrower type.
  • Derive the argument type for a function that expects a shared argument type for multiple parameters, such as coalesce, in, least, or greatest.
  • Derive the operand types for operators such as arithmetic operations or comparisons.
  • Derive the result type for expressions such as the case expression.
  • Derive the element, key, or value types for array and map constructors.
  • Derive the result type of UNION, INTERSECT, or EXCEPT set operators.

Special rules are applied if the least common type resolves to FLOAT. If any of the contributing types is an exact numeric type (TINYINT, SMALLINT, INTEGER, BIGINT, or DECIMAL) the least common type is pushed to DOUBLE to avoid potential loss of digits.

When the least common type is a STRING the collation is computed following the collation precedence rules.

Implicit downcasting and crosscasting

Azure Databricks employs these forms of implicit casting only on function and operator invocation, and only where it can unambiguously determine the intent.

  • Implicit downcasting

    Implicit downcasting automatically casts a wider type to a narrower type without requiring you to specify the cast explicitly. Downcasting is convenient, but it carries the risk of unexpected runtime errors if the actual value fails to be representable in the narrow type.

    Downcasting applies the type precedence list in reverse order.

  • Implicit crosscasting

    Implicit crosscasting casts a value from one type family to another without requiring you to specify the cast explicitly.

    Azure Databricks supports implicit crosscasting from:

    • Any simple type, except BINARY, to STRING.
    • A STRING to any simple type.

Casting on function invocation

Given a resolved function or operator, the following rules apply, in the order they are listed, for each parameter and argument pair:

  • If a supported parameter type is part of the argument’s type precedence graph, Azure Databricks promotes the argument to that parameter type.

    In most cases the function description explicitly states the supported types or chain, such as “any numeric type”.

    For example, sin(expr) operates on DOUBLE but will accept any numeric.

  • If the expected parameter type is a STRING and the argument is a simple type Azure Databricks crosscasts the argument to the string parameter type.

    For example, substr(str, start, len) expects str to be a STRING. Instead, you can pass a numeric or datetime type.

  • If the argument type is a STRING and the expected parameter type is a simple type, Azure Databricks crosscasts the string argument to the widest supported parameter type.

    For example, date_add(date, days) expects a DATE and an INTEGER.

    If you invoke date_add() with two STRINGs, Azure Databricks crosscasts the first STRING to DATE and the second STRING to an INTEGER.

  • If the function expects a numeric type, such as an INTEGER, or a DATE type, but the argument is a more general type, such as a DOUBLE or TIMESTAMP, Azure Databricks implicitly downcasts the argument to that parameter type.

    For example, a date_add(date, days) expects a DATE and an INTEGER.

    If you invoke date_add() with a TIMESTAMP and a BIGINT, Azure Databricks downcasts the TIMESTAMP to DATE by removing the time component and the BIGINT to an INTEGER.

  • Otherwise, Azure Databricks raises an error.

Examples

The coalesce function accepts any set of argument types as long as they share a least common type.

The result type is the least common type of the arguments.

-- The least common type of TINYINT and BIGINT is BIGINT
> SELECT typeof(coalesce(1Y, 1L, NULL));
  BIGINT

-- INTEGER and DATE do not share a precedence chain or support crosscasting in either direction.
> SELECT typeof(coalesce(1, DATE'2020-01-01'));
  Error: DATATYPE_MISMATCH.DATA_DIFF_TYPES

-- Both are ARRAYs and the elements have a least common type
> SELECT typeof(coalesce(ARRAY(1Y), ARRAY(1L)))
  ARRAY<BIGINT>

-- The least common type of INT and FLOAT is DOUBLE
> SELECT typeof(coalesce(1, 1F))
  DOUBLE

> SELECT typeof(coalesce(1L, 1F))
  DOUBLE

> SELECT typeof(coalesce(1BD, 1F))
  DOUBLE

-- The least common type between an INT and STRING is BIGINT
> SELECT typeof(coalesce(5, '6'));
  BIGINT

-- The least common type is a BIGINT, but the value is not BIGINT.
> SELECT coalesce('6.1', 5);
  Error: CAST_INVALID_INPUT

-- The least common type between a DECIMAL and a STRING is a DOUBLE
>  SELECT typeof(coalesce(1BD, '6'));
  DOUBLE

-- Two distinct explicit collations result in an error
>  SELECT collation(coalesce('hello' COLLATE UTF8_BINARY,
                             'world' COLLATE UNICODE));
  Error: COLLATION_MISMATCH.EXPLICIT

-- The resulting collation between two distinct implicit collations is indeterminate
>  SELECT collation(coalesce(c1, c2))
     FROM VALUES('hello' COLLATE UTF8_BINARY,
                 'world' COLLATE UNICODE) AS T(c1, c2);
  NULL

-- The resulting collation between a explicit and an implicit collations is the explicit collation.
> SELECT collation(coalesce(c1 COLLATE UTF8_BINARY, c2))
    FROM VALUES('hello',
                'world' COLLATE UNICODE) AS T(c1, c2);
  UTF8_BINARY

-- The resulting collation between an implicit and the default collation is the implicit collation.
> SELECT collation(coalesce(c1, ‘world’))
    FROM VALUES('hello' COLLATE UNICODE) AS T(c1, c2);
  UNICODE

-- The resulting collation between the default collation and the indeterminate collation is the default collation.
> SELECT collation(coalesce(coalesce(‘hello’ COLLATE UTF8_BINARY, ‘world’ COLLATE UNICODE), ‘world’));
  UTF8_BINARY

The substring function expects arguments of type STRING for the string and INTEGER for the start and length parameters.

-- Promotion of TINYINT to INTEGER
> SELECT substring('hello', 1Y, 2);
 he

-- No casting
> SELECT substring('hello', 1, 2);
 he

-- Casting of a literal string
> SELECT substring('hello', '1', 2);
 he

-- Downcasting of a BIGINT to an INT
> SELECT substring('hello', 1L, 2);
 he

-- Crosscasting from STRING to INTEGER
> SELECT substring('hello', str, 2)
  FROM VALUES(CAST('1' AS STRING)) AS T(str);
 he

-- Crosscasting from INTEGER to STRING
> SELECT substring(12345, 2, 2);
 23

|| (CONCAT) allows implicit crosscasting to string.

-- A numeric is cast to STRING
> SELECT 'This is a numeric: ' || 5.4E10;
 This is a numeric: 5.4E10

-- A date is cast to STRING
> SELECT 'This is a date: ' || DATE'2021-11-30';
 This is a date: 2021-11-30

date_add can be invoked with a TIMESTAMP or BIGINT due to implicit downcasting.

> SELECT date_add(TIMESTAMP'2011-11-30 08:30:00', 5L);
 2011-12-05

date_add can be invoked with STRINGs due to implicit crosscasting.

> SELECT date_add('2011-11-30 08:30:00', '5');
  2011-12-05