Fear
This gem provides Option
, Either
, and Try
monads implemented an idiomatic way.
It is highly inspired by scala's implementation.
Installation
Add this line to your application's Gemfile:
gem 'fear'
And then execute:
$ bundle
Or install it yourself as:
$ gem install fear
Usage
Option (API Documentation)
Represents optional (nullable) values. Instances of Option
are either an instance of
Some
or the object None
.
The most idiomatic way to use an Option
instance is to treat it as a collection
name = Fear.option(params[:name])
upper = name.map(&:strip).select { |n| n.length != 0 }.map(&:upcase)
puts upper.get_or_else('')
This allows for sophisticated chaining of Option
values without
having to check for the existence of a value.
A less-idiomatic way to use Option
values is via pattern matching
case Fear.option(params[:name])
in Fear::Some(name)
name.strip.upcase
in Fear::None
'No name value'
end
or manually checking for non emptiness
name = Fear.option(params[:name])
if name.empty?
puts 'No name value'
else
puts name.strip.upcase
end
Alternatively, you can use camel-case factory methods Fear::Option()
, Fear::Some()
and Fear::None
methods:
Fear::Option(42) #=> #<Fear::Some get=42>
Fear::Option(nil) #=> #<Fear::None>
Fear::Some(42) #=> #<Fear::Some get=42>
Fear::Some(nil) #=> #<Fear::Some get=nil>
Fear::None #=> #<Fear::None>
Option#get_or_else
Returns the value from this Some
or evaluates the given default argument if this is a None
.
Fear.some(42).get_or_else { 24/2 } #=> 42
Fear.none.get_or_else { 24/2 } #=> 12
Fear.some(42).get_or_else(12) #=> 42
Fear.none.get_or_else(12) #=> 12
Option#or_else
returns self Some
or the given alternative if this is a None
.
Fear.some(42).or_else { Fear.some(21) } #=> Fear.some(42)
Fear.none.or_else { Fear.some(21) } #=> Fear.some(21)
Fear.none.or_else { None } #=> None
Option#include?
Checks if Option
has an element that is equal (as determined by ==
) to given values.
Fear.some(17).include?(17) #=> true
Fear.some(17).include?(7) #=> false
Fear.none.include?(17) #=> false
Option#each
Performs the given block if this is a Some
.
Fear.some(17).each { |value| puts value } #=> prints 17
Fear.none.each { |value| puts value } #=> does nothing
Option#map
Maps the given block to the value from this Some
or returns self if this is a None
Fear.some(42).map { |v| v/2 } #=> Fear.some(21)
Fear.none.map { |v| v/2 } #=> None
Option#flat_map
Returns the given block applied to the value from this Some
or returns self if this is a None
Fear.some(42).flat_map { |v| Fear.some(v/2) } #=> Fear.some(21)
Fear.none.flat_map { |v| Fear.some(v/2) } #=> None
Option#any?
Returns false
if None
or returns the result of the application of the given predicate to the Some
value.
Fear.some(12).any? { |v| v > 10 } #=> true
Fear.some(7).any? { |v| v > 10 } #=> false
Fear.none.any? { |v| v > 10 } #=> false
Option#select
Returns self if it is nonempty and applying the predicate to this Option
's value returns true
. Otherwise,
return None
.
Fear.some(42).select { |v| v > 40 } #=> Fear.some(42)
Fear.some(42).select { |v| v < 40 } #=> None
Fear.none.select { |v| v < 40 } #=> None
Option#filter_map
Returns a new Some
of truthy results (everything except false
or nil
) of
running the block or None
otherwise.
Fear.some(42).filter_map { |v| v/2 if v.even? } #=> Fear.some(21)
Fear.some(42).filter_map { |v| v/2 if v.odd? } #=> Fear.none
Fear.some(42).filter_map { |v| false } #=> Fear.none
Fear.none.filter_map { |v| v/2 } #=> Fear.none
Option#reject
Returns Some
if applying the predicate to this Option
's value returns false
. Otherwise, return None
.
Fear.some(42).reject { |v| v > 40 } #=> None
Fear.some(42).reject { |v| v < 40 } #=> Fear.some(42)
Fear.none.reject { |v| v < 40 } #=> None
Option#get
Not an idiomatic way of using Option at all. Returns values of raise NoSuchElementError
error if option is empty.
Option#empty?
Returns true
if the Option
is None
, false
otherwise.
Fear.some(42).empty? #=> false
Fear.none.empty? #=> true
Option#blank?
Returns true
if the Option
is None
, false
otherwise.
Fear.some(42).blank? #=> false
Fear.none.blank? #=> true
Option#present?
Returns false
if the Option
is None
, true
otherwise.
Fear.some(42).present? #=> true
Fear.none.present? #=> false
Option#zip
Returns a Fear::Some
formed from this Option and another Option by combining the corresponding elements in a pair.
If either of the two options is empty, Fear::None
is returned.
Fear.some("foo").zip(Fear.some("bar")) #=> Fear.some(["foo", "bar"])
Fear.some("foo").zip(Fear.some("bar")) { |x, y| x + y } #=> Fear.some("foobar")
Fear.some("foo").zip(Fear.none) #=> Fear.none
Fear.none.zip(Fear.some("bar")) #=> Fear.none
@see https://github.com/scala/scala/blob/2.11.x/src/library/scala/Option.scala
Try (API Documentation)
The Try
represents a computation that may either result
in an exception, or return a successfully computed value. Instances of Try
,
are either an instance of Success
or Failure
.
For example, Try
can be used to perform division on a
user-defined input, without the need to do explicit
exception-handling in all of the places that an exception
might occur.
dividend = Fear.try { Integer(params[:dividend]) }
divisor = Fear.try { Integer(params[:divisor]) }
problem = dividend.flat_map { |x| divisor.map { |y| x / y } }
case problem
in Fear::Success(result)
puts "Result of #{dividend.get} / #{divisor.get} is: #{result}"
in Fear::Failure(ZeroDivisionError)
puts "Division by zero is not allowed"
in Fear::Failure(exception)
puts "You entered something wrong. Try again"
puts "Info from the exception: #{exception.}"
end
An important property of Try
shown in the above example is its
ability to pipeline, or chain, operations, catching exceptions
along the way. The flat_map
and map
combinators in the above
example each essentially pass off either their successfully completed
value, wrapped in the Success
type for it to be further operated
upon by the next combinator in the chain, or the exception wrapped
in the Failure
type usually to be simply passed on down the chain.
Combinators such as recover_with
and recover
are designed to provide some
type of default behavior in the case of failure.
NOTE: Only non-fatal exceptions are caught by the combinators on Try
.
Serious system errors, on the other hand, will be thrown.
Alternatively, include you can use camel-case factory method Fear::Try()
:
Fear::Try { 4/0 } #=> #<Fear::Failure exception=...>
Fear::Try { 4/2 } #=> #<Fear::Success value=2>
Try#get_or_else
Returns the value from this Success
or evaluates the given default argument if this is a Failure
.
Fear.success(42).get_or_else { 24/2 } #=> 42
Fear.failure(ArgumentError.new).get_or_else { 24/2 } #=> 12
Try#include?
Returns true
if it has an element that is equal given values, false
otherwise.
Fear.success(17).include?(17) #=> true
Fear.success(17).include?(7) #=> false
Fear.failure(ArgumentError.new).include?(17) #=> false
Try#each
Performs the given block if this is a Success
. If block raise an error,
then this method may raise an exception.
Fear.success(17).each { |value| puts value } #=> prints 17
Fear.failure(ArgumentError.new).each { |value| puts value } #=> does nothing
Try#map
Maps the given block to the value from this Success
or returns self if this is a Failure
.
Fear.success(42).map { |v| v/2 } #=> Fear.success(21)
Fear.failure(ArgumentError.new).map { |v| v/2 } #=> Fear.failure(ArgumentError.new)
Try#flat_map
Returns the given block applied to the value from this Success
or returns self if this is a Failure
.
Fear.success(42).flat_map { |v| Fear.success(v/2) } #=> Fear.success(21)
Fear.failure(ArgumentError.new).flat_map { |v| Fear.success(v/2) } #=> Fear.failure(ArgumentError.new)
Try#to_option
Returns an Some
containing the Success
value or a None
if this is a Failure
.
Fear.success(42).to_option #=> Fear.some(42)
Fear.failure(ArgumentError.new).to_option #=> None
Try#any?
Returns false
if Failure
or returns the result of the application of the given predicate to the Success
value.
Fear.success(12).any? { |v| v > 10 } #=> true
Fear.success(7).any? { |v| v > 10 } #=> false
Fear.failure(ArgumentError.new).any? { |v| v > 10 } #=> false
Try#success? and Try#failure?
Fear.success(12).success? #=> true
Fear.success(12).failure? #=> true
Fear.failure(ArgumentError.new).success? #=> false
Fear.failure(ArgumentError.new).failure? #=> true
Try#get
Returns the value from this Success
or raise the exception if this is a Failure
.
Fear.success(42).get #=> 42
Fear.failure(ArgumentError.new).get #=> ArgumentError: ArgumentError
Try#or_else
Returns self Try
if it's a Success
or the given alternative if this is a Failure
.
Fear.success(42).or_else { Fear.success(-1) } #=> Fear.success(42)
Fear.failure(ArgumentError.new).or_else { Fear.success(-1) } #=> Fear.success(-1)
Fear.failure(ArgumentError.new).or_else { Fear.try { 1/0 } } #=> Fear.failure(ZeroDivisionError.new('divided by 0'))
Try#flatten
Transforms a nested Try
, ie, a Success
of Success
, into an un-nested Try
, ie, a Success
.
Fear.success(42).flatten #=> Fear.success(42)
Fear.success(Fear.success(42)).flatten #=> Fear.success(42)
Fear.success(Fear.failure(ArgumentError.new)).flatten #=> Fear.failure(ArgumentError.new)
Fear.failure(ArgumentError.new).flatten { -1 } #=> Fear.failure(ArgumentError.new)
Try#select
Converts this to a Failure
if the predicate is not satisfied.
Fear.success(42).select { |v| v > 40 }
#=> Fear.success(42)
Fear.success(42).select { |v| v < 40 }
#=> Fear.failure(Fear::NoSuchElementError.new("Predicate does not hold for 42"))
Fear.failure(ArgumentError.new).select { |v| v < 40 }
#=> Fear.failure(ArgumentError.new)
Recovering from errors
There are two ways to recover from the error. Try#recover_with
method is like flat_map
for the exception. And
you can pattern match against the error!
Fear.success(42).recover_with do |m|
m.case(ZeroDivisionError) { Fear.success(0) }
end #=> Fear.success(42)
Fear.failure(ArgumentError.new).recover_with do |m|
m.case(ZeroDivisionError) { Fear.success(0) }
m.case(ArgumentError) { |error| Fear.success(error.class.name) }
end #=> Fear.success('ArgumentError')
If the block raises error, this new error returned as an result
Fear.failure(ArgumentError.new).recover_with do
raise
end #=> Fear.failure(RuntimeError)
The second possibility for recovery is Try#recover
method. It is like map
for the exception. And it's also heavely
relies on pattern matching.
Fear.success(42).recover do |m|
m.case(&:message)
end #=> Fear.success(42)
Fear.failure(ArgumentError.new).recover do |m|
m.case(ZeroDivisionError) { 0 }
m.case(&:message)
end #=> Fear.success('ArgumentError')
If the block raises an error, this new error returned as an result
Fear.failure(ArgumentError.new).recover do |m|
raise
end #=> Fear.failure(RuntimeError)
Try#to_either
Returns Left
with exception if this is a Failure
, otherwise returns Right
with Success
value.
Fear.success(42).to_either #=> Fear.right(42)
Fear.failure(ArgumentError.new).to_either #=> Fear.left(ArgumentError.new)
Either (API Documentation)
Represents a value of one of two possible types (a disjoint union.)
An instance of Either
is either an instance of Left
or Right
.
A common use of Either
is as an alternative to Option
for dealing
with possible missing values. In this usage, None
is replaced
with a Left
which can contain useful information.
Right
takes the place of Some
. Convention dictates
that Left
is used for failure and Right
is used for Right.
For example, you could use Either<String, Fixnum>
to #select_or_else
whether a
received input is a +String+ or an +Fixnum+.
in = Readline.readline('Type Either a string or an Int: ', true)
result = begin
Fear.right(Integer(in))
rescue ArgumentError
Fear.left(in)
end
case result
in Fear::Right(x)
"You passed me the Int: #{x}, which I will increment. #{x} + 1 = #{x+1}"
in Fear::Left(x)
"You passed me the String: #{x}"
end
Either is right-biased, which means that Right
is assumed to be the default case to
operate on. If it is Left
, operations like #map
, #flat_map
, ... return the Left
value
unchanged.
Alternatively, you can use camel-case factory methods Fear::Left()
, and Fear::Right()
:
Fear::Left(42) #=> #<Fear::Left value=42>
Fear::Right(42) #=> #<Fear::Right value=42>
Either#get_or_else
Returns the value from this Right
or evaluates the given default argument if this is a Left
.
Fear.right(42).get_or_else { 24/2 } #=> 42
Fear.left('undefined').get_or_else { 24/2 } #=> 12
Fear.right(42).get_or_else(12) #=> 42
Fear.left('undefined').get_or_else(12) #=> 12
Either#or_else
Returns self Right
or the given alternative if this is a Left
.
Fear.right(42).or_else { Fear.right(21) } #=> Fear.right(42)
Fear.left('unknown').or_else { Fear.right(21) } #=> Fear.right(21)
Fear.left('unknown').or_else { Fear.left('empty') } #=> Fear.left('empty')
Either#include?
Returns true
if Right
has an element that is equal to given value, false
otherwise.
Fear.right(17).include?(17) #=> true
Fear.right(17).include?(7) #=> false
Fear.left('undefined').include?(17) #=> false
Either#each
Performs the given block if this is a Right
.
Fear.right(17).each { |value| puts value } #=> prints 17
Fear.left('undefined').each { |value| puts value } #=> does nothing
Either#map
Maps the given block to the value from this Right
or returns self if this is a Left
.
Fear.right(42).map { |v| v/2 } #=> Fear.right(21)
Fear.left('undefined').map { |v| v/2 } #=> Fear.left('undefined')
Either#flat_map
Returns the given block applied to the value from this Right
or returns self if this is a Left
.
Fear.right(42).flat_map { |v| Fear.right(v/2) } #=> Fear.right(21)
Fear.left('undefined').flat_map { |v| Fear.right(v/2) } #=> Fear.left('undefined')
Either#to_option
Returns an Some
containing the Right
value or a None
if this is a Left
.
Fear.right(42).to_option #=> Fear.some(42)
Fear.left('undefined').to_option #=> Fear::None
Either#any?
Returns false
if Left
or returns the result of the application of the given predicate to the Right
value.
Fear.right(12).any? { |v| v > 10 } #=> true
Fear.right(7).any? { |v| v > 10 } #=> false
Fear.left('undefined').any? { |v| v > 10 } #=> false
Either#right?, Either#success?
Returns true
if this is a Right
, false
otherwise.
Fear.right(42).right? #=> true
Fear.left('err').right? #=> false
Either#left?, Either#failure?
Returns true
if this is a Left
, false
otherwise.
Fear.right(42).left? #=> false
Fear.left('err').left? #=> true
Either#select_or_else
Returns Left
of the default if the given predicate does not hold for the right value, otherwise,
returns Right
.
Fear.right(12).select_or_else(-1, &:even?) #=> Fear.right(12)
Fear.right(7).select_or_else(-1, &:even?) #=> Fear.left(-1)
Fear.left(12).select_or_else(-1, &:even?) #=> Fear.left(12)
Fear.left(12).select_or_else(-> { -1 }, &:even?) #=> Fear.left(12)
Either#select
Returns Left
of value if the given predicate does not hold for the right value, otherwise, returns Right
.
Fear.right(12).select(&:even?) #=> Fear.right(12)
Fear.right(7).select(&:even?) #=> Fear.left(7)
Fear.left(12).select(&:even?) #=> Fear.left(12)
Fear.left(7).select(&:even?) #=> Fear.left(7)
Either#reject
Returns Left
of value if the given predicate holds for the right value, otherwise, returns Right
.
Fear.right(12).reject(&:even?) #=> Fear.left(12)
Fear.right(7).reject(&:even?) #=> Fear.right(7)
Fear.left(12).reject(&:even?) #=> Fear.left(12)
Fear.left(7).reject(&:even?) #=> Fear.left(7)
Either#swap
If this is a Left
, then return the left value in Right
or vice versa.
Fear.left('left').swap #=> Fear.right('left')
Fear.right('right').swap #=> Fear.left('left')
Either#left
Projects this Fear::Either
as a Fear::Left
.
This allows performing right-biased operation of the left
side of the Fear::Either
.
Fear.left(42).left.map(&:succ) #=> Fear.left(43)
Fear.right(42).left.map(&:succ) #=> Fear.left(42)
Fear.left(42).left.select(&:even?) #=> Fear.left(42)
Fear.right(42).left.select(&:odd?) #=> Fear.right(42)
Either#reduce
Applies reduce_left
if this is a Left
or reduce_right
if this is a Right
.
result = possibly_failing_operation()
log(
result.reduce(
->(ex) { "Operation failed with #{ex}" },
->(v) { "Operation produced value: #{v}" },
)
)
Either#join_right
Joins an Either
through Right
. This method requires that the right side of this Either
is itself an
Either
type. This method, and join_left
, are analogous to Option#flatten
Fear.right(Fear.right(12)).join_right #=> Fear.right(12)
Fear.right(Fear.left("flower")).join_right #=> Fear.left("flower")
Fear.left("flower").join_right #=> Fear.left("flower")
Fear.left(Fear.right("flower")).join_right #=> Fear.left(Fear.right("flower"))
Either#join_left
Joins an Either
through Left
. This method requires that the left side of this Either
is itself an
Either
type. This method, and join_right
, are analogous to Option#flatten
Fear.left(Fear.right("flower")).join_left #=> Fear.right("flower")
Fear.left(Fear.left(12)).join_left #=> Fear.left(12)
Fear.right("daisy").join_left #=> Fear.right("daisy")
Fear.right(Fear.left("daisy")).join_left #=> Fear.right(Fear.left("daisy"))
Future (API Documentation)
Asynchronous computations that yield futures are created
with the Fear.future
call
success = "Hello"
f = Fear.future { success + ' future!' }
f.on_success do |result|
puts result
end
Multiple callbacks may be registered; there is no guarantee that they will be executed in a particular order.
The future may contain an exception and this means that the future failed. Futures obtained through combinators have the same error as the future they were obtained from.
f = Fear.future { 5 }
g = Fear.future { 3 }
f.flat_map do |x|
g.map { |y| x + y }
end
Futures use Concurrent::Promise
under the hood. Fear.future
accepts optional configuration Hash passed directly to underlying promise. For example,
run it on custom thread pool.
require 'open-uri'
pool = Concurrent::FixedThreadPool.new(5)
future = Fear.future(executor: pool) { open('https://example.com/') }
future.map(&:read).each do |body|
puts "#{body}"
end
Futures support common monadic operations -- #map
, #flat_map
, and #each
. That's why it's possible to combine them
using Fear.for
, It returns the Future containing Success of 5 + 3
eventually.
f = Fear.future { 5 }
g = Fear.future { 3 }
Fear.for(f, g) do |x, y|
x + y
end
Future goes with the number of callbacks. You can register several callbacks, but the order of execution isn't guaranteed
f = Fear.future { ... } # call external service
f.on_success do |result|
# handle service response
end
f.on_failure do |error|
# handle exception
end
or you can wait for Future completion
f.on_complete do |result|
result.match do |m|
m.success { |value| ... }
m.failure { |error| ... }
end
end
In sake of convenience #on_success
callback aliased as #each
.
It's possible to get future value directly, but since it may be incomplete, #value
method returns Fear::Option
. So,
there are three possible responses:
future.value #=>
# Fear::Some<Fear::Success> #=> future completed with value
# Fear::Some<Fear::Failure> #=> future completed with error
# Fear::None #=> future not yet completed
There is a variety of methods to manipulate with futures.
Fear.future { open('http://example.com').read }
.transform(
->(value) { ... },
->(error) { ... },
)
future = Fear.future { 5 }
future.select(&:odd?) # evaluates to Fear.success(5)
future.select(&:even?) # evaluates to Fear.error(NoSuchElementError)
You can zip several asynchronous computations into one future. For you can call two external services and then zip the results into one future containing array of both responses:
future1 = Fear.future { call_service1 }
future1 = Fear.future { call_service2 }
future1.zip(future2)
It returns the same result as Fear.future { [call_service1, call_service2] }
, but the first version performs
two simultaneous calls.
There are two ways to recover from failure. Future#recover
is live #map
for failures:
Fear.future { 2 / 0 }.recover do |m|
m.case(ZeroDivisionError) { 0 }
end #=> returns new future of Fear.success(0)
If the future resolved to success or recovery matcher did not matched, it returns the future Fear::Failure
.
The second option is Future#fallback_to
method. It allows to fallback to result of another future in case of failure
future = Fear.future { fail 'error' }
fallback = Fear.future { 5 }
future.fallback_to(fallback) # evaluates to 5
You can run callbacks in specific order using #and_then
method:
f = Fear.future { 5 }
f.and_then do
fail 'runtime error'
end.and_then do |m|
m.success { |value| puts value } # it evaluates this branch
m.failure { |error| puts error.massage }
end
Testing future values
Sometimes it may be helpful to await for future completion. You can await either future, or result. Don't forget to pass timeout in seconds:
future = Fear.future { 42 }
Fear::Await.result(future, 3) #=> 42
Fear::Await.ready(future, 3) #=> Fear::Future.successful(42)
For composition (API Documentation)
Provides syntactic sugar for composition of multiple monadic operations.
It supports two such operations - flat_map
and map
. Any class providing them
is supported by For
.
Fear.for(Fear.some(2), Fear.some(3)) do |a, b|
a * b
end #=> Fear.some(6)
If one of operands is None, the result is None
Fear.for(Fear.some(2), None) do |a, b|
a * b
end #=> None
Fear.for(None, Fear.some(2)) do |a, b|
a * b
end #=> None
Lets look at first example:
Fear.for(Fear.some(2), None) do |a, b|
a * b
end #=> None
it is translated to:
Fear.some(2).flat_map do |a|
Fear.some(3).map do |b|
a * b
end
end
It works with arrays as well
Fear.for([1, 2], [2, 3], [3, 4]) { |a, b, c| a * b * c }
#=> [6, 8, 9, 12, 12, 16, 18, 24]
it is translated to:
[1, 2].flat_map do |a|
[2, 3].flat_map do |b|
[3, 4].map do |c|
a * b * c
end
end
end
If you pass lambda as a variable value, it would be evaluated only on demand.
Fear.for(proc { None }, proc { raise 'kaboom' } ) do |a, b|
a * b
end #=> None
It does not fail since b
is not evaluated.
You can refer to previously defined variables from within lambdas.
maybe_user = find_user('Paul') #=> <#Option value=<#User ...>>
Fear.for(maybe_user, ->(user) { user.birthday }) do |user, birthday|
"#{user.name} was born on #{birthday}"
end #=> Fear.some('Paul was born on 1987-06-17')
Pattern Matching (API Documentation)
Syntax
To pattern match against a value, use Fear.match
function, and provide at least one case clause:
x = Random.rand(10)
Fear.match(x) do |m|
m.case(0) { 'zero' }
m.case(1) { 'one' }
m.case(2) { 'two' }
m.else { 'many' }
end
The x
above is a random integer from 0 to 10. The last clause else
is a “catch all” case
for anything other than 0
, 1
, and 2
. If you want to ensure that an Integer value is passed,
matching against type available:
Fear.match(x) do |m|
m.case(Integer, 0) { 'zero' }
m.case(Integer, 1) { 'one' }
m.case(Integer, 2) { 'two' }
m.case(Integer) { 'many' }
end
Providing something other than Integer will raise Fear::MatchError
error.
Pattern guards
You can use whatever you want as a pattern guard, if it respond to #===
method to to make cases more specific.
m.case(20..40) { |m| "#{m} is within range" }
m.case(->(x) { x > 10}) { |m| "#{m} is greater than 10" }
m.case(:even?.to_proc) { |x| "#{x} is even" }
m.case(:odd?.to_proc) { |x| "#{x} is odd" }
It's also possible to create matcher and use it several times:
matcher = Fear.matcher do |m|
m.case(Integer) { |n| "#{n} is a number" }
m.case(String) { |n| "#{n} is a string" }
m.else { |n| "#{n} is a #{n.class}" }
end
matcher.(42) #=> "42 is a number"
matcher.(10..20) #=> "10..20 is a Range"
How to debug pattern extractors?
You can build pattern manually and ask for failure reason:
Fear['Some([:err, 444])'].failure_reason(Fear.some([:err, 445]))
# =>
Expected `445` to match:
Some([:err, 444])
~~~~~~~~~~~~^
by the way you can also match against such pattern
Fear['Some([:err, 444])'] === Fear.some([:err, 445]) #=> false
Fear['Some([:err, 444])'] === Fear.some([:err, 445]) #=> true
More examples
Factorial using pattern matching
factorial = Fear.matcher do |m|
m.case(->(n) { n <= 1} ) { 1 }
m.else { |n| n * factorial.(n - 1) }
end
factorial.(10) #=> 3628800
Fibonacci number
fibonacci = Fear.matcher do |m|
m.case(0) { 0 }
m.case(1) { 1 }
m.case(->(n) { n > 1}) { |n| fibonacci.(n - 1) + fibonacci.(n - 2) }
end
fibonacci.(10) #=> 55
Binary tree set implemented using pattern matching https://gist.github.com/bolshakov/3c51bbf7be95066d55d6d1ac8c605a1d
Monads pattern matching
You can use Option#match
, Either#match
, and Try#match
method. It performs matching not
only on container itself, but on enclosed value as well.
Pattern match against an Option
Fear.some(42).match do |m|
m.some { |x| x * 2 }
m.none { 'none' }
end #=> 84
pattern match on enclosed value
Fear.some(41).match do |m|
m.some(:even?.to_proc) { |x| x / 2 }
m.some(:odd?.to_proc, ->(v) { v > 0 }) { |x| x * 2 }
m.none { 'none' }
end #=> 82
it raises Fear::MatchError
error if nothing matched. To avoid exception, you can pass #else
branch
Fear.some(42).match do |m|
m.some(:odd?.to_proc) { |x| x * 2 }
m.else { 'nothing' }
end #=> nothing
Pattern matching works the similar way for Either
and Try
monads.
In sake of performance, you may want to generate pattern matching function and reuse it multiple times:
matcher = Fear::Option.matcher do |m|
m.some(42) { 'Yep' }
m.some { 'Nope' }
m.none { 'Error' }
end
matcher.(Fear.some(42)) #=> 'Yep'
matcher.(Fear.some(40)) #=> 'Nope'
Under the hood
Pattern matcher is a combination of partial functions wrapped into nice DSL. Every partial function defined on domain described with a guard.
pf = Fear.case(Integer) { |x| x / 2 }
pf.defined_at?(4) #=> true
pf.defined_at?('Foo') #=> false
pf.call('Foo') #=> raises Fear::MatchError
pf.call_or_else('Foo') { 'not a number' } #=> 'not a number'
pf.call_or_else(4) { 'not a number' } #=> 2
pf.lift.call('Foo') #=> Fear::None
pf.lift.call(4) #=> Fear.some(2)
It uses #===
method under the hood, so you can pass:
- Class to check kind of an object.
- Lambda to evaluate it against an object.
- Any literal, like
4
,"Foobar"
,:not_found
etc. - Qo matcher --
m.case(Qo[name: 'John']) { .... }
Partial functions may be combined with each other:
is_even = Fear.case(->(arg) { arg % 2 == 0}) { |arg| "#{arg} is even" }
is_odd = Fear.case(->(arg) { arg % 2 == 1}) { |arg| "#{arg} is odd" }
(10..20).map(&is_even.or_else(is_odd))
to_integer = Fear.case(String, &:to_i)
integer_two_times = Fear.case(Integer) { |x| x * 2 }
two_times = to_integer.and_then(integer_two_times).or_else(integer_two_times)
two_times.(4) #=> 8
two_times.('42') #=> 84
Since matcher is just a syntactic sugar for partial functions, you can combine matchers with partial functions and each other.
handle_numbers = Fear.case(Integer, &:itself).and_then(
Fear.matcher do |m|
m.case(0) { 'zero' }
m.case(->(n) { n < 10 }) { 'smaller than ten' }
m.case(->(n) { n > 10 }) { 'bigger than ten' }
end
)
handle_strings = Fear.case(String, &:itself).and_then(
Fear.matcher do |m|
m.case('zero') { 0 }
m.case('one') { 1 }
m.else { 'unexpected' }
end
)
handle = handle_numbers.or_else(handle_strings)
handle.(0) #=> 'zero'
handle.(12) #=> 'bigger than ten'
handle.('one') #=> 1
Native pattern-matching
Starting from ruby 2.7 you can use native pattern matching capabilities:
case Fear.some(42)
in Fear::Some(x)
x * 2
in Fear::None
'none'
end #=> 84
case Fear.some(41)
in Fear::Some(x) if x.even?
x / 2
in Fear::Some(x) if x.odd? && x > 0
x * 2
in Fear::None
'none'
end #=> 82
case Fear.some(42)
in Fear::Some(x) if x.odd?
x * 2
else
'nothing'
end #=> nothing
It's possible to pattern match against Fear::Either and Fear::Try as well:
case either
in Fear::Right(Integer | String => x)
"integer or string: #{x}"
in Fear::Left(String => error_code) if error_code = :not_found
'not found'
end
case Fear.try { 10 / x }
in Fear::Failure(ZeroDivisionError)
# ..
in Fear::Success(x)
# ..
end
Dry-Types integration
To use Fear::Option
as optional type for Dry::Types
use the dry-types-fear gem.
Testing
To simplify testing, you may use fear-rspec gem. It provides a bunch of rspec matchers.
Contributing
- Fork it ( https://github.com/bolshakov/fear/fork )
- Create your feature branch (
git checkout -b my-new-feature
) - Commit your changes (
git commit -am 'Add some feature'
) - Push to the branch (
git push origin my-new-feature
) - Create a new Pull Request