Struct fixed::FixedI32 [−][src]
#[repr(transparent)]pub struct FixedI32<Frac> { /* fields omitted */ }Expand description
A 32-bit signed number with Frac fractional bits.
The number has 32 bits, of which f = Frac are fractional
bits and 32 − f are integer bits. The value x can lie
in the range −231/2f ≤ x < 231/2f. The difference between successive
numbers is constant throughout the range: Δ = 1/2f.
For FixedI32<U0>, f = 0 and Δ = 1, and the
fixed-point number behaves like an i32 with the value lying in the range −231 ≤ x < 231. For FixedI32<U32>,
f = 32 and Δ = 1/232, and the
value lies in the range −1/2 ≤ x < 1/2.
Frac is an Unsigned as provided by the typenum crate; the plan is to
to have a major version 2 with const generics instead when the Rust compiler
support for them is powerful enough.
FixedI32<Frac> has the same size, alignment and ABI as i32;
it is #[repr(transparent)] with i32 as the only non-zero-sized field.
Examples
use fixed::{types::extra::U3, FixedI32};
let eleven = FixedI32::<U3>::from_num(11);
assert_eq!(eleven, FixedI32::<U3>::from_bits(11 << 3));
assert_eq!(eleven, 11);
assert_eq!(eleven.to_string(), "11");
let two_point_75 = eleven / 4;
assert_eq!(two_point_75, FixedI32::<U3>::from_bits(11 << 1));
assert_eq!(two_point_75, 2.75);
assert_eq!(two_point_75.to_string(), "2.8");Implementations
The implementation of items in this block is independent
of the number of fractional bits Frac.
Zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::ZERO, Fix::from_bits(0));The difference between any two successive representable numbers, Δ.
If the number has f = Frac fractional bits, then
Δ = 1/2f.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::DELTA, Fix::from_bits(1));
// binary 0.0001 is decimal 0.0625
assert_eq!(Fix::DELTA, 0.0625);The smallest value that can be represented.
If the number has f = Frac fractional bits,
then the minimum is −231/2f.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::MIN, Fix::from_bits(i32::MIN));The largest value that can be represented.
If the number has f = Frac fractional bits, then the maximum is
(231 − 1)/2f.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::MAX, Fix::from_bits(i32::MAX));Creates a fixed-point number that has a bitwise representation identical to the given integer.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
// 0010.0000 == 2
assert_eq!(Fix::from_bits(0b10_0000), 2);Creates an integer that has a bitwise representation identical to the given fixed-point number.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
// 2 is 0010.0000
assert_eq!(Fix::from_num(2).to_bits(), 0b10_0000);Converts a fixed-point number from big endian to the target’s endianness.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let f = Fix::from_bits(0x1234_5678);
if cfg!(target_endian = "big") {
assert_eq!(Fix::from_be(f), f);
} else {
assert_eq!(Fix::from_be(f), f.swap_bytes());
}Converts a fixed-point number from little endian to the target’s endianness.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let f = Fix::from_bits(0x1234_5678);
if cfg!(target_endian = "little") {
assert_eq!(Fix::from_le(f), f);
} else {
assert_eq!(Fix::from_le(f), f.swap_bytes());
}Converts self to big endian from the target’s endianness.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let f = Fix::from_bits(0x1234_5678);
if cfg!(target_endian = "big") {
assert_eq!(f.to_be(), f);
} else {
assert_eq!(f.to_be(), f.swap_bytes());
}Converts self to little endian from the target’s endianness.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let f = Fix::from_bits(0x1234_5678);
if cfg!(target_endian = "little") {
assert_eq!(f.to_le(), f);
} else {
assert_eq!(f.to_le(), f.swap_bytes());
}Reverses the byte order of the fixed-point number.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let f = Fix::from_bits(0x1234_5678);
let swapped = Fix::from_bits(0x7856_3412);
assert_eq!(f.swap_bytes(), swapped);Creates a fixed-point number from its representation as a byte array in big endian.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(
Fix::from_be_bytes([0x12, 0x34, 0x56, 0x78]),
Fix::from_bits(0x1234_5678)
);Creates a fixed-point number from its representation as a byte array in little endian.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(
Fix::from_le_bytes([0x78, 0x56, 0x34, 0x12]),
Fix::from_bits(0x1234_5678)
);Creates a fixed-point number from its representation as a byte array in native endian.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(
if cfg!(target_endian = "big") {
Fix::from_ne_bytes([0x12, 0x34, 0x56, 0x78])
} else {
Fix::from_ne_bytes([0x78, 0x56, 0x34, 0x12])
},
Fix::from_bits(0x1234_5678)
);Returns the memory representation of this fixed-point number as a byte array in big-endian byte order.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let val = Fix::from_bits(0x1234_5678);
assert_eq!(
val.to_be_bytes(),
[0x12, 0x34, 0x56, 0x78]
);Returns the memory representation of this fixed-point number as a byte array in little-endian byte order.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let val = Fix::from_bits(0x1234_5678);
assert_eq!(
val.to_le_bytes(),
[0x78, 0x56, 0x34, 0x12]
);Returns the memory representation of this fixed-point number as a byte array in native byte order.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let val = Fix::from_bits(0x1234_5678);
assert_eq!(
val.to_ne_bytes(),
if cfg!(target_endian = "big") {
[0x12, 0x34, 0x56, 0x78]
} else {
[0x78, 0x56, 0x34, 0x12]
}
);Returns the number of ones in the binary representation.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let f = Fix::from_bits(0b11_0010);
assert_eq!(f.count_ones(), 3);Returns the number of zeros in the binary representation.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let f = Fix::from_bits(!0b11_0010);
assert_eq!(f.count_zeros(), 3);Returns the number of leading ones in the binary representation.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let all_ones = !Fix::ZERO;
let f = all_ones - Fix::from_bits(0b10_0000);
assert_eq!(f.leading_ones(), 32 - 6);Returns the number of leading zeros in the binary representation.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let f = Fix::from_bits(0b10_0000);
assert_eq!(f.leading_zeros(), 32 - 6);Returns the number of trailing ones in the binary representation.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let f = Fix::from_bits(0b101_1111);
assert_eq!(f.trailing_ones(), 5);Returns the number of trailing zeros in the binary representation.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let f = Fix::from_bits(0b10_0000);
assert_eq!(f.trailing_zeros(), 5);Returns the number of bits required to represent the value.
The number of bits required includes an initial one for negative numbers, and an initial zero for non-negative numbers.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(-3).signed_bits(), 7); // “_101.0000”
assert_eq!(Fix::from_num(-1).signed_bits(), 5); // “___1.0000”
assert_eq!(Fix::from_num(-0.0625).signed_bits(), 1); // “____.___1”
assert_eq!(Fix::from_num(0).signed_bits(), 1); // “____.___0”
assert_eq!(Fix::from_num(0.0625).signed_bits(), 2); // “____.__01”
assert_eq!(Fix::from_num(1).signed_bits(), 6); // “__01.0000”
assert_eq!(Fix::from_num(3).signed_bits(), 7); // “_011.0000”Reverses the order of the bits of the fixed-point number.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let bits = 0x1234_5678_i32;
let rev_bits = bits.reverse_bits();
assert_eq!(Fix::from_bits(bits).reverse_bits(), Fix::from_bits(rev_bits));Shifts to the left by n bits, wrapping the
truncated bits to the right end.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let bits: i32 = (0b111 << (32 - 3)) | 0b1010;
let rot = 0b1010111;
assert_eq!(bits.rotate_left(3), rot);
assert_eq!(Fix::from_bits(bits).rotate_left(3), Fix::from_bits(rot));Shifts to the right by n bits, wrapping the
truncated bits to the left end.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let bits: i32 = 0b1010111;
let rot = (0b111 << (32 - 3)) | 0b1010;
assert_eq!(bits.rotate_right(3), rot);
assert_eq!(Fix::from_bits(bits).rotate_right(3), Fix::from_bits(rot));Multiplies two fixed-point numbers and returns a wider type to retain all precision.
If self has f fractional bits and 32 − f
integer bits, and rhs has g fractional bits and 32 − g integer bits, then the returned fixed-point number will
have f + g fractional bits and 64 − f − g integer bits.
Examples
use fixed::{
types::extra::{U2, U4},
FixedI32,
};
// decimal: 1.25 × 1.0625 = 1.328_125
// binary: 1.01 × 1.0001 == 1.010101
let a = FixedI32::<U2>::from_num(1.25);
let b = FixedI32::<U4>::from_num(1.0625);
assert_eq!(a.wide_mul(b), 1.328_125);Multiply and add. Returns self × mul + add.
For some cases, the product self × mul would overflow
on its own, but the final result self × mul + add is representable; in
these cases this method returns the correct result without overflow.
The mul parameter can have a fixed-point type like
self but with a different number of fractional bits.
Panics
When debug assertions are enabled, this method panics if the result
overflows. When debug assertions are not enabled, the wrapped value
can be returned, but it is not considered a breaking change if in the
future it panics; if wrapping is required use wrapping_mul_add
instead.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(
Fix::from_num(4).mul_add(Fix::from_num(0.5), Fix::from_num(3)),
Fix::from_num(5)
);
// MAX × 1.5 − MAX = MAX / 2, which does not overflow
assert_eq!(Fix::MAX.mul_add(Fix::from_num(1.5), -Fix::MAX), Fix::MAX / 2);Remainder for Euclidean division.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).rem_euclid(Fix::from_num(2)), Fix::from_num(1.5));
assert_eq!(Fix::from_num(-7.5).rem_euclid(Fix::from_num(2)), Fix::from_num(0.5));Returns the absolute value.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let five = Fix::from_num(5);
let minus_five = Fix::from_num(-5);
assert_eq!(five.abs(), five);
assert_eq!(minus_five.abs(), five);Returns the absolute value using an unsigned type without any wrapping or panicking.
Examples
use fixed::{types::extra::U4, FixedI32, FixedU32};
type Fix = FixedI32<U4>;
type UFix = FixedU32<U4>;
assert_eq!(Fix::from_num(-5).unsigned_abs(), UFix::from_num(5));
// min_as_unsigned has only highest bit set
let min_as_unsigned = UFix::ONE << (UFix::INT_NBITS - 1);
assert_eq!(Fix::MIN.unsigned_abs(), min_as_unsigned);Returns the distance from self to other.
The distance is the absolute value of the difference.
Panics
When debug assertions are enabled, this method panics if the result overflows.
When debug assertions are not enabled, the wrapped value can be returned, but it
is not considered a breaking change if in the future it panics; if wrapping is
required use wrapping_dist instead.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::ONE.dist(Fix::from_num(5)), Fix::from_num(4));
assert_eq!(Fix::from_num(-1).dist(Fix::from_num(2)), Fix::from_num(3));Returns the distance from self to other using an
unsigned type without any wrapping or panicking.
The distance is the absolute value of the difference.
Examples
use fixed::{types::extra::U4, FixedI32, FixedU32};
type Fix = FixedI32<U4>;
type UFix = FixedU32<U4>;
assert_eq!(Fix::from_num(-1).unsigned_dist(Fix::from_num(2)), UFix::from_num(3));
assert_eq!(Fix::MIN.unsigned_dist(Fix::MAX), UFix::MAX);Returns the mean of self and other.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).mean(Fix::from_num(4)), Fix::from_num(3.5));
assert_eq!(Fix::from_num(-3).mean(Fix::from_num(4)), Fix::from_num(0.5));Bitwise NOT. Usable in constant context.
This is equivalent to the ! operator and
Not::not, but
can also be used in constant context. Unless required in constant
context, use the operator or trait instead.
Planned deprecation
This method will be deprecated when the ! operator and the
Not trait are usable in constant context.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
const A: Fix = Fix::from_bits(0x3E);
const NOT_A: Fix = A.const_not();
assert_eq!(NOT_A, !A);Bitwise AND. Usable in constant context.
This is equivalent to the & operator and
BitAnd::bitand,
but can also be used in constant context. Unless required in constant
context, use the operator or trait instead.
Planned deprecation
This method will be deprecated when the & operator and the
BitAnd trait are usable in constant context.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
const A: Fix = Fix::from_bits(0x3E);
const B: Fix = Fix::from_bits(0x55);
const A_BITAND_B: Fix = A.const_bitand(B);
assert_eq!(A_BITAND_B, A & B);Bitwise OR. Usable in constant context.
This is equivalent to the | operator and
BitOr::bitor,
but can also be used in constant context. Unless required in constant
context, use the operator or trait instead.
Planned deprecation
This method will be deprecated when the | operator and the
BitOr trait are usable in constant context.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
const A: Fix = Fix::from_bits(0x3E);
const B: Fix = Fix::from_bits(0x55);
const A_BITOR_B: Fix = A.const_bitor(B);
assert_eq!(A_BITOR_B, A | B);Bitwise XOR. Usable in constant context.
This is equivalent to the ^ operator and
BitXor::bitxor,
but can also be used in constant context. Unless required in constant
context, use the operator or trait instead.
Planned deprecation
This method will be deprecated when the ^ operator and the
BitXor trait are usable in constant context.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
const A: Fix = Fix::from_bits(0x3E);
const B: Fix = Fix::from_bits(0x55);
const A_BITXOR_B: Fix = A.const_bitxor(B);
assert_eq!(A_BITXOR_B, A ^ B);Checked negation. Returns the negated value, or None on overflow.
Overflow can only occur when negating the minimum value.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(5).checked_neg(), Some(Fix::from_num(-5)));
assert_eq!(Fix::MIN.checked_neg(), None);Checked multiply and add.
Returns self × mul + add, or None on overflow.
For some cases, the product self × mul would overflow
on its own, but the final result self × mul + add is representable; in
these cases this method returns the correct result without overflow.
The mul parameter can have a fixed-point type like
self but with a different number of fractional bits.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(
Fix::from_num(4).checked_mul_add(Fix::from_num(0.5), Fix::from_num(3)),
Some(Fix::from_num(5))
);
assert_eq!(Fix::MAX.checked_mul_add(Fix::ONE, Fix::ZERO), Some(Fix::MAX));
assert_eq!(Fix::MAX.checked_mul_add(Fix::ONE, Fix::DELTA), None);
// MAX × 1.5 − MAX = MAX / 2, which does not overflow
assert_eq!(Fix::MAX.checked_mul_add(Fix::from_num(1.5), -Fix::MAX), Some(Fix::MAX / 2));Checked division by an integer. Returns the quotient, or
None if the divisor is zero or if the division results in overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::MAX.checked_div_int(1), Some(Fix::MAX));
assert_eq!(Fix::ONE.checked_div_int(0), None);
assert_eq!(Fix::MIN.checked_div_int(-1), None);Checked remainder for Euclidean division. Returns the
remainder, or None if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let num = Fix::from_num(7.5);
assert_eq!(num.checked_rem_euclid(Fix::from_num(2)), Some(Fix::from_num(1.5)));
assert_eq!(num.checked_rem_euclid(Fix::ZERO), None);
assert_eq!((-num).checked_rem_euclid(Fix::from_num(2)), Some(Fix::from_num(0.5)));Checked absolute value. Returns the absolute value, or None on overflow.
Overflow can only occur when trying to find the absolute value of the minimum value.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(-5).checked_abs(), Some(Fix::from_num(5)));
assert_eq!(Fix::MIN.checked_abs(), None);Checked distance. Returns the distance from self to other, or None on overflow.
The distance is the absolute value of the difference.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::ONE.checked_dist(Fix::from_num(5)), Some(Fix::from_num(4)));
assert_eq!(Fix::MIN.checked_dist(Fix::ZERO), None);Saturating negation. Returns the negated value, saturating on overflow.
Overflow can only occur when negating the minimum value.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(5).saturating_neg(), Fix::from_num(-5));
assert_eq!(Fix::MIN.saturating_neg(), Fix::MAX);Saturating addition. Returns the sum, saturating on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).saturating_add(Fix::from_num(2)), Fix::from_num(5));
assert_eq!(Fix::MAX.saturating_add(Fix::ONE), Fix::MAX);Saturating subtraction. Returns the difference, saturating on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::ONE.saturating_sub(Fix::from_num(3)), Fix::from_num(-2));
assert_eq!(Fix::MIN.saturating_sub(Fix::ONE), Fix::MIN);Saturating multiply and add.
Returns self × mul + add, saturating on overflow.
For some cases, the product self × mul would overflow
on its own, but the final result self × mul + add is representable; in
these cases this method returns the correct result without overflow.
The mul parameter can have a fixed-point type like
self but with a different number of fractional bits.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(
Fix::from_num(4).saturating_mul_add(Fix::from_num(0.5), Fix::from_num(3)),
Fix::from_num(5)
);
let half_max = Fix::MAX / 2;
assert_eq!(half_max.saturating_mul_add(Fix::from_num(3), half_max), Fix::MAX);
assert_eq!(half_max.saturating_mul_add(Fix::from_num(-5), half_max), Fix::MIN);
// MAX × 1.5 − MAX = MAX / 2, which does not overflow
assert_eq!(Fix::MAX.saturating_mul_add(Fix::from_num(1.5), -Fix::MAX), half_max);Saturating multiplication by an integer. Returns the product, saturating on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).saturating_mul_int(2), Fix::from_num(6));
assert_eq!(Fix::MAX.saturating_mul_int(2), Fix::MAX);Saturating absolute value. Returns the absolute value, saturating on overflow.
Overflow can only occur when trying to find the absolute value of the minimum value.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(-5).saturating_abs(), Fix::from_num(5));
assert_eq!(Fix::MIN.saturating_abs(), Fix::MAX);Saturating distance. Returns the distance from self to other, saturating on overflow.
The distance is the absolute value of the difference.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::ONE.saturating_dist(Fix::from_num(5)), Fix::from_num(4));
assert_eq!(Fix::MIN.saturating_dist(Fix::MAX), Fix::MAX);Wrapping negation. Returns the negated value, wrapping on overflow.
Overflow can only occur when negating the minimum value.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(5).wrapping_neg(), Fix::from_num(-5));
assert_eq!(Fix::MIN.wrapping_neg(), Fix::MIN);Wrapping addition. Returns the sum, wrapping on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let one_minus_delta = Fix::ONE - Fix::DELTA;
assert_eq!(Fix::from_num(3).wrapping_add(Fix::from_num(2)), Fix::from_num(5));
assert_eq!(Fix::MAX.wrapping_add(Fix::ONE), Fix::MIN + one_minus_delta);Wrapping subtraction. Returns the difference, wrapping on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let one_minus_delta = Fix::ONE - Fix::DELTA;
assert_eq!(Fix::from_num(3).wrapping_sub(Fix::from_num(5)), Fix::from_num(-2));
assert_eq!(Fix::MIN.wrapping_sub(Fix::ONE), Fix::MAX - one_minus_delta);Wrapping multiply and add.
Returns self × mul + add, wrapping on overflow.
The mul parameter can have a fixed-point type like
self but with a different number of fractional bits.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(
Fix::from_num(4).wrapping_mul_add(Fix::from_num(0.5), Fix::from_num(3)),
Fix::from_num(5)
);
assert_eq!(Fix::MAX.wrapping_mul_add(Fix::ONE, Fix::from_num(0)), Fix::MAX);
assert_eq!(Fix::MAX.wrapping_mul_add(Fix::ONE, Fix::from_bits(1)), Fix::MIN);
let wrapped = Fix::MAX.wrapping_mul_int(4);
assert_eq!(Fix::MAX.wrapping_mul_add(Fix::from_num(3), Fix::MAX), wrapped);Wrapping multiplication by an integer. Returns the product, wrapping on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).wrapping_mul_int(2), Fix::from_num(6));
let wrapped = Fix::from_bits(!0 << 2);
assert_eq!(Fix::MAX.wrapping_mul_int(4), wrapped);Wrapping division by an integer. Returns the quotient, wrapping on overflow.
Overflow can only occur when dividing the minimum value by −1.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
// 1.5 is binary 1.1
let one_point_5 = Fix::from_bits(0b11 << (4 - 1));
assert_eq!(Fix::from_num(3).wrapping_div_int(2), one_point_5);
assert_eq!(Fix::MIN.wrapping_div_int(-1), Fix::MIN);Wrapping shift left. Wraps rhs if rhs ≥ 32,
then shifts and returns the number.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!((Fix::ONE / 2).wrapping_shl(3), Fix::from_num(4));
assert_eq!((Fix::ONE / 2).wrapping_shl(3 + 32), Fix::from_num(4));Wrapping shift right. Wraps rhs if rhs ≥ 32,
then shifts and returns the number.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!((Fix::from_num(4)).wrapping_shr(3), Fix::ONE / 2);
assert_eq!((Fix::from_num(4)).wrapping_shr(3 + 32), Fix::ONE / 2);Wrapping absolute value. Returns the absolute value, wrapping on overflow.
Overflow can only occur when trying to find the absolute value of the minimum value.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(-5).wrapping_abs(), Fix::from_num(5));
assert_eq!(Fix::MIN.wrapping_abs(), Fix::MIN);Wrapping distance. Returns the distance from self to other, wrapping on overflow.
The distance is the absolute value of the difference.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::ONE.wrapping_dist(Fix::from_num(5)), Fix::from_num(4));
assert_eq!(Fix::MIN.wrapping_dist(Fix::MAX), -Fix::DELTA);Unwrapped negation. Returns the negated value, panicking on overflow.
Overflow can only occur when negating the minimum value.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(5).unwrapped_neg(), Fix::from_num(-5));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MIN.unwrapped_neg();Unwrapped addition. Returns the sum, panicking on overflow.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).unwrapped_add(Fix::from_num(2)), Fix::from_num(5));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MAX.unwrapped_add(Fix::DELTA);Unwrapped subtraction. Returns the difference, panicking on overflow.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).unwrapped_sub(Fix::from_num(5)), Fix::from_num(-2));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MIN.unwrapped_sub(Fix::DELTA);Unwrapped remainder. Returns the remainder, panicking if the divisor is zero.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(1.5).unwrapped_rem(Fix::ONE), Fix::from_num(0.5));The following panics because the divisor is zero.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _divisor_is_zero = Fix::from_num(1.5).unwrapped_rem(Fix::ZERO);Unwrapped multiply and add.
Returns self × mul + add, panicking on overflow.
For some cases, the product self × mul would overflow
on its own, but the final result self × mul + add is representable; in
these cases this method returns the correct result without overflow.
The mul parameter can have a fixed-point type like
self but with a different number of fractional bits.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(
Fix::from_num(4).unwrapped_mul_add(Fix::from_num(0.5), Fix::from_num(3)),
Fix::from_num(5)
);
// MAX × 1.5 − MAX = MAX / 2, which does not overflow
assert_eq!(Fix::MAX.unwrapped_mul_add(Fix::from_num(1.5), -Fix::MAX), Fix::MAX / 2);The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MAX.unwrapped_mul_add(Fix::ONE, Fix::DELTA);Unwrapped multiplication by an integer. Returns the product, panicking on overflow.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).unwrapped_mul_int(2), Fix::from_num(6));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MAX.unwrapped_mul_int(4);Unwrapped division by an integer. Returns the quotient, panicking on overflow.
Overflow can only occur when dividing the minimum value by −1.
Panics
Panics if the divisor is zero or if the division results in overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
// 1.5 is binary 1.1
let one_point_5 = Fix::from_bits(0b11 << (4 - 1));
assert_eq!(Fix::from_num(3).unwrapped_div_int(2), one_point_5);The following panics because the divisor is zero.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _divisor_is_zero = Fix::from_num(3).unwrapped_div_int(0);The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MIN.unwrapped_div_int(-1);Unwrapped remainder for Euclidean division. Returns the remainder, panicking if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let num = Fix::from_num(7.5);
assert_eq!(num.unwrapped_rem_euclid(Fix::from_num(2)), Fix::from_num(1.5));The following panics because the divisor is zero.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _divisor_is_zero = Fix::from_num(3).unwrapped_rem_euclid(Fix::ZERO);Unwrapped shift left. Panics if rhs ≥ 32.
Panics
Panics if rhs ≥ 32.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!((Fix::ONE / 2).unwrapped_shl(3), Fix::from_num(4));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::ONE.unwrapped_shl(32);Unwrapped shift right. Panics if rhs ≥ 32.
Panics
Panics if rhs ≥ 32.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!((Fix::from_num(4)).unwrapped_shr(3), Fix::ONE / 2);The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::ONE.unwrapped_shr(32);Unwrapped absolute value. Returns the absolute value, panicking on overflow.
Overflow can only occur when trying to find the absolute value of the minimum value.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(-5).unwrapped_abs(), Fix::from_num(5));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MIN.unwrapped_abs();Unwrapped distance. Returns the distance from self to other, panicking on overflow.
The distance is the absolute value of the difference.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::ONE.unwrapped_dist(Fix::from_num(5)), Fix::from_num(4));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MIN.unwrapped_dist(Fix::ZERO);Overflowing negation.
Returns a tuple of the negated value and a bool indicating whether
an overflow has occurred. On overflow, the wrapped value is returned.
Overflow can only occur when negating the minimum value.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(5).overflowing_neg(), (Fix::from_num(-5), false));
assert_eq!(Fix::MIN.overflowing_neg(), (Fix::MIN, true));Overflowing addition.
Returns a tuple of the sum and a bool indicating whether an
overflow has occurred. On overflow, the wrapped value is returned.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let one_minus_delta = Fix::ONE - Fix::DELTA;
assert_eq!(Fix::from_num(3).overflowing_add(Fix::from_num(2)), (Fix::from_num(5), false));
assert_eq!(Fix::MAX.overflowing_add(Fix::ONE), (Fix::MIN + one_minus_delta, true));Overflowing subtraction.
Returns a tuple of the difference and a bool indicating whether an
overflow has occurred. On overflow, the wrapped value is returned.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let one_minus_delta = Fix::ONE - Fix::DELTA;
assert_eq!(Fix::from_num(3).overflowing_sub(Fix::from_num(5)), (Fix::from_num(-2), false));
assert_eq!(Fix::MIN.overflowing_sub(Fix::ONE), (Fix::MAX - one_minus_delta, true));Overflowing multiply and add.
Returns a tuple of self × mul + add and a bool indicating
whether an overflow has occurred. On overflow, the wrapped value is
returned.
For some cases, the product self × mul would overflow
on its own, but the final result self × mul + add is representable; in
these cases this method returns the correct result without overflow.
The mul parameter can have a fixed-point type like
self but with a different number of fractional bits.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(
Fix::MAX.overflowing_mul_add(Fix::ONE, Fix::ZERO),
(Fix::MAX, false)
);
assert_eq!(
Fix::MAX.overflowing_mul_add(Fix::ONE, Fix::DELTA),
(Fix::MIN, true)
);
assert_eq!(
Fix::MAX.overflowing_mul_add(Fix::from_num(3), Fix::MAX),
Fix::MAX.overflowing_mul_int(4)
);
// MAX × 1.5 − MAX = MAX / 2, which does not overflow
assert_eq!(
Fix::MAX.overflowing_mul_add(Fix::from_num(1.5), -Fix::MAX),
(Fix::MAX / 2, false)
);Overflowing multiplication by an integer.
Returns a tuple of the product and a bool indicating whether an
overflow has occurred. On overflow, the wrapped value is returned.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).overflowing_mul_int(2), (Fix::from_num(6), false));
let wrapped = Fix::from_bits(!0 << 2);
assert_eq!(Fix::MAX.overflowing_mul_int(4), (wrapped, true));Overflowing division by an integer.
Returns a tuple of the quotient and a bool indicating whether an overflow has
occurred. On overflow, the wrapped value is returned. Overflow can
only occur when dividing the minimum value by −1.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
// 1.5 is binary 1.1
let one_point_5 = Fix::from_bits(0b11 << (4 - 1));
assert_eq!(Fix::from_num(3).overflowing_div_int(2), (one_point_5, false));
assert_eq!(Fix::MIN.overflowing_div_int(-1), (Fix::MIN, true));Overflowing shift left.
Returns a tuple of the shifted value and a bool indicating whether
an overflow has occurred. Overflow occurs when rhs ≥ 32.
On overflow rhs is wrapped before the shift operation.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!((Fix::ONE / 2).overflowing_shl(3), (Fix::from_num(4), false));
assert_eq!((Fix::ONE / 2).overflowing_shl(3 + 32), (Fix::from_num(4), true));Overflowing shift right.
Returns a tuple of the shifted value and a bool indicating whether
an overflow has occurred. Overflow occurs when rhs ≥ 32.
On overflow rhs is wrapped before the shift operation.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!((Fix::from_num(4)).overflowing_shr(3), (Fix::ONE / 2, false));
assert_eq!((Fix::from_num(4)).overflowing_shr(3 + 32), (Fix::ONE / 2, true));Overflowing absolute value.
Returns a tuple of the absolute value and a bool indicating
whether an overflow has occurred. On overflow, the wrapped value is
returned.
Overflow can only occur when trying to find the absolute value of the minimum value.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(-5).overflowing_abs(), (Fix::from_num(5), false));
assert_eq!(Fix::MIN.overflowing_abs(), (Fix::MIN, true));Overflowing distance.
Returns a tuple of the distance from self to other and a bool indicating whether an overflow has
occurred. On overflow, the wrapped value is returned.
The distance is the absolute value of the difference.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(
Fix::ONE.overflowing_dist(Fix::from_num(5)),
(Fix::from_num(4), false)
);
assert_eq!(
Fix::MIN.overflowing_dist(Fix::MAX),
(-Fix::DELTA, true)
);The implementation of items in this block depends on the
number of fractional bits Frac.
The number of integer bits.
Examples
use fixed::{types::extra::U6, FixedI32};
type Fix = FixedI32<U6>;
assert_eq!(Fix::INT_NBITS, 32 - 6);The number of fractional bits.
Examples
use fixed::{types::extra::U6, FixedI32};
type Fix = FixedI32<U6>;
assert_eq!(Fix::FRAC_NBITS, 6);Creates a fixed-point number from another number.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other number
srcfor whichToFixedis implemented, in which case this method returnssrc.to_fixed().
Panics
For floating-point numbers, panics if the value is not finite.
When debug assertions are enabled, panics if the value does not fit.
When debug assertions are not enabled, the wrapped value can be
returned, but it is not considered a breaking change if in the future
it panics; if wrapping is required use wrapping_from_num instead.
Examples
use fixed::{types::extra::U4, types::I16F16, FixedI32};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = I16F16::from_bits(0b111 << (16 - 2));
assert_eq!(Fix::from_num(src), Fix::from_bits(0b111 << (4 - 2)));
assert_eq!(Fix::from_num(3i32), Fix::from_bits(3 << 4));
assert_eq!(Fix::from_num(-3i64), Fix::from_bits(-3 << 4));
assert_eq!(Fix::from_num(1.75f32), Fix::from_bits(0b111 << (4 - 2)));
assert_eq!(Fix::from_num(-1.75f64), Fix::from_bits(-0b111 << (4-2)));Converts a fixed-point number to another number.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. Any fractional bits are discarded, which rounds towards −∞. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other type
Dstfor whichFromFixedis implemented, in which case this method returnsDst::from_fixed(self).
Panics
When debug assertions are enabled, panics if the value does not fit.
When debug assertions are not enabled, the wrapped value can be
returned, but it is not considered a breaking change if in the future
it panics; if wrapping is required use wrapping_to_num instead.
Examples
use fixed::{types::extra::U4, types::I30F2, FixedI32};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = Fix::from_bits(0b111 << (4 - 2));
assert_eq!(src.to_num::<I30F2>(), I30F2::from_bits(0b111));
// src >> 2 is 0.0111, which for I30F2 is truncated to 0.01
assert_eq!((src >> 2u32).to_num::<I30F2>(), I30F2::from_bits(0b1));
// 2.5 is 10.1 in binary
let two_point_5 = Fix::from_bits(0b101 << (4 - 1));
assert_eq!(two_point_5.to_num::<i32>(), 2);
assert_eq!((-two_point_5).to_num::<i64>(), -3);
// 1.625 is 1.101 in binary
let one_point_625 = Fix::from_bits(0b1101 << (4 - 3));
assert_eq!(one_point_625.to_num::<f32>(), 1.625f32);
assert_eq!((-one_point_625).to_num::<f64>(), -1.625f64);Creates a fixed-point number from another number if it
fits, otherwise returns None.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other number
srcfor whichToFixedis implemented, in which case this method returnssrc.checked_to_fixed().
Examples
use fixed::{
types::extra::{U2, U4},
types::I16F16,
FixedI32,
};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = I16F16::from_bits(0b111 << (16 - 2));
assert_eq!(Fix::checked_from_num(src), Some(Fix::from_bits(0b111 << (4 - 2))));
let too_large = FixedI32::<U2>::MAX;
assert!(Fix::checked_from_num(too_large).is_none());
assert_eq!(Fix::checked_from_num(3), Some(Fix::from_bits(3 << 4)));
let too_large = i32::MAX;
assert!(Fix::checked_from_num(too_large).is_none());
let too_small = i32::MIN;
assert!(Fix::checked_from_num(too_small).is_none());
// 1.75 is 1.11 in binary
let expected = Fix::from_bits(0b111 << (4 - 2));
assert_eq!(Fix::checked_from_num(1.75f32), Some(expected));
assert_eq!(Fix::checked_from_num(-1.75f64), Some(-expected));
assert!(Fix::checked_from_num(2e38).is_none());
assert!(Fix::checked_from_num(std::f64::NAN).is_none());Converts a fixed-point number to another number if it
fits, otherwise returns None.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. Any fractional bits are discarded, which rounds towards −∞. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other type
Dstfor whichFromFixedis implemented, in which case this method returnsDst::checked_from_fixed(self).
Examples
use fixed::{
types::extra::{U0, U4, U6},
types::I16F16,
FixedI32,
};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = Fix::from_bits(0b111 << (4 - 2));
let expected = I16F16::from_bits(0b111 << (16 - 2));
assert_eq!(src.checked_to_num::<I16F16>(), Some(expected));
type TooFewIntBits = FixedI32<U6>;
assert!(Fix::MAX.checked_to_num::<TooFewIntBits>().is_none());
// 2.5 is 10.1 in binary
let two_point_5 = Fix::from_bits(0b101 << (4 - 1));
assert_eq!(two_point_5.checked_to_num::<i32>(), Some(2));
assert_eq!((-two_point_5).checked_to_num::<i64>(), Some(-3));
type AllInt = FixedI32<U0>;
assert!(AllInt::from_bits(-1).checked_to_num::<u32>().is_none());
// 1.625 is 1.101 in binary
let one_point_625 = Fix::from_bits(0b1101 << (4 - 3));
assert_eq!(one_point_625.checked_to_num::<f32>(), Some(1.625f32));Creates a fixed-point number from another number, saturating if it does not fit.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other number
srcfor whichToFixedis implemented, in which case this method returnssrc.saturating_to_fixed().
Panics
This method panics if the value is a floating-point NaN.
Examples
use fixed::{
types::extra::{U2, U4},
types::I16F16,
FixedI32,
};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = I16F16::from_bits(0b111 << (16 - 2));
assert_eq!(Fix::saturating_from_num(src), Fix::from_bits(0b111 << (4 - 2)));
let too_large = FixedI32::<U2>::MAX;
assert_eq!(Fix::saturating_from_num(too_large), Fix::MAX);
assert_eq!(Fix::saturating_from_num(3), Fix::from_bits(3 << 4));
let too_small = i32::MIN;
assert_eq!(Fix::saturating_from_num(too_small), Fix::MIN);
// 1.75 is 1.11 in binary
let expected = Fix::from_bits(0b111 << (4 - 2));
assert_eq!(Fix::saturating_from_num(1.75f32), expected);
assert_eq!(Fix::saturating_from_num(-1.75f64), -expected);
assert_eq!(Fix::saturating_from_num(2e38), Fix::MAX);
assert_eq!(Fix::saturating_from_num(std::f64::NEG_INFINITY), Fix::MIN);Converts a fixed-point number to another number, saturating the value if it does not fit.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. Any fractional bits are discarded, which rounds towards −∞. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other type
Dstfor whichFromFixedis implemented, in which case this method returnsDst::saturating_from_fixed(self).
Examples
use fixed::{
types::extra::{U0, U4, U6},
types::I16F16,
FixedI32,
};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = Fix::from_bits(0b111 << (4 - 2));
let expected = I16F16::from_bits(0b111 << (16 - 2));
assert_eq!(src.saturating_to_num::<I16F16>(), expected);
type TooFewIntBits = FixedI32<U6>;
let saturated = Fix::MAX.saturating_to_num::<TooFewIntBits>();
assert_eq!(saturated, TooFewIntBits::MAX);
// 2.5 is 10.1 in binary
let two_point_5 = Fix::from_bits(0b101 << (4 - 1));
assert_eq!(two_point_5.saturating_to_num::<i32>(), 2);
type AllInt = FixedI32<U0>;
assert_eq!(AllInt::from_bits(-1).saturating_to_num::<u32>(), 0);
// 1.625 is 1.101 in binary
let one_point_625 = Fix::from_bits(0b1101 << (4 - 3));
assert_eq!(one_point_625.saturating_to_num::<f32>(), 1.625f32);Creates a fixed-point number from another number, wrapping the value on overflow.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other number
srcfor whichToFixedis implemented, in which case this method returnssrc.wrapping_to_fixed().
Panics
For floating-point numbers, panics if the value is not finite.
Examples
use fixed::{
types::extra::{U0, U4},
types::I16F16,
FixedI32,
};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = I16F16::from_bits(0b111 << (16 - 2));
assert_eq!(Fix::wrapping_from_num(src), Fix::from_bits(0b111 << (4 - 2)));
// integer 0b1101 << (32 - 7) will wrap to fixed-point 1010...
let too_large = FixedI32::<U0>::from_bits(0b1101 << (32 - 7));
let wrapped = Fix::from_bits(0b1010 << (32 - 4));
assert_eq!(Fix::wrapping_from_num(too_large), wrapped);
// integer 0b1101 << (32 - 7) will wrap to fixed-point 1010...
let large: i32 = 0b1101 << (32 - 7);
let wrapped = Fix::from_bits(0b1010 << (32 - 4));
assert_eq!(Fix::wrapping_from_num(large), wrapped);
// 1.75 is 1.11 in binary
let expected = Fix::from_bits(0b111 << (4 - 2));
assert_eq!(Fix::wrapping_from_num(1.75f32), expected);
// 1.75 << (32 - 4) wraps to binary 11000...
let large = 1.75 * 2f32.powi(32 - 4);
let wrapped = Fix::from_bits(0b1100 << (32 - 4));
assert_eq!(Fix::wrapping_from_num(large), wrapped);Converts a fixed-point number to another number, wrapping the value on overflow.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. Any fractional bits are discarded, which rounds towards −∞. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other type
Dstfor whichFromFixedis implemented, in which case this method returnsDst::wrapping_from_fixed(self).
Examples
use fixed::{
types::extra::{U0, U4, U6},
types::I16F16,
FixedI32,
};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = Fix::from_bits(0b111 << (4 - 2));
let expected = I16F16::from_bits(0b111 << (16 - 2));
assert_eq!(src.wrapping_to_num::<I16F16>(), expected);
type TooFewIntBits = FixedI32<U6>;
let wrapped = TooFewIntBits::from_bits(Fix::MAX.to_bits() << 2);
assert_eq!(Fix::MAX.wrapping_to_num::<TooFewIntBits>(), wrapped);
// 2.5 is 10.1 in binary
let two_point_5 = Fix::from_bits(0b101 << (4 - 1));
assert_eq!(two_point_5.wrapping_to_num::<i32>(), 2);
type AllInt = FixedI32<U0>;
assert_eq!(AllInt::from_bits(-1).wrapping_to_num::<u32>(), u32::MAX);
// 1.625 is 1.101 in binary
let one_point_625 = Fix::from_bits(0b1101 << (4 - 3));
assert_eq!(one_point_625.wrapping_to_num::<f32>(), 1.625f32);Creates a fixed-point number from another number, panicking on overflow.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other number
srcfor whichToFixedis implemented, in which case this method returnssrc.unwrapped_to_fixed().
Panics
Panics if the value does not fit.
For floating-point numbers, also panics if the value is not finite.
Examples
use fixed::{
types::{extra::U4, I16F16},
FixedI32,
};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = I16F16::from_bits(0b111 << (16 - 2));
assert_eq!(Fix::unwrapped_from_num(src), Fix::from_bits(0b111 << (4 - 2)));The following panics because of overflow.
use fixed::{
types::extra::{U0, U4},
FixedI32,
};
type Fix = FixedI32<U4>;
let too_large = FixedI32::<U0>::from_bits(0b1101 << (32 - 7));
let _overflow = Fix::unwrapped_from_num(too_large);Converts a fixed-point number to another number, panicking on overflow.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. Any fractional bits are discarded, which rounds towards −∞. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other type
Dstfor whichFromFixedis implemented, in which case this method returnsDst::unwrapped_from_fixed(self).
Panics
Panics if the value does not fit.
Examples
use fixed::{
types::{extra::U4, I16F16},
FixedI32,
};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = Fix::from_bits(0b111 << (4 - 2));
let expected = I16F16::from_bits(0b111 << (16 - 2));
assert_eq!(src.unwrapped_to_num::<I16F16>(), expected);The following panics because of overflow.
use fixed::{
types::extra::{U4, U6},
FixedI32,
};
type Fix = FixedI32<U4>;
type TooFewIntBits = FixedI32<U6>;
let _overflow = Fix::MAX.unwrapped_to_num::<TooFewIntBits>();Creates a fixed-point number from another number.
Returns a tuple of the fixed-point number and a bool indicating
whether an overflow has occurred. On overflow, the wrapped value is
returned.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other number
srcfor whichToFixedis implemented, in which case this method returnssrc.overflowing_to_fixed().
Panics
For floating-point numbers, panics if the value is not finite.
Examples
use fixed::{
types::extra::{U0, U4},
types::I16F16,
FixedI32,
};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = I16F16::from_bits(0b111 << (16 - 2));
let expected = Fix::from_bits(0b111 << (4 - 2));
assert_eq!(Fix::overflowing_from_num(src), (expected, false));
// integer 0b1101 << (32 - 7) will wrap to fixed-point 1010...
let too_large = FixedI32::<U0>::from_bits(0b1101 << (32 - 7));
let wrapped = Fix::from_bits(0b1010 << (32 - 4));
assert_eq!(Fix::overflowing_from_num(too_large), (wrapped, true));
assert_eq!(Fix::overflowing_from_num(3), (Fix::from_bits(3 << 4), false));
// integer 0b1101 << (32 - 7) will wrap to fixed-point 1010...
let large: i32 = 0b1101 << (32 - 7);
let wrapped = Fix::from_bits(0b1010 << (32 - 4));
assert_eq!(Fix::overflowing_from_num(large), (wrapped, true));
// 1.75 is 1.11 in binary
let expected = Fix::from_bits(0b111 << (4 - 2));
assert_eq!(Fix::overflowing_from_num(1.75f32), (expected, false));
// 1.75 << (32 - 4) wraps to binary 11000...
let large = 1.75 * 2f32.powi(32 - 4);
let wrapped = Fix::from_bits(0b1100 << (32 - 4));
assert_eq!(Fix::overflowing_from_num(large), (wrapped, true));Converts a fixed-point number to another number.
Returns a tuple of the number and a bool indicating whether an
overflow has occurred. On overflow, the wrapped value is returned.
The other number can be:
- Another fixed-point number. Any extra fractional bits are discarded, which rounds towards −∞.
- An integer of type
i8,i16,i32,i64,i128,isize,u8,u16,u32,u64,u128, orusize. Any fractional bits are discarded, which rounds towards −∞. - A floating-point number of type
f16,bf16,f32,f64orF128Bits. For this conversion, the method rounds to the nearest, with ties rounding to even. - Any other type
Dstfor whichFromFixedis implemented, in which case this method returnsDst::overflowing_from_fixed(self).
Examples
use fixed::{
types::extra::{U0, U4, U6},
types::I16F16,
FixedI32,
};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let src = Fix::from_bits(0b111 << (4 - 2));
let expected = I16F16::from_bits(0b111 << (16 - 2));
assert_eq!(src.overflowing_to_num::<I16F16>(), (expected, false));
type TooFewIntBits = FixedI32<U6>;
let wrapped = TooFewIntBits::from_bits(Fix::MAX.to_bits() << 2);
assert_eq!(Fix::MAX.overflowing_to_num::<TooFewIntBits>(), (wrapped, true));
// 2.5 is 10.1 in binary
let two_point_5 = Fix::from_bits(0b101 << (4 - 1));
assert_eq!(two_point_5.overflowing_to_num::<i32>(), (2, false));
let does_not_fit = FixedI32::<U0>::from_bits(-1);
let wrapped = 1u32.wrapping_neg();
assert_eq!(does_not_fit.overflowing_to_num::<u32>(), (wrapped, true));
// 1.625 is 1.101 in binary
let one_point_625 = Fix::from_bits(0b1101 << (4 - 3));
assert_eq!(one_point_625.overflowing_to_num::<f32>(), (1.625f32, false));Parses a string slice containing binary digits to return a fixed-point number.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary
let f = Fix::from_str_binary("1.11");
let check = Fix::from_bits(0b111 << (4 - 2));
assert_eq!(f, Ok(check));
let neg = Fix::from_str_binary("-1.11");
assert_eq!(neg, Ok(-check));Parses a string slice containing octal digits to return a fixed-point number.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary, 1.6 in octal
let f = Fix::from_str_octal("1.6");
let check = Fix::from_bits(0b111 << (4 - 2));
assert_eq!(f, Ok(check));
let neg = Fix::from_str_octal("-1.6");
assert_eq!(neg, Ok(-check));Parses a string slice containing hexadecimal digits to return a fixed-point number.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
// 1.75 is 1.11 in binary, 1.C in hexadecimal
let f = Fix::from_str_hex("1.C");
let check = Fix::from_bits(0b111 << (4 - 2));
assert_eq!(f, Ok(check));
let neg = Fix::from_str_hex("-1.C");
assert_eq!(neg, Ok(-check));Parses a string slice containing decimal digits to return a fixed-point number, saturating on overflow.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
assert_eq!(I8F8::saturating_from_str("9999"), Ok(I8F8::MAX));
assert_eq!(I8F8::saturating_from_str("-9999"), Ok(I8F8::MIN));Parses a string slice containing binary digits to return a fixed-point number, saturating on overflow.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
assert_eq!(I8F8::saturating_from_str_binary("101100111000"), Ok(I8F8::MAX));
assert_eq!(I8F8::saturating_from_str_binary("-101100111000"), Ok(I8F8::MIN));Parses a string slice containing octal digits to return a fixed-point number, saturating on overflow.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
assert_eq!(I8F8::saturating_from_str_octal("7777"), Ok(I8F8::MAX));
assert_eq!(I8F8::saturating_from_str_octal("-7777"), Ok(I8F8::MIN));Prases a string slice containing hexadecimal digits to return a fixed-point number, saturating on overflow.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
assert_eq!(I8F8::saturating_from_str_hex("FFFF"), Ok(I8F8::MAX));
assert_eq!(I8F8::saturating_from_str_hex("-FFFF"), Ok(I8F8::MIN));Parses a string slice containing decimal digits to return a fixed-point number, wrapping on overflow.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
// 9999.5 = 15.5 + 256 × n
assert_eq!(I8F8::wrapping_from_str("9999.5"), Ok(I8F8::from_num(15.5)));
assert_eq!(I8F8::wrapping_from_str("-9999.5"), Ok(I8F8::from_num(-15.5)));Parses a string slice containing binary digits to return a fixed-point number, wrapping on overflow.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
let check = I8F8::from_bits(0b1110001 << (8 - 1));
assert_eq!(I8F8::wrapping_from_str_binary("101100111000.1"), Ok(check));
assert_eq!(I8F8::wrapping_from_str_binary("-101100111000.1"), Ok(-check));Parses a string slice containing octal digits to return a fixed-point number, wrapping on overflow.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
let check = I8F8::from_bits(0o1654 << (8 - 3));
assert_eq!(I8F8::wrapping_from_str_octal("7165.4"), Ok(check));
assert_eq!(I8F8::wrapping_from_str_octal("-7165.4"), Ok(-check));Parses a string slice containing hexadecimal digits to return a fixed-point number, wrapping on overflow.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
let check = I8F8::from_bits(0xFFE);
assert_eq!(I8F8::wrapping_from_str_hex("C0F.FE"), Ok(check));
assert_eq!(I8F8::wrapping_from_str_hex("-C0F.FE"), Ok(-check));Parses a string slice containing decimal digits to return a fixed-point number.
Returns a tuple of the fixed-point number and a bool indicating
whether an overflow has occurred. On overflow, the wrapped value is
returned.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
assert_eq!(I8F8::overflowing_from_str("99.5"), Ok((I8F8::from_num(99.5), false)));
// 9999.5 = 15.5 + 256 × n
assert_eq!(I8F8::overflowing_from_str("-9999.5"), Ok((I8F8::from_num(-15.5), true)));pub fn overflowing_from_str_binary(
src: &str
) -> Result<(FixedI32<Frac>, bool), ParseFixedError>
pub fn overflowing_from_str_binary(
src: &str
) -> Result<(FixedI32<Frac>, bool), ParseFixedError>
Parses a string slice containing binary digits to return a fixed-point number.
Returns a tuple of the fixed-point number and a bool indicating
whether an overflow has occurred. On overflow, the wrapped value is
returned.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
let check = I8F8::from_bits(0b1110001 << (8 - 1));
assert_eq!(I8F8::overflowing_from_str_binary("111000.1"), Ok((check, false)));
assert_eq!(I8F8::overflowing_from_str_binary("-101100111000.1"), Ok((-check, true)));pub fn overflowing_from_str_octal(
src: &str
) -> Result<(FixedI32<Frac>, bool), ParseFixedError>
pub fn overflowing_from_str_octal(
src: &str
) -> Result<(FixedI32<Frac>, bool), ParseFixedError>
Parses a string slice containing octal digits to return a fixed-point number.
Returns a tuple of the fixed-point number and a bool indicating
whether an overflow has occurred. On overflow, the wrapped value is
returned.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
let check = I8F8::from_bits(0o1654 << (8 - 3));
assert_eq!(I8F8::overflowing_from_str_octal("165.4"), Ok((check, false)));
assert_eq!(I8F8::overflowing_from_str_octal("-7165.4"), Ok((-check, true)));Parses a string slice containing hexadecimal digits to return a fixed-point number.
Returns a tuple of the fixed-point number and a bool indicating
whether an overflow has occurred. On overflow, the wrapped value is
returned.
Rounding is to the nearest, with ties rounded to even.
Examples
use fixed::types::I8F8;
let check = I8F8::from_bits(0xFFE);
assert_eq!(I8F8::overflowing_from_str_hex("F.FE"), Ok((check, false)));
assert_eq!(I8F8::overflowing_from_str_hex("-C0F.FE"), Ok((-check, true)));Returns the integer part.
Note that since the numbers are stored in two’s
complement, negative numbers with non-zero fractional parts will be
rounded towards −∞, except in the case where there are no integer
bits, that is FixedI32<U32>, where the return value is always zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
// 0010.0000
let two = Fix::from_num(2);
// 0010.0100
let two_and_quarter = two + two / 8;
assert_eq!(two_and_quarter.int(), two);
// 1101.0000
let three = Fix::from_num(3);
// 1101.1100
assert_eq!((-two_and_quarter).int(), -three);Returns the fractional part.
Note that since the numbers are stored in two’s
complement, the returned fraction will be non-negative for negative
numbers, except in the case where there are no integer bits, that is
FixedI32<U32> where the return value is always equal to
self.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
// 0000.0100
let quarter = Fix::ONE / 4;
// 0010.0100
let two_and_quarter = quarter * 9;
assert_eq!(two_and_quarter.frac(), quarter);
// 0000.1100
let three_quarters = quarter * 3;
// 1101.1100
assert_eq!((-two_and_quarter).frac(), three_quarters);Rounds to the next integer towards 0.
Note that for negative numbers, this is different from truncating/discarding the fractional bits. This is because in two’s-complement representations, the value of all the bits except for the most significant bit is positive; discarding positive bits would round towards −∞ unlike this method which rounds towards zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.1).round_to_zero(), Fix::from_num(2));
assert_eq!(Fix::from_num(2.9).round_to_zero(), Fix::from_num(2));
assert_eq!(Fix::from_num(-2.1).round_to_zero(), Fix::from_num(-2));
assert_eq!(Fix::from_num(-2.9).round_to_zero(), Fix::from_num(-2));Rounds to the next integer towards +∞.
Panics
When debug assertions are enabled, panics if the result does not fit.
When debug assertions are not enabled, the wrapped result can be
returned, but it is not considered a breaking change if in the future
it panics; if wrapping is required use wrapping_ceil instead.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).ceil(), Fix::from_num(3));
assert_eq!(Fix::from_num(-2.5).ceil(), Fix::from_num(-2));Rounds to the next integer towards −∞.
Panics
When debug assertions are enabled, panics if the result does not fit.
When debug assertions are not enabled, the wrapped result can be
returned, but it is not considered a breaking change if in the future
it panics; if wrapping is required use wrapping_floor instead.
Overflow can only occur when there are zero integer bits.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).floor(), Fix::from_num(2));
assert_eq!(Fix::from_num(-2.5).floor(), Fix::from_num(-3));Rounds to the nearest integer, with ties rounded away from zero.
Panics
When debug assertions are enabled, panics if the result does not fit.
When debug assertions are not enabled, the wrapped result can be
returned, but it is not considered a breaking change if in the future
it panics; if wrapping is required use wrapping_round instead.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).round(), Fix::from_num(3));
assert_eq!(Fix::from_num(-2.5).round(), Fix::from_num(-3));Rounds to the nearest integer, with ties rounded to even.
Panics
When debug assertions are enabled, panics if the result does not fit.
When debug assertions are not enabled, the wrapped result can be
returned, but it is not considered a breaking change if in the future
it panics; if wrapping is required use wrapping_round_ties_to_even
instead.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).round_ties_to_even(), Fix::from_num(2));
assert_eq!(Fix::from_num(3.5).round_ties_to_even(), Fix::from_num(4));Checked ceil. Rounds to the next integer towards +∞,
returning None on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).checked_ceil(), Some(Fix::from_num(3)));
assert_eq!(Fix::from_num(-2.5).checked_ceil(), Some(Fix::from_num(-2)));
assert!(Fix::MAX.checked_ceil().is_none());Checked floor. Rounds to the next integer towards −∞.Returns None on overflow.
Overflow can only occur when there are zero integer bits.
Examples
use fixed::{
types::extra::{U4, U32},
FixedI32,
};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).checked_floor(), Some(Fix::from_num(2)));
assert_eq!(Fix::from_num(-2.5).checked_floor(), Some(Fix::from_num(-3)));
type AllFrac = FixedI32<U32>;
assert!(AllFrac::MIN.checked_floor().is_none());Checked round. Rounds to the nearest integer, with ties
rounded away from zero, returning None on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).checked_round(), Some(Fix::from_num(3)));
assert_eq!(Fix::from_num(-2.5).checked_round(), Some(Fix::from_num(-3)));
assert!(Fix::MAX.checked_round().is_none());Checked round. Rounds to the nearest integer, with ties
rounded to even, returning None on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).checked_round_ties_to_even(), Some(Fix::from_num(2)));
assert_eq!(Fix::from_num(3.5).checked_round_ties_to_even(), Some(Fix::from_num(4)));
assert!(Fix::MAX.checked_round_ties_to_even().is_none());Saturating ceil. Rounds to the next integer towards +∞, saturating on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).saturating_ceil(), Fix::from_num(3));
assert_eq!(Fix::from_num(-2.5).saturating_ceil(), Fix::from_num(-2));
assert_eq!(Fix::MAX.saturating_ceil(), Fix::MAX);Saturating floor. Rounds to the next integer towards −∞, saturating on overflow.
Overflow can only occur when there are zero integer bits.
Examples
use fixed::{
types::extra::{U4, U32},
FixedI32,
};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).saturating_floor(), Fix::from_num(2));
assert_eq!(Fix::from_num(-2.5).saturating_floor(), Fix::from_num(-3));
type AllFrac = FixedI32<U32>;
assert_eq!(AllFrac::MIN.saturating_floor(), AllFrac::MIN);Saturating round. Rounds to the nearest integer, with ties rounded away from zero, and saturating on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).saturating_round(), Fix::from_num(3));
assert_eq!(Fix::from_num(-2.5).saturating_round(), Fix::from_num(-3));
assert_eq!(Fix::MAX.saturating_round(), Fix::MAX);Saturating round. Rounds to the nearest integer, with ties rounded to even, and saturating on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).saturating_round_ties_to_even(), Fix::from_num(2));
assert_eq!(Fix::from_num(3.5).saturating_round_ties_to_even(), Fix::from_num(4));
assert_eq!(Fix::MAX.saturating_round_ties_to_even(), Fix::MAX);Wrapping ceil. Rounds to the next integer towards +∞, wrapping on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).wrapping_ceil(), Fix::from_num(3));
assert_eq!(Fix::from_num(-2.5).wrapping_ceil(), Fix::from_num(-2));
assert_eq!(Fix::MAX.wrapping_ceil(), Fix::MIN);Wrapping floor. Rounds to the next integer towards −∞, wrapping on overflow.
Overflow can only occur when there are zero integer bits.
Examples
use fixed::{
types::extra::{U4, U32},
FixedI32,
};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).wrapping_floor(), Fix::from_num(2));
assert_eq!(Fix::from_num(-2.5).wrapping_floor(), Fix::from_num(-3));
type AllFrac = FixedI32<U32>;
assert_eq!(AllFrac::MIN.wrapping_floor(), AllFrac::ZERO);Wrapping round. Rounds to the next integer to the nearest, with ties rounded away from zero, and wrapping on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).wrapping_round(), Fix::from_num(3));
assert_eq!(Fix::from_num(-2.5).wrapping_round(), Fix::from_num(-3));
assert_eq!(Fix::MAX.wrapping_round(), Fix::MIN);Wrapping round. Rounds to the next integer to the nearest, with ties rounded to even, and wrapping on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).wrapping_round_ties_to_even(), Fix::from_num(2));
assert_eq!(Fix::from_num(3.5).wrapping_round_ties_to_even(), Fix::from_num(4));
assert_eq!(Fix::MAX.wrapping_round_ties_to_even(), Fix::MIN);Unwrapped ceil. Rounds to the next integer towards +∞, panicking on overflow.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).unwrapped_ceil(), Fix::from_num(3));
assert_eq!(Fix::from_num(-2.5).unwrapped_ceil(), Fix::from_num(-2));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MAX.unwrapped_ceil();Unwrapped floor. Rounds to the next integer towards −∞, panicking on overflow.
Overflow can only occur when there are zero integer bits.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).unwrapped_floor(), Fix::from_num(2));
assert_eq!(Fix::from_num(-2.5).unwrapped_floor(), Fix::from_num(-3));The following panics because of overflow.
use fixed::{types::extra::U32, FixedI32};
type AllFrac = FixedI32<U32>;
let _overflow = AllFrac::MIN.unwrapped_floor();Unwrapped round. Rounds to the next integer to the nearest, with ties rounded away from zero, and panicking on overflow.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).unwrapped_round(), Fix::from_num(3));
assert_eq!(Fix::from_num(-2.5).unwrapped_round(), Fix::from_num(-3));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MAX.unwrapped_round();Unwrapped round. Rounds to the next integer to the nearest, with ties rounded to even, and panicking on overflow.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).unwrapped_round_ties_to_even(), Fix::from_num(2));
assert_eq!(Fix::from_num(3.5).unwrapped_round_ties_to_even(), Fix::from_num(4));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MAX.unwrapped_round_ties_to_even();Overflowing ceil. Rounds to the next integer towards +∞.
Returns a tuple of the fixed-point number and a bool, indicating
whether an overflow has occurred. On overflow, the wrapped value is
returned.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).overflowing_ceil(), (Fix::from_num(3), false));
assert_eq!(Fix::from_num(-2.5).overflowing_ceil(), (Fix::from_num(-2), false));
assert_eq!(Fix::MAX.overflowing_ceil(), (Fix::MIN, true));Overflowing floor. Rounds to the next integer towards −∞.
Returns a tuple of the fixed-point number and
a bool, indicating whether an overflow has
occurred. On overflow, the wrapped value isreturned. Overflow can only
occur when there are zero integer bits.
Examples
use fixed::{
types::extra::{U4, U32},
FixedI32,
};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).overflowing_floor(), (Fix::from_num(2), false));
assert_eq!(Fix::from_num(-2.5).overflowing_floor(), (Fix::from_num(-3), false));
type AllFrac = FixedI32<U32>;
assert_eq!(AllFrac::MIN.overflowing_floor(), (AllFrac::ZERO, true));Overflowing round. Rounds to the next integer to the nearest, with ties rounded away from zero.
Returns a tuple of the fixed-point number and a bool indicating
whether an overflow has occurred. On overflow, the wrapped value is
returned.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).overflowing_round(), (Fix::from_num(3), false));
assert_eq!(Fix::from_num(-2.5).overflowing_round(), (Fix::from_num(-3), false));
assert_eq!(Fix::MAX.overflowing_round(), (Fix::MIN, true));Overflowing round. Rounds to the next integer to the nearest, with ties rounded to even.
Returns a tuple of the fixed-point number and a bool indicating
whether an overflow has occurred. On overflow, the wrapped value is
returned.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2.5).overflowing_round_ties_to_even(), (Fix::from_num(2), false));
assert_eq!(Fix::from_num(3.5).overflowing_round_ties_to_even(), (Fix::from_num(4), false));
assert_eq!(Fix::MAX.overflowing_round_ties_to_even(), (Fix::MIN, true));Integer base-2 logarithm, rounded down.
Panics
Panics if the fixed-point number is ≤ 0.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(4).int_log2(), 2);
assert_eq!(Fix::from_num(3.9375).int_log2(), 1);
assert_eq!(Fix::from_num(0.25).int_log2(), -2);
assert_eq!(Fix::from_num(0.1875).int_log2(), -3);Integer base-10 logarithm, rounded down.
Panics
Panics if the fixed-point number is ≤ 0.
Examples
use fixed::{
types::extra::{U2, U6},
FixedI32,
};
assert_eq!(FixedI32::<U2>::from_num(10).int_log10(), 1);
assert_eq!(FixedI32::<U2>::from_num(9.75).int_log10(), 0);
assert_eq!(FixedI32::<U6>::from_num(0.109375).int_log10(), -1);
assert_eq!(FixedI32::<U6>::from_num(0.09375).int_log10(), -2);Checked integer base-2 logarithm, rounded down.
Returns the logarithm or None if the fixed-point number is
≤ 0.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::ZERO.checked_int_log2(), None);
assert_eq!(Fix::from_num(4).checked_int_log2(), Some(2));
assert_eq!(Fix::from_num(3.9375).checked_int_log2(), Some(1));
assert_eq!(Fix::from_num(0.25).checked_int_log2(), Some(-2));
assert_eq!(Fix::from_num(0.1875).checked_int_log2(), Some(-3));Checked integer base-10 logarithm, rounded down.
Returns the logarithm or None if the fixed-point number is
≤ 0.
Examples
use fixed::{
types::extra::{U2, U6},
FixedI32,
};
assert_eq!(FixedI32::<U2>::ZERO.checked_int_log10(), None);
assert_eq!(FixedI32::<U2>::from_num(10).checked_int_log10(), Some(1));
assert_eq!(FixedI32::<U2>::from_num(9.75).checked_int_log10(), Some(0));
assert_eq!(FixedI32::<U6>::from_num(0.109375).checked_int_log10(), Some(-1));
assert_eq!(FixedI32::<U6>::from_num(0.09375).checked_int_log10(), Some(-2));Returns a number representing the sign of self.
Panics
When debug assertions are enabled, this method panics
- if the value is positive and the fixed-point number has zero or one integer bits such that it cannot hold the value 1.
- if the value is negative and the fixed-point number has zero integer bits, such that it cannot hold the value −1.
When debug assertions are not enabled, the wrapped value can be returned in those cases, but it is not considered a breaking change if in the future it panics; using this method when 1 and −1 cannot be represented is almost certainly a bug.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(5).signum(), 1);
assert_eq!(Fix::ZERO.signum(), 0);
assert_eq!(Fix::from_num(-5).signum(), -1);Returns the reciprocal (inverse) of the fixed-point number, 1/self.
Panics
Panics if the fixed-point number is zero.
When debug assertions are enabled, this method also panics if the
reciprocal overflows. When debug assertions are not enabled, the
wrapped value can be returned, but it is not considered a breaking
change if in the future it panics; if wrapping is required use
wrapping_recip instead.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(2).recip(), Fix::from_num(0.5));Euclidean division.
Panics
Panics if the divisor is zero.
When debug assertions are enabled, this method also panics if the
division overflows. When debug assertions are not enabled, the wrapped
value can be returned, but it is not considered a breaking change if
in the future it panics; if wrapping is required use
wrapping_div_euclid instead.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).div_euclid(Fix::from_num(2)), Fix::from_num(3));
assert_eq!(Fix::from_num(-7.5).div_euclid(Fix::from_num(2)), Fix::from_num(-4));Euclidean division by an integer.
Panics
Panics if the divisor is zero.
When debug assertions are enabled, this method
also panics if the division overflows. Overflow can only occur when
dividing the minimum value by −1. When debug assertions are not
enabled, the wrapped value can be returned, but it is not considered a
breaking change if in the future it panics; if wrapping is required
use wrapping_div_euclid_int instead.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).div_euclid_int(2), Fix::from_num(3));
assert_eq!(Fix::from_num(-7.5).div_euclid_int(2), Fix::from_num(-4));Multiply and accumulate. Adds (a × b) to self.
For some cases, the product a × b would overflow on its
own, but the final result self + a × b is representable; in these cases
this method saves the correct result without overflow.
The a and b parameters can have a fixed-point type like
self but with a different number of fractional bits.
Panics
When debug assertions are enabled, this method panics if the result
overflows. When debug assertions are not enabled, the wrapped value
can be returned, but it is not considered a breaking change if in the
future it panics; if wrapping is required use wrapping_mul_acc
instead.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let mut acc = Fix::from_num(3);
acc.mul_acc(Fix::from_num(4), Fix::from_num(0.5));
assert_eq!(acc, 5);
// MAX × 1.5 − MAX = MAX / 2, which does not overflow
acc = -Fix::MAX;
acc.mul_acc(Fix::MAX, Fix::from_num(1.5));
assert_eq!(acc, Fix::MAX / 2);Remainder for Euclidean division by an integer.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).rem_euclid_int(2), Fix::from_num(1.5));
assert_eq!(Fix::from_num(-7.5).rem_euclid_int(2), Fix::from_num(0.5));Checked signum. Returns a number representing the
sign of self, or None on overflow.
Overflow can only occur
- if the value is positive and the fixed-point number has zero or one integer bits such that it cannot hold the value 1.
- if the value is negative and the fixed-point number has zero integer bits, such that it cannot hold the value −1.
Examples
use fixed::{
types::extra::{U4, U31, U32},
FixedI32,
};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(5).checked_signum(), Some(Fix::ONE));
assert_eq!(Fix::ZERO.checked_signum(), Some(Fix::ZERO));
assert_eq!(Fix::from_num(-5).checked_signum(), Some(Fix::from_num(-1)));
type OneIntBit = FixedI32<U31>;
type ZeroIntBits = FixedI32<U32>;
assert_eq!(OneIntBit::from_num(0.5).checked_signum(), None);
assert_eq!(ZeroIntBits::from_num(0.25).checked_signum(), None);
assert_eq!(ZeroIntBits::from_num(-0.5).checked_signum(), None);Checked Euclidean division. Returns the quotient, or
None if the divisor is zero or on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).checked_div_euclid(Fix::from_num(2)), Some(Fix::from_num(3)));
assert_eq!(Fix::from_num(7.5).checked_div_euclid(Fix::ZERO), None);
assert_eq!(Fix::MAX.checked_div_euclid(Fix::from_num(0.25)), None);
assert_eq!(Fix::from_num(-7.5).checked_div_euclid(Fix::from_num(2)), Some(Fix::from_num(-4)));Checked multiply and accumulate. Adds (a × b) to self,
or returns None on overflow.
Like all other checked methods, this method wraps the successful return value in
an Option. Since the unchecked mul_acc method does not return a value,
which is equivalent to returning (), this method wraps ()
into Some(()) on success.
When overflow occurs, self is not modified and retains its previous value.
For some cases, the product a × b would overflow on its
own, but the final result self + a × b is representable; in these cases
this method saves the correct result without overflow.
The a and b parameters can have a fixed-point type like
self but with a different number of fractional bits.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let mut acc = Fix::from_num(3);
let check = acc.checked_mul_acc(Fix::from_num(4), Fix::from_num(0.5));
assert_eq!(check, Some(()));
assert_eq!(acc, 5);
acc = Fix::DELTA;
let check = acc.checked_mul_acc(Fix::MAX, Fix::ONE);
assert_eq!(check, None);
// acc is unchanged on error
assert_eq!(acc, Fix::DELTA);
// MAX × 1.5 − MAX = MAX / 2, which does not overflow
acc = -Fix::MAX;
let check = acc.checked_mul_acc(Fix::MAX, Fix::from_num(1.5));
assert_eq!(check, Some(()));
assert_eq!(acc, Fix::MAX / 2);Checked fixed-point remainder for division by an integer.
Returns the remainder, or None if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3.75).checked_rem_int(2), Some(Fix::from_num(1.75)));
assert_eq!(Fix::from_num(3.75).checked_rem_int(0), None);
assert_eq!(Fix::from_num(-3.75).checked_rem_int(2), Some(Fix::from_num(-1.75)));Checked Euclidean division by an integer. Returns the
quotient, or None if the divisor is zero or if the division results in overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).checked_div_euclid_int(2), Some(Fix::from_num(3)));
assert_eq!(Fix::from_num(7.5).checked_div_euclid_int(0), None);
assert_eq!(Fix::MIN.checked_div_euclid_int(-1), None);Checked remainder for Euclidean division by an integer.
Returns the remainder, or None if the divisor is zero or if the remainder results in overflow.
Examples
use fixed::{types::extra::U28, FixedI32};
type Fix = FixedI32<U28>;
assert_eq!(Fix::from_num(7.5).checked_rem_euclid_int(2), Some(Fix::from_num(1.5)));
assert_eq!(Fix::from_num(7.5).checked_rem_euclid_int(0), None);
assert_eq!(Fix::from_num(-7.5).checked_rem_euclid_int(2), Some(Fix::from_num(0.5)));
// −8 ≤ Fix < 8, so the answer 12.5 overflows
assert_eq!(Fix::from_num(-7.5).checked_rem_euclid_int(20), None);Saturating signum. Returns a number representing
the sign of self, saturating on overflow.
Overflow can only occur
- if the value is positive and the fixed-point number has zero or one integer bits such that it cannot hold the value 1.
- if the value is negative and the fixed-point number has zero integer bits, such that it cannot hold the value −1.
Examples
use fixed::{
types::extra::{U4, U31, U32},
FixedI32,
};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(5).saturating_signum(), 1);
assert_eq!(Fix::ZERO.saturating_signum(), 0);
assert_eq!(Fix::from_num(-5).saturating_signum(), -1);
type OneIntBit = FixedI32<U31>;
type ZeroIntBits = FixedI32<U32>;
assert_eq!(OneIntBit::from_num(0.5).saturating_signum(), OneIntBit::MAX);
assert_eq!(ZeroIntBits::from_num(0.25).saturating_signum(), ZeroIntBits::MAX);
assert_eq!(ZeroIntBits::from_num(-0.5).saturating_signum(), ZeroIntBits::MIN);Saturating multiplication. Returns the product, saturating on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).saturating_mul(Fix::from_num(2)), Fix::from_num(6));
assert_eq!(Fix::MAX.saturating_mul(Fix::from_num(2)), Fix::MAX);Saturating division. Returns the quotient, saturating on overflow.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let one_half = Fix::ONE / 2;
assert_eq!(Fix::ONE.saturating_div(Fix::from_num(2)), one_half);
assert_eq!(Fix::MAX.saturating_div(one_half), Fix::MAX);Saturating reciprocal. Returns the reciprocal, saturating on overflow.
Panics
Panics if the fixed-point number is zero.
Examples
use fixed::{types::extra::U31, FixedI32};
// only one integer bit
type Fix = FixedI32<U31>;
assert_eq!(Fix::from_num(0.25).saturating_recip(), Fix::MAX);
assert_eq!(Fix::from_num(-0.25).saturating_recip(), Fix::MIN);Saturating Euclidean division. Returns the quotient, saturating on overflow.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).saturating_div_euclid(Fix::from_num(2)), Fix::from_num(3));
assert_eq!(Fix::MAX.saturating_div_euclid(Fix::from_num(0.25)), Fix::MAX);
assert_eq!(Fix::from_num(-7.5).saturating_div_euclid(Fix::from_num(2)), Fix::from_num(-4));
assert_eq!(Fix::MIN.saturating_div_euclid(Fix::from_num(0.25)), Fix::MIN);Saturating Euclidean division by an integer. Returns the quotient, saturating on overflow.
Overflow can only occur when dividing the minimum value by −1.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).saturating_div_euclid_int(2), Fix::from_num(3));
assert_eq!(Fix::from_num(-7.5).saturating_div_euclid_int(2), Fix::from_num(-4));
assert_eq!(Fix::MIN.saturating_div_euclid_int(-1), Fix::MAX);Saturating multiply and accumulate. Adds (a × b) to self,
saturating on overflow.
For some cases, the product a × b would overflow on its
own, but the final result self + a × b is representable; in these cases
this method saves the correct result without overflow.
The a and b parameters can have a fixed-point type like
self but with a different number of fractional bits.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let mut acc = Fix::from_num(3);
acc.saturating_mul_acc(Fix::from_num(4), Fix::from_num(0.5));
assert_eq!(acc, 5);
acc = Fix::MAX / 2;
acc.saturating_mul_acc(Fix::MAX / 2, Fix::from_num(3));
assert_eq!(acc, Fix::MAX);
// MAX × 1.5 − MAX = MAX / 2, which does not overflow
acc = -Fix::MAX;
acc.saturating_mul_acc(Fix::MAX, Fix::from_num(1.5));
assert_eq!(acc, Fix::MAX / 2);Saturating remainder for Euclidean division by an integer. Returns the remainder, saturating on overflow.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U28, FixedI32};
type Fix = FixedI32<U28>;
assert_eq!(Fix::from_num(7.5).saturating_rem_euclid_int(2), Fix::from_num(1.5));
assert_eq!(Fix::from_num(-7.5).saturating_rem_euclid_int(2), Fix::from_num(0.5));
// −8 ≤ Fix < 8, so the answer 12.5 saturates
assert_eq!(Fix::from_num(-7.5).saturating_rem_euclid_int(20), Fix::MAX);Wrapping signum. Returns a number representing
the sign of self, wrapping on overflow.
Overflow can only occur
- if the value is positive and the fixed-point number has zero or one integer bits such that it cannot hold the value 1.
- if the value is negative and the fixed-point number has zero integer bits, such that it cannot hold the value −1.
Examples
use fixed::{
types::extra::{U4, U31, U32},
FixedI32,
};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(5).wrapping_signum(), 1);
assert_eq!(Fix::ZERO.wrapping_signum(), 0);
assert_eq!(Fix::from_num(-5).wrapping_signum(), -1);
type OneIntBit = FixedI32<U31>;
type ZeroIntBits = FixedI32<U32>;
assert_eq!(OneIntBit::from_num(0.5).wrapping_signum(), -1);
assert_eq!(ZeroIntBits::from_num(0.25).wrapping_signum(), 0);
assert_eq!(ZeroIntBits::from_num(-0.5).wrapping_signum(), 0);Wrapping multiplication. Returns the product, wrapping on overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).wrapping_mul(Fix::from_num(2)), Fix::from_num(6));
let wrapped = Fix::from_bits(!0 << 2);
assert_eq!(Fix::MAX.wrapping_mul(Fix::from_num(4)), wrapped);Wrapping division. Returns the quotient, wrapping on overflow.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let one_point_5 = Fix::from_bits(0b11 << (4 - 1));
assert_eq!(Fix::from_num(3).wrapping_div(Fix::from_num(2)), one_point_5);
let quarter = Fix::ONE / 4;
let wrapped = Fix::from_bits(!0 << 2);
assert_eq!(Fix::MAX.wrapping_div(quarter), wrapped);Wrapping Euclidean division. Returns the quotient, wrapping on overflow.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).wrapping_div_euclid(Fix::from_num(2)), Fix::from_num(3));
let wrapped = Fix::MAX.wrapping_mul_int(4).round_to_zero();
assert_eq!(Fix::MAX.wrapping_div_euclid(Fix::from_num(0.25)), wrapped);Wrapping Euclidean division by an integer. Returns the quotient, wrapping on overflow.
Overflow can only occur when dividing the minimum value by −1.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).wrapping_div_euclid_int(2), Fix::from_num(3));
assert_eq!(Fix::from_num(-7.5).wrapping_div_euclid_int(2), Fix::from_num(-4));
let wrapped = Fix::MIN.round_to_zero();
assert_eq!(Fix::MIN.wrapping_div_euclid_int(-1), wrapped);Wrapping multiply and accumulate. Adds (a × b) to self,
wrapping on overflow.
The a and b parameters can have a fixed-point type like
self but with a different number of fractional bits.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let mut acc = Fix::from_num(3);
acc.wrapping_mul_acc(Fix::from_num(4), Fix::from_num(0.5));
assert_eq!(acc, 5);
acc = Fix::MAX;
acc.wrapping_mul_acc(Fix::MAX, Fix::from_num(3));
assert_eq!(acc, Fix::MAX.wrapping_mul_int(4));Wrapping remainder for Euclidean division by an integer. Returns the remainder, wrapping on overflow.
Note that while remainder for Euclidean division cannot be negative, the wrapped value can be negative.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U28, FixedI32};
type Fix = FixedI32<U28>;
assert_eq!(Fix::from_num(7.5).wrapping_rem_euclid_int(2), Fix::from_num(1.5));
assert_eq!(Fix::from_num(-7.5).wrapping_rem_euclid_int(2), Fix::from_num(0.5));
// −8 ≤ Fix < 8, so the answer 12.5 wraps to −3.5
assert_eq!(Fix::from_num(-7.5).wrapping_rem_euclid_int(20), Fix::from_num(-3.5));Unwrapped signum. Returns a number representing
the sign of self, panicking on overflow.
Overflow can only occur
- if the value is positive and the fixed-point number has zero or one integer bits such that it cannot hold the value 1.
- if the value is negative and the fixed-point number has zero integer bits, such that it cannot hold the value −1.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(5).unwrapped_signum(), 1);
assert_eq!(Fix::ZERO.unwrapped_signum(), 0);
assert_eq!(Fix::from_num(-5).unwrapped_signum(), -1);The following panics because of overflow.
use fixed::{types::extra::U31, FixedI32};
type OneIntBit = FixedI32<U31>;
let _overflow = OneIntBit::from_num(0.5).unwrapped_signum();Unwrapped multiplication. Returns the product, panicking on overflow.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).unwrapped_mul(Fix::from_num(2)), Fix::from_num(6));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MAX.unwrapped_mul(Fix::from_num(4));Unwrapped division. Returns the quotient, panicking on overflow.
Panics
Panics if the divisor is zero or if the division results in overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let one_point_5 = Fix::from_bits(0b11 << (4 - 1));
assert_eq!(Fix::from_num(3).unwrapped_div(Fix::from_num(2)), one_point_5);The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let quarter = Fix::ONE / 4;
let _overflow = Fix::MAX.unwrapped_div(quarter);Unwrapped Euclidean division. Returns the quotient, panicking on overflow.
Panics
Panics if the divisor is zero or if the division results in overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).unwrapped_div_euclid(Fix::from_num(2)), Fix::from_num(3));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MAX.unwrapped_div_euclid(Fix::from_num(0.25));Unwrapped multiply and accumulate. Adds (a × b) to self,
panicking on overflow.
For some cases, the product a × b would overflow on its
own, but the final result self + a × b is representable; in these cases
this method saves the correct result without overflow.
The a and b parameters can have a fixed-point type like
self but with a different number of fractional bits.
Panics
Panics if the result does not fit.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let mut acc = Fix::from_num(3);
acc.unwrapped_mul_acc(Fix::from_num(4), Fix::from_num(0.5));
assert_eq!(acc, 5);
// MAX × 1.5 − MAX = MAX / 2, which does not overflow
acc = -Fix::MAX;
acc.unwrapped_mul_acc(Fix::MAX, Fix::from_num(1.5));
assert_eq!(acc, Fix::MAX / 2);The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let mut acc = Fix::DELTA;
acc.unwrapped_mul_acc(Fix::MAX, Fix::ONE);Unwrapped fixed-point remainder for division by an integer. Returns the remainder, panicking if the divisor is zero.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3.75).unwrapped_rem_int(2), Fix::from_num(1.75));The following panics because the divisor is zero.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _divisor_is_zero = Fix::from_num(3.75).unwrapped_rem_int(0);Unwrapped Euclidean division by an integer. Returns the quotient, panicking on overflow.
Overflow can only occur when dividing the minimum value by −1.
Panics
Panics if the divisor is zero or if the division results in overflow.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).unwrapped_div_euclid_int(2), Fix::from_num(3));
assert_eq!(Fix::from_num(-7.5).unwrapped_div_euclid_int(2), Fix::from_num(-4));The following panics because of overflow.
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let _overflow = Fix::MIN.unwrapped_div_euclid_int(-1);Unwrapped remainder for Euclidean division by an integer. Returns the remainder, panicking on overflow.
Note that while remainder for Euclidean division cannot be negative, the wrapped value can be negative.
Panics
Panics if the divisor is zero or if the division results in overflow.
Examples
use fixed::{types::extra::U28, FixedI32};
type Fix = FixedI32<U28>;
assert_eq!(Fix::from_num(7.5).unwrapped_rem_euclid_int(2), Fix::from_num(1.5));
assert_eq!(Fix::from_num(-7.5).unwrapped_rem_euclid_int(2), Fix::from_num(0.5));The following panics because of overflow.
use fixed::{types::extra::U28, FixedI32};
type Fix = FixedI32<U28>;
// −8 ≤ Fix < 8, so the answer 12.5 overflows
let _overflow = Fix::from_num(-7.5).unwrapped_rem_euclid_int(20);Overflowing signum.
Returns a tuple of the signum and a bool indicating whether an
overflow has occurred. On overflow, the wrapped value is returned.
Overflow can only occur
- if the value is positive and the fixed-point number has zero or one integer bits such that it cannot hold the value 1.
- if the value is negative and the fixed-point number has zero integer bits, such that it cannot hold the value −1.
Examples
use fixed::{
types::extra::{U4, U31, U32},
FixedI32,
};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(5).overflowing_signum(), (Fix::ONE, false));
assert_eq!(Fix::ZERO.overflowing_signum(), (Fix::ZERO, false));
assert_eq!(Fix::from_num(-5).overflowing_signum(), (Fix::from_num(-1), false));
type OneIntBit = FixedI32<U31>;
type ZeroIntBits = FixedI32<U32>;
assert_eq!(OneIntBit::from_num(0.5).overflowing_signum(), (OneIntBit::from_num(-1), true));
assert_eq!(ZeroIntBits::from_num(0.25).overflowing_signum(), (ZeroIntBits::ZERO, true));
assert_eq!(ZeroIntBits::from_num(-0.5).overflowing_signum(), (ZeroIntBits::ZERO, true));Overflowing multiplication.
Returns a tuple of the product and a bool indicating whether an
overflow has occurred. On overflow, the wrapped value is returned.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(3).overflowing_mul(Fix::from_num(2)), (Fix::from_num(6), false));
let wrapped = Fix::from_bits(!0 << 2);
assert_eq!(Fix::MAX.overflowing_mul(Fix::from_num(4)), (wrapped, true));Overflowing division.
Returns a tuple of the quotient and a bool indicating whether an
overflow has occurred. On overflow, the wrapped value is returned.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let one_point_5 = Fix::from_bits(0b11 << (4 - 1));
assert_eq!(Fix::from_num(3).overflowing_div(Fix::from_num(2)), (one_point_5, false));
let quarter = Fix::ONE / 4;
let wrapped = Fix::from_bits(!0 << 2);
assert_eq!(Fix::MAX.overflowing_div(quarter), (wrapped, true));Overflowing reciprocal.
Returns a tuple of the reciprocal and a bool indicating whether
an overflow has occurred. On overflow, the wrapped value is returned.
Panics
Panics if the fixed-point number is zero.
Examples
use fixed::{
types::extra::{U4, U31},
FixedI32,
};
type Fix = FixedI32<U4>;
// only one integer bit
type Small = FixedI32<U31>;
assert_eq!(Fix::from_num(0.25).overflowing_recip(), (Fix::from_num(4), false));
assert_eq!(Small::from_num(0.25).overflowing_recip(), (Small::ZERO, true));Overflowing Euclidean division.
Returns a tuple of the quotient and a bool indicating whether an
overflow has occurred. On overflow, the wrapped value is returned.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let check = Fix::from_num(3);
assert_eq!(Fix::from_num(7.5).overflowing_div_euclid(Fix::from_num(2)), (check, false));
let wrapped = Fix::MAX.wrapping_mul_int(4).round_to_zero();
assert_eq!(Fix::MAX.overflowing_div_euclid(Fix::from_num(0.25)), (wrapped, true));Overflowing Euclidean division by an integer.
Returns a tuple of the quotient and a bool indicating whether an overflow has
occurred. On overflow, the wrapped value is returned. Overflow can
only occur when dividing the minimum value by −1.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::from_num(7.5).overflowing_div_euclid_int(2), (Fix::from_num(3), false));
assert_eq!(Fix::from_num(-7.5).overflowing_div_euclid_int(2), (Fix::from_num(-4), false));
let wrapped = Fix::MIN.round_to_zero();
assert_eq!(Fix::MIN.overflowing_div_euclid_int(-1), (wrapped, true));Overflowing multiply and accumulate. Adds (a × b) to self,
wrapping and returning true if overflow occurs.
For some cases, the product a × b would overflow on its
own, but the final result self + a × b is representable; in these cases
this method saves the correct result without overflow.
The a and b parameters can have a fixed-point type like
self but with a different number of fractional bits.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
let mut acc = Fix::from_num(3);
assert!(!acc.overflowing_mul_acc(Fix::from_num(4), Fix::from_num(0.5)));
assert_eq!(acc, 5);
acc = Fix::MAX;
assert!(acc.overflowing_mul_acc(Fix::MAX, Fix::from_num(3)));
assert_eq!(acc, Fix::MAX.wrapping_mul_int(4));
// MAX × 1.5 − MAX = MAX / 2, which does not overflow
acc = -Fix::MAX;
assert!(!acc.overflowing_mul_acc(Fix::MAX, Fix::from_num(1.5)));
assert_eq!(acc, Fix::MAX / 2);Remainder for Euclidean division by an integer.
Returns a tuple of the remainder and a bool indicating whether an overflow has
occurred. On overflow, the wrapped value is returned.
Note that while remainder for Euclidean division cannot be negative, the wrapped value can be negative.
Panics
Panics if the divisor is zero.
Examples
use fixed::{types::extra::U28, FixedI32};
type Fix = FixedI32<U28>;
assert_eq!(Fix::from_num(7.5).overflowing_rem_euclid_int(2), (Fix::from_num(1.5), false));
assert_eq!(Fix::from_num(-7.5).overflowing_rem_euclid_int(2), (Fix::from_num(0.5), false));
// −8 ≤ Fix < 8, so the answer 12.5 wraps to −3.5
assert_eq!(Fix::from_num(-7.5).overflowing_rem_euclid_int(20), (Fix::from_num(-3.5), true));This block contains constants in the range 0 < x < 0.5.
Examples
use fixed::{consts, types::extra::U32, FixedI32};
type Fix = FixedI32<U32>;
assert_eq!(Fix::LOG10_2, Fix::from_num(consts::LOG10_2));1/τ = 0.159154…
2/τ = 0.318309…
This block contains constants in the range 0.5 ≤ x < 1.
These constants are not representable in signed fixed-point numbers with less than 1 integer bit.
Examples
use fixed::{consts, types::extra::U31, FixedI32};
type Fix = FixedI32<U31>;
assert_eq!(Fix::LN_2, Fix::from_num(consts::LN_2));
assert!(0.5 <= Fix::LN_2 && Fix::LN_2 < 1);The following example fails to compile, since the maximum representable value with 32 fractional bits and 0 integer bits is < 0.5.
use fixed::{consts, types::extra::U32, FixedI32};
type Fix = FixedI32<U32>;
let _ = Fix::LN_2;τ/8 = 0.785398…
τ/12 = 0.523598…
4/τ = 0.636619…
1/√π = 0.564189…
1/√2 = 0.707106…
1/√3 = 0.577350…
The golden ratio conjugate, Φ = 1/φ = 0.618033…
This block contains constants in the range 1 ≤ x < 2.
These constants are not representable in signed fixed-point numbers with less than 2 integer bits.
Examples
use fixed::{consts, types::extra::U30, FixedI32};
type Fix = FixedI32<U30>;
assert_eq!(Fix::LOG2_E, Fix::from_num(consts::LOG2_E));
assert!(1 <= Fix::LOG2_E && Fix::LOG2_E < 2);The following example fails to compile, since the maximum representable value with 31 fractional bits and 1 integer bit is < 1.
use fixed::{consts, types::extra::U31, FixedI32};
type Fix = FixedI32<U31>;
let _ = Fix::LOG2_E;One.
Examples
use fixed::{types::extra::U4, FixedI32};
type Fix = FixedI32<U4>;
assert_eq!(Fix::ONE, Fix::from_num(1));τ/4 = 1.57079…
τ/6 = 1.04719…
2/√π = 1.12837…
This block contains constants in the range 2 ≤ x < 4.
These constants are not representable in signed fixed-point numbers with less than 3 integer bits.
Examples
use fixed::{consts, types::extra::U29, FixedI32};
type Fix = FixedI32<U29>;
assert_eq!(Fix::E, Fix::from_num(consts::E));
assert!(2 <= Fix::E && Fix::E < 4);The following example fails to compile, since the maximum representable value with 30 fractional bits and 2 integer bits is < 2.
use fixed::{consts, types::extra::U30, FixedI32};
type Fix = FixedI32<U30>;
let _ = Fix::E;τ/2 = 3.14159…
τ/3 = 2.09439…
This block contains constants in the range 4 ≤ x < 8.
These constants are not representable in signed fixed-point numbers with less than 4 integer bits.
Examples
use fixed::{consts, types::extra::U28, FixedI32};
type Fix = FixedI32<U28>;
assert_eq!(Fix::TAU, Fix::from_num(consts::TAU));
assert!(4 <= Fix::TAU && Fix::TAU < 8);The following example fails to compile, since the maximum representable value with 29 fractional bits and 3 integer bits is < 4.
use fixed::{consts, types::extra::U29, FixedI32};
type Fix = FixedI32<U29>;
let _ = Fix::TAU;Trait Implementations
Performs the += operation. Read more
Performs the += operation. Read more
Performs the &= operation. Read more
Performs the &= operation. Read more
Performs the |= operation. Read more
Performs the |= operation. Read more
Performs the ^= operation. Read more
Performs the ^= operation. Read more
Adds two numbers, checking for overflow. If overflow happens, None is
returned. Read more
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Divides two numbers, checking for underflow, overflow and division by
zero. If any of that happens, None is returned. Read more
Multiplies two numbers, checking for underflow or overflow. If underflow
or overflow happens, None is returned. Read more
Negates a number, returning None for results that can’t be represented, like signed MIN
values that can’t be positive, or non-zero unsigned values that can’t be negative. Read more
Finds the remainder of dividing two numbers, checking for underflow, overflow and division
by zero. If any of that happens, None is returned. Read more
Checked shift left. Computes self << rhs, returning None
if rhs is larger than or equal to the number of bits in self. Read more
Checked shift right. Computes self >> rhs, returning None
if rhs is larger than or equal to the number of bits in self. Read more
Subtracts two numbers, checking for underflow. If underflow happens,
None is returned. Read more
Deserialize this value from the given Serde deserializer. Read more
Performs the /= operation. Read more
Performs the /= operation. Read more
Performs the /= operation. Read more
Performs the /= operation. Read more
type NonZeroBits = NonZeroI32
type NonZeroBits = NonZeroI32
type Frac = Frac
type Frac = Frac
The number of fractional bits as a compile-time Unsigned as provided
by the typenum crate. Read more
An unsigned fixed-point number type with the same number of integer and
fractional bits as Self. Read more
An unsigned fixed-point number type with the same number of integer and
fractional bits as Self. Read more
The number of fractional bits. Read more
Creates a fixed-point number that has a bitwise representation identical to the given integer. Read more
Creates an integer that has a bitwise representation identical to the given fixed-point number. Read more
Converts a fixed-point number from big endian to the target’s endianness. Read more
Converts a fixed-point number from little endian to the target’s endianness. Read more
Converts this fixed-point number to big endian from the target’s endianness. Read more
Converts this fixed-point number to little endian from the target’s endianness. Read more
Reverses the byte order of the fixed-point number. Read more
Creates a fixed-point number from its representation as a byte array in big endian. Read more
Creates a fixed-point number from its representation as a byte array in little endian. Read more
Creates a fixed-point number from its representation as a byte array in native endian. Read more
Returns the memory representation of this fixed-point number as a byte array in big-endian byte order. Read more
Returns the memory representation of this fixed-point number as a byte array in little-endian byte order. Read more
Returns the memory representation of this fixed-point number as a byte array in native byte order. Read more
Creates a fixed-point number from another number. Read more
Converts a fixed-point number to another number. Read more
Creates a fixed-point number from another number, saturating the value if it does not fit. Read more
Converts a fixed-point number to another number, saturating the value if it does not fit. Read more
Creates a fixed-point number from another number, wrapping the value on overflow. Read more
Converts a fixed-point number to another number, wrapping the value on overflow. Read more
Creates a fixed-point number from another number, panicking on overflow. Read more
Converts a fixed-point number to another number, panicking on overflow. Read more
Creates a fixed-point number from another number. Read more
Converts a fixed-point number to another number. Read more
Parses a string slice containing binary digits to return a fixed-point number. Read more
Parses a string slice containing octal digits to return a fixed-point number. Read more
Parses a string slice containing hexadecimal digits to return a fixed-point number. Read more
Parses a string slice containing decimal digits to return a fixed-point number, saturating on overflow. Read more
Parses a string slice containing binary digits to return a fixed-point number, saturating on overflow. Read more
Parses a string slice containing octal digits to return a fixed-point number, saturating on overflow. Read more
Parses a string slice containing hexadecimal digits to return a fixed-point number, saturating on overflow. Read more
Parses a string slice containing decimal digits to return a fixed-point number, wrapping on overflow. Read more
Parses a string slice containing binary digits to return a fixed-point number, wrapping on overflow. Read more
Parses a string slice containing octal digits to return a fixed-point number, wrapping on overflow. Read more
Parses a string slice containing hexadecimal digits to return a fixed-point number, wrapping on overflow. Read more
Parses a string slice containing decimal digits to return a fixed-point number. Read more
Parses a string slice containing binary digits to return a fixed-point number. Read more
Parses a string slice containing octal digits to return a fixed-point number. Read more
Parses a string slice containing hexadecimal digits to return a fixed-point number. Read more
Rounds to the next integer towards 0. Read more
Rounds to the nearest integer, with ties rounded away from zero. Read more
Rounds to the nearest integer, with ties rounded to even. Read more
Saturating ceil. Rounds to the next integer towards +∞, saturating on overflow. Read more
Saturating floor. Rounds to the next integer towards −∞, saturating on overflow. Read more
Saturating round. Rounds to the nearest integer, with ties rounded away from zero, and saturating on overflow. Read more
Saturating round. Rounds to the nearest integer, with ties rounded to_even, and saturating on overflow. Read more
Wrapping ceil. Rounds to the next integer towards +∞, wrapping on overflow. Read more
Wrapping floor. Rounds to the next integer towards −∞, wrapping on overflow. Read more
Wrapping round. Rounds to the next integer to the nearest, with ties rounded away from zero, and wrapping on overflow. Read more
Wrapping round. Rounds to the next integer to the nearest, with ties rounded to even, and wrapping on overflow. Read more
Unwrapped ceil. Rounds to the next integer towards +∞, panicking on overflow. Read more
Unwrapped floor. Rounds to the next integer towards −∞, panicking on overflow. Read more
Unwrapped round. Rounds to the next integer to the nearest, with ties rounded away from zero, and panicking on overflow. Read more
Unwrapped round. Rounds to the next integer to the nearest, with ties rounded to even, and panicking on overflow. Read more
Overflowing ceil. Rounds to the next integer towards +∞. Read more
Overflowing floor. Rounds to the next integer towards −∞. Read more
Overflowing round. Rounds to the next integer to the nearest, with ties rounded away from zero. Read more
Overflowing round. Rounds to the next integer to the nearest, with ties rounded to even. Read more
Returns the number of ones in the binary representation. Read more
Returns the number of zeros in the binary representation. Read more
Returns the number of leading ones in the binary representation. Read more
Returns the number of leading zeros in the binary representation. Read more
Returns the number of trailing ones in the binary representation. Read more
Returns the number of trailing zeros in the binary representation. Read more
Reverses the order of the bits of the fixed-point number. Read more
Shifts to the left by n bits, wrapping the truncated bits to the right end. Read more
Shifts to the right by n bits, wrapping the truncated bits to the left end. Read more
Multiply and add. Returns self × mul + add. Read more
Multiply and accumulate. Adds (a × b) to self. Read more
Euclidean division by an integer. Read more
Remainder for Euclidean division. Read more
Euclidean division by an integer. Read more
Remainder for Euclidean division by an integer. Read more
Saturated negation. Returns the negated value, saturating on overflow. Read more
Saturating addition. Returns the sum, saturating on overflow. Read more
Saturating subtraction. Returns the difference, saturating on overflow. Read more
Saturating multiplication. Returns the product, saturating on overflow. Read more
Saturating division. Returns the quotient, saturating on overflow. Read more
Saturating reciprocal. Read more
Saturating multiply and add. Returns self × mul + add, saturating on overflow. Read more
Saturating multiply and add. Adds (a × b) to self, saturating on overflow. Read more
Saturating Euclidean division. Returns the quotient, saturating on overflow. Read more
Saturating multiplication by an integer. Returns the product, saturating on overflow. Read more
Saturating Euclidean division by an integer. Returns the quotient, saturating on overflow. Read more
Saturating remainder for Euclidean division by an integer. Returns the remainder, saturating on overflow. Read more
Saturating distance. Returns the distance from self to other,
saturating on overflow. Read more
Wrapping negation. Returns the negated value, wrapping on overflow. Read more
Wrapping addition. Returns the sum, wrapping on overflow. Read more
Wrapping subtraction. Returns the difference, wrapping on overflow. Read more
Wrapping multiplication. Returns the product, wrapping on overflow. Read more
Wrapping division. Returns the quotient, wrapping on overflow. Read more
Wrapping reciprocal. Read more
Wrapping multiply and add. Returns self × mul + add, wrapping on overflow. Read more
Wrapping multiply and accumulate. Adds (a × b) to self, wrapping on overflow. Read more
Wrapping Euclidean division. Returns the quotient, wrapping on overflow. Read more
Wrapping multiplication by an integer. Returns the product, wrapping on overflow. Read more
Wrapping division by an integer. Returns the quotient, wrapping on overflow. Read more
Wrapping Euclidean division by an integer. Returns the quotient, wrapping on overflow. Read more
Wrapping remainder for Euclidean division by an integer. Returns the remainder, wrapping on overflow. Read more
Wrapping shift left. Wraps rhs if rhs ≥ the number of
bits, then shifts and returns the number. Read more
Wrapping shift right. Wraps rhs if rhs ≥ the number of
bits, then shifts and returns the number. Read more
Wrapping distance. Returns the distance from self to other, wrapping
on overflow. Read more
Unwrapped negation. Returns the negated value, panicking on overflow. Read more
Unwrapped addition. Returns the sum, panicking on overflow. Read more
Unwrapped subtraction. Returns the difference, panicking on overflow. Read more
Unwrapped multiplication. Returns the product, panicking on overflow. Read more
Unwrapped division. Returns the quotient, panicking on overflow. Read more
Unwrapped remainder. Returns the quotient, panicking if the divisor is zero. Read more
Unwrapped reciprocal. Returns reciprocal, panicking on overflow. Read more
Unwrapped multiply and add. Returns self × mul + add, panicking on overflow. Read more
Unwrapped multiply and accumulate. Adds (a × b) to self, panicking on overflow. Read more
Unwrapped Euclidean division. Returns the quotient, panicking on overflow. Read more
Unwrapped remainder for Euclidean division. Returns the remainder, panicking if the divisor is zero. Read more
Unwrapped multiplication by an integer. Returns the product, panicking on overflow. Read more
Unwrapped division by an integer. Returns the quotient, panicking on overflow. Read more
Unwrapped remainder for division by an integer. Returns the remainder, panicking if the divisor is zero. Read more
Unwrapped Euclidean division by an integer. Returns the quotient, panicking on overflow. Read more
Unwrapped remainder for Euclidean division by an integer. Returns the remainder, panicking on overflow. Read more
Unwrapped shift left. Panics if rhs ≥ the number of bits. Read more
Unwrapped shift right. Panics if rhs ≥ the number of bits. Read more
Unwrapped distance. Returns the distance from self to other,
panicking on overflow. Read more
Overflowing multiply and add. Read more
Overflowing Euclidean division. Read more
Overflowing multiplication by an integer. Read more
Overflowing division by an integer. Read more
Overflowing Euclidean division by an integer. Read more
Overflowing remainder for Euclidean division by an integer. Read more
Returns a reference to self as FixedSigned if the type is signed,
or None if it is unsigned. Read more
Returns a reference to self as FixedUnsigned if the type is
unsigned, or None if it is signed. Read more
Returns a mutable reference to self as FixedSigned if the type is
signed, or None if it is unsigned. Read more
Returns a mutable reference to self as FixedUnsigned if the type
is unsigned, or None if it is signed. Read more
Returns the number of bits required to represent the value. Read more
Returns the absolute value using an unsigned type without any wrapping or panicking. Read more
Returns the distance from self to other using an unsigned type
without any wrapping or panicking. Read more
Saturating absolute value. Returns the absolute value, saturating on overflow. Read more
Saturating signum. Returns a number representing the sign of
self, saturating on overflow. Read more
Wrapping absolute value. Returns the absolute value, wrapping on overflow. Read more
Wrapping signum. Returns a number representing the sign of
self, wrapping on overflow. Read more
Unwrapped absolute value. Returns the absolute value, panicking on overflow. Read more
Unwrapped signum. Returns a number representing the sign of
self, panicking on overflow. Read more
Return 1.0 / sqrt(2.0).
Return 2.0 / sqrt(π).
Converts a fixed-point number.
Any extra fractional bits are discarded, which rounds towards −∞.
Panics
When debug assertions are enabled, panics if the value
does not fit. When debug assertions are not enabled,
the wrapped value can be returned, but it is not
considered a breaking change if in the future it
panics; if wrapping is required use
wrapping_from_fixed instead.
Converts a fixed-point number if it fits, otherwise returns None.
Any extra fractional bits are discarded, which rounds towards −∞.
Converts a fixed-point number, saturating if it does not fit.
Any extra fractional bits are discarded, which rounds towards −∞.
Converts a fixed-point number, wrapping if it does not fit.
Any extra fractional bits are discarded, which rounds towards −∞.
Converts a fixed-point number, panicking if it does not fit.
Any extra fractional bits are discarded, which rounds towards −∞.
Panics
Panics if the value does not fit, even when debug assertions are not enabled.
Converts an i64 to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts an u64 to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts an isize to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts an i8 to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts an i16 to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts an i32 to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts an i128 to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts a usize to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts an u8 to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts an u16 to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts an u32 to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts an u128 to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
Converts a f32 to return an optional value of this type. If the
value cannot be represented by this type, then None is returned. Read more
impl<FracSrc: LeEqU128, FracDst: LeEqU32> LosslessTryFrom<FixedI128<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU128, FracDst: LeEqU32> LosslessTryFrom<FixedI128<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU16, FracDst: LeEqU32> LosslessTryFrom<FixedI16<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU16, FracDst: LeEqU32> LosslessTryFrom<FixedI16<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
Converts a fixed-point number to a floating-point number.
This conversion actually never fails (infallible) but does not lose any precision (lossless).
Converts a fixed-point number to a floating-point number.
This conversion actually never fails (infallible) but does not lose any precision (lossless).
impl<FracSrc: LeEqU32, FracDst: LeEqU8> LosslessTryFrom<FixedI32<FracSrc>> for FixedI8<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU32, FracDst: LeEqU8> LosslessTryFrom<FixedI32<FracSrc>> for FixedI8<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU32, FracDst: LeEqU16> LosslessTryFrom<FixedI32<FracSrc>> for FixedI16<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU32, FracDst: LeEqU16> LosslessTryFrom<FixedI32<FracSrc>> for FixedI16<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU32, FracDst: LeEqU32> LosslessTryFrom<FixedI32<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU32, FracDst: LeEqU32> LosslessTryFrom<FixedI32<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU32, FracDst: LeEqU64> LosslessTryFrom<FixedI32<FracSrc>> for FixedI64<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU32, FracDst: LeEqU64> LosslessTryFrom<FixedI32<FracSrc>> for FixedI64<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU32, FracDst: LeEqU128> LosslessTryFrom<FixedI32<FracSrc>> for FixedI128<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU32, FracDst: LeEqU128> LosslessTryFrom<FixedI32<FracSrc>> for FixedI128<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU32, FracDst: LeEqU8> LosslessTryFrom<FixedI32<FracSrc>> for FixedU8<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU32, FracDst: LeEqU8> LosslessTryFrom<FixedI32<FracSrc>> for FixedU8<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU32, FracDst: LeEqU16> LosslessTryFrom<FixedI32<FracSrc>> for FixedU16<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU32, FracDst: LeEqU16> LosslessTryFrom<FixedI32<FracSrc>> for FixedU16<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU32, FracDst: LeEqU32> LosslessTryFrom<FixedI32<FracSrc>> for FixedU32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU32, FracDst: LeEqU32> LosslessTryFrom<FixedI32<FracSrc>> for FixedU32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU32, FracDst: LeEqU64> LosslessTryFrom<FixedI32<FracSrc>> for FixedU64<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU32, FracDst: LeEqU64> LosslessTryFrom<FixedI32<FracSrc>> for FixedU64<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU32, FracDst: LeEqU128> LosslessTryFrom<FixedI32<FracSrc>> for FixedU128<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU32, FracDst: LeEqU128> LosslessTryFrom<FixedI32<FracSrc>> for FixedU128<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-point number to an integer.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
impl<FracSrc: LeEqU64, FracDst: LeEqU32> LosslessTryFrom<FixedI64<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU64, FracDst: LeEqU32> LosslessTryFrom<FixedI64<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU8, FracDst: LeEqU32> LosslessTryFrom<FixedI8<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU8, FracDst: LeEqU32> LosslessTryFrom<FixedI8<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU128, FracDst: LeEqU32> LosslessTryFrom<FixedU128<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU128, FracDst: LeEqU32> LosslessTryFrom<FixedU128<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU16, FracDst: LeEqU32> LosslessTryFrom<FixedU16<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU16, FracDst: LeEqU32> LosslessTryFrom<FixedU16<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU32, FracDst: LeEqU32> LosslessTryFrom<FixedU32<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU32, FracDst: LeEqU32> LosslessTryFrom<FixedU32<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU64, FracDst: LeEqU32> LosslessTryFrom<FixedU64<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU64, FracDst: LeEqU32> LosslessTryFrom<FixedU64<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
impl<FracSrc: LeEqU8, FracDst: LeEqU32> LosslessTryFrom<FixedU8<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
impl<FracSrc: LeEqU8, FracDst: LeEqU32> LosslessTryFrom<FixedU8<FracSrc>> for FixedI32<FracDst> where
FracSrc: IsLessOrEqual<FracDst, Output = True>,
Converts a fixed-pint number.
This conversion may fail (fallible) but does not lose precision (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
impl<Frac: LeEqU32> LosslessTryFrom<f16> for FixedI32<Frac> where
U24: IsLessOrEqual<Frac, Output = True>,
impl<Frac: LeEqU32> LosslessTryFrom<f16> for FixedI32<Frac> where
U24: IsLessOrEqual<Frac, Output = True>,
Converts a floating-point number to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts an integer to a fixed-point number.
This conversion may fail (fallible) but cannot lose any fractional bits (lossless).
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-point number to a floating-point number.
This conversion never fails (infallible) but may lose precision (lossy). Rounding is to the nearest, with ties rounded to even.
Converts a fixed-point number to a floating-point number.
This conversion never fails (infallible) but may lose precision (lossy). Rounding is to the nearest, with ties rounded to even.
Converts a fixed-point number to a floating-point number.
This conversion never fails (infallible) but may lose precision (lossy). Rounding is to the nearest, with ties rounded to even.
Converts a fixed-point number to a floating-point number.
This conversion never fails (infallible) but may lose precision (lossy). Rounding is to the nearest, with ties rounded to even.
Converts a fixed-point number to a floating-point number.
This conversion never fails (infallible) but may lose precision (lossy). Rounding is to the nearest, with ties rounded to even.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-point number to an integer.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-point number to an integer.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source are discarded, which rounds towards −∞.
Converts a fixed-point number to an integer.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source are discarded, which rounds towards −∞.
Converts a fixed-point number to an integer.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source are discarded, which rounds towards −∞.
Converts a fixed-point number to an integer.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source are discarded, which rounds towards −∞.
Converts a fixed-point number to an integer.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a fixed-pint number.
This conversion never fails (infallible) but may lose precision (lossy). Any fractional bits in the source that cannot be represented in the destination are discarded, which rounds towards −∞.
Converts a bool to a fixed-point number.
This conversion never fails (infallible) and cannot lose any fractional bits, so it is actually lossless.
Converts an integer to a fixed-point number.
This conversion never fails (infallible) and cannot lose any fractional bits, so it is actually lossless.
Converts an integer to a fixed-point number.
This conversion never fails (infallible) and actually does not lose any precision (lossless).
Converts an integer to a fixed-point number.
This conversion never fails (infallible) and cannot lose any fractional bits, so it is actually lossless.
Converts an integer to a fixed-point number.
This conversion never fails (infallible) and cannot lose any fractional bits, so it is actually lossless.
Converts an integer to a fixed-point number.
This conversion never fails (infallible) and cannot lose any fractional bits, so it is actually lossless.
Performs the fused multiply-add operation.
Performs the *= operation. Read more
Performs the *= operation. Read more
Performs the *= operation. Read more
Performs the *= operation. Read more
Convert from a string and radix (typically 2..=36). Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
This method returns an ordering between self and other values if one exists. Read more
This method tests less than (for self and other) and is used by the < operator. Read more
This method tests less than or equal to (for self and other) and is used by the <=
operator. Read more
This method tests greater than (for self and other) and is used by the > operator. Read more
Performs the %= operation. Read more
Performs the %= operation. Read more
Performs the %= operation. Read more
Performs the %= operation. Read more
Performs the %= operation. Read more
Performs the %= operation. Read more
Saturating addition. Computes self + other, saturating at the relevant high or low boundary of
the type. Read more
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Saturating multiplication. Computes self * other, saturating at the relevant high or low boundary of
the type. Read more
Saturating subtraction. Computes self - other, saturating at the relevant high or low boundary of
the type. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the <<= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Performs the >>= operation. Read more
Returns true if the number is positive and false if the number is zero or negative.
Returns true if the number is negative and false if the number is zero or positive.
Performs the -= operation. Read more
Performs the -= operation. Read more
Converts a fixed-point number.
Any extra fractional bits are discarded, which rounds towards −∞.
Panics
When debug assertions are enabled, panics if the value
does not fit. When debug assertions are not enabled,
the wrapped value can be returned, but it is not
considered a breaking change if in the future it
panics; if wrapping is required use
wrapping_to_fixed instead.
Converts a fixed-point number if it fits, otherwise returns None.
Any extra fractional bits are discarded, which rounds towards −∞.
Converts a fixed-point number, saturating if it does not fit.
Any extra fractional bits are discarded, which rounds towards −∞.
Converts a fixed-point number, wrapping if it does not fit.
Any extra fractional bits are discarded, which rounds towards −∞.
Converts a fixed-point number, panicking if it does not fit.
Any extra fractional bits are discarded, which rounds towards −∞.
Panics
Panics if the value does not fit, even when debug assertions are not enabled.
Converts the value of self to an i64. If the value cannot be
represented by an i64, then None is returned. Read more
Converts the value of self to a u64. If the value cannot be
represented by a u64, then None is returned. Read more
Converts the value of self to an isize. If the value cannot be
represented by an isize, then None is returned. Read more
Converts the value of self to an i8. If the value cannot be
represented by an i8, then None is returned. Read more
Converts the value of self to an i16. If the value cannot be
represented by an i16, then None is returned. Read more
Converts the value of self to an i32. If the value cannot be
represented by an i32, then None is returned. Read more
Converts the value of self to an i128. If the value cannot be
represented by an i128 (i64 under the default implementation), then
None is returned. Read more
Converts the value of self to a usize. If the value cannot be
represented by a usize, then None is returned. Read more
Converts the value of self to a u8. If the value cannot be
represented by a u8, then None is returned. Read more
Converts the value of self to a u16. If the value cannot be
represented by a u16, then None is returned. Read more
Converts the value of self to a u32. If the value cannot be
represented by a u32, then None is returned. Read more
Converts the value of self to a u128. If the value cannot be
represented by a u128 (u64 under the default implementation), then
None is returned. Read more
Converts the value of self to an f32. Overflows may map to positive
or negative inifinity, otherwise None is returned if the value cannot
be represented by an f32. Read more
Convert a reference to the inner type into a reference to the wrapper type. Read more
Convert a mutable reference to the inner type into a mutable reference to the wrapper type. Read more
Convert a slice to the inner type into a slice to the wrapper type.
Convert a mutable slice to the inner type into a mutable slice to the wrapper type. Read more
Convert a reference to the wrapper type into a reference to the inner type. Read more
Convert a mutable reference to the wrapper type into a mutable reference to the inner type. Read more
Convert a slice to the wrapped type into a slice to the inner type.
Convert a mutable slice to the wrapped type into a mutable slice to the inner type. Read more
Convert a reference to the inner type into a reference to the wrapper type. Read more
Convert a mutable reference to the inner type into a mutable reference to the wrapper type. Read more
Convert a slice to the inner type into a slice to the wrapper type.
Convert a mutable slice to the inner type into a mutable slice to the wrapper type. Read more
Convert a reference to the wrapper type into a reference to the inner type. Read more
Convert a mutable reference to the wrapper type into a mutable reference to the inner type. Read more
Convert a slice to the wrapped type into a slice to the inner type.
Convert a mutable slice to the wrapped type into a mutable slice to the inner type. Read more
Convert a reference to the inner type into a reference to the wrapper type. Read more
Convert a mutable reference to the inner type into a mutable reference to the wrapper type. Read more
Convert a slice to the inner type into a slice to the wrapper type.
Convert a mutable slice to the inner type into a mutable slice to the wrapper type. Read more
Convert a reference to the wrapper type into a reference to the inner type. Read more
Convert a mutable reference to the wrapper type into a mutable reference to the inner type. Read more
Convert a slice to the wrapped type into a slice to the inner type.
Convert a mutable slice to the wrapped type into a mutable slice to the inner type. Read more
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Wrapping (modular) addition. Computes self + other, wrapping around at the boundary of
the type. Read more
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Casts the value.
Wrapping (modular) multiplication. Computes self * other, wrapping around at the boundary
of the type. Read more
Wrapping (modular) negation. Computes -self,
wrapping around at the boundary of the type. Read more
Panic-free bitwise shift-left; yields self << mask(rhs),
where mask removes any high order bits of rhs that would
cause the shift to exceed the bitwidth of the type. Read more
Panic-free bitwise shift-right; yields self >> mask(rhs),
where mask removes any high order bits of rhs that would
cause the shift to exceed the bitwidth of the type. Read more
Wrapping (modular) subtraction. Computes self - other, wrapping around at the boundary
of the type. Read more
Auto Trait Implementations
impl<Frac> RefUnwindSafe for FixedI32<Frac> where
Frac: RefUnwindSafe,
impl<Frac> UnwindSafe for FixedI32<Frac> where
Frac: UnwindSafe,
Blanket Implementations
Mutably borrows from an owned value. Read more
Casts the value.
Performs the conversion.
Performs the conversion.
Casts the value.
Casts the value.
Casts the value.
Casts the value.