Calling Methods¶ ↑
Calling a method sends a message to an object so it can perform some work.
In ruby you send a message to an object like this:
my_method()
Note that the parenthesis are optional:
my_method
Except when there is difference between using and omitting parentheses, this document uses parenthesis when arguments are present to avoid confusion.
This section only covers calling methods. See also the syntax documentation on defining methods.
Receiver¶ ↑
self
is the default receiver. If you don’t specify any receiver self
will be used. To specify a receiver use .
:
my_object.my_method
This sends the my_method
message to my_object
. Any object can be a receiver but depending on the method’s visibility sending a message may raise a NoMethodError
.
You may also use ::
to designate a receiver, but this is rarely used due to the potential for confusion with ::
for namespaces.
Chaining Method Calls¶ ↑
You can “chain” method calls by immediately following one method call with another.
This example chains methods Array#append
and Array#compact
:
a = [:foo, 'bar', 2] a1 = [:baz, nil, :bam, nil] a2 = a.append(*a1).compact a2 # => [:foo, "bar", 2, :baz, :bam]
Details:
-
First method
merge
creates a copy ofa
, appends (separately) each element ofa1
to the copy, and returns[:foo, "bar", 2, :baz, nil, :bam, nil]
-
Chained method
compact
creates a copy of that return value, removes itsnil
-valued entries, and returns[:foo, "bar", 2, :baz, :bam]
You can chain methods that are in different classes. This example chains methods Hash#to_a
and Array#reverse
:
h = {foo: 0, bar: 1, baz: 2} h.to_a.reverse # => [[:baz, 2], [:bar, 1], [:foo, 0]]
Details:
-
First method
Hash#to_a
convertsa
to an Array, and returns[[:foo, 0], [:bar, 1], [:baz, 2]]
-
Chained method
Array#reverse
creates copy of that return value, reverses it, and returns[[:baz, 2], [:bar, 1], [:foo, 0]]
Safe Navigation Operator¶ ↑
&.
, called “safe navigation operator”, allows to skip method call when receiver is nil
. It returns nil
and doesn’t evaluate method’s arguments if the call is skipped.
REGEX = /(ruby) is (\w+)/i "Ruby is awesome!".match(REGEX).values_at(1, 2) # => ["Ruby", "awesome"] "Python is fascinating!".match(REGEX).values_at(1, 2) # NoMethodError: undefined method `values_at' for nil:NilClass "Python is fascinating!".match(REGEX)&.values_at(1, 2) # => nil
This allows to easily chain methods which could return empty value. Note that &.
skips only one next call, so for a longer chain it is necessary to add operator on each level:
"Python is fascinating!".match(REGEX)&.values_at(1, 2).join(' - ') # NoMethodError: undefined method `join' for nil:NilClass "Python is fascinating!".match(REGEX)&.values_at(1, 2)&.join(' - ') # => nil
Arguments¶ ↑
There are three types of arguments when sending a message, the positional arguments, keyword (or named) arguments and the block argument. Each message sent may use one, two or all types of arguments, but the arguments must be supplied in this order.
All arguments in ruby are passed by reference and are not lazily evaluated.
Each argument is separated by a ,
:
my_method(1, '2', :three)
Arguments may be an expression, a hash argument:
'key' => value
or a keyword argument:
key: value
Hash
and keyword arguments must be contiguous and must appear after all positional arguments, but may be mixed:
my_method('a' => 1, b: 2, 'c' => 3)
Positional Arguments¶ ↑
The positional arguments for the message follow the method name:
my_method(argument1, argument2)
In many cases, parenthesis are not necessary when sending a message:
my_method argument1, argument2
However, parenthesis are necessary to avoid ambiguity. This will raise a SyntaxError
because ruby does not know which method argument3 should be sent to:
method_one argument1, method_two argument2, argument3
If the method definition has a *argument
extra positional arguments will be assigned to argument
in the method as an Array
.
If the method definition doesn’t include keyword arguments, the keyword or hash-type arguments are assigned as a single hash to the last argument:
def my_method(options) p options end my_method('a' => 1, b: 2) # prints: {'a'=>1, :b=>2}
If too many positional arguments are given, an ArgumentError
is raised.
Default Positional Arguments¶ ↑
When the method defines default arguments you do not need to supply all the arguments to the method. Ruby will fill in the missing arguments in-order.
First we’ll cover the simple case where the default arguments appear on the right. Consider this method:
def my_method(a, b, c = 3, d = 4) p [a, b, c, d] end
Here c
and d
have default values which ruby will apply for you. If you send only two arguments to this method:
my_method(1, 2)
You will see ruby print [1, 2, 3, 4]
.
If you send three arguments:
my_method(1, 2, 5)
You will see ruby print [1, 2, 5, 4]
Ruby fills in the missing arguments from left to right.
Ruby allows default values to appear in the middle of positional arguments. Consider this more complicated method:
def my_method(a, b = 2, c = 3, d) p [a, b, c, d] end
Here b
and c
have default values. If you send only two arguments to this method:
my_method(1, 4)
You will see ruby print [1, 2, 3, 4]
.
If you send three arguments:
my_method(1, 5, 6)
You will see ruby print [1, 5, 3, 6]
.
Describing this in words gets complicated and confusing. I’ll describe it in variables and values instead.
First 1
is assigned to a
, then 6
is assigned to d
. This leaves only the arguments with default values. Since 5
has not been assigned to a value yet, it is given to b
and c
uses its default value of 3
.
Keyword Arguments¶ ↑
Keyword arguments follow any positional arguments and are separated by commas like positional arguments:
my_method(positional1, keyword1: value1, keyword2: value2)
Any keyword arguments not given will use the default value from the method definition. If a keyword argument is given that the method did not list, and the method definition does not accept arbitrary keyword arguments, an ArgumentError
will be raised.
Keyword argument value can be omitted, meaning the value will be fetched from the context by the name of the key
keyword1 = 'some value' my_method(positional1, keyword1:) # ...is the same as my_method(positional1, keyword1: keyword1)
Be aware that when method parenthesis are omitted, too, the parsing order might be unexpected:
my_method positional1, keyword1: some_other_expression # ...is actually parsed as my_method(positional1, keyword1: some_other_expression)
Block Argument¶ ↑
The block argument sends a closure from the calling scope to the method.
The block argument is always last when sending a message to a method. A block is sent to a method using do ... end
or { ... }
:
my_method do # ... end
or:
my_method { # ... }
do end
has lower precedence than { }
so:
method_1 method_2 { # ... }
Sends the block to method_2
while:
method_1 method_2 do # ... end
Sends the block to method_1
. Note that in the first case if parentheses are used the block is sent to method_1
.
A block will accept arguments from the method it was sent to. Arguments are defined similar to the way a method defines arguments. The block’s arguments go in | ... |
following the opening do
or {
:
my_method do |argument1, argument2| # ... end
Block Local Arguments¶ ↑
You may also declare block-local arguments to a block using ;
in the block arguments list. Assigning to a block-local argument will not override local arguments outside the block in the caller’s scope:
def my_method yield self end place = "world" my_method do |obj; place| place = "block" puts "hello #{obj} this is #{place}" end puts "place is: #{place}"
This prints:
hello main this is block place is world
So the place
variable in the block is not the same place
variable as outside the block. Removing ; place
from the block arguments gives this result:
hello main this is block place is block
Unpacking Positional Arguments¶ ↑
Given the following method:
def my_method(argument1, argument2, argument3) end
You can turn an Array
into an argument list with *
(or splat) operator:
arguments = [1, 2, 3] my_method(*arguments)
or:
arguments = [2, 3] my_method(1, *arguments)
Both are equivalent to:
my_method(1, 2, 3)
The *
unpacking operator can be applied to any object, not only arrays. If the object responds to a to_a method, this method is called, and is expected to return an Array
, and elements of this array are passed as separate positional arguments:
class Name def initialize(name) @name = name end def to_a = @name.split(' ') end name = Name.new('Jane Doe') p(*name) # prints separate values: # Jane # Doe
If the object doesn’t have a to_a method, the object itself is passed as one argument:
class Name def initialize(name) @name = name end end name = Name.new('Jane Doe') p(*name) # Prints the object itself: # #<Name:0x00007f9d07bca650 @name="Jane Doe">
This allows to handle one or many arguments polymorphically. Note also that nil
has NilClass#to_a
defined to return an empty array, so conditional unpacking is possible:
my_method(*(some_arguments if some_condition?))
If to_a method exists and does not return an Array
, it would be an error on unpacking:
class Name def initialize(name) @name = name end def to_a = @name end name = Name.new('Jane Doe') p(*name) # can't convert Name to Array (Name#to_a gives String) (TypeError)
You may also use the **
(described next) to convert a Hash
into keyword arguments.
If the number of objects in the Array
do not match the number of arguments for the method, an ArgumentError
will be raised.
If the splat operator comes first in the call, parentheses must be used to avoid an ambiguity of interpretation as an unpacking operator or multiplication operator. In this case, Ruby issues a warning in verbose mode:
my_method *arguments # warning: '*' interpreted as argument prefix my_method(*arguments) # no warning
Unpacking Keyword Arguments¶ ↑
Given the following method:
def my_method(first: 1, second: 2, third: 3) end
You can turn a Hash
into keyword arguments with the **
(keyword splat) operator:
arguments = { first: 3, second: 4, third: 5 } my_method(**arguments)
or:
arguments = { first: 3, second: 4 } my_method(third: 5, **arguments)
Both are equivalent to:
my_method(first: 3, second: 4, third: 5)
The **
unpacking operator can be applied to any object, not only hashes. If the object responds to a to_hash method, this method is called, and is expected to return an Hash
, and elements of this hash are passed as keyword arguments:
class Name def initialize(name) @name = name end def to_hash = {first: @name.split(' ').first, last: @name.split(' ').last} end name = Name.new('Jane Doe') p(**name) # Prints: {name: "Jane", last: "Doe"}
Unlike *
operator, **
raises an error when used on an object that doesn’t respond to to_hash. The one exception is nil
, which doesn’t explicitly define this method, but is still allowed to be used in **
unpacking, not adding any keyword arguments.
Again, this allows for conditional unpacking:
my_method(some: params, **(some_extra_params if pass_extra_params?))
Like *
operator, **
raises an error when the object responds to to_hash, but it doesn’t return a Hash
.
If the method definition uses the keyword splat operator to gather arbitrary keyword arguments, they will not be gathered by *
:
def my_method(*a, **kw) p arguments: a, keywords: kw end my_method(1, 2, '3' => 4, five: 6)
Prints:
{:arguments=>[1, 2], :keywords=>{'3'=>4, :five=>6}}
Proc
to Block Conversion¶ ↑
Given a method that use a block:
def my_method yield self end
You can convert a proc or lambda to a block argument with the &
(block conversion) operator:
argument = proc { |a| puts "#{a.inspect} was yielded" } my_method(&argument)
If the block conversion operator comes first in the call, parenthesis must be used to avoid a warning:
my_method &argument # warning my_method(&argument) # no warning
Method
Lookup¶ ↑
When you send a message, Ruby looks up the method that matches the name of the message for the receiver. Methods are stored in classes and modules so method lookup walks these, not the objects themselves.
Here is the order of method lookup for the receiver’s class or module R
:
-
The prepended modules of
R
in reverse order -
For a matching method in
R
-
The included modules of
R
in reverse order
If R
is a class with a superclass, this is repeated with R
‘s superclass until a method is found.
Once a match is found method lookup stops.
If no match is found this repeats from the beginning, but looking for method_missing
. The default method_missing
is BasicObject#method_missing
which raises a NameError
when invoked.
If refinements (an experimental feature) are active, the method lookup changes. See the refinements documentation for details.