Methods implement the functionality of your program. Here is a simple method definition:
def one_plus_one 1 + 1 end
A method definition consists of the def
keyword, a method name, the body of the method, return
value and the end
keyword. When called the method will execute the body of the method. This method returns 2
.
This section only covers defining methods. See also the syntax documentation on calling methods.
Method
Names¶ ↑Method
names may be one of the operators or must start a letter or a character with the eighth bit set. It may contain letters, numbers, an _
(underscore or low line) or a character with the eighth bit set. The convention is to use underscores to separate words in a multiword method name:
def method_name puts "use underscores to separate words" end
Ruby programs must be written in a US-ASCII-compatible character set such as UTF-8, ISO-8859-1 etc. In such character sets if the eighth bit is set it indicates an extended character. Ruby allows method names and other identifiers to contain such characters. Ruby programs cannot contain some characters like ASCII NUL (\x00
).
The following are examples of valid Ruby methods:
def hello "hello" end def こんにちは puts "means hello in Japanese" end
Typically method names are US-ASCII compatible since the keys to type them exist on all keyboards.
Method
names may end with a !
(bang or exclamation mark), a ?
(question mark), or =
(equals sign).
The bang methods (!
at the end of the method name) are called and executed just like any other method. However, by convention, a method with an exclamation point or bang is considered dangerous. In Ruby's core library the dangerous method implies that when a method ends with a bang (!
), it indicates that unlike its non-bang equivalent, permanently modifies its receiver. Almost always, the Ruby core library will have a non-bang counterpart (method name which does NOT end with !
) of every bang method (method name which does end with !
) that does not modify the receiver. This convention is typically true for the Ruby core library but may or may not hold true for other Ruby libraries.
Methods that end with a question mark by convention return boolean, but they may not always return just true
or false
. Often, they will return an object to indicate a true value (or “truthy” value).
Methods that end with an equals sign indicate an assignment method.
These are method names for the various Ruby operators. Each of these operators accepts only one argument. Following the operator is the typical use or name of the operator. Creating an alternate meaning for the operator may lead to confusion as the user expects plus to add things, minus to subtract things, etc. Additionally, you cannot alter the precedence of the operators.
+
add
-
subtract
*
multiply
**
power
/
divide
%
modulus division, String#%
&
AND
^
XOR (exclusive OR)
>>
right-shift
<<
left-shift, append
==
equal
!=
not equal
===
case equality. See Object#===
=~
pattern match. (Not just for regular expressions)
!~
does not match
<=>
comparison aka spaceship operator. See Comparable
<
less-than
<=
less-than or equal
>
greater-than
>=
greater-than or equal
To define unary methods minus and plus, follow the operator with an @
as in +@
:
class C def -@ puts "you inverted this object" end end obj = C.new -obj # prints "you inverted this object"
The @
is needed to differentiate unary minus and plus operators from binary minus and plus operators.
You can also follow tilde and not (!
) unary methods with @
, but it is not required as there are no binary tilde and not operators.
Unary methods accept zero arguments.
Additionally, methods for element reference and assignment may be defined: []
and []=
respectively. Both can take one or more arguments, and element reference can take none.
class C def [](a, b) puts a + b end def []=(a, b, c) puts a * b + c end end obj = C.new obj[2, 3] # prints "5" obj[2, 3] = 4 # prints "10"
By default, a method returns the last expression that was evaluated in the body of the method. In the example above, the last (and only) expression evaluated was the simple sum 1 + 1
. The return
keyword can be used to make it explicit that a method returns a value.
def one_plus_one return 1 + 1 end
It can also be used to make a method return before the last expression is evaluated.
def two_plus_two return 2 + 2 1 + 1 # this expression is never evaluated end
Note that for assignment methods the return value will be ignored when using the assignment syntax. Instead, the argument will be returned:
def a=(value) return 1 + value end p(self.a = 5) # prints 5
The actual return value will be returned when invoking the method directly:
p send(:a=, 5) # prints 6
The standard syntax to define a method:
def my_method # ... end
adds the method to a class. You can define an instance method on a specific class with the class
keyword:
class C def my_method # ... end end
A method may be defined on another object. You may define a “class method” (a method that is defined on the class, not an instance of the class) like this:
class C def self.my_method # ... end end
However, this is simply a special case of a greater syntactical power in Ruby, the ability to add methods to any object. Classes are objects, so adding class methods is simply adding methods to the Class
object.
The syntax for adding a method to an object is as follows:
greeting = "Hello" def greeting.broaden self + ", world!" end greeting.broaden # returns "Hello, world!"
self
is a keyword referring to the current object under consideration by the compiler, which might make the use of self
in defining a class method above a little clearer. Indeed, the example of adding a hello
method to the class String
can be rewritten thus:
def String.hello "Hello, world!" end
A method defined like this is called a “singleton method”. broaden
will only exist on the string instance greeting
. Other strings will not have broaden
.
When Ruby encounters the def
keyword, it doesn't consider it an error if the method already exists: it simply redefines it. This is called overriding. Rather like extending core classes, this is a potentially dangerous ability, and should be used sparingly because it can cause unexpected results. For example, consider this irb session:
>> "43".to_i => 43 >> class String >> def to_i >> 42 >> end >> end => nil >> "43".to_i => 42
This will effectively sabotage any code which makes use of the method String#to_i
to parse numbers from strings.
A method may accept arguments. The argument list follows the method name:
def add_one(value) value + 1 end
When called, the user of the add_one
method must provide an argument. The argument is a local variable in the method body. The method will then add one to this argument and return the value. If given 1
this method will return 2
.
The parentheses around the arguments are optional:
def add_one value value + 1 end
Multiple arguments are separated by a comma:
def add_values(a, b) a + b end
When called, the arguments must be provided in the exact order. In other words, the arguments are positional.
Arguments may have default values:
def add_values(a, b = 1) a + b end
The default value does not need to appear first, but arguments with defaults must be grouped together. This is ok:
def add_values(a = 1, b = 2, c) a + b + c end
This will raise a SyntaxError:
def add_values(a = 1, b, c = 1) a + b + c end
Default argument values can refer to arguments that have already been evaluated as local variables, and argument values are always evaluated left to right. So this is allowed:
def add_values(a = 1, b = a) a + b end add_values # => 2
But this will raise a NameError
(unless there is a method named b
defined):
def add_values(a = b, b = 1) a + b end add_values # NameError (undefined local variable or method `b' for main:Object)
Array
Decomposition¶ ↑You can decompose (unpack or extract values from) an Array
using extra parentheses in the arguments:
def my_method((a, b)) p a: a, b: b end my_method([1, 2])
This prints:
{:a=>1, :b=>2}
If the argument has extra elements in the Array
they will be ignored:
def my_method((a, b)) p a: a, b: b end my_method([1, 2, 3])
This has the same output as above.
You can use a *
to collect the remaining arguments. This splits an Array
into a first element and the rest:
def my_method((a, *b)) p a: a, b: b end my_method([1, 2, 3])
This prints:
{:a=>1, :b=>[2, 3]}
The argument will be decomposed if it responds to to_ary. You should only define to_ary if you can use your object in place of an Array
.
Use of the inner parentheses only uses one of the sent arguments. If the argument is not an Array
it will be assigned to the first argument in the decomposition and the remaining arguments in the decomposition will be nil
:
def my_method(a, (b, c), d) p a: a, b: b, c: c, d: d end my_method(1, 2, 3)
This prints:
{:a=>1, :b=>2, :c=>nil, :d=>3}
You can nest decomposition arbitrarily:
def my_method(((a, b), c)) # ... end
Prefixing an argument with *
causes any remaining arguments to be converted to an Array:
def gather_arguments(*arguments) p arguments end gather_arguments 1, 2, 3 # prints [1, 2, 3]
The array argument must appear before any keyword arguments.
It is possible to gather arguments at the beginning or in the middle:
def gather_arguments(first_arg, *middle_arguments, last_arg) p middle_arguments end gather_arguments 1, 2, 3, 4 # prints [2, 3]
The array argument will capture a Hash
as the last entry if a hash was sent by the caller after all positional arguments.
def gather_arguments(*arguments) p arguments end gather_arguments 1, a: 2 # prints [1, {:a=>2}]
However, this only occurs if the method does not declare any keyword arguments.
def gather_arguments_keyword(*positional, keyword: nil) p positional: positional, keyword: keyword end gather_arguments_keyword 1, 2, three: 3 #=> raises: unknown keyword: three (ArgumentError)
Also, note that a bare *
can be used to ignore arguments:
def ignore_arguments(*) end
Keyword arguments are similar to positional arguments with default values:
def add_values(first: 1, second: 2) first + second end
Arbitrary keyword arguments will be accepted with **
:
def gather_arguments(first: nil, **rest) p first, rest end gather_arguments first: 1, second: 2, third: 3 # prints 1 then {:second=>2, :third=>3}
When calling a method with keyword arguments the arguments may appear in any order. If an unknown keyword argument is sent by the caller, and the method does not accept arbitrary keyword arguments, an ArgumentError
is raised.
To require a specific keyword argument, do not include a default value for the keyword argument:
def add_values(first:, second:) first + second end add_values # ArgumentError (missing keywords: first, second) add_values(first: 1, second: 2) # => 3
When mixing keyword arguments and positional arguments, all positional arguments must appear before any keyword arguments.
Also, note that **
can be used to ignore keyword arguments:
def ignore_keywords(**) end
To mark a method as accepting keywords, but not actually accepting keywords, you can use the **nil
:
def no_keywords(**nil) end
Calling such a method with keywords or a non-empty keyword splat will result in an ArgumentError
. This syntax is supported so that keywords can be added to the method later without affected backwards compatibility.
Between Ruby 2.0 and 2.6, keyword and positional arguments were not separated, and a keyword argument could be used as a positional argument and vice-versa. In Ruby 3.0, keyword and positional arguments will be separated if the method definition includes keyword arguments. In Ruby 3.0, if the method definition does not include keyword arguments, keyword arguments provided when calling the method will continue to be treated as a final positional hash argument.
Currently, the keyword and positional arguments are not separated, but cases where behavior will change in Ruby 3.0 will result in a warning being emitted.
There are a few different types of keyword argument separation issues.
Hash
to Keywords¶ ↑If a method is called with the hash, the hash could be treated as keywords:
def my_method(**keywords) keywords end my_method({a: 1}) # {:a => 1}
This occurs even if the hash could be an optional positional argument or an element of a rest argument:
def my_method(hash=nil, **keywords) [hash, keywords] end my_method({a: 1}) # [nil, {:a => 1}] def my_method(*args, **keywords) [args, keywords] end my_method({a: 1}) # [[], {:a => 1}]
However, if the hash is needed for a mandatory positional argument, it would not be treated as keywords:
def my_method(hash, **keywords) [hash, keywords] end my_method({a: 1}) # [{:a => 1}, {}]
If a method is called with keywords, but it is missing one mandatory positional argument, the keywords are converted to a hash and the hash used as the mandatory positional argument:
def my_method(hash, **keywords) [hash, keywords] end my_method(a: 1) # [{:a => 1}, {}]
This is also true for empty keyword splats:
kw = {} my_method(**kw) # [{}, {}]
If a method definition accepts specific keywords and not arbitrary keywords, keywords or a positional hash may be split if the hash includes both Symbol
keys and non-Symbol keys and the keywords or positional hash are not needed as a mandatory positional argument. In this case, the non-Symbol keys are separated into a positional argument hash, and the Symbol
keys are used as the keyword arguments:
def my_method(hash=3, a: 4) [hash, a] end my_method(a: 1, 'a' => 2) # [{"a"=>2}, 1] my_method({a: 1, 'a' => 2}) # [{"a"=>2}, 1]
The block argument is indicated by &
and must come last:
def my_method(&my_block) my_block.call(self) end
Most frequently the block argument is used to pass a block to another method:
def each_item(&block) @items.each(&block) end
If you are only going to call the block and will not otherwise manipulate it or send it to another method using yield
without an explicit block parameter is preferred. This method is equivalent to the first method in this section:
def my_method yield self end
Exception
Handling¶ ↑Methods have an implied exception handling block so you do not need to use begin
or end
to handle exceptions. This:
def my_method begin # code that may raise an exception rescue # handle exception end end
May be written as:
def my_method # code that may raise an exception rescue # handle exception end
Similarly, if you wish to always run code even if an exception is raised, you can use ensure
without begin
and end
:
def my_method # code that may raise an exception ensure # code that runs even if previous code raised an exception end
You can also combine rescue
with ensure
and/or else
, without begin
and end
:
def my_method # code that may raise an exception rescue # handle exception else # only run if no exception raised above ensure # code that runs even if previous code raised an exception end
If you wish to rescue an exception for only part of your method, use begin
and end
. For more details see the page on exception handling.