# Optional Values A very common use case is values that may or may not be present. You could represent this case using enums like so: ```tomo enum MaybeInt(AnInt(x:Int), NoInt) func maybe_takes_int(maybe_x:MaybeInt): when maybe_x is AnInt(x): say("Got an int: $x") else: say("Got nothing") ``` However, it's overly onerous to have to define a separate type for each situation where you might want to not have a value. Instead, Tomo has built-in support for optional types: ``` func maybe_takes_int(x:Int?): if x: say("Got an int: $x") else: say("Got nothing") ``` This establishes a common language for talking about optional values without having to use a more generalized form of `enum` which may have different naming conventions and which would generate a lot of unnecessary code. ## Syntax Optional types are written using a `?` after the type name. So, an optional integer would be written as `Int?` and an optional array of texts would be written as `[Text]?`. None can be written explicitly using `none` with a type annotation. For example, if you wanted to declare a variable that could be either an integer value or `none` and initialize it as none, you would write it as: ```tomo x := none:Int ``` Similarly, if you wanted to declare a variable that could be an array of texts or none and initialize it as none, you would write: ```tomo x := ![Text] ``` If you want to declare a variable and initialize it with a non-none value, but keep open the possibility of assigning `none` later, you can use the postfix `?` operator to indicate that a value is optional: ```tomo x := 5? # Later on, assign none: x = !Int ``` ## Type Inference For convenience, `none` can also be written without the explicit type annotation for any type in situations where the compiler knows what type of optional value is expected: - When assigning to a variable that has already been declared as optional. - When returning from a function with an explicit optional return type. - When passing an argument to a function with an optional argument type. Here are some examples: ```tomo x := 5? x = none func doop(arg:Int?)->Text?: return none doop(none) ``` Non-none values can also be automatically promoted to optional values without the need for an explicit `?` operator in the cases listed above: ```tomo x := !Int x = 5 func doop(arg:Int?)->Text?: return "okay" doop(123) ``` ## None Checking In addition to using conditionals to check for `none`, you can also use `or` to get a non-none value by either providing an alternative non-none value or by providing an early out statement like `return`/`skip`/`stop` or a function with an `Abort` type like `fail()` or `exit()`: ```tomo maybe_x := 5? >> maybe_x or -1 = 5 : Int >> maybe_x or fail("No value!") = 5 : Int maybe_x = !Int >> maybe_x or -1 = -1 : Int >> maybe_x or fail("No value!") # Failure! func do_stuff(matches:[Text]): pass for line in lines: matches := line:matches($/{..},{..}/) or skip # The `or skip` above means that if we're here, `matches` is non-none: do_stuff(matches) ``` ## Implementation Notes The implementation of optional types is highly efficient and has no memory overhead for pointers, collection types (arrays, sets, tables), booleans, texts, enums, nums, or integers (`Int` type only). This is done by using carefully chosen values, such as `0` for pointers, `2` for booleans, or a negative length for arrays. However, for fixed-size integers (`Int64`, `Int32`, `Int16`, and `Int8`), bytes, and structs, an additional byte is required for out-of-band information about whether the value is none or not. Floating point numbers (`Num` and `Num32`) use `NaN` to represent none, so optional nums should be careful to avoid using `NaN` as a non-none value. This option was chosen to minimize the memory overhead of optional nums and because `NaN` literally means "not a number".