nidula
nidula
is a lightweight library bringing Rust's
Option and
Result types to Dart, together with
a parallel to Rust's try operator that is both compile-time safe and chainable.
This library aims to provide as close to a 1:1 experience in Dart as possible to
Rust's implementation of these types, carrying over all of the methods for composing
Option
and Result
values (and_then()
, or_else()
, map()
, etc.). Dart 3's exhaustive pattern matching can be easily leveraged thanks to the provided snippets (see the Pattern matching snippets (VSCode) section).
Contents:
- 1. Option
- 2. Result
- 3. Pattern matching snippets (VSCode)
- 4. Warning: None/Err propagation with try-catch blocks
- 5. Error conversion before propagation
- 6. Key differences from Rust
- 7. History
1. Option
Option
types represent the presence (Some
) or absence (None
) of a value.
Dart handles this pretty well on its own via null
and a focus on null-safety built
in to the compiler and analyzer.
The advantage of Option
types over nullable types lies in their composability.
Option
type values have many methods that allow composing many Option
-returning
operations together and helpers for propagating None
values in larger operations
without the need for repetitive null-checking.
This supports writing clean, concise, and most importantly, safe code.
Option<int> multiplyBy5(int i) => Some(i * 5);
// NB: this is a curried function
// example: `divideBy(2)(8)` results in `Some(8 ~/ 2)`, i.e., `Some(4)`
Option<int> Function(int dividend) Function(int divisor) divideBy =
(int divisor) => (int dividend) => switch (divisor) {
0 => None(),
_ => Some(dividend ~/ divisor),
};
void main() {
Option<int> a = Some(10);
Option<int> b = Some(0);
Option<int> c = None();
Option<int> d = a.andThen(divideBy(2)).andThen(multiplyBy5); // Some(25)
Option<int> e = a.andThen(divideBy(0)).andThen(multiplyBy5); // None()
Option<int> f = b.andThen(divideBy(2)).andThen(multiplyBy5); // Some(0)
Option<int> g = b.andThen(divideBy(0)).andThen(multiplyBy5); // None()
Option<int> h = c.andThen(divideBy(2)).andThen(multiplyBy5); // None()
Option<int> i = c.andThen(divideBy(0)).andThen(multiplyBy5); // None()
}
1.1. Parallel to Rust's try-operator
With Option
types, a parallel to Rust's try-operator is achieved combining try_
with tryScope
(for synchronous functions) or asyncTryScope
(for asynchronous ones). For those unfamiliar with Rust, the try operator tries to unwrap the Option
value, however, if the Option
is a None
, the try operator propagates None
(this way we don't have to always write code for checking for and possibly returning the None
; the more potential None
cases there are, the more pragmatic this pattern becomes).
Example:
// Example from Option.tryScope docstring
Option<int> example2(Option<int> l) {
return Option.tryScope<int>((nt) {
l = Some(l.try_(nt) + [1, 2, 3].elementAt(1));
// it will propagate now if initial `l` was None, else continues
l = None(); // not propagating yet
l.try_(nt); // it will propagate now if initial `l` was Some
l = Some(l.try_(nt) + [5, 6].elementAt(1)); // dead code (not detected by IDE)
return Some(l.try_(nt));
});
}
Option<int> myOption = example(Some(9));
switch (myOption) {
case Some(:int v): print('Contained value: $v');
case None(): print('None');
}
NonePropagationToken
features a private constructor, thus l.try_(NonePropagationToken())
cannot be used to pass the required argument (and thus execute the method).
The provided argument nt
in the tryScope
callback is an instance of NonePropagationToken
, and is expected to be passed to try_
. The propagation that is thrown inside the fn
argument of tryScope
must be handled by tryScope
's body. If there is no tryScope
, then there cannot be any a NonePropagationToken nt
, making l.try_
impossible to invoke. Therefore, the NonePropagationToken
guarantees compile-time safety.
The same holds for asyncTryScope
.
Note that the try_
method allows chaining, for example: return Ok(a.try_(nt).makeCall().try_(nt).makeSecondCall().try_(nt))
, where makeCall
and makeSecondCall
must be methods defined in T
returning Option<T>
.
1.1.1. NonePropagation instances
NonePropagation
s are Dart errors thrown with StackTrace.empty
when calling try_(et)
on options that are None
, and are supposed to be handled solely by this library with the provided helpers.
1.2. Chaining methods
Instead of employing try_
for None
propagation, an alternative approach involves leveraging asynchronous chaining methods such as onSome
, onNone
, and chain
on Option<T>
and Future<Option<T>>
. This method aligns with functional programming principles.
Option<T>
also has synchronous chaining methods onSomeSync
, onNoneSync
and chainSync
.
1.3. Comparison with nullable types
A big difference between Option
types and nullable types (e.g. int?
) is that Option
types can be nested. For example: both
None()
and Some(None())
are valid values for Option<Option<int>>
.
On the other hand, with nullable types some structures are just not possible. For example, the type
int??
is not something similar to Option<Option<int>>
; on the contrary, is exactly the same as int?
(i.e. int?? = int?
).
Thus, the distinction between None()
and Some(None())
is just not possible to do with null
.
Nested options are mostly useful e.g. when we do a find in a list of Option
s.
2. Result
Result
types represent the result of some operation, either success (Ok
), or
failure (Err
), and both variants can hold data.
This promotes safe handling of error values without the need for try/catch blocks
while also providing composability like Option
via methods for composing Result
-returning
operations together and helpers for propagating Err
values within larger operations
without the need for repetitive error catching, checking, and rethrowing.
Again, like Option
, this helps promote clean, concise, and safe code.
Result<int, String> multiplyBy5(int i) => Ok(i * 5);
// NB: this is a curried function
// example: `divideBy(2)(8)` results in `Ok(8 ~/ 2)`, i.e., `Ok(4)`
Result<int, String> Function(int dividend) Function(int divisor) divideBy =
(int divisor) => (int dividend) => switch (divisor) {
0 => Err('divided by 0'),
_ => Ok(dividend ~/ divisor),
};
void main() {
Result<int, String> a = Ok(10);
Result<int, String> b = Ok(0);
Result<int, String> c = Err('foo');
Result<int, String> d = a.andThen(divideBy(2)).andThen(multiplyBy5); // Ok(25)
Result<int, String> e = a.andThen(divideBy(0)).andThen(multiplyBy5); // Err(divided by 0)
Result<int, String> f = b.andThen(divideBy(2)).andThen(multiplyBy5); // Some(0)
Result<int, String> g = b.andThen(divideBy(0)).andThen(multiplyBy5); // Err(divided by 0)
Result<int, String> h = c.andThen(divideBy(2)).andThen(multiplyBy5); // Err(foo)
Result<int, String> i = c.andThen(divideBy(0)).andThen(multiplyBy5); // Err(foo)
}
2.1. Parallel to Rust's try-operator
With Result
types, a parallel to Rust's try-operator is achieved combining try_
with tryScope
(for synchronous functions) or asyncTryScope
(for asynchronous ones). For those unfamiliar with Rust, the try operator tries to unwrap the Result
value, however, if the Result
is an Err
, the try operator propagates Err
(this way we don't have to always write code for checking for and possibly returning the Err
; the more potential Err
cases there are, the more pragmatic this pattern becomes).
Example:
// Example from Result.tryScope docstring
Result<double, String> example2(Result<double, String> s) {
return Result.tryScope((et) {
s = Ok(s.try_(et) / 2); // it will propagate now if initial `s` was Err
s = Err('not propagating yet');
s.try_(et); // it will propagate now if initial `s` was Ok
s = Ok(s.try_(et) / 0); // dead code (not detected by IDE)
return Ok(s.try_(et));
});
}
Result<double, String> myResult = example2(Ok(0.9));
switch (myResult) {
case Ok(:double v): print('Ok value: $v');
case Err(:String e): print('Error: $e');
}
ErrPropagationToken
features a private constructor, thus l.try_(ErrPropagationToken())
cannot be used to pass the required argument (and thus execute the method).
The provided argument et
in the tryScope
callback is an instance of ErrPropagationToken
, and is expected to be passed to try_
. The propagation that is thrown inside the fn
argument of tryScope
must be handled by tryScope
's body. If there is no tryScope
, then there cannot be any a ErrPropagationToken et
, making l.try_
impossible to invoke. Therefore, the ErrPropagationToken
guarantees compile-time safety.
The same holds for asyncTryScope
.
Note that the try_
method allows chaining, for example: return Some(a.try_(et).makeCall().try_(et).makeSecondCall().try_(et))
, where makeCall
and makeSecondCall
must be methods defined in T
returning Result<T, E>
.
2.1.1. ErrPropagation instances
ErrPropagation<E>
s are Dart errors thrown with StackTrace.empty
when calling try_(et)
on results that are Err
, and are supposed to be handled solely by this library with the provided helpers.
2.2. Chaining methods
Instead of employing try_
for Err
propagation, an alternative approach involves leveraging asynchronous chaining methods such as onOk
, onErr
and chain
on Result<T, E>
and Future<Result<T, E>>
. This method aligns with functional programming principles.
Result<T, E>
also has synchronous chaining methods onOkSync
, onErrSync
and chainSync
.
2.3. Unit type
Result
doesn't always have to concern data. A Result
can be used strictly
for error handling, where an Ok
simply means there was no error and you can safely
continue. In Rust this is typically done by returning the
unit type ()
as Result<(), E>
and the same can be done in Dart with an empty Record
via ()
.
Result<(), String> failableOperation() {
if (someReasonToFail) {
return Err('Failure');
}
return Ok(());
}
Result<(), String> err = failableOperation();
if (err case Err(e: String error)) {
print(error);
return;
}
// No error, continue...
To further support this, just like how you can unwrap Option
and Result
values
by calling them like a function, an extension for Future<Option<T>>
and Future<Result<T, E>>
is provided to allow calling them like a function as well which will transform the
future into a future that unwraps the resulting Option
or Result
when completing.
(This also applies to FutureOr
values.)
// Here we have two functions that return Result<(), String>, one of which is a Future.
// We can wrap them in a asyncTryScope block (async in this case) and call them like a function
// to unwrap them, discarding the unit value if Ok, or propagating the Err value otherwise.
Result<(), String> err = await Result.asyncTryScope((et) async {
(await failableOperation1()).try_(et);
failableOperation2().try_(et);
return Ok(());
});
if (err case Err(e: String error)) {
print(error);
return;
}
// No error, continue...
Note that just like how unit
has one value in Rust, empty Record
values in
Dart are optimized to the same runtime constant reference so there is no performance
or memory overhead when using ()
as a unit
type.
3. Pattern matching snippets (VSCode)
Doing pattern matching is slightly verbose, and the repetitive task can be time-consuming and/or error-prone. This section presents some VSCode snippets that make interacting with options and results a lot faster.
3.1. Configuration
Select Snippets: Configure User Snippets
, then choose New Global Snippets file...
and give a name (e.g. nidula
).
Delete everything that is inside the generated file, and then paste:
{
"Option pattern matching expression": {
"scope": "dart",
"prefix": "match option expression",
"body": [
"final ${1:_} = switch (${2:option}) {"
" None() => $0,"
" Some(v: final ${3:v}) => ,"
"};",
],
"description": "Pattern matching expression snippet for Opiton values.",
},
"Option pattern matching statement": {
"scope": "dart",
"prefix": "match option statement",
"body": [
"switch (${1:option}) {"
" case None():"
" $0;"
" case Some(v: final ${2:v}):"
" ;"
"}",
],
"description": "Pattern matching statement snippet for Option values.",
},
"Result pattern matching expression": {
"scope": "dart",
"prefix": "match result expression",
"body": [
"final ${1:_} = switch (${2:result}) {"
" Err(e: final ${3:e}) => $0,"
" Ok(v: final ${4:v}) => ,"
"};",
],
"description": "Pattern matching expression snippet for Result values.",
},
"Result pattern matching statement": {
"scope": "dart",
"prefix": "match result statement",
"body": [
"switch (${1:result}) {"
" case Err(e: final ${2:e}):"
" $0;"
" case Ok(v: final ${3:v}):"
" ;"
"}",
],
"description": "Pattern matching statement snippet for Result values.",
},
"Option case Some and value": {
"scope": "dart",
"prefix": "if option case Some(v: T v)",
"body": [
"if (${1:option} case Some(v: final ${2:v})) {"
" $0"
"}"
],
"description": "Option case Some and its value.",
},
"Result case Err and value": {
"scope": "dart",
"prefix": "if result case Err(e: E e)",
"body": [
"if (${1:result} case Err(e: final ${2:e})) {"
" $0"
"}"
],
"description": "Result case Err and its value.",
},
"Result case Ok and value": {
"scope": "dart",
"prefix": "if result case Ok(v: T v)",
"body": [
"if (${1:result} case Ok(v: final ${2:v})) {"
" $0"
"}"
],
"description": "Result case Ok and its value.",
},
}
Now, every time e.g. result
or option
(note the extra empty space in both cases) are typed in a Dart file, IDE autocomplete will suggest the snippets above. Use the tab key to go to the next placeholder (in case of autocomplete suggestion, press the escape key before switching placeholders with the tab key).
4. Warning: None/Err propagation with try-catch blocks
Using try-catch in combination with try_
and tryScope
/asyncTryScope
can
be done, however we need to ensure NonePropagation
and ErrPropagation
are handled only inside
tryScope
/asyncTryScope
.
If the try block wraps the tryScope
/asyncTryScope
function and there is no outer tryScope
/asyncTryScope
wrapping the try-catch
block, then it is fine. For example:
Result<double, String> example3(Result<double, String> s) {
try {
return Result.tryScope((et) {
s = Ok(s.try_(et) / 2); // it will propagate now if initial `s` was Err
throw 'example';
s = Err('not propagating yet'); // dead code
s.try_(et);
s = Ok(s.try_(et) / 0);
return Ok(s.try_(et));
});
} on String {
return Err('caught a String');
}
}
However, we must be a little careful with a try-catch inside the tryScope
/asyncTryScope
's callback or any function that is called inside of it.
Bad example
The next example catches also ErrPropagation<String>
(that is thrown by try_
if s
is an Err
),
which compromises the error propagation.
Result<double, String> badExample(Result<double, String> s) {
return Result.tryScope<double, String>((et) {
try {
s = Ok(s.try_(et) / [1,2,3].elementAt(100));
} catch (e) {
s = Err('index too high');
}
return Ok(s.try_(et));
});
}
Good — Catch specific errors if possible
Catching the exact exceptions/errors that might be thrown — thus, avoiding
catching all possible errors with } on catch (e) {
— would be the
ideal approach:
Result<double, String> goodExample1(Result<double, String> s) {
return Result.tryScope<double, String>((et) {
try {
s = Ok(s.try_(et) / [1,2,3].elementAt(100));
} on RangeError catch (e) {
s = Err('index too high');
}
return Ok(s.try_(et));
});
}
Good — When catching specific errors is not possible
If it is not possible to catch the exact errors, or there would be too many
to distinguish from, then always rethrow Propagation
:
Result<double, String> goodExample2(Result<double, String> s) {
return Result.tryScope<double, String>((et) {
try {
s = Ok(s.try_(et) / [1,2,3].elementAt(100));
} on Propagation {
rethrow; // always rethrow so that the contained error propagates
} catch (e) {
s = Err('index too high');
}
return Ok(s.try_(et));
});
}
5. Error conversion before propagation
In Rust, it is possible to covert errors leveraging the From
trait. With Dart, there is not
an equivalent.
The recommended solution is to use mapErr
every time.
5.1. Extensions for common conversions
In case using mapErr
might inflate the verbosity of the code, extensions containing conversions can be defined
in your application codebase. For each conversion we need to define a new
method, e.g., tryCvtBool
, which converts the error contained in Err<(), int>
(which is of int
type) to a bool
before propagating it.
Example:
extension CvtResultIntErr<T> on Result<T, int> {
T tryCvtString(ErrPropagationToken<String> et) {
return mapErr((errE) => '$errE').try_(et);
}
T tryCvtBool(ErrPropagationToken<bool> et) {
return mapErr((errE) => errE == 1).try_(et);
}
}
extension CvtResultBoolErr<T> on Result<T, bool> {
T tryCvtString(ErrPropagationToken<String> et) {
return mapErr((errE) => '$errE').try_(et);
}
}
void a() {
final Result<(), int> ok = Ok(());
final a = Result.tryScope<(), int>((et) {
return Ok(ok.try_(et));
});
final b = Result.tryScope<(), String>((et) {
return Ok(ok.tryCvtString(et));
});
final c = Result.tryScope<(), bool>((et) {
return Ok(ok.tryCvtBool(et));
});
final Result<(), bool> ok2 = Ok(());
final a2 = Result.tryScope<(), bool>((et) {
return Ok(ok2.try_(et));
});
final b2 = Result.tryScope<(), String>((et) {
return Ok(ok2.tryCvtString(et));
});
}
6. Key differences from Rust
Option
andResult
types provided by this library are immutable. All composition methods either return new instances or the same instance unmodified if applicable, and methods for inserting/replacing values are not provided.- This library lacks all of the methods Rust's
Option
andResult
types have that are related toref
,deref
,mut
,pin
,clone
, andcopy
due to not being applicable to Dart as a higher-level language. - The Option.filter
method has a Dart-idiomatic
Option.where
alias. - Added methods
Option.match
andResult.match
, as they are more pragmatic for simple computations or side effects than Dart's built-in pattern matching. However:- Dart's pattern matching switch expressions on
Result
values are more powerful than thesematch
methods. - Dart's pattern matching switch statements on
Result
values allow to "early"return
, unlike thesematch
methods.
- Dart's pattern matching switch expressions on
- Added methods
Result.okToNullable
andResult.errToNullable
. - Added chaining methods such as
onSome
,onOk
,chain
, ... None
/Err
propagation is not supported at the language level in Dart since there's no concept of it so it's not quite as ergonomic as Rust, but is still easily managed via the provided helpers.
7. History
nidula
is a fork of option_result
bringing numerous enhancements:
- Parallel to Rust's try-operator implementation rewritten from scratch.
- Simple library-internal error handling strategy.
- Efficient, as no stacktraces re used for library internal propagations.
- The return type for
Option.mapOr
,Option.mapOrElse
,Result.mapOr
andResult.mapOrElse
is onlyU
innidula
. - Added
toJson
andfromJson
support. - Added
Result.okToNullable
, andResult.errToNullable
. - Added
zipOp
. - Only
T v
andE e
fields are available.value
,val
,err
anderror
aliases (getters) were removed.
- There is only a single public library to import components from.
- Final modifiers to prevent extending
Ok
,Err
,Some
andNone
.- Correctly exhaustive pattern matching support, IDE-wise.
==
operator takes also generic types into consideration when comparingOption
objects andResult
objects.- Added variable names to all function parameters in types.
- Callback autocomplete outputs e.g.
(okV) {}
instead of(p0) {}
.
- Callback autocomplete outputs e.g.
Libraries
- nidula
- This is the base
nidula
library, containing bothOption
andResult
types.