Struct rust_decimal::Decimal [−][src]
#[repr(C)]pub struct Decimal { /* fields omitted */ }
Decimal
represents a 128 bit representation of a fixed-precision decimal number.
The finite set of values of type Decimal
are of the form m / 10e,
where m is an integer such that -296 < m < 296, and e is an integer
between 0 and 28 inclusive.
Implementations
impl Decimal
[src]
impl Decimal
[src]pub const MIN: Decimal
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The smallest value that can be represented by this decimal type.
pub const MAX: Decimal
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The largest value that can be represented by this decimal type.
pub const ZERO: Decimal
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A constant representing 0.
pub const ONE: Decimal
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A constant representing 1.
#[must_use]pub fn new(num: i64, scale: u32) -> Decimal
[src]
Returns a Decimal
with a 64 bit m
representation and corresponding e
scale.
Arguments
num
- An i64 that represents them
portion of the decimal numberscale
- A u32 representing thee
portion of the decimal number.
Panics
This function panics if scale
is > 28.
Example
use rust_decimal::Decimal; let pi = Decimal::new(3141, 3); assert_eq!(pi.to_string(), "3.141");
#[must_use]pub fn from_i128_with_scale(num: i128, scale: u32) -> Decimal
[src]
Creates a Decimal
using a 128 bit signed m
representation and corresponding e
scale.
Arguments
num
- An i128 that represents them
portion of the decimal numberscale
- A u32 representing thee
portion of the decimal number.
Panics
This function panics if scale
is > 28 or if num
exceeds the maximum supported 96 bits.
Example
use rust_decimal::Decimal; let pi = Decimal::from_i128_with_scale(3141i128, 3); assert_eq!(pi.to_string(), "3.141");
pub fn try_from_i128_with_scale(num: i128, scale: u32) -> Result<Decimal>
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Checked version of from_i128_with_scale
. Will return Err
instead
of panicking at run-time.
Example
use rust_decimal::Decimal; let max = Decimal::try_from_i128_with_scale(i128::MAX, u32::MAX); assert!(max.is_err());
#[must_use]pub const fn from_parts(
lo: u32,
mid: u32,
hi: u32,
negative: bool,
scale: u32
) -> Decimal
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lo: u32,
mid: u32,
hi: u32,
negative: bool,
scale: u32
) -> Decimal
Returns a Decimal
using the instances constituent parts.
Arguments
lo
- The low 32 bits of a 96-bit integer.mid
- The middle 32 bits of a 96-bit integer.hi
- The high 32 bits of a 96-bit integer.negative
-true
to indicate a negative number.scale
- A power of 10 ranging from 0 to 28.
Caution: Undefined behavior
While a scale greater than 28 can be passed in, it will be automatically capped by this function at the maximum precision. The library opts towards this functionality as opposed to a panic to ensure that the function can be treated as constant. This may lead to undefined behavior in downstream applications and should be treated with caution.
Example
use rust_decimal::Decimal; let pi = Decimal::from_parts(1102470952, 185874565, 1703060790, false, 28); assert_eq!(pi.to_string(), "3.1415926535897932384626433832");
pub fn from_scientific(value: &str) -> Result<Decimal, Error>
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Returns a Result
which if successful contains the Decimal
constitution of
the scientific notation provided by value
.
Arguments
value
- The scientific notation of theDecimal
.
Example
use rust_decimal::Decimal; let value = Decimal::from_scientific("9.7e-7").unwrap(); assert_eq!(value.to_string(), "0.00000097");
#[must_use]pub const fn scale(&self) -> u32
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Returns the scale of the decimal number, otherwise known as e
.
Example
use rust_decimal::Decimal; let num = Decimal::new(1234, 3); assert_eq!(num.scale(), 3u32);
#[must_use]pub const fn mantissa(&self) -> i128
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Returns the mantissa of the decimal number.
Example
use rust_decimal::prelude::*; let num = Decimal::from_str("-1.2345678").unwrap(); assert_eq!(num.mantissa(), -12345678i128); assert_eq!(num.scale(), 7);
#[must_use]pub const fn is_zero(&self) -> bool
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Returns true if this Decimal number is equivalent to zero.
Example
use rust_decimal::prelude::*; let num = Decimal::ZERO; assert!(num.is_zero());
pub fn set_sign(&mut self, positive: bool)
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please use set_sign_positive
instead
An optimized method for changing the sign of a decimal number.
Arguments
positive
: true if the resulting decimal should be positive.
Example
use rust_decimal::Decimal; let mut one = Decimal::new(1, 0); one.set_sign(false); assert_eq!(one.to_string(), "-1");
pub fn set_sign_positive(&mut self, positive: bool)
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An optimized method for changing the sign of a decimal number.
Arguments
positive
: true if the resulting decimal should be positive.
Example
use rust_decimal::Decimal; let mut one = Decimal::new(1, 0); one.set_sign_positive(false); assert_eq!(one.to_string(), "-1");
pub fn set_sign_negative(&mut self, negative: bool)
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An optimized method for changing the sign of a decimal number.
Arguments
negative
: true if the resulting decimal should be negative.
Example
use rust_decimal::Decimal; let mut one = Decimal::new(1, 0); one.set_sign_negative(true); assert_eq!(one.to_string(), "-1");
pub fn set_scale(&mut self, scale: u32) -> Result<(), Error>
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An optimized method for changing the scale of a decimal number.
Arguments
scale
: the new scale of the number
Example
use rust_decimal::Decimal; let mut one = Decimal::new(1, 0); one.set_scale(5).unwrap(); assert_eq!(one.to_string(), "0.00001");
pub fn rescale(&mut self, scale: u32)
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Modifies the Decimal
to the given scale, attempting to do so without changing the
underlying number itself.
Note that setting the scale to something less then the current Decimal
s scale will
cause the newly created Decimal
to have some rounding.
Scales greater than the maximum precision supported by Decimal
will be automatically
rounded to Decimal::MAX_PRECISION
.
Rounding leverages the half up strategy.
Arguments
scale
: The scale to use for the newDecimal
number.
Example
use rust_decimal::Decimal; let mut number = Decimal::new(1_123, 3); number.rescale(6); assert_eq!(number, Decimal::new(1_123_000, 6)); let mut round = Decimal::new(145, 2); round.rescale(1); assert_eq!(round, Decimal::new(15, 1));
#[must_use]pub const fn serialize(&self) -> [u8; 16]
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Returns a serialized version of the decimal number. The resulting byte array will have the following representation:
- Bytes 1-4: flags
- Bytes 5-8: lo portion of
m
- Bytes 9-12: mid portion of
m
- Bytes 13-16: high portion of
m
#[must_use]pub const fn deserialize(bytes: [u8; 16]) -> Decimal
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Deserializes the given bytes into a decimal number. The deserialized byte representation must be 16 bytes and adhere to the following convention:
- Bytes 1-4: flags
- Bytes 5-8: lo portion of
m
- Bytes 9-12: mid portion of
m
- Bytes 13-16: high portion of
m
#[must_use]pub fn is_negative(&self) -> bool
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please use is_sign_negative
instead
Returns true
if the decimal is negative.
#[must_use]pub fn is_positive(&self) -> bool
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please use is_sign_positive
instead
Returns true
if the decimal is positive.
pub const fn is_sign_negative(&self) -> bool
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Returns true
if the sign bit of the decimal is negative.
#[must_use]pub const fn is_sign_positive(&self) -> bool
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Returns true
if the sign bit of the decimal is positive.
#[must_use]pub const fn min_value() -> Decimal
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Use the associated constant Decimal::MIN
Returns the minimum possible number that Decimal
can represent.
#[must_use]pub const fn max_value() -> Decimal
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Use the associated constant Decimal::MAX
Returns the maximum possible number that Decimal
can represent.
#[must_use]pub fn trunc(&self) -> Decimal
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Returns a new Decimal
integral with no fractional portion.
This is a true truncation whereby no rounding is performed.
Example
use rust_decimal::Decimal; let pi = Decimal::new(3141, 3); let trunc = Decimal::new(3, 0); // note that it returns a decimal assert_eq!(pi.trunc(), trunc);
#[must_use]pub fn fract(&self) -> Decimal
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Returns a new Decimal
representing the fractional portion of the number.
Example
use rust_decimal::Decimal; let pi = Decimal::new(3141, 3); let fract = Decimal::new(141, 3); // note that it returns a decimal assert_eq!(pi.fract(), fract);
#[must_use]pub fn abs(&self) -> Decimal
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Computes the absolute value of self
.
Example
use rust_decimal::Decimal; let num = Decimal::new(-3141, 3); assert_eq!(num.abs().to_string(), "3.141");
#[must_use]pub fn floor(&self) -> Decimal
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Returns the largest integer less than or equal to a number.
Example
use rust_decimal::Decimal; let num = Decimal::new(3641, 3); assert_eq!(num.floor().to_string(), "3");
#[must_use]pub fn ceil(&self) -> Decimal
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Returns the smallest integer greater than or equal to a number.
Example
use rust_decimal::Decimal; let num = Decimal::new(3141, 3); assert_eq!(num.ceil().to_string(), "4"); let num = Decimal::new(3, 0); assert_eq!(num.ceil().to_string(), "3");
#[must_use]pub fn max(self, other: Decimal) -> Decimal
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Returns the maximum of the two numbers.
use rust_decimal::Decimal; let x = Decimal::new(1, 0); let y = Decimal::new(2, 0); assert_eq!(y, x.max(y));
#[must_use]pub fn min(self, other: Decimal) -> Decimal
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Returns the minimum of the two numbers.
use rust_decimal::Decimal; let x = Decimal::new(1, 0); let y = Decimal::new(2, 0); assert_eq!(x, x.min(y));
#[must_use]pub fn normalize(&self) -> Decimal
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Strips any trailing zero’s from a Decimal
and converts -0 to 0.
Example
use rust_decimal::prelude::*; let number = Decimal::from_str("3.100").unwrap(); assert_eq!(number.normalize().to_string(), "3.1");
pub fn normalize_assign(&mut self)
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An in place version of normalize
. Strips any trailing zero’s from a Decimal
and converts -0 to 0.
Example
use rust_decimal::prelude::*; let mut number = Decimal::from_str("3.100").unwrap(); assert_eq!(number.to_string(), "3.100"); number.normalize_assign(); assert_eq!(number.to_string(), "3.1");
#[must_use]pub fn round(&self) -> Decimal
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Returns a new Decimal
number with no fractional portion (i.e. an integer).
Rounding currently follows “Bankers Rounding” rules. e.g. 6.5 -> 6, 7.5 -> 8
Example
use rust_decimal::Decimal; // Demonstrating bankers rounding... let number_down = Decimal::new(65, 1); let number_up = Decimal::new(75, 1); assert_eq!(number_down.round().to_string(), "6"); assert_eq!(number_up.round().to_string(), "8");
#[must_use]pub fn round_dp_with_strategy(
&self,
dp: u32,
strategy: RoundingStrategy
) -> Decimal
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&self,
dp: u32,
strategy: RoundingStrategy
) -> Decimal
Returns a new Decimal
number with the specified number of decimal points for fractional
portion.
Rounding is performed using the provided RoundingStrategy
Arguments
dp
: the number of decimal points to round to.strategy
: theRoundingStrategy
to use.
Example
use rust_decimal::{Decimal, RoundingStrategy}; use core::str::FromStr; let tax = Decimal::from_str("3.4395").unwrap(); assert_eq!(tax.round_dp_with_strategy(2, RoundingStrategy::MidpointAwayFromZero).to_string(), "3.44");
#[must_use]pub fn round_dp(&self, dp: u32) -> Decimal
[src]
Returns a new Decimal
number with the specified number of decimal points for fractional portion.
Rounding currently follows “Bankers Rounding” rules. e.g. 6.5 -> 6, 7.5 -> 8
Arguments
dp
: the number of decimal points to round to.
Example
use rust_decimal::Decimal; use core::str::FromStr; let pi = Decimal::from_str("3.1415926535897932384626433832").unwrap(); assert_eq!(pi.round_dp(2).to_string(), "3.14");
pub const fn unpack(&self) -> UnpackedDecimal
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Convert Decimal
to an internal representation of the underlying struct. This is useful
for debugging the internal state of the object.
Important Disclaimer
This is primarily intended for library maintainers. The internal representation of a
Decimal
is considered “unstable” for public use.
Example
use rust_decimal::Decimal; use core::str::FromStr; let pi = Decimal::from_str("3.1415926535897932384626433832").unwrap(); assert_eq!(format!("{:?}", pi), "3.1415926535897932384626433832"); assert_eq!(format!("{:?}", pi.unpack()), "UnpackedDecimal { \ negative: false, scale: 28, hi: 1703060790, mid: 185874565, lo: 1102470952 \ }");
#[must_use]pub fn checked_add(self, other: Decimal) -> Option<Decimal>
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Checked addition. Computes self + other
, returning None
if overflow occurred.
#[must_use]pub fn checked_sub(self, other: Decimal) -> Option<Decimal>
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Checked subtraction. Computes self - other
, returning None
if overflow occurred.
#[must_use]pub fn checked_mul(self, other: Decimal) -> Option<Decimal>
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Checked multiplication. Computes self * other
, returning None
if overflow occurred.
#[must_use]pub fn checked_div(self, other: Decimal) -> Option<Decimal>
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Checked division. Computes self / other
, returning None
if other == 0.0
or the
division results in overflow.
#[must_use]pub fn checked_rem(self, other: Decimal) -> Option<Decimal>
[src]
Checked remainder. Computes self % other
, returning None
if other == 0.0
.
pub fn from_str_radix(str: &str, radix: u32) -> Result<Self, Error>
[src]
Trait Implementations
impl<'a> AddAssign<&'a Decimal> for &'a mut Decimal
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impl<'a> AddAssign<&'a Decimal> for &'a mut Decimal
[src]fn add_assign(&mut self, other: &'a Decimal)
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impl Arbitrary<'_> for Decimal
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impl Arbitrary<'_> for Decimal
[src]fn arbitrary(u: &mut Unstructured<'_>) -> ArbitraryResult<Self>
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pub fn arbitrary_take_rest(u: Unstructured<'a>) -> Result<Self, Error>
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pub fn size_hint(depth: usize) -> (usize, Option<usize>)
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impl<'expr> AsExpression<Nullable<Numeric>> for &'expr Decimal
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impl<'expr> AsExpression<Nullable<Numeric>> for &'expr Decimal
[src]type Expression = Bound<Nullable<Numeric>, Self>
The expression being returned
fn as_expression(self) -> Self::Expression
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impl AsExpression<Nullable<Numeric>> for Decimal
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impl AsExpression<Nullable<Numeric>> for Decimal
[src]type Expression = Bound<Nullable<Numeric>, Self>
The expression being returned
fn as_expression(self) -> Self::Expression
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impl<'expr> AsExpression<Numeric> for &'expr Decimal
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impl<'expr> AsExpression<Numeric> for &'expr Decimal
[src]type Expression = Bound<Numeric, Self>
The expression being returned
fn as_expression(self) -> Self::Expression
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impl AsExpression<Numeric> for Decimal
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impl AsExpression<Numeric> for Decimal
[src]type Expression = Bound<Numeric, Self>
The expression being returned
fn as_expression(self) -> Self::Expression
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impl CheckedAdd for Decimal
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impl CheckedAdd for Decimal
[src]fn checked_add(&self, v: &Decimal) -> Option<Decimal>
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impl CheckedDiv for Decimal
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impl CheckedDiv for Decimal
[src]fn checked_div(&self, v: &Decimal) -> Option<Decimal>
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impl CheckedMul for Decimal
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impl CheckedMul for Decimal
[src]fn checked_mul(&self, v: &Decimal) -> Option<Decimal>
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impl CheckedRem for Decimal
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impl CheckedRem for Decimal
[src]fn checked_rem(&self, v: &Decimal) -> Option<Decimal>
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impl CheckedSub for Decimal
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impl CheckedSub for Decimal
[src]fn checked_sub(&self, v: &Decimal) -> Option<Decimal>
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impl<'de> Deserialize<'de> for Decimal
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impl<'de> Deserialize<'de> for Decimal
[src]fn deserialize<D>(deserializer: D) -> Result<Decimal, D::Error> where
D: Deserializer<'de>,
[src]
D: Deserializer<'de>,
impl<'a> DivAssign<&'a Decimal> for &'a mut Decimal
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impl<'a> DivAssign<&'a Decimal> for &'a mut Decimal
[src]fn div_assign(&mut self, other: &'a Decimal)
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impl FromPrimitive for Decimal
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impl FromPrimitive for Decimal
[src]fn from_i32(n: i32) -> Option<Decimal>
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fn from_i64(n: i64) -> Option<Decimal>
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fn from_i128(n: i128) -> Option<Decimal>
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fn from_u32(n: u32) -> Option<Decimal>
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fn from_u64(n: u64) -> Option<Decimal>
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fn from_u128(n: u128) -> Option<Decimal>
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fn from_f32(n: f32) -> Option<Decimal>
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fn from_f64(n: f64) -> Option<Decimal>
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pub fn from_isize(n: isize) -> Option<Self>
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pub fn from_i8(n: i8) -> Option<Self>
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pub fn from_i16(n: i16) -> Option<Self>
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pub fn from_usize(n: usize) -> Option<Self>
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pub fn from_u8(n: u8) -> Option<Self>
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pub fn from_u16(n: u16) -> Option<Self>
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impl<'a> FromSql<'a> for Decimal
[src]
impl<'a> FromSql<'a> for Decimal
[src]fn from_sql(
_: &Type,
raw: &[u8]
) -> Result<Decimal, Box<dyn Error + Sync + Send + 'static>>
[src]
_: &Type,
raw: &[u8]
) -> Result<Decimal, Box<dyn Error + Sync + Send + 'static>>
fn accepts(ty: &Type) -> bool
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pub fn from_sql_null(
ty: &Type
) -> Result<Self, Box<dyn Error + 'static + Sync + Send, Global>>
[src]
ty: &Type
) -> Result<Self, Box<dyn Error + 'static + Sync + Send, Global>>
pub fn from_sql_nullable(
ty: &Type,
raw: Option<&'a [u8]>
) -> Result<Self, Box<dyn Error + 'static + Sync + Send, Global>>
[src]
ty: &Type,
raw: Option<&'a [u8]>
) -> Result<Self, Box<dyn Error + 'static + Sync + Send, Global>>
impl<__ST, __DB> FromSqlRow<__ST, __DB> for Decimal where
__DB: Backend,
Self: FromSql<__ST, __DB>,
[src]
impl<__ST, __DB> FromSqlRow<__ST, __DB> for Decimal where
__DB: Backend,
Self: FromSql<__ST, __DB>,
[src]fn build_from_row<R: Row<__DB>>(row: &mut R) -> Result<Self>
[src]
pub const FIELDS_NEEDED: usize
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impl MathematicalOps for Decimal
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impl MathematicalOps for Decimal
[src]fn exp(&self) -> Decimal
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fn exp_with_tolerance(&self, tolerance: Decimal) -> Decimal
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fn powi(&self, exp: i64) -> Decimal
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fn checked_powi(&self, exp: i64) -> Option<Decimal>
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fn powu(&self, exp: u64) -> Decimal
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fn checked_powu(&self, exp: u64) -> Option<Decimal>
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fn powf(&self, exp: f64) -> Decimal
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fn checked_powf(&self, exp: f64) -> Option<Decimal>
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fn powd(&self, exp: Decimal) -> Decimal
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fn checked_powd(&self, exp: Decimal) -> Option<Decimal>
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fn sqrt(&self) -> Option<Decimal>
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The square root of a Decimal. Uses a standard Babylonian method.
fn ln(&self) -> Decimal
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The natural logarithm for a Decimal. Uses a fast estimation algorithm This is more accurate on larger numbers and less on numbers less than 1.
fn erf(&self) -> Decimal
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Abramowitz Approximation of Error Function from wikipedia
fn norm_cdf(&self) -> Decimal
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The Cumulative distribution function for a Normal distribution
fn norm_pdf(&self) -> Decimal
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The Probability density function for a Normal distribution
impl<'a> MulAssign<&'a Decimal> for &'a mut Decimal
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impl<'a> MulAssign<&'a Decimal> for &'a mut Decimal
[src]fn mul_assign(&mut self, other: &'a Decimal)
[src]
impl Num for Decimal
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impl Num for Decimal
[src]type FromStrRadixErr = Error
fn from_str_radix(str: &str, radix: u32) -> Result<Self, Self::FromStrRadixErr>
[src]
impl PartialOrd<Decimal> for Decimal
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impl PartialOrd<Decimal> for Decimal
[src]impl<__ST, __DB> Queryable<__ST, __DB> for Decimal where
__DB: Backend,
Self: FromSql<__ST, __DB>,
[src]
impl<__ST, __DB> Queryable<__ST, __DB> for Decimal where
__DB: Backend,
Self: FromSql<__ST, __DB>,
[src]impl<'a> RemAssign<&'a Decimal> for &'a mut Decimal
[src]
impl<'a> RemAssign<&'a Decimal> for &'a mut Decimal
[src]fn rem_assign(&mut self, other: &'a Decimal)
[src]
impl<'a> SubAssign<&'a Decimal> for &'a mut Decimal
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impl<'a> SubAssign<&'a Decimal> for &'a mut Decimal
[src]fn sub_assign(&mut self, other: &'a Decimal)
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impl ToPrimitive for Decimal
[src]
impl ToPrimitive for Decimal
[src]fn to_i64(&self) -> Option<i64>
[src]
fn to_i128(&self) -> Option<i128>
[src]
fn to_u64(&self) -> Option<u64>
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fn to_u128(&self) -> Option<u128>
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fn to_f64(&self) -> Option<f64>
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pub fn to_isize(&self) -> Option<isize>
[src]
pub fn to_i8(&self) -> Option<i8>
[src]
pub fn to_i16(&self) -> Option<i16>
[src]
pub fn to_i32(&self) -> Option<i32>
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pub fn to_usize(&self) -> Option<usize>
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pub fn to_u8(&self) -> Option<u8>
[src]
pub fn to_u16(&self) -> Option<u16>
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pub fn to_u32(&self) -> Option<u32>
[src]
pub fn to_f32(&self) -> Option<f32>
[src]
impl<__DB> ToSql<Nullable<Numeric>, __DB> for Decimal where
__DB: Backend,
Self: ToSql<Numeric, __DB>,
[src]
impl<__DB> ToSql<Nullable<Numeric>, __DB> for Decimal where
__DB: Backend,
Self: ToSql<Numeric, __DB>,
[src]Auto Trait Implementations
impl RefUnwindSafe for Decimal
impl RefUnwindSafe for Decimal
impl UnwindSafe for Decimal
impl UnwindSafe for Decimal
Blanket Implementations
impl<T> BorrowToSql for T where
T: ToSql,
[src]
impl<T> BorrowToSql for T where
T: ToSql,
[src]pub fn borrow_to_sql(&self) -> &dyn ToSql
[src]
impl<T> DeserializeOwned for T where
T: for<'de> Deserialize<'de>,
[src]
impl<T> DeserializeOwned for T where
T: for<'de> Deserialize<'de>,
[src]impl<T> FromSqlOwned for T where
T: for<'a> FromSql<'a>,
[src]
impl<T> FromSqlOwned for T where
T: for<'a> FromSql<'a>,
[src]impl<T> IntoSql for T
[src]
impl<T> IntoSql for T
[src]pub fn into_sql<T>(self) -> Self::Expression where
Self: AsExpression<T>,
[src]
Self: AsExpression<T>,
pub fn as_sql<'a, T>(&'a self) -> <&'a Self as AsExpression<T>>::Expression where
&'a Self: AsExpression<T>,
[src]
&'a Self: AsExpression<T>,
impl<T> NumAssign for T where
T: Num + NumAssignOps<T>,
[src]
impl<T> NumAssign for T where
T: Num + NumAssignOps<T>,
[src]impl<T, Rhs> NumAssignOps<Rhs> for T where
T: AddAssign<Rhs> + SubAssign<Rhs> + MulAssign<Rhs> + DivAssign<Rhs> + RemAssign<Rhs>,
[src]
impl<T, Rhs> NumAssignOps<Rhs> for T where
T: AddAssign<Rhs> + SubAssign<Rhs> + MulAssign<Rhs> + DivAssign<Rhs> + RemAssign<Rhs>,
[src]impl<T> NumAssignRef for T where
T: NumAssign + for<'r> NumAssignOps<&'r T>,
[src]
impl<T> NumAssignRef for T where
T: NumAssign + for<'r> NumAssignOps<&'r T>,
[src]impl<T, Rhs, Output> NumOps<Rhs, Output> for T where
T: Sub<Rhs, Output = Output> + Mul<Rhs, Output = Output> + Div<Rhs, Output = Output> + Add<Rhs, Output = Output> + Rem<Rhs, Output = Output>,
[src]
impl<T, Rhs, Output> NumOps<Rhs, Output> for T where
T: Sub<Rhs, Output = Output> + Mul<Rhs, Output = Output> + Div<Rhs, Output = Output> + Add<Rhs, Output = Output> + Rem<Rhs, Output = Output>,
[src]impl<T, Base> RefNum<Base> for T where
T: NumOps<Base, Base> + for<'r> NumOps<&'r Base, Base>,
[src]
impl<T, Base> RefNum<Base> for T where
T: NumOps<Base, Base> + for<'r> NumOps<&'r Base, Base>,
[src]impl<T> Same<T> for T
impl<T> Same<T> for T
type Output = T
Should always be Self
impl<V, T> VZip<V> for T where
V: MultiLane<T>,
impl<V, T> VZip<V> for T where
V: MultiLane<T>,