sealed abstract class Or[+G, +B] extends Product with Serializable
Represents a value that is one of two possible types, with one type being “good” and the other “bad.”
An Or
will either be a “good” value wrapped in an instance of
Good
or a “bad” value wrapped in an instance
of Bad
.
The motivation for Or
Or
differs from Scala's Either
type in that
Either
treats both its Left
and Right
alternatives in an identical manner, whereas
Or
treats its two alternatives differently: it favors
Good
over Bad
.
Because of this, it is more convenient to work with Or
s
when you prefer one alternative over the other; for example, if one alternative represents a valid result
and another represents an error.
To illustrate, imagine you want to create instances this Person
class from user input strings:
case class Person(name: String, age: Int)
You might write a method that parses the name from user input string and returns an
Option[String]
: None
if the string is empty or blank, else the
trimmed string wrapped in a Some
:
def parseName(input: String): Option[String] = { val trimmed = input.trim if (!trimmed.isEmpty) Some(trimmed) else None }
You might also write a method that parses the age from user input string and returns an
Option[Int]
: None
if either the string is not a valid integer or
it is a negative integer, else the string converted to an integer wrapped in a Some
:
def parseAge(input: String): Option[Int] = { try { val age = input.trim.toInt if (age >= 0) Some(age) else None } catch { case _: NumberFormatException => None } }
With these building blocks you could write a method that parses name and age input
strings and returns either a Person
, wrapped in a Some
, or
None
if either the name or age, or both, was invalid:
def parsePerson(inputName: String, inputAge: String): Option[Person] = for { name <- parseName(inputName) age <- parseAge(inputAge) } yield Person(name, age)
Here are some examples of invoking parsePerson
:
parsePerson("Bridget Jones", "29") // Result: Some(Person(Bridget Jones,29))
parsePerson("Bridget Jones", "") // Result: None
parsePerson("Bridget Jones", "-29") // Result: None
parsePerson("", "") // Result: None
Now imagine you want to give an error message back if the user's input is invalid.
You might rewrite the parsing methods to return an Either
instead. In this
case, the desired result is a valid name or age, which by convention should be placed
on the right of the Either
. The left will be a String
error
message. Here's the new parseName
function, which returns an Either[String, String]
:
def parseName(input: String): Either[String, String] = { val trimmed = input.trim if (!trimmed.isEmpty) Right(trimmed) else Left(s""""${input}" is not a valid name""") }
And here's the new parseAge
function, which returns an Either[String, Int]
:
def parseAge(input: String): Either[String, Int] = { try { val age = input.trim.toInt if (age >= 0) Right(age) else Left(s""""${age}" is not a valid age""") } catch { case _: NumberFormatException => Left(s""""${input}" is not a valid integer""") } }
The new parsePerson
method will return an Either[String, Person]
:
def parsePerson(inputName: String, inputAge: String): Either[String, Person] = for { name <- parseName(inputName).right age <- parseAge(inputAge).right } yield Person(name, age)
Note that Either
requires you to add .right
at the end of each generator in the for
expression. Although the convention is to place the
valid result on the right, you must explicitly (and repetitively) indicate that you've done so by transforming
the Either
to a RightProjection
by invoking .right
at each step.
Given this implementation, the parsePerson
method will now short-circuit at the first sign
of trouble (as it did when we used an Option
), but you now get the first error message returned
in a Left
. Here are some examples:
parsePerson("Bridget Jones", "29") // Result: Right(Person(Bridget Jones,29))
parsePerson("Bridget Jones", "") // Result: Left("" is not a valid integer)
parsePerson("Bridget Jones", "-29") // Result: Left("-29" is not a valid age)
parsePerson("", "") // Result: Left("" is not a valid name)
An Either
with “attitude”
Because Or
declares one alternative to be “good” and the other “bad,”
it is more convenient than Either
in this kind of situation. One difference to note with
Or
is that the Good
alternative is on the left, Bad
on the right.
The reason is that Or
is designed to be written using infix notation, and placing the
“happy path” first is more readable. For example, instead of writing:
Or[Int, ErrorMessage]
You can write:
Int Or ErrorMessage
Here's how the parseName
method might be written using an Or
, where
ErrorMessage
is a type alias for String
declared in the org.scalactic
package object:
import org.scalactic._
def parseName(input: String): String Or ErrorMessage = { val trimmed = input.trim if (!trimmed.isEmpty) Good(trimmed) else Bad(s""""${input}" is not a valid name""") }
You can think of the String
Or
ErrorMessage
result
type like this:
TheparseName
method will return a nameString
or, if the input string is not a valid name, anErrorMessage
.
Here's how the parseAge
method might be written:
def parseAge(input: String): Int Or ErrorMessage = { try { val age = input.trim.toInt if (age >= 0) Good(age) else Bad(s""""${age}" is not a valid age""") } catch { case _: NumberFormatException => Bad(s""""${input}" is not a valid integer""") } }
Given these implementations, here's how you'd write the parsePerson
method:
def parsePerson(inputName: String, inputAge: String): Person Or ErrorMessage = for { name <- parseName(inputName) age <- parseAge(inputAge) } yield Person(name, age)
Because of Or
's attitude, you need not write .good
at the end of
each generator. Or
will keep going so long as each step produces a Good
,
short circuiting at the first sign of a Bad
. Here are a few invocations of this
parsePerson
method:
parsePerson("Bridget Jones", "29") // Result: Good(Person(Bridget Jones,29))
parsePerson("Bridget Jones", "") // Result: Bad("" is not a valid integer)
parsePerson("Bridget Jones", "-29") // Result: Bad("-29" is not a valid age)
parsePerson("", "") // Result: Bad("" is not a valid name)
Accumulating errors with Or
Another difference between Or
and Either
is that Or
enables
you to accumulate errors if the Bad
type is an Every
.
An Every
is similar to a Seq
in that it contains ordered elements, but
different from Seq
in that it cannot be empty. An Every
is
either a One
,
which contains one and only one element, or a Many
, which contains two or
more elements.
Note: an Or
whose Bad
type is an Every
, or one of its subtypes,
is called an “accumulating Or
.”
To rewrite the previous example so that errors can be accumulated, you need first to return an Every
as the Bad
type. Here's how you'd change the parseName
method:
def parseName(input: String): String Or One[ErrorMessage] = { val trimmed = input.trim if (!trimmed.isEmpty) Good(trimmed) else Bad(One(s""""${input}" is not a valid name""")) }
Because parseName
will either return a valid name String
wrapped in a
Good
, or one error message, wrapped in a Bad
, you would write the
Bad
type as One[ErrorMessage]
. The same is true for parseAge
:
def parseAge(input: String): Int Or One[ErrorMessage] = { try { val age = input.trim.toInt if (age >= 0) Good(age) else Bad(One(s""""${age}" is not a valid age""")) } catch { case _: NumberFormatException => Bad(One(s""""${input}" is not a valid integer""")) } }
Because a for
expression short-circuits on the first Bad
encountered, you'll
need to use a different approach to write the parsePerson
method. In this example, the
withGood
method from trait Accumulation
will do the trick:
import Accumulation._
def parsePerson(inputName: String, inputAge: String): Person Or Every[ErrorMessage] = { val name = parseName(inputName) val age = parseAge(inputAge) withGood(name, age) { Person(_, _) } }
Trait Accumulation
offers overloaded withGood
methods that take 1 to
22 accumulating Or
s, plus a function taking the same number of corresponding
Good
values. In this example, if both name
and age
are
Good
s, the withGood
method will pass the good name String
and age Int
to the Person(_, _)
function, and return the resulting Person
object wrapped in a Good
. If either name
and age
, or both,
are Bad
, withGood
will return the accumulated errors in a Bad
.
The result of parsePerson
, if Bad
, will therefore contain either one or two
error messages, i.e., the result will either be a One
or a Many
.
As a result, the result type of parsePerson
must be Person
Or
Every[ErrorMessage]
. Regardless of whether a Bad
result contains one
or two error messages, it will contain every error message. Here's some invocations of
this accumulating version of parsePerson
:
parsePerson("Bridget Jones", "29") // Result: Good(Person(Bridget Jones,29))
parsePerson("Bridget Jones", "") // Result: Bad(One("" is not a valid integer))
parsePerson("Bridget Jones", "-29") // Result: Bad(One("-29" is not a valid age))
parsePerson("", "") // Result: Bad(Many("" is not a valid name, "" is not a valid integer))
Note that in the last example, the Bad
contains an error message for both name and age.
Other ways to accumulate errors
The Accumlation
trait also enables other ways of accumulating errors.
Using combined
If you have a collection of
accumulating Or
s, for example, you can combine them into one Or
using combined
, like this:
List(parseAge("29"), parseAge("30"), parseAge("31")).combined // Result: Good(List(29, 30, 31))
List(parseAge("29"), parseAge("-30"), parseAge("31")).combined // Result: Bad(One("-30" is not a valid age))
List(parseAge("29"), parseAge("-30"), parseAge("-31")).combined // Result: Bad(Many("-30" is not a valid age, "-31" is not a valid age))
Using validatedBy
Or if you have a collection of values and a function that transforms that type of value into an accumulating
Or
s, you can validate the values using the function using validatedBy
, like this:
List("29", "30", "31").validatedBy(parseAge) // Result: Good(List(29, 30, 31))
List("29", "-30", "31").validatedBy(parseAge) // Result: Bad(One("-30" is not a valid age))
List("29", "-30", "-31").validatedBy(parseAge) // Result: Bad(Many("-30" is not a valid age, "-31" is not a valid age))
Using zip
You can also zip two accumulating Or
s together. If both are Good
, you'll get a
Good
tuple containin both original Good
values. Otherwise, you'll get a Bad
containing every error message. Here are some examples:
parseName("Dude") zip parseAge("21") // Result: Good((Dude,21))
parseName("Dude") zip parseAge("-21") // Result: Bad(One("-21" is not a valid age))
parseName("") zip parseAge("-21") // Result: Bad(Many("" is not a valid name, "-21" is not a valid age))
Using when
In addition, given an accumlating Or
, you can pass one or more validation functions to when
on the Or
to submit that Or
to further scrutiny. A validation function accepts a Good
type and returns a Validation[E]
,
where E
is the type in the Every
in the Bad
type. For an Int
Or
One[ErrorMessage]
, for example
the validation function type would be Int
=>
Validation[ErrorMessage]
. Here are a few examples:
def isRound(i: Int): Validation[ErrorMessage] = if (i % 10 == 0) Pass else Fail(i + " was not a round number")
def isDivBy3(i: Int): Validation[ErrorMessage] = if (i % 3 == 0) Pass else Fail(i + " was not divisible by 3")
If the Or
on which you call when
is already Bad
, you get the same (Bad
) Or
back, because
no Good
value exists to pass to the valiation functions:
parseAge("-30").when(isRound, isDivBy3) // Result: Bad(One("-30" is not a valid age))
If the Or
on which you call when
is Good
, and also passes all the validation functions (i.e., the
all return None
), you again get the same Or
back, but this time, a Good
one:
parseAge("30").when(isRound, isDivBy3) // Result: Good(30)
If one or more of the validation functions fails, however, you'll get a Bad
back contining every error. Here are some examples:
parseAge("33").when(isRound, isDivBy3) // Result: Bad(One(33 was not a round number))
parseAge("20").when(isRound, isDivBy3) // Result: Bad(One(20 was not divisible by 3))
parseAge("31").when(isRound, isDivBy3) // Result: Bad(Many(31 was not a round number, 31 was not divisible by 3))
Note that you can use when
to accumulate errors in a for
expression involving an accumulating Or
, like this:
for (age <- parseAge("-30") when (isRound, isDivBy3)) yield age // Result: Bad(One("-30" is not a valid age))
for (age <- parseAge("30") when (isRound, isDivBy3)) yield age // Result: Good(30)
for (age <- parseAge("33") when (isRound, isDivBy3)) yield age // Result: Bad(One(33 was not a round number))
for (age <- parseAge("20") when (isRound, isDivBy3)) yield age // Result: Bad(One(20 was not divisible by 3))
for (age <- parseAge("31") when (isRound, isDivBy3)) yield age // Result: Bad(Many(31 was not a round number, 31 was not divisible by 3))
Much ado about Nothing
Because Or
has two types, but each of its two subtypes only takes a value of one or the other type, the Scala compiler will
infer Nothing
for the unspecified type:
scala> Good(3) res0: org.scalactic.Good[Int,Nothing] = Good(3) scala> Bad("oops") res1: org.scalactic.Bad[Nothing,String] = Bad(oops)
Often Nothing
will work fine, as it will be widened as soon as the compiler encounters a more specific type.
Sometimes, however, you may need to specify it. In such situations you can use this syntax:
scala> Good(3).orBad[String] res2: org.scalactic.Good[Int,String] = Good(3) scala> Good[Int].orBad("oops") res3: org.scalactic.Bad[Int,String] = Bad(oops)
If you want to specify both types, because you don't like the inferred type, you can do so like this:
scala> Good[AnyVal, String](3) res4: org.scalactic.Good[AnyVal,String] = Good(3) scala> Bad[Int, ErrorMessage]("oops") res5: org.scalactic.Bad[Int,org.scalactic.ErrorMessage] = Bad(oops)
But you may find the code is clearer if you instead use a type ascription, like this:
scala> Good(3): AnyVal Or String res6: org.scalactic.Or[AnyVal,String] = Good(3) scala> Bad("oops"): Int Or ErrorMessage res7: org.scalactic.Or[Int,org.scalactic.ErrorMessage] = Bad(oops)
Note: The Or
hierarchy was inspired in part by the disjoint union (\/
) and Validation
types of
scalaz
, the ProcessResult
type of
Typesafe Activator, and the Result
type of
ScalaKittens.
- Source
- Or.scala
- Alphabetic
- By Inheritance
- Or
- Serializable
- Serializable
- Product
- Equals
- AnyRef
- Any
- Hide All
- Show All
- Public
- All
Abstract Value Members
-
abstract
def
accumulating: Or[G, One[B]]
Converts this
Or
to anOr
with the sameGood
type and aBad
type consisting ofOne
parameterized by thisOr
'sBad
type.Converts this
Or
to anOr
with the sameGood
type and aBad
type consisting ofOne
parameterized by thisOr
'sBad
type.For example, invoking the
accumulating
method on anInt Or ErrorMessage
would convert it to anInt Or One[ErrorMessage]
. This result type, because theBad
type is anEvery
, can be used with the mechanisms provided in traitAccumulation
to accumulate errors.Note that if this
Or
is already an accumulatingOr
, the behavior of thisaccumulating
method does not change. For example, if you invokeaccumulating
on anInt Or One[ErrorMessage]
you will be rewarded with anInt Or One[One[ErrorMessage]]
.- returns
this
Good
, if thisOr
is aGood
; or thisBad
value wrapped in aOne
if thisOr
is aBad
.
-
abstract
def
badMap[C](f: (B) ⇒ C): Or[G, C]
Maps the given function to this
Or
's value if it is aBad
or returnsthis
if it is aGood
.Maps the given function to this
Or
's value if it is aBad
or returnsthis
if it is aGood
.- f
the function to apply
- returns
if this is a
Bad
, the result of applying the given function to the contained value wrapped in aBad
, else thisGood
is returned
-
abstract
def
canEqual(that: Any): Boolean
- Definition Classes
- Equals
-
abstract
def
exists(p: (G) ⇒ Boolean): Boolean
Returns
true
if thisOr
is aGood
and the predicatep
returns true when applied to thisGood
's value.Returns
true
if thisOr
is aGood
and the predicatep
returns true when applied to thisGood
's value.Note: The
exists
method will return the same result asforall
if thisOr
is aGood
, but the opposite result if thisOr
is aBad
.- p
the predicate to apply to the
Good
value, if this is aGood
- returns
the result of applying the passed predicate
p
to theGood
value, if this is aGood
, elsefalse
-
abstract
def
filter[C >: B](f: (G) ⇒ Validation[C]): Or[G, C]
Returns this
Or
if either 1) it is aBad
or 2) it is aGood
and applying the validation functionf
to thisGood
's value returnsPass
; otherwise, returns a newBad
containing the error value contained in theFail
resulting from applying the validation functionf
to thisGood
's value.Returns this
Or
if either 1) it is aBad
or 2) it is aGood
and applying the validation functionf
to thisGood
's value returnsPass
; otherwise, returns a newBad
containing the error value contained in theFail
resulting from applying the validation functionf
to thisGood
's value.For examples of
filter
used infor
expressions, see the main documentation for traitValidation
.- f
the validation function to apply
- returns
a
Good
if thisOr
is aGood
that passes the validation function, else aBad
.
-
abstract
def
flatMap[H, C >: B](f: (G) ⇒ Or[H, C]): Or[H, C]
Returns the given function applied to the value contained in this
Or
if it is aGood
, or returnsthis
if it is aBad
.Returns the given function applied to the value contained in this
Or
if it is aGood
, or returnsthis
if it is aBad
.- f
the function to apply
- returns
if this is a
Good
, the result of applying the given function to the contained value wrapped in aGood
, else thisBad
is returned
-
abstract
def
fold[V](gf: (G) ⇒ V, bf: (B) ⇒ V): V
Folds this
Or
into a value of typeV
by applying the givengf
function if this is aGood
else the givenbf
function if this is aBad
.Folds this
Or
into a value of typeV
by applying the givengf
function if this is aGood
else the givenbf
function if this is aBad
.- gf
the function to apply to this
Or
'sGood
value, if it is aGood
- bf
the function to apply to this
Or
'sBad
value, if it is aBad
- returns
the result of applying the appropriate one of the two passed functions,
gf
or bf, to thisOr
's value
-
abstract
def
forall(f: (G) ⇒ Boolean): Boolean
Returns
true
if either thisOr
is aBad
or if the predicatep
returnstrue
when applied to thisGood
's value.Returns
true
if either thisOr
is aBad
or if the predicatep
returnstrue
when applied to thisGood
's value.Note: The
forall
method will return the same result asexists
if thisOr
is aGood
, but the opposite result if thisOr
is aBad
.- returns
the result of applying the passed predicate
p
to theGood
value, if this is aGood
, elsetrue
-
abstract
def
foreach(f: (G) ⇒ Unit): Unit
Applies the given function f to the contained value if this
Or
is aGood
; does nothing if thisOr
is aBad
.Applies the given function f to the contained value if this
Or
is aGood
; does nothing if thisOr
is aBad
.- f
the function to apply
-
abstract
def
get: G
Returns the
Or
's value if it is aGood
or throwsNoSuchElementException
if it is aBad
.Returns the
Or
's value if it is aGood
or throwsNoSuchElementException
if it is aBad
.- returns
the contained value if this is a
Good
- Exceptions thrown
NoSuchElementException
if this is aBad
-
abstract
def
getOrElse[H >: G](default: ⇒ H): H
Returns, if this
Or
isGood
, thisGood
's value; otherwise returns the result of evaluatingdefault
.Returns, if this
Or
isGood
, thisGood
's value; otherwise returns the result of evaluatingdefault
.- default
the default expression to evaluate if this
Or
is aBad
- returns
the contained value, if this
Or
is aGood
, else the result of evaluating the givendefault
-
abstract
def
map[H](f: (G) ⇒ H): Or[H, B]
Maps the given function to this
Or
's value if it is aGood
or returnsthis
if it is aBad
.Maps the given function to this
Or
's value if it is aGood
or returnsthis
if it is aBad
.- f
the function to apply
- returns
if this is a
Good
, the result of applying the given function to the contained value wrapped in aGood
, else thisBad
is returned
-
abstract
def
orElse[H >: G, C >: B](alternative: ⇒ Or[H, C]): Or[H, C]
Returns this
Or
if it is aGood
, otherwise returns the result of evaluating the passedalternative
.Returns this
Or
if it is aGood
, otherwise returns the result of evaluating the passedalternative
.- alternative
the alternative by-name to evaluate if this
Or
is aBad
- returns
this
Or
, if it is aGood
, else the result of evaluatingalternative
-
abstract
def
productArity: Int
- Definition Classes
- Product
-
abstract
def
productElement(n: Int): Any
- Definition Classes
- Product
-
abstract
def
recover[H >: G](f: (B) ⇒ H): Or[H, B]
Maps the given function to this
Or
's value if it is aBad
, transforming it into aGood
, or returnsthis
if it is already aGood
.Maps the given function to this
Or
's value if it is aBad
, transforming it into aGood
, or returnsthis
if it is already aGood
.- f
the function to apply
- returns
if this is a
Bad
, the result of applying the given function to the contained value wrapped in aGood
, else thisGood
is returned
-
abstract
def
recoverWith[H >: G, C](f: (B) ⇒ Or[H, C]): Or[H, C]
Maps the given function to this
Or
's value if it is aBad
, returning the result, or returnsthis
if it is already aGood
.Maps the given function to this
Or
's value if it is aBad
, returning the result, or returnsthis
if it is already aGood
.- f
the function to apply
- returns
if this is a
Bad
, the result of applying the given function to the contained value, else thisGood
is returned
-
abstract
def
swap: Or[B, G]
Returns an
Or
with theGood
andBad
types swapped:Bad
becomesGood
andGood
becomesBad
.Returns an
Or
with theGood
andBad
types swapped:Bad
becomesGood
andGood
becomesBad
.Here's an example:
scala> val lyrics = Bad("Hey Jude, don't make it bad. Take a sad song and make it better.") lyrics: org.scalactic.Bad[Nothing,String] = Bad(Hey Jude, don't make it bad. Take a sad song and make it better.) scala> lyrics.swap res12: org.scalactic.Or[String,Nothing] = Good(Hey Jude, don't make it bad. Take a sad song and make it better.)
Now that song will be rolling around in your head all afternoon. But at least it is a good song (thanks to
swap
).- returns
if this
Or
is aGood
, itsGood
value wrapped in aBad
; if thisOr
is aBad
, itsBad
value wrapped in aGood
.
-
abstract
def
toEither: Either[B, G]
Returns an
Either
: aRight
containing theGood
value, if this is aGood
; aLeft
containing theBad
value, if this is aBad
.Returns an
Either
: aRight
containing theGood
value, if this is aGood
; aLeft
containing theBad
value, if this is aBad
.Note that values effectively “switch sides” when convering an
Or
to anEither
. If the type of theOr
on which you invoketoEither
isOr[Int, ErrorMessage]
for example, the result will be anEither[ErrorMessage, Int]
. The reason is that the convention forEither
is thatLeft
is used for “bad” values andRight
is used for “good” ones.- returns
this
Good
value, wrapped in aRight
, or thisBad
value, wrapped in aLeft
.
-
abstract
def
toOption: Option[G]
Returns a
Some
containing theGood
value, if thisOr
is aGood
, elseNone
.Returns a
Some
containing theGood
value, if thisOr
is aGood
, elseNone
.- returns
the contained “good” value wrapped in a
Some
, if thisOr
is aGood
;None
if thisOr
is aBad
.
-
abstract
def
toSeq: IndexedSeq[G]
Returns an immutable
IndexedSeq
containing theGood
value, if thisOr
is aGood
, else an empty immutableIndexedSeq
.Returns an immutable
IndexedSeq
containing theGood
value, if thisOr
is aGood
, else an empty immutableIndexedSeq
.- returns
the contained “good” value in a lone-element
Seq
if thisOr
is aGood
; an emptySeq
if thisOr
is aBad
.
-
abstract
def
toTry(implicit ev: <:<[B, Throwable]): Try[G]
Returns a
Try
: aSuccess
containing theGood
value, if this is aGood
; aFailure
containing theBad
value, if this is aBad
.Returns a
Try
: aSuccess
containing theGood
value, if this is aGood
; aFailure
containing theBad
value, if this is aBad
.Note: This method can only be called if the
Bad
type of thisOr
is a subclass ofThrowable
(orThrowable
itself).Note that values effectively “switch sides” when converting an
Or
to anEither
. If the type of theOr
on which you invoketoEither
isOr[Int, ErrorMessage]
for example, the result will be anEither[ErrorMessage, Int]
. The reason is that the convention forEither
is thatLeft
is used for “bad” values andRight
is used for “good” ones.- returns
this
Good
value, wrapped in aRight
, or thisBad
value, wrapped in aLeft
.
-
abstract
def
transform[H, C](gf: (G) ⇒ Or[H, C], bf: (B) ⇒ Or[H, C]): Or[H, C]
Transforms this
Or
by applying the functiongf
to thisOr
'sGood
value if it is aGood
, or by applyingbf
to thisOr
'sBad
value if it is aBad
.Transforms this
Or
by applying the functiongf
to thisOr
'sGood
value if it is aGood
, or by applyingbf
to thisOr
'sBad
value if it is aBad
.- gf
the function to apply to this
Or
'sGood
value, if it is aGood
- bf
the function to apply to this
Or
'sBad
value, if it is aBad
- returns
the result of applying the appropriate one of the two passed functions,
gf
or bf, to thisOr
's value
Concrete Value Members
-
final
def
!=(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
-
final
def
##(): Int
- Definition Classes
- AnyRef → Any
-
final
def
==(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
-
final
def
asInstanceOf[T0]: T0
- Definition Classes
- Any
-
def
clone(): AnyRef
- Attributes
- protected[java.lang]
- Definition Classes
- AnyRef
- Annotations
- @native() @throws( ... )
-
final
def
eq(arg0: AnyRef): Boolean
- Definition Classes
- AnyRef
-
def
equals(arg0: Any): Boolean
- Definition Classes
- AnyRef → Any
-
def
finalize(): Unit
- Attributes
- protected[java.lang]
- Definition Classes
- AnyRef
- Annotations
- @throws( classOf[java.lang.Throwable] )
-
final
def
getClass(): Class[_]
- Definition Classes
- AnyRef → Any
- Annotations
- @native()
-
def
hashCode(): Int
- Definition Classes
- AnyRef → Any
- Annotations
- @native()
-
val
isBad: Boolean
Indicates whether this
Or
is aBad
Indicates whether this
Or
is aBad
- returns
true if this
Or
is aBad
,false
if it is aGood
.
-
val
isGood: Boolean
Indicates whether this
Or
is aGood
Indicates whether this
Or
is aGood
- returns
true if this
Or
is aGood
,false
if it is aBad
.
-
final
def
isInstanceOf[T0]: Boolean
- Definition Classes
- Any
-
final
def
ne(arg0: AnyRef): Boolean
- Definition Classes
- AnyRef
-
final
def
notify(): Unit
- Definition Classes
- AnyRef
- Annotations
- @native()
-
final
def
notifyAll(): Unit
- Definition Classes
- AnyRef
- Annotations
- @native()
-
def
productIterator: Iterator[Any]
- Definition Classes
- Product
-
def
productPrefix: String
- Definition Classes
- Product
-
final
def
synchronized[T0](arg0: ⇒ T0): T0
- Definition Classes
- AnyRef
-
def
toString(): String
- Definition Classes
- AnyRef → Any
-
final
def
wait(): Unit
- Definition Classes
- AnyRef
- Annotations
- @throws( ... )
-
final
def
wait(arg0: Long, arg1: Int): Unit
- Definition Classes
- AnyRef
- Annotations
- @throws( ... )
-
final
def
wait(arg0: Long): Unit
- Definition Classes
- AnyRef
- Annotations
- @native() @throws( ... )
-
def
withFilter[C >: B](f: (G) ⇒ Validation[C]): Or[G, C]
Currently just forwards to filter, and therefore, returns the same result.
Deprecated Value Members
-
def
asOr: Or[G, B]
The
asOr
method has been deprecated and will be removed in a future version of Scalactic. Please remove invocations ofasOr
in expressions of typeGood(value).orBad[Type]
andGood[Type].orBad(value)
(which now return a type already widened toOr
), otherwise please use a type annotation to widen the type, such as:(Good(3): Int Or ErrorMessage)
.The
asOr
method has been deprecated and will be removed in a future version of Scalactic. Please remove invocations ofasOr
in expressions of typeGood(value).orBad[Type]
andGood[Type].orBad(value)
(which now return a type already widened toOr
), otherwise please use a type annotation to widen the type, such as:(Good(3): Int Or ErrorMessage)
.- Annotations
- @deprecated
- Deprecated
The asOr is no longer needed because Good(value).orBad[Type] and Good[Type].orBad(value) now return Or. You can delete invocations of asOr in those cases, otherwise, please use a type annotation to widen the type, like (Good(3): Int Or ErrorMessage).