Enum datafusion::common::ScalarValue

pub enum ScalarValue {
    Null,
    Boolean(Option<bool>),
    Float32(Option<f32>),
    Float64(Option<f64>),
    Decimal128(Option<i128>, u8, i8),
    Decimal256(Option<i256>, u8, i8),
    Int8(Option<i8>),
    Int16(Option<i16>),
    Int32(Option<i32>),
    Int64(Option<i64>),
    UInt8(Option<u8>),
    UInt16(Option<u16>),
    UInt32(Option<u32>),
    UInt64(Option<u64>),
    Utf8(Option<String>),
    LargeUtf8(Option<String>),
    Binary(Option<Vec<u8>>),
    FixedSizeBinary(i32, Option<Vec<u8>>),
    LargeBinary(Option<Vec<u8>>),
    FixedSizeList(Arc<FixedSizeListArray>),
    List(Arc<GenericListArray<i32>>),
    LargeList(Arc<GenericListArray<i64>>),
    Date32(Option<i32>),
    Date64(Option<i64>),
    Time32Second(Option<i32>),
    Time32Millisecond(Option<i32>),
    Time64Microsecond(Option<i64>),
    Time64Nanosecond(Option<i64>),
    TimestampSecond(Option<i64>, Option<Arc<str>>),
    TimestampMillisecond(Option<i64>, Option<Arc<str>>),
    TimestampMicrosecond(Option<i64>, Option<Arc<str>>),
    TimestampNanosecond(Option<i64>, Option<Arc<str>>),
    IntervalYearMonth(Option<i32>),
    IntervalDayTime(Option<i64>),
    IntervalMonthDayNano(Option<i128>),
    DurationSecond(Option<i64>),
    DurationMillisecond(Option<i64>),
    DurationMicrosecond(Option<i64>),
    DurationNanosecond(Option<i64>),
    Struct(Option<Vec<ScalarValue>>, Fields),
    Dictionary(Box<DataType>, Box<ScalarValue>),
}

A dynamically typed, nullable single value, (the single-valued counter-part to arrow’s Array)

Performance

In general, please use arrow Arrays rather than ScalarValue whenever possible, as it is far more efficient for multiple values.

Example

// Create single scalar value for an Int32 value
let s1 = ScalarValue::Int32(Some(10));

// You can also create values using the From impl:
let s2 = ScalarValue::from(10i32);
assert_eq!(s1, s2);

Null Handling

ScalarValue represents null values in the same way as Arrow. Nulls are “typed” in the sense that a null value in an Int32Array is different than a null value in a Float64Array, and is different than the values in a NullArray.

// You can create a 'null' Int32 value directly:
let s1 = ScalarValue::Int32(None);

// You can also create a null value for a given datatype:
let s2 = ScalarValue::try_from(&DataType::Int32)?;
assert_eq!(s1, s2);

// Note that this is DIFFERENT than a `ScalarValue::Null`
let s3 = ScalarValue::Null;
assert_ne!(s1, s3);

Further Reading

See datatypes for details on datatypes and the format for the definitive reference.

Variants

Null

represents DataType::Null (castable to/from any other type)

Boolean(Option<bool>)

true or false value

Float32(Option<f32>)

32bit float

Float64(Option<f64>)

64bit float

Decimal128(Option<i128>, u8, i8)

128bit decimal, using the i128 to represent the decimal, precision scale

Decimal256(Option<i256>, u8, i8)

256bit decimal, using the i256 to represent the decimal, precision scale

Int8(Option<i8>)

signed 8bit int

Int16(Option<i16>)

signed 16bit int

Int32(Option<i32>)

signed 32bit int

Int64(Option<i64>)

signed 64bit int

UInt8(Option<u8>)

unsigned 8bit int

UInt16(Option<u16>)

unsigned 16bit int

UInt32(Option<u32>)

unsigned 32bit int

UInt64(Option<u64>)

unsigned 64bit int

Utf8(Option<String>)

utf-8 encoded string.

LargeUtf8(Option<String>)

utf-8 encoded string representing a LargeString’s arrow type.

Binary(Option<Vec<u8>>)

binary

FixedSizeBinary(i32, Option<Vec<u8>>)

fixed size binary

LargeBinary(Option<Vec<u8>>)

large binary

FixedSizeList(Arc<FixedSizeListArray>)

Fixed size list scalar.

The array must be a FixedSizeListArray with length 1.

List(Arc<GenericListArray<i32>>)

Represents a single element of a ListArray as an ArrayRef

The array must be a ListArray with length 1.

LargeList(Arc<GenericListArray<i64>>)

The array must be a LargeListArray with length 1.

Date32(Option<i32>)

Date stored as a signed 32bit int days since UNIX epoch 1970-01-01

Date64(Option<i64>)

Date stored as a signed 64bit int milliseconds since UNIX epoch 1970-01-01

Time32Second(Option<i32>)

Time stored as a signed 32bit int as seconds since midnight

Time32Millisecond(Option<i32>)

Time stored as a signed 32bit int as milliseconds since midnight

Time64Microsecond(Option<i64>)

Time stored as a signed 64bit int as microseconds since midnight

Time64Nanosecond(Option<i64>)

Time stored as a signed 64bit int as nanoseconds since midnight

TimestampSecond(Option<i64>, Option<Arc<str>>)

Timestamp Second

TimestampMillisecond(Option<i64>, Option<Arc<str>>)

Timestamp Milliseconds

TimestampMicrosecond(Option<i64>, Option<Arc<str>>)

Timestamp Microseconds

TimestampNanosecond(Option<i64>, Option<Arc<str>>)

Timestamp Nanoseconds

IntervalYearMonth(Option<i32>)

Number of elapsed whole months

IntervalDayTime(Option<i64>)

Number of elapsed days and milliseconds (no leap seconds) stored as 2 contiguous 32-bit signed integers

IntervalMonthDayNano(Option<i128>)

A triple of the number of elapsed months, days, and nanoseconds. Months and days are encoded as 32-bit signed integers. Nanoseconds is encoded as a 64-bit signed integer (no leap seconds).

DurationSecond(Option<i64>)

Duration in seconds

DurationMillisecond(Option<i64>)

Duration in milliseconds

DurationMicrosecond(Option<i64>)

Duration in microseconds

DurationNanosecond(Option<i64>)

Duration in nanoseconds

Struct(Option<Vec<ScalarValue>>, Fields)

struct of nested ScalarValue

Dictionary(Box<DataType>, Box<ScalarValue>)

Dictionary type: index type and value

Implementations

impl ScalarValue

pub fn new_primitive<T>( a: Option<<T as ArrowPrimitiveType>::Native>, d: &DataType ) -> Result<ScalarValue, DataFusionError>

where T: ArrowPrimitiveType,

Create a Result<ScalarValue> with the provided value and datatype

Panics

Panics if d is not compatible with T

pub fn try_new_decimal128( value: i128, precision: u8, scale: i8 ) -> Result<ScalarValue, DataFusionError>

Create a decimal Scalar from value/precision and scale.

pub fn new_utf8(val: impl Into<String>) -> ScalarValue

Returns a ScalarValue::Utf8 representing val

pub fn new_interval_ym(years: i32, months: i32) -> ScalarValue

Returns a ScalarValue::IntervalYearMonth representing years years and months months

pub fn new_interval_dt(days: i32, millis: i32) -> ScalarValue

Returns a ScalarValue::IntervalDayTime representing days days and millis milliseconds

pub fn new_interval_mdn(months: i32, days: i32, nanos: i64) -> ScalarValue

Returns a ScalarValue::IntervalMonthDayNano representing months months and days days, and nanos nanoseconds

pub fn new_timestamp<T>( value: Option<i64>, tz_opt: Option<Arc<str>> ) -> ScalarValue

where T: ArrowTimestampType,

Returns a ScalarValue representing value and tz_opt timezone

pub fn new_zero(datatype: &DataType) -> Result<ScalarValue, DataFusionError>

Create a zero value in the given type.

pub fn new_one(datatype: &DataType) -> Result<ScalarValue, DataFusionError>

Create an one value in the given type.

pub fn new_negative_one( datatype: &DataType ) -> Result<ScalarValue, DataFusionError>

Create a negative one value in the given type.

pub fn new_ten(datatype: &DataType) -> Result<ScalarValue, DataFusionError>

pub fn data_type(&self) -> DataType

return the DataType of this ScalarValue

pub fn get_datatype(&self) -> DataType

👎Deprecated since 31.0.0: use data_type instead

Getter for the DataType of the value.

Suggest using Self::data_type as a more standard API

pub fn arithmetic_negate(&self) -> Result<ScalarValue, DataFusionError>

Calculate arithmetic negation for a scalar value

pub fn add<T>(&self, other: T) -> Result<ScalarValue, DataFusionError>

where T: Borrow<ScalarValue>,

Wrapping addition of ScalarValue

NB: operating on ScalarValue directly is not efficient, performance sensitive code should operate on Arrays directly, using vectorized array kernels

pub fn add_checked<T>(&self, other: T) -> Result<ScalarValue, DataFusionError>

where T: Borrow<ScalarValue>,

Checked addition of ScalarValue

NB: operating on ScalarValue directly is not efficient, performance sensitive code should operate on Arrays directly, using vectorized array kernels

pub fn sub<T>(&self, other: T) -> Result<ScalarValue, DataFusionError>

where T: Borrow<ScalarValue>,

Wrapping subtraction of ScalarValue

NB: operating on ScalarValue directly is not efficient, performance sensitive code should operate on Arrays directly, using vectorized array kernels

pub fn sub_checked<T>(&self, other: T) -> Result<ScalarValue, DataFusionError>

where T: Borrow<ScalarValue>,

Checked subtraction of ScalarValue

NB: operating on ScalarValue directly is not efficient, performance sensitive code should operate on Arrays directly, using vectorized array kernels

pub fn mul<T>(&self, other: T) -> Result<ScalarValue, DataFusionError>

where T: Borrow<ScalarValue>,

Wrapping multiplication of ScalarValue

NB: operating on ScalarValue directly is not efficient, performance sensitive code should operate on Arrays directly, using vectorized array kernels.

pub fn mul_checked<T>(&self, other: T) -> Result<ScalarValue, DataFusionError>

where T: Borrow<ScalarValue>,

Checked multiplication of ScalarValue

NB: operating on ScalarValue directly is not efficient, performance sensitive code should operate on Arrays directly, using vectorized array kernels.

pub fn div<T>(&self, other: T) -> Result<ScalarValue, DataFusionError>

where T: Borrow<ScalarValue>,

Performs lhs / rhs

Overflow or division by zero will result in an error, with exception to floating point numbers, which instead follow the IEEE 754 rules.

NB: operating on ScalarValue directly is not efficient, performance sensitive code should operate on Arrays directly, using vectorized array kernels.

pub fn rem<T>(&self, other: T) -> Result<ScalarValue, DataFusionError>

where T: Borrow<ScalarValue>,

Performs lhs % rhs

Overflow or division by zero will result in an error, with exception to floating point numbers, which instead follow the IEEE 754 rules.

NB: operating on ScalarValue directly is not efficient, performance sensitive code should operate on Arrays directly, using vectorized array kernels.

pub fn is_unsigned(&self) -> bool

pub fn is_null(&self) -> bool

whether this value is null or not.

pub fn distance(&self, other: &ScalarValue) -> Option<usize>

Absolute distance between two numeric values (of the same type). This method will return None if either one of the arguments are null. It might also return None if the resulting distance is greater than usize::MAX. If the type is a float, then the distance will be rounded to the nearest integer.

Note: the datatype itself must support subtraction.

pub fn to_array(&self) -> Result<Arc<dyn Array>, DataFusionError>

Converts a scalar value into an 1-row array.

Errors

Errors if the ScalarValue cannot be converted into a 1-row array

pub fn to_scalar(&self) -> Result<Scalar<Arc<dyn Array>>, DataFusionError>

Converts a scalar into an arrow Scalar (which implements the Datum interface).

This can be used to call arrow compute kernels such as lt

Errors

Errors if the ScalarValue cannot be converted into a 1-row array

Example

use datafusion_common::ScalarValue;
use arrow::array::{BooleanArray, Int32Array};

let arr = Int32Array::from(vec![Some(1), None, Some(10)]);
let five = ScalarValue::Int32(Some(5));

let result = arrow::compute::kernels::cmp::lt(
  &arr,
  &five.to_scalar().unwrap(),
).unwrap();

let expected = BooleanArray::from(vec![
    Some(true),
    None,
    Some(false)
  ]
);

assert_eq!(&result, &expected);

pub fn iter_to_array( scalars: impl IntoIterator<Item = ScalarValue> ) -> Result<Arc<dyn Array>, DataFusionError>

Converts an iterator of references ScalarValue into an ArrayRef corresponding to those values. For example, an iterator of ScalarValue::Int32 would be converted to an Int32Array.

Returns an error if the iterator is empty or if the ScalarValues are not all the same type

Panics

Panics if self is a dictionary with invalid key type

Example

use datafusion_common::ScalarValue;
use arrow::array::{ArrayRef, BooleanArray};

let scalars = vec![
  ScalarValue::Boolean(Some(true)),
  ScalarValue::Boolean(None),
  ScalarValue::Boolean(Some(false)),
];

// Build an Array from the list of ScalarValues
let array = ScalarValue::iter_to_array(scalars.into_iter())
  .unwrap();

let expected: ArrayRef = std::sync::Arc::new(
  BooleanArray::from(vec![
    Some(true),
    None,
    Some(false)
  ]
));

assert_eq!(&array, &expected);

pub fn new_list( values: &[ScalarValue], data_type: &DataType ) -> Arc<GenericListArray<i32>>

Converts Vec<ScalarValue> where each element has type corresponding to data_type, to a ListArray.

Example

use datafusion_common::ScalarValue;
use arrow::array::{ListArray, Int32Array};
use arrow::datatypes::{DataType, Int32Type};
use datafusion_common::cast::as_list_array;

let scalars = vec![
   ScalarValue::Int32(Some(1)),
   ScalarValue::Int32(None),
   ScalarValue::Int32(Some(2))
];

let result = ScalarValue::new_list(&scalars, &DataType::Int32);

let expected = ListArray::from_iter_primitive::<Int32Type, _, _>(
    vec![
       Some(vec![Some(1), None, Some(2)])
    ]);

assert_eq!(*result, expected);

pub fn new_list_from_iter( values: impl IntoIterator<Item = ScalarValue> + ExactSizeIterator, data_type: &DataType ) -> Arc<GenericListArray<i32>>

Converts IntoIterator<Item = ScalarValue> where each element has type corresponding to data_type, to a ListArray.

Example

use datafusion_common::ScalarValue;
use arrow::array::{ListArray, Int32Array};
use arrow::datatypes::{DataType, Int32Type};
use datafusion_common::cast::as_list_array;

let scalars = vec![
   ScalarValue::Int32(Some(1)),
   ScalarValue::Int32(None),
   ScalarValue::Int32(Some(2))
];

let result = ScalarValue::new_list_from_iter(scalars.into_iter(), &DataType::Int32);

let expected = ListArray::from_iter_primitive::<Int32Type, _, _>(
    vec![
       Some(vec![Some(1), None, Some(2)])
    ]);

assert_eq!(*result, expected);

pub fn new_large_list( values: &[ScalarValue], data_type: &DataType ) -> Arc<GenericListArray<i64>>

Converts Vec<ScalarValue> where each element has type corresponding to data_type, to a LargeListArray.

Example

use datafusion_common::ScalarValue;
use arrow::array::{LargeListArray, Int32Array};
use arrow::datatypes::{DataType, Int32Type};
use datafusion_common::cast::as_large_list_array;

let scalars = vec![
   ScalarValue::Int32(Some(1)),
   ScalarValue::Int32(None),
   ScalarValue::Int32(Some(2))
];

let result = ScalarValue::new_large_list(&scalars, &DataType::Int32);

let expected = LargeListArray::from_iter_primitive::<Int32Type, _, _>(
    vec![
       Some(vec![Some(1), None, Some(2)])
    ]);

assert_eq!(*result, expected);

pub fn to_array_of_size( &self, size: usize ) -> Result<Arc<dyn Array>, DataFusionError>

Converts a scalar value into an array of size rows.

Errors

Errors if self is

• a decimal that fails be converted to a decimal array of size
• a Fixedsizelist that fails to be concatenated into an array of size
• a List that fails to be concatenated into an array of size
• a Dictionary that fails be converted to a dictionary array of size

pub fn convert_array_to_scalar_vec( array: &dyn Array ) -> Result<Vec<Vec<ScalarValue>>, DataFusionError>

Retrieve ScalarValue for each row in array

Example

use datafusion_common::ScalarValue;
use arrow::array::ListArray;
use arrow::datatypes::{DataType, Int32Type};

let list_arr = ListArray::from_iter_primitive::<Int32Type, _, _>(vec![
   Some(vec![Some(1), Some(2), Some(3)]),
   None,
   Some(vec![Some(4), Some(5)])
]);

let scalar_vec = ScalarValue::convert_array_to_scalar_vec(&list_arr).unwrap();

let expected = vec![
  vec![
    ScalarValue::Int32(Some(1)),
    ScalarValue::Int32(Some(2)),
    ScalarValue::Int32(Some(3)),
  ],
  vec![],
  vec![ScalarValue::Int32(Some(4)), ScalarValue::Int32(Some(5))]
];

assert_eq!(scalar_vec, expected);

pub fn raw_data(&self) -> Result<Arc<dyn Array>, DataFusionError>

Get raw data (inner array) inside ScalarValue

pub fn try_from_array( array: &dyn Array, index: usize ) -> Result<ScalarValue, DataFusionError>

Converts a value in array at index into a ScalarValue

pub fn try_from_string( value: String, target_type: &DataType ) -> Result<ScalarValue, DataFusionError>

Try to parse value into a ScalarValue of type target_type

pub fn eq_array( &self, array: &Arc<dyn Array>, index: usize ) -> Result<bool, DataFusionError>

Compares a single row of array @ index for equality with self, in an optimized fashion.

This method implements an optimized version of:

    let arr_scalar = Self::try_from_array(array, index).unwrap();
    arr_scalar.eq(self)

Performance note: the arrow compute kernels should be preferred over this function if at all possible as they can be vectorized and are generally much faster.

This function has a few narrow usescases such as hash table key comparisons where comparing a single row at a time is necessary.

Errors

Errors if

• it fails to downcast array to the data type of self
• self is a Struct

Panics

Panics if self is a dictionary with invalid key type

pub fn size(&self) -> usize

Estimate size if bytes including Self. For values with internal containers such as String includes the allocated size (capacity) rather than the current length (len)

pub fn size_of_vec(vec: &Vec<ScalarValue>) -> usize

Estimates size of Vec in bytes.

Includes the size of the Vec container itself.

pub fn size_of_vec_deque(vec_deque: &VecDeque<ScalarValue>) -> usize

Estimates size of VecDeque in bytes.

Includes the size of the VecDeque container itself.

pub fn size_of_hashset<S>(set: &HashSet<ScalarValue, S>) -> usize

Estimates size of HashSet in bytes.

Includes the size of the HashSet container itself.

Trait Implementations

impl Clone for ScalarValue

fn clone(&self) -> ScalarValue

Returns a copy of the value.

fn clone_from(&mut self, source: &Self)

Performs copy-assignment from source.

impl Debug for ScalarValue

fn fmt(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Formats the value using the given formatter.

impl Display for ScalarValue

fn fmt(&self, f: &mut Formatter<'_>) -> Result<(), Error>

Formats the value using the given formatter.

impl<T> From<&HyperLogLog<T>> for ScalarValue

where T: Hash,

fn from(v: &HyperLogLog<T>) -> ScalarValue

Converts to this type from the input type.

impl From<&str> for ScalarValue

fn from(value: &str) -> ScalarValue

Converts to this type from the input type.

impl From<Option<&str>> for ScalarValue

fn from(value: Option<&str>) -> ScalarValue

Converts to this type from the input type.

impl From<Option<bool>> for ScalarValue

fn from(value: Option<bool>) -> ScalarValue

Converts to this type from the input type.

impl From<Option<f32>> for ScalarValue

fn from(value: Option<f32>) -> ScalarValue

Converts to this type from the input type.

impl From<Option<f64>> for ScalarValue

fn from(value: Option<f64>) -> ScalarValue

Converts to this type from the input type.

impl From<Option<i16>> for ScalarValue

fn from(value: Option<i16>) -> ScalarValue

Converts to this type from the input type.

impl From<Option<i32>> for ScalarValue

fn from(value: Option<i32>) -> ScalarValue

Converts to this type from the input type.

impl From<Option<i64>> for ScalarValue

fn from(value: Option<i64>) -> ScalarValue

Converts to this type from the input type.

impl From<Option<i8>> for ScalarValue

fn from(value: Option<i8>) -> ScalarValue

Converts to this type from the input type.

impl From<Option<u16>> for ScalarValue

fn from(value: Option<u16>) -> ScalarValue

Converts to this type from the input type.

impl From<Option<u32>> for ScalarValue

fn from(value: Option<u32>) -> ScalarValue

Converts to this type from the input type.

impl From<Option<u64>> for ScalarValue

fn from(value: Option<u64>) -> ScalarValue

Converts to this type from the input type.

impl From<Option<u8>> for ScalarValue

fn from(value: Option<u8>) -> ScalarValue

Converts to this type from the input type.

impl From<ScalarValue> for NullableInterval

fn from(value: ScalarValue) -> NullableInterval

Create an interval that represents a single value.

impl From<String> for ScalarValue

fn from(value: String) -> ScalarValue

Converts to this type from the input type.

impl From<Vec<(&str, ScalarValue)>> for ScalarValue

fn from(value: Vec<(&str, ScalarValue)>) -> ScalarValue

Converts to this type from the input type.

impl From<bool> for ScalarValue

fn from(value: bool) -> ScalarValue

Converts to this type from the input type.

impl From<f32> for ScalarValue

fn from(value: f32) -> ScalarValue

Converts to this type from the input type.

impl From<f64> for ScalarValue

fn from(value: f64) -> ScalarValue

Converts to this type from the input type.

impl From<i16> for ScalarValue

fn from(value: i16) -> ScalarValue

Converts to this type from the input type.

impl From<i32> for ScalarValue

fn from(value: i32) -> ScalarValue

Converts to this type from the input type.

impl From<i64> for ScalarValue

fn from(value: i64) -> ScalarValue

Converts to this type from the input type.

impl From<i8> for ScalarValue

fn from(value: i8) -> ScalarValue

Converts to this type from the input type.

impl From<u16> for ScalarValue

fn from(value: u16) -> ScalarValue

Converts to this type from the input type.

impl From<u32> for ScalarValue

fn from(value: u32) -> ScalarValue

Converts to this type from the input type.

impl From<u64> for ScalarValue

fn from(value: u64) -> ScalarValue

Converts to this type from the input type.

impl From<u8> for ScalarValue

fn from(value: u8) -> ScalarValue

Converts to this type from the input type.

impl FromStr for ScalarValue

type Err = Infallible

The associated error which can be returned from parsing.

fn from_str(s: &str) -> Result<ScalarValue, <ScalarValue as FromStr>::Err>

Parses a string s to return a value of this type.

impl Hash for ScalarValue

fn hash<H>(&self, state: &mut H)

where H: Hasher,

Feeds this value into the given Hasher.

fn hash_slice<H>(data: &[Self], state: &mut H)

where H: Hasher, Self: Sized,

Feeds a slice of this type into the given Hasher.

impl Literal for ScalarValue

fn lit(&self) -> Expr

convert the value to a Literal expression

impl PartialEq for ScalarValue

fn eq(&self, other: &ScalarValue) -> bool

This method tests for self and other values to be equal, and is used by ==.

fn ne(&self, other: &Rhs) -> bool

This method tests for !=. The default implementation is almost always sufficient, and should not be overridden without very good reason.

impl PartialOrd for ScalarValue

fn partial_cmp(&self, other: &ScalarValue) -> Option<Ordering>

This method returns an ordering between self and other values if one exists.

fn lt(&self, other: &Rhs) -> bool

This method tests less than (for self and other) and is used by the < operator.

fn le(&self, other: &Rhs) -> bool

This method tests less than or equal to (for self and other) and is used by the <= operator.

fn gt(&self, other: &Rhs) -> bool

This method tests greater than (for self and other) and is used by the > operator.

fn ge(&self, other: &Rhs) -> bool

This method tests greater than or equal to (for self and other) and is used by the >= operator.

impl TryFrom<&DataType> for ScalarValue

fn try_from(data_type: &DataType) -> Result<ScalarValue, DataFusionError>

Create a Null instance of ScalarValue for this datatype

type Error = DataFusionError

The type returned in the event of a conversion error.

impl TryFrom<DataType> for ScalarValue

fn try_from(datatype: DataType) -> Result<ScalarValue, DataFusionError>

Create a Null instance of ScalarValue for this datatype

type Error = DataFusionError

The type returned in the event of a conversion error.

impl TryFrom<ScalarValue> for i256

type Error = DataFusionError

The type returned in the event of a conversion error.

fn try_from(value: ScalarValue) -> Result<i256, DataFusionError>

Performs the conversion.

impl TryFrom<ScalarValue> for u32

type Error = DataFusionError

The type returned in the event of a conversion error.

fn try_from(value: ScalarValue) -> Result<u32, DataFusionError>

Performs the conversion.

impl Eq for ScalarValue