Module std::fmt
[−]
[src]
Utilities for formatting and printing strings
This module contains the runtime support for the format!
syntax extension.
This macro is implemented in the compiler to emit calls to this module in
order to format arguments at runtime into strings and streams.
Usage
The format!
macro is intended to be familiar to those coming from C's
printf/fprintf functions or Python's str.format
function. In its current
revision, the format!
macro returns a String
type which is the result of
the formatting. In the future it will also be able to pass in a stream to
format arguments directly while performing minimal allocations.
Some examples of the format!
extension are:
format!("Hello"); // => "Hello" format!("Hello, {}!", "world"); // => "Hello, world!" format!("The number is {}", 1); // => "The number is 1" format!("{:?}", (3, 4)); // => "(3, 4)" format!("{value}", value=4); // => "4" format!("{} {}", 1, 2); // => "1 2"
From these, you can see that the first argument is a format string. It is required by the compiler for this to be a string literal; it cannot be a variable passed in (in order to perform validity checking). The compiler will then parse the format string and determine if the list of arguments provided is suitable to pass to this format string.
Positional parameters
Each formatting argument is allowed to specify which value argument it's
referencing, and if omitted it is assumed to be "the next argument". For
example, the format string {} {} {}
would take three parameters, and they
would be formatted in the same order as they're given. The format string
{2} {1} {0}
, however, would format arguments in reverse order.
Things can get a little tricky once you start intermingling the two types of positional specifiers. The "next argument" specifier can be thought of as an iterator over the argument. Each time a "next argument" specifier is seen, the iterator advances. This leads to behavior like this:
fn main() { format!("{1} {} {0} {}", 1, 2); // => "2 1 1 2" }format!("{1} {} {0} {}", 1, 2); // => "2 1 1 2"
The internal iterator over the argument has not been advanced by the time
the first {}
is seen, so it prints the first argument. Then upon reaching
the second {}
, the iterator has advanced forward to the second argument.
Essentially, parameters which explicitly name their argument do not affect
parameters which do not name an argument in terms of positional specifiers.
A format string is required to use all of its arguments, otherwise it is a compile-time error. You may refer to the same argument more than once in the format string, although it must always be referred to with the same type.
Named parameters
Rust itself does not have a Python-like equivalent of named parameters to a
function, but the format!
macro is a syntax extension which allows it to
leverage named parameters. Named parameters are listed at the end of the
argument list and have the syntax:
identifier '=' expression
For example, the following format!
expressions all use named argument:
format!("{argument}", argument = "test"); // => "test" format!("{name} {}", 1, name = 2); // => "2 1" format!("{a} {c} {b}", a="a", b='b', c=3); // => "a 3 b"
It is not valid to put positional parameters (those without names) after arguments which have names. Like with positional parameters, it is not valid to provide named parameters that are unused by the format string.
Argument types
Each argument's type is dictated by the format string. It is a requirement that every argument is only ever referred to by one type. For example, this is an invalid format string:
{0:x} {0:o}
This is invalid because the first argument is both referred to as a hexadecimal as well as an octal.
There are various parameters which do require a particular type, however.
Namely, the {:.*}
syntax, which sets the number of numbers after the
decimal in floating-point types:
let formatted_number = format!("{:.*}", 2, 1.234567); assert_eq!("1.23", formatted_number)
If this syntax is used, then the number of characters to print precedes the
actual object being formatted, and the number of characters must have the
type usize
. Although a usize
can be printed with {}
, it is invalid to
reference an argument as such. For example this is another invalid format
string:
{:.*} {0}
Formatting traits
When requesting that an argument be formatted with a particular type, you
are actually requesting that an argument ascribes to a particular trait.
This allows multiple actual types to be formatted via {:x}
(like i8
as
well as isize
). The current mapping of types to traits is:
- nothing ⇒
Display
?
⇒Debug
o
⇒Octal
x
⇒LowerHex
X
⇒UpperHex
p
⇒Pointer
b
⇒Binary
e
⇒LowerExp
E
⇒UpperExp
What this means is that any type of argument which implements the
fmt::Binary
trait can then be formatted with {:b}
. Implementations
are provided for these traits for a number of primitive types by the
standard library as well. If no format is specified (as in {}
or {:6}
),
then the format trait used is the Display
trait.
When implementing a format trait for your own type, you will have to implement a method of the signature:
fn main() { #![allow(dead_code)] use std::fmt; struct Foo; // our custom type impl fmt::Display for Foo { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { write!(f, "testing, testing") } } }fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
Your type will be passed as self
by-reference, and then the function
should emit output into the f.buf
stream. It is up to each format trait
implementation to correctly adhere to the requested formatting parameters.
The values of these parameters will be listed in the fields of the
Formatter
struct. In order to help with this, the Formatter
struct also
provides some helper methods.
Additionally, the return value of this function is fmt::Result
which is a
typedef to Result<(), std::io::Error>
(also known as std::io::Result<()>
).
Formatting implementations should ensure that they return errors from write!
correctly (propagating errors upward).
An example of implementing the formatting traits would look like:
use std::fmt; #[derive(Debug)] struct Vector2D { x: isize, y: isize, } impl fmt::Display for Vector2D { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { // The `f` value implements the `Write` trait, which is what the // write! macro is expecting. Note that this formatting ignores the // various flags provided to format strings. write!(f, "({}, {})", self.x, self.y) } } // Different traits allow different forms of output of a type. The meaning // of this format is to print the magnitude of a vector. impl fmt::Binary for Vector2D { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let magnitude = (self.x * self.x + self.y * self.y) as f64; let magnitude = magnitude.sqrt(); // Respect the formatting flags by using the helper method // `pad_integral` on the Formatter object. See the method // documentation for details, and the function `pad` can be used // to pad strings. let decimals = f.precision().unwrap_or(3); let string = format!("{:.*}", decimals, magnitude); f.pad_integral(true, "", &string) } } fn main() { let myvector = Vector2D { x: 3, y: 4 }; println!("{}", myvector); // => "(3, 4)" println!("{:?}", myvector); // => "Vector2D {x: 3, y:4}" println!("{:10.3b}", myvector); // => " 5.000" }use std::fmt; #[derive(Debug)] struct Vector2D { x: isize, y: isize, } impl fmt::Display for Vector2D { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { // The `f` value implements the `Write` trait, which is what the // write! macro is expecting. Note that this formatting ignores the // various flags provided to format strings. write!(f, "({}, {})", self.x, self.y) } } // Different traits allow different forms of output of a type. The meaning // of this format is to print the magnitude of a vector. impl fmt::Binary for Vector2D { fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result { let magnitude = (self.x * self.x + self.y * self.y) as f64; let magnitude = magnitude.sqrt(); // Respect the formatting flags by using the helper method // `pad_integral` on the Formatter object. See the method // documentation for details, and the function `pad` can be used // to pad strings. let decimals = f.precision().unwrap_or(3); let string = format!("{:.*}", decimals, magnitude); f.pad_integral(true, "", &string) } } fn main() { let myvector = Vector2D { x: 3, y: 4 }; println!("{}", myvector); // => "(3, 4)" println!("{:?}", myvector); // => "Vector2D {x: 3, y:4}" println!("{:10.3b}", myvector); // => " 5.000" }
fmt::Display
vs fmt::Debug
These two formatting traits have distinct purposes:
fmt::Display
implementations assert that the type can be faithfully represented as a UTF-8 string at all times. It is not expected that all types implement theDisplay
trait.fmt::Debug
implementations should be implemented for all public types. Output will typically represent the internal state as faithfully as possible. The purpose of theDebug
trait is to facilitate debugging Rust code. In most cases, using#[derive(Debug)]
is sufficient and recommended.
Some examples of the output from both traits:
fn main() { assert_eq!(format!("{} {:?}", 3, 4), "3 4"); assert_eq!(format!("{} {:?}", 'a', 'b'), "a 'b'"); assert_eq!(format!("{} {:?}", "foo\n", "bar\n"), "foo\n \"bar\\n\""); }assert_eq!(format!("{} {:?}", 3, 4), "3 4"); assert_eq!(format!("{} {:?}", 'a', 'b'), "a 'b'"); assert_eq!(format!("{} {:?}", "foo\n", "bar\n"), "foo\n \"bar\\n\"");
Related macros
There are a number of related macros in the format!
family. The ones that
are currently implemented are:
format! // described above write! // first argument is a &mut io::Write, the destination writeln! // same as write but appends a newline print! // the format string is printed to the standard output println! // same as print but appends a newline format_args! // described below.
write!
This and writeln
are two macros which are used to emit the format string
to a specified stream. This is used to prevent intermediate allocations of
format strings and instead directly write the output. Under the hood, this
function is actually invoking the write
function defined in this module.
Example usage is:
use std::io::Write; let mut w = Vec::new(); write!(&mut w, "Hello {}!", "world");
print!
This and println
emit their output to stdout. Similarly to the write!
macro, the goal of these macros is to avoid intermediate allocations when
printing output. Example usage is:
print!("Hello {}!", "world"); println!("I have a newline {}", "character at the end");
format_args!
This is a curious macro which is used to safely pass around an opaque object describing the format string. This object does not require any heap allocations to create, and it only references information on the stack. Under the hood, all of the related macros are implemented in terms of this. First off, some example usage is:
fn main() { #![allow(unused_must_use)] use std::fmt; use std::io::{self, Write}; fmt::format(format_args!("this returns {}", "String")); let mut some_writer = io::stdout(); write!(&mut some_writer, "{}", format_args!("print with a {}", "macro")); fn my_fmt_fn(args: fmt::Arguments) { write!(&mut io::stdout(), "{}", args); } my_fmt_fn(format_args!("or a {} too", "function")); }use std::fmt; use std::io::{self, Write}; fmt::format(format_args!("this returns {}", "String")); let mut some_writer = io::stdout(); write!(&mut some_writer, "{}", format_args!("print with a {}", "macro")); fn my_fmt_fn(args: fmt::Arguments) { write!(&mut io::stdout(), "{}", args); } my_fmt_fn(format_args!("or a {} too", "function"));
The result of the format_args!
macro is a value of type fmt::Arguments
.
This structure can then be passed to the write
and format
functions
inside this module in order to process the format string.
The goal of this macro is to even further prevent intermediate allocations
when dealing formatting strings.
For example, a logging library could use the standard formatting syntax, but it would internally pass around this structure until it has been determined where output should go to.
Syntax
The syntax for the formatting language used is drawn from other languages,
so it should not be too alien. Arguments are formatted with python-like
syntax, meaning that arguments are surrounded by {}
instead of the C-like
%
. The actual grammar for the formatting syntax is:
format_string := <text> [ format <text> ] *
format := '{' [ argument ] [ ':' format_spec ] '}'
argument := integer | identifier
format_spec := [[fill]align][sign]['#'][0][width]['.' precision][type]
fill := character
align := '<' | '^' | '>'
sign := '+' | '-'
width := count
precision := count | '*'
type := identifier | ''
count := parameter | integer
parameter := integer '$'
Formatting Parameters
Each argument being formatted can be transformed by a number of formatting
parameters (corresponding to format_spec
in the syntax above). These
parameters affect the string representation of what's being formatted. This
syntax draws heavily from Python's, so it may seem a bit familiar.
Fill/Alignment
The fill character is provided normally in conjunction with the width
parameter. This indicates that if the value being formatted is smaller than
width
some extra characters will be printed around it. The extra
characters are specified by fill
, and the alignment can be one of two
options:
<
- the argument is left-aligned inwidth
columns^
- the argument is center-aligned inwidth
columns>
- the argument is right-aligned inwidth
columns
Note that alignment may not be implemented by some types. A good way to ensure padding is applied is to format your input, then use this resulting string to pad your output.
Sign/#
/0
These can all be interpreted as flags for a particular formatter.
+
- This is intended for numeric types and indicates that the sign should always be printed. Positive signs are never printed by default, and the negative sign is only printed by default for theSigned
trait. This flag indicates that the correct sign (+
or-
) should always be printed.-
- Currently not used#
- This flag is indicates that the "alternate" form of printing should be used. The alternate forms are:#?
- pretty-print theDebug
formatting#x
- precedes the argument with a0x
#X
- precedes the argument with a0x
#b
- precedes the argument with a0b
#o
- precedes the argument with a0o
0
- This is used to indicate for integer formats that the padding should both be done with a0
character as well as be sign-aware. A format like{:08}
would yield00000001
for the integer1
, while the same format would yield-0000001
for the integer-1
. Notice that the negative version has one fewer zero than the positive version.
Width
This is a parameter for the "minimum width" that the format should take up. If the value's string does not fill up this many characters, then the padding specified by fill/alignment will be used to take up the required space.
The default fill/alignment for non-numerics is a space and left-aligned. The
defaults for numeric formatters is also a space but with right-alignment. If
the 0
flag is specified for numerics, then the implicit fill character is
0
.
The value for the width can also be provided as a usize
in the list of
parameters by using the 2$
syntax indicating that the second argument is a
usize
specifying the width.
Precision
For non-numeric types, this can be considered a "maximum width". If the resulting string is longer than this width, then it is truncated down to this many characters and only those are emitted.
For integral types, this is ignored.
For floating-point types, this indicates how many digits after the decimal point should be printed.
There are three possible ways to specify the desired precision
:
An integer
.N
:the integer
N
itself is the precision.An integer followed by dollar sign
.N$
:use format argument
N
(which must be ausize
) as the precision.An asterisk
.*
:.*
means that this{...}
is associated with two format inputs rather than one: the first input holds theusize
precision, and the second holds the value to print. Note that in this case, if one uses the format string{<arg>:<spec>.*}
, then the<arg>
part refers to the value to print, and theprecision
must come in the input preceding<arg>
.
For example, these:
fn main() { // Hello {arg 0 (x)} is {arg 1 (0.01} with precision specified inline (5)} println!("Hello {0} is {1:.5}", "x", 0.01); // Hello {arg 1 (x)} is {arg 2 (0.01} with precision specified in arg 0 (5)} println!("Hello {1} is {2:.0$}", 5, "x", 0.01); // Hello {arg 0 (x)} is {arg 2 (0.01} with precision specified in arg 1 (5)} println!("Hello {0} is {2:.1$}", "x", 5, 0.01); // Hello {next arg (x)} is {second of next two args (0.01} with precision // specified in first of next two args (5)} println!("Hello {} is {:.*}", "x", 5, 0.01); // Hello {next arg (x)} is {arg 2 (0.01} with precision // specified in its predecessor (5)} println!("Hello {} is {2:.*}", "x", 5, 0.01); }// Hello {arg 0 (x)} is {arg 1 (0.01} with precision specified inline (5)} println!("Hello {0} is {1:.5}", "x", 0.01); // Hello {arg 1 (x)} is {arg 2 (0.01} with precision specified in arg 0 (5)} println!("Hello {1} is {2:.0$}", 5, "x", 0.01); // Hello {arg 0 (x)} is {arg 2 (0.01} with precision specified in arg 1 (5)} println!("Hello {0} is {2:.1$}", "x", 5, 0.01); // Hello {next arg (x)} is {second of next two args (0.01} with precision // specified in first of next two args (5)} println!("Hello {} is {:.*}", "x", 5, 0.01); // Hello {next arg (x)} is {arg 2 (0.01} with precision // specified in its predecessor (5)} println!("Hello {} is {2:.*}", "x", 5, 0.01);
All print the same thing:
Hello x is 0.01000
While these:
fn main() { println!("{}, `{name:.*}` has 3 fractional digits", "Hello", 3, name=1234.56); println!("{}, `{name:.*}` has 3 characters", "Hello", 3, name="1234.56"); }println!("{}, `{name:.*}` has 3 fractional digits", "Hello", 3, name=1234.56); println!("{}, `{name:.*}` has 3 characters", "Hello", 3, name="1234.56");
print two significantly different things:
Hello, `1234.560` has 3 fractional digits
Hello, `123` has 3 characters
Escaping
The literal characters {
and }
may be included in a string by preceding
them with the same character. For example, the {
character is escaped with
{{
and the }
character is escaped with }}
.
Structs
Arguments |
This structure represents a safely precompiled version of a format string and its arguments. This cannot be generated at runtime because it cannot safely be done so, so no constructors are given and the fields are private to prevent modification. |
DebugList |
A struct to help with |
DebugMap |
A struct to help with |
DebugSet |
A struct to help with |
DebugStruct |
A struct to help with |
DebugTuple |
A struct to help with |
Error |
The error type which is returned from formatting a message into a stream. |
Formatter |
A struct to represent both where to emit formatting strings to and how they should be formatted. A mutable version of this is passed to all formatting traits. |
Radix |
[Unstable] A radix with in the range of |
RadixFmt |
[Unstable] A helper type for formatting radixes. |
Traits
Binary |
Format trait for the |
Debug |
Format trait for the |
Display |
Format trait for an empty format, |
LowerExp |
Format trait for the |
LowerHex |
Format trait for the |
Octal |
Format trait for the |
Pointer |
Format trait for the |
UpperExp |
Format trait for the |
UpperHex |
Format trait for the |
Write |
A collection of methods that are required to format a message into a stream. |
Functions
format |
The format function takes a precompiled format string and a list of arguments, to return the resulting formatted string. |
write |
The |
radix |
[Unstable] Constructs a radix formatter in the range of |
Type Definitions
Result |