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Pattern Matching / Destructuring
One of ReScript's best feature is our pattern matching. Pattern matching combines 3 brilliant features into one:
Destructuring.
switch
based on shape of data.Exhaustiveness check.
We'll dive into each aspect below.
Destructuring
Even JavaScript has destructuring, which is "opening up" a data structure to extract the parts we want and assign variable names to them:
Destructuring works with most built-in data structures:
// Record
type student = {name: string, age: int}
let student1 = {name: "John", age: 10}
let {name} = student1 // "John" assigned to `name`
// Variant
type result =
| Success(string)
let myResult = Success("You did it!")
let Success(message) = myResult // "You did it!" assigned to `message`
You can also use destructuring anywhere you'd usually put a binding:
For a record, you can rename the field while destructuring:
You can in theory destructure array and list at the top level too:
RESlet myArray = [1, 2, 3]
let [item1, item2, _] = myArray
// 1 assigned to `item1`, 2 assigned to `item2`, 3rd item ignored
let myList = list{1, 2, 3}
let list{head, ...tail} = myList
// 1 assigned to `head`, `list{2, 3}` assigned to tail
But the array example is highly disrecommended (use tuple instead) and the list example will error on you. They're only there for completeness' sake. As you'll see below, the proper way of using destructuring array and list is using switch
.
switch
Based on Shape of Data
While the destructuring aspect of pattern matching is nice, it doesn't really change the way you think about structuring your code. One paradigm-changing way of thinking about your code is to execute some code based on the shape of the data.
Consider a variant:
We'd like to handle each of the 3 cases differently. For example, print a success message if the value is GoodResult(...)
, do something else when the value is NoResult
, etc.
In other languages, you'd end up with a series of if-elses that are hard to read and error-prone. In ReScript, you can instead use the supercharged switch
pattern matching facility to destructure the value while calling the right code based on what you destructured:
In this case, message
will have the value "Success! Product shipped!"
.
Suddenly, your if-elses that messily checks some structure of the value got turned into a clean, compiler-verified, linear list of code to execute based on exactly the shape of the value.
Complex Examples
Here's a real-world scenario that'd be a headache to code in other languages. Given this data structure:
Imagine this requirement:
Informally greet a person who's a teacher and if his name is Mary or Joe.
Greet other teachers formally.
If the person's a student, congratulate him/her score if they passed the semester.
If the student has a gpa of 0 and is on vacations or sabbatical, display a different message.
A catch-all message for a student.
ReScript can do this easily!
let person1 = Teacher({name: "Jane", age: 35})
let message = switch person1 {
| Teacher({name: "Mary" | "Joe"}) =>
`Hey, still going to the party on Saturday?`
| Teacher({name}) =>
// this is matched only if `name` isn't "Mary" or "Joe"
`Hello ${name}.`
| Student({name, reportCard: {passing: true, gpa}}) =>
`Congrats ${name}, nice GPA of ${Js.Float.toString(gpa)} you got there!`
| Student({
reportCard: {gpa: 0.0},
status: Vacations(daysLeft) | Sabbatical(daysLeft)
}) =>
`Come back in ${Js.Int.toString(daysLeft)} days!`
| Student({status: Sick}) =>
`How are you feeling?`
| Student({name}) =>
`Good luck next semester ${name}!`
}
Note how we've:
drilled deep down into the value concisely
using a nested pattern check
"Mary" | "Joe"
andVacations | Sabbatical
while extracting the
daysLeft
number from the latter caseand assigned the greeting to the binding
message
.
Here's another example of pattern matching, this time on an inline tuple.
Note how pattern matching on a tuple is equivalent to a 2D table:
isBig \ myAnimal | Dog | Cat | Bird |
---|---|---|---|
true | 1 | 2 | 3 |
false | 4 | 4 | 5 |
Fall-Through Patterns
The nested pattern check, demonstrated in the earlier person
example, also works at the top level of a switch
:
Having multiple cases fall into the same handling can clean up certain types of logic.
Ignore Part of a Value
If you have a value like Teacher(payload)
where you just want to pattern match on the Teacher
part and ignore the payload
completely, you can use the _
wildcard like this:
_
also works at the top level of the switch
, serving as a catch-all condition:
Do not abuse a top-level catch-all condition. Instead, prefer writing out all the cases:
Slightly more verbose, but a one-time writing effort. This helps when you add a new variant case e.g. Quarantined
to the status
type and need to update the places that pattern match on it. A top-level wildcard here would have accidentally and silently continued working, potentially causing bugs.
If Clause
Sometime, you want to check more than the shape of a value. You want to also run some arbitrary check on it. You might be tempted to write this:
switch
patterns support a shortcut for the arbitrary if
check, to keep your pattern linear-looking:
Note: Rescript versions < 9.0 had a when
clause, not an if
clause. Rescript 9.0 changed when
to if
. (when
may still work, but is deprecated.)
Match on Exceptions
If the function throws an exception (covered later), you can also match on that, in addition to the function's normally returned values.
Match on Array
Match on List
Pattern matching on list is similar to array, but with the extra feature of extracting the tail of a list (all elements except the first one):
Small Pitfall
Note: you can only pass literals (i.e. concrete values) as a pattern, not let-binding names or other things. The following doesn't work as expected:
A first time ReScript user might accidentally write that code, assuming that it's matching on coordinates
when the second value is of the same value as centerY
. In reality, this is interpreted as matching on coordinates and assigning the second value of the tuple to the name centerY
, which isn't what's intended.
Exhaustiveness Check
As if the above features aren't enough, ReScript also provides arguably the most important pattern matching feature: compile-time check of missing patterns.
Let's revisit one of the above examples:
let message = switch person1 {
| Teacher({name: "Mary" | "Joe"}) =>
`Hey, still going to the party on Saturday?`
| Student({name, reportCard: {passing: true, gpa}}) =>
`Congrats ${name}, nice GPA of ${Js.Float.toString(gpa)} you got there!`
| Student({
reportCard: {gpa: 0.0},
status: Vacations(daysLeft) | Sabbatical(daysLeft)
}) =>
`Come back in ${Js.Int.toString(daysLeft)} days!`
| Student({status: Sick}) =>
`How are you feeling?`
| Student({name}) =>
`Good luck next semester ${name}!`
}
Did you see what we removed? This time, we've omitted the handling of the case where person1
is Teacher({name})
when name
isn't Mary or Joe.
Failing to handle every scenario of a value likely constitutes the majority of program bugs out there. This happens very often when you refactor a piece of code someone else wrote. Fortunately for ReScript, the compiler will tell you so:
Warning 8: this pattern-matching is not exhaustive. Here is an example of a value that is not matched: Some({name: ""})
BAM! You've just erased an entire category of important bugs before you even ran the code. In fact, this is how most of nullable values is handled:
If you don't handle the None
case, the compiler warns. No more undefined
bugs in your code!
Conclusion & Tips & Tricks
Hopefully you can see how pattern matching is a game changer for writing correct code, through the concise destructuring syntax, the proper conditions handling of switch
, and the static exhaustiveness check.
Below is some advice:
Avoid using the wildcard _
unnecessarily. Using the wildcard _
will bypass the compiler's exhaustiveness check. Consequently, the compiler will not be able to notify you of probable errors when you add a new case to a variant. Try only using _
against infinite possibilities, e.g. string, int, etc.
Use the if
clause sparingly.
Flatten your pattern-match whenever you can. This is a real bug remover. Here's a series of examples, from worst to best:
Now that's just silly =). Let's turn it into pattern-matching:
Slightly better, but still nested. Pattern-matching allows you to do this:
Much more linear-looking! Now, you might be tempted to do this:
Which is much more concise, but kills the exhaustiveness check mentioned above; refrain from using that. This is the best:
Pretty darn hard to make a mistake in this code at this point! Whenever you'd like to use an if-else with many branches, prefer pattern matching instead. It's more concise and performant too.