Trait tract_pulse::internal::fmt::Octal 1.0.0[−][src]
Expand description
o formatting.
The Octal trait should format its output as a number in base-8.
For primitive signed integers (i8 to i128, and isize),
negative values are formatted as the two’s complement representation.
The alternate flag, #, adds a 0o in front of the output.
For more information on formatters, see the module-level documentation.
Examples
Basic usage with i32:
let x = 42; // 42 is '52' in octal assert_eq!(format!("{:o}", x), "52"); assert_eq!(format!("{:#o}", x), "0o52"); assert_eq!(format!("{:o}", -16), "37777777760");
Implementing Octal on a type:
use std::fmt; struct Length(i32); impl fmt::Octal for Length { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { let val = self.0; fmt::Octal::fmt(&val, f) // delegate to i32's implementation } } let l = Length(9); assert_eq!(format!("l as octal is: {:o}", l), "l as octal is: 11"); assert_eq!(format!("l as octal is: {:#06o}", l), "l as octal is: 0o0011");
Required methods
Implementations on Foreign Types
impl<O, V> Octal for BitArray<O, V> where
O: BitOrder,
V: BitView,
impl<O, V> Octal for BitArray<O, V> where
O: BitOrder,
V: BitView, impl<O, T> Octal for BitBox<O, T> where
O: BitOrder,
T: BitStore,
impl<O, T> Octal for BitBox<O, T> where
O: BitOrder,
T: BitStore, impl<'_, T> Octal for Domain<'_, T> where
T: BitStore,
impl<'_, T> Octal for Domain<'_, T> where
T: BitStore, impl<O, T> Octal for BitVec<O, T> where
O: BitOrder,
T: BitStore,
impl<O, T> Octal for BitVec<O, T> where
O: BitOrder,
T: BitStore, impl<O, T> Octal for BitSlice<O, T> where
O: BitOrder,
T: BitStore,
impl<O, T> Octal for BitSlice<O, T> where
O: BitOrder,
T: BitStore, Render the contents of a BitSlice in a numeric format.
These implementations render the bits of memory contained in a
BitSlice as one of the three numeric bases that the Rust format
system supports:
Binaryrenders each bit individually as0or1,Octalrenders clusters of three bits as the numbers0through7,- and
UpperHexandLowerHexrender clusters of four bits as the numbers0through9andAthroughF.
The formatters produce a “word” for each element T of memory. The
chunked formats (octal and hexadecimal) operate somewhat peculiarly:
they show the semantic value of the memory, as interpreted by the
ordering parameter’s implementation rather than the raw value of
memory you might observe with a debugger. In order to ease the
process of expanding numbers back into bits, each digit is grouped to
the right edge of the memory element. So, for example, the byte
0xFF would be rendered in as 0o377 rather than 0o773.
Rendered words are chunked by memory elements, rather than by as clean as possible a number of digits, in order to aid visualization of the slice’s place in memory.
Implementors
impl Octal for NonZeroI161.34.0[src]
impl Octal for NonZeroI161.34.0[src]impl Octal for NonZeroI321.34.0[src]
impl Octal for NonZeroI321.34.0[src]impl Octal for NonZeroI641.34.0[src]
impl Octal for NonZeroI641.34.0[src]impl Octal for NonZeroI1281.34.0[src]
impl Octal for NonZeroI1281.34.0[src]impl Octal for NonZeroIsize1.34.0[src]
impl Octal for NonZeroIsize1.34.0[src]impl Octal for NonZeroU161.28.0[src]
impl Octal for NonZeroU161.28.0[src]impl Octal for NonZeroU321.28.0[src]
impl Octal for NonZeroU321.28.0[src]impl Octal for NonZeroU641.28.0[src]
impl Octal for NonZeroU641.28.0[src]impl Octal for NonZeroU1281.28.0[src]
impl Octal for NonZeroU1281.28.0[src]impl Octal for NonZeroUsize1.28.0[src]
impl Octal for NonZeroUsize1.28.0[src]