#frunk #macro #proc-macro #internal

macro frunk_proc_macros_impl

Proc macros inernal implementations for Frunk

7 releases

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0.1.0 Jun 25, 2021
0.0.5 Apr 16, 2021
0.0.4 Dec 21, 2019
0.0.2 Feb 9, 2019

#12 in #frunk

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Frunk Crates.io Continuous integration Gitter Frunk

frunk frəNGk

  • Functional programming toolbelt in Rust.
  • Might seem funky at first, but you'll like it.
  • Comes from: funktional (German) + Rust → Frunk

The general idea is to make things easier by providing FP tools in Rust to allow for stuff like this:

use frunk::monoid::combine_all;

let v = vec![Some(1), Some(3)];
assert_eq!(combine_all(&v), Some(4));

// Slightly more magical
let t1 =       (1, 2.5f32,                String::from("hi"),  Some(3));
let t2 =       (1, 2.5f32,            String::from(" world"),     None);
let t3 =       (1, 2.5f32,         String::from(", goodbye"), Some(10));
let tuples = vec![t1, t2, t3];

let expected = (3, 7.5f32, String::from("hi world, goodbye"), Some(13));
assert_eq!(combine_all(&tuples), expected);

For a deep dive, RustDocs are available for:

Table of Contents

  1. HList
  2. Generic
  3. Coproduct
  4. Validated
  5. Semigroup
  6. Monoid
  7. Features
  8. Benchmarks
  9. Todo
  10. Contributing
  11. Inspirations
  12. Maintainers

Examples

HList

Statically typed heterogeneous lists.

First, let's enable hlist:

use frunk::{HNil, HCons, hlist};

Some basics:

let h = hlist![1];
// Type annotations for HList are optional. Here we let the compiler infer it for us
// h has a static type of: HCons<i32, HNil>

// HLists have a head and tail
assert_eq!(hlist![1].head, 1);
assert_eq!(hlist![1].tail, HNil);

// You can convert a tuple to an HList and vice-versa
let h2 = hlist![ 42f32, true, "hello" ];
let t: (f32, bool, &str) = h2.into();
assert_eq!(t, (42f32, true, "hello"));

let t3 = (999, false, "world");
let h3: HList![ isize, bool, &str ] = t3.into();
assert_eq!(h3, hlist![ 999, false, "world" ]);

HLists have a hlist_pat! macro for pattern matching;

let h: HList!(&str, &str, i32, bool) = hlist!["Joe", "Blow", 30, true];
// We use the HList! type macro to make it easier to write
// a type signature for HLists, which is a series of nested HCons
// h has an expanded static type of: HCons<&str, HCons<&str, HCons<i32, HCons<bool, HNil>>>>

let hlist_pat!(f_name, l_name, age, is_admin) = h;
assert_eq!(f_name, "Joe");
assert_eq!(l_name, "Blow");
assert_eq!(age, 30);
assert_eq!(is_admin, true);

// You can also use into_tuple2() to turn the hlist into a nested pair

To traverse or build lists, you can also prepend/or pop elements at the front:

let list = hlist![true, "hello", Some(41)];
// h has a static type of: HCons<bool, HCons<&str, HCons<Option<{integer}>, HNil>>>
let (head1, tail1) = list.pop();
assert_eq!(head1, true);
assert_eq!(tail1, hlist!["hello", Some(41)]);
let list1 = tail1.prepend(head1);
assert_eq!(list, list1);

// or using macro sugar:
let hlist_pat![head2, ...tail2] = list; // equivalent to pop
let list2 = hlist![head2, ...tail2];    // equivalent to prepend
assert_eq!(list, list2);

You can reverse, map, and fold over them too:

// Reverse
let h1 = hlist![true, "hi"];
assert_eq!(h1.into_reverse(), hlist!["hi", true]);

// Fold (foldl and foldr exist)
let h2 = hlist![1, false, 42f32];
let folded = h2.foldr(
    hlist![
        |acc, i| i + acc,
        |acc, _| if acc > 42f32 { 9000 } else { 0 },
        |acc, f| f + acc
    ],
    1f32
);
assert_eq!(folded, 9001)

// Map
let h3 = hlist![9000, "joe", 41f32];
let mapped = h3.map(hlist![
    |n| n + 1,
    |s| s,
    |f| f + 1f32]);
assert_eq!(mapped, hlist![9001, "joe", 42f32]);

You can pluck a type out of an HList using pluck(), which also gives you back the remainder after plucking that type out. This method is checked at compile-time to make sure that the type you ask for can be extracted.

let h = hlist![1, "hello", true, 42f32];
let (t, remainder): (bool, _) = h.pluck();
assert!(t);
assert_eq!(remainder, hlist![1, "hello", 42f32])

Similarly, you can re-shape, or sculpt, an Hlist, there is a sculpt() method, which allows you to re-organise and/or cull the elements by type. Like pluck(), sculpt() gives you back your target with the remainder data in a pair. This method is also checked at compile time to make sure that it won't fail at runtime (the types in your requested target shape must be a subset of the types in the original HList.

let h = hlist![9000, "joe", 41f32, true];
let (reshaped, remainder): (HList![f32, i32, &str], _) = h.sculpt();
assert_eq!(reshaped, hlist![41f32, 9000, "joe"]);
assert_eq!(remainder, hlist![true]);

Generic

Generic is a way of representing a type in ... a generic way. By coding around Generic, you can to write functions that abstract over types and arity, but still have the ability to recover your original type afterwards. This can be a fairly powerful thing.

Setup

In order to derive the trait Generic (or LabelledGeneric) you will have to add frunk_core dependency

[dependencies]
frunk_core = { version = "$version" }

Frunk comes out of the box with a nice custom Generic derivation so that boilerplate is kept to a minimum.

Here are some examples:

HList ⇄ Struct

#[derive(Generic, Debug, PartialEq)]
struct Person<'a> {
    first_name: &'a str,
    last_name: &'a str,
    age: usize,
}

let h = hlist!("Joe", "Blow", 30);
let p: Person = frunk::from_generic(h);
assert_eq!(p,
           Person {
               first_name: "Joe",
               last_name: "Blow",
               age: 30,
           });

This also works the other way too; just pass a struct to into_generic and get its generic representation.

Converting between Structs

Sometimes you may have 2 different types that are structurally the same (e.g. different domains but the same data). Use cases include:

  • You have a models for deserialising from an external API and equivalents for your app logic
  • You want to represent different stages of the same data using types (see this question on StackOverflow)

Generic comes with a handy convert_from method that helps make this painless:

// Assume we have all the imports needed
#[derive(Generic)]
struct ApiPerson<'a> {
    FirstName: &'a str,
    LastName: &'a str,
    Age: usize,
}

#[derive(Generic)]
struct DomainPerson<'a> {
    first_name: &'a str,
    last_name: &'a str,
    age: usize,
}

let a_person = ApiPerson {
                   FirstName: "Joe",
                   LastName: "Blow",
                   Age: 30,
};
let d_person: DomainPerson = frunk::convert_from(a_person); // done

LabelledGeneric

In addition to Generic, there is also LabelledGeneric, which, as the name implies, relies on a generic representation that is labelled. This means that if two structs derive LabelledGeneric, you can convert between them only if their field names match!

Here's an example:

// Suppose that again, we have different User types representing the same data
// in different stages in our application logic.

#[derive(LabelledGeneric)]
struct NewUser<'a> {
    first_name: &'a str,
    last_name: &'a str,
    age: usize,
}

#[derive(LabelledGeneric)]
struct SavedUser<'a> {
    first_name: &'a str,
    last_name: &'a str,
    age: usize,
}

let n_user = NewUser {
    first_name: "Joe",
    last_name: "Blow",
    age: 30
};

// Convert from a NewUser to a Saved using LabelledGeneric
//
// This will fail if the fields of the types converted to and from do not
// have the same names or do not line up properly :)
//
// Also note that we're using a helper method to avoid having to use universal
// function call syntax
let s_user: SavedUser = frunk::labelled_convert_from(n_user);

assert_eq!(s_user.first_name, "Joe");
assert_eq!(s_user.last_name, "Blow");
assert_eq!(s_user.age, 30);

// Uh-oh ! last_name and first_name have been flipped!
#[derive(LabelledGeneric)]
struct DeletedUser<'a> {
    last_name: &'a str,
    first_name: &'a str,
    age: usize,
}

//  This would fail at compile time :)
let d_user: DeletedUser = frunk::labelled_convert_from(s_user);

// This will, however, work, because we make use of the Sculptor type-class
// to type-safely reshape the representations to align/match each other.
let d_user: DeletedUser = frunk::transform_from(s_user);
Transmogrifying

Sometimes you need might have one data type that is "similar in shape" to another data type, but it is similar recursively (e.g. it has fields that are structs that have fields that are a superset of the fields in the target type, so they are transformable recursively). .transform_from can't help you there because it doesn't deal with recursion, but the Transmogrifier can help if both are LabelledGeneric by transmogrify()ing from one to the other.

What is "transmogrifying"? In this context, it means to recursively tranform some data of type A into data of type B, in a typesafe way, as long as A and B are "similarly-shaped". In other words, as long as B's fields and their subfields are subsets of A's fields and their respective subfields, then A can be turned into B.

As usual, the goal with Frunk is to do this:

  • Using stable (so no specialisation, which would have been helpful, methinks)
  • Typesafe
  • No usage of unsafe

Here is an example:

use frunk::labelled::Transmogrifier;

#[derive(LabelledGeneric)]
struct InternalPhoneNumber {
    emergency: Option<usize>,
    main: usize,
    secondary: Option<usize>,
}

#[derive(LabelledGeneric)]
struct InternalAddress<'a> {
    is_whitelisted: bool,
    name: &'a str,
    phone: InternalPhoneNumber,
}

#[derive(LabelledGeneric)]
struct InternalUser<'a> {
    name: &'a str,
    age: usize,
    address: InternalAddress<'a>,
    is_banned: bool,
}

#[derive(LabelledGeneric, PartialEq, Debug)]
struct ExternalPhoneNumber {
    main: usize,
}

#[derive(LabelledGeneric, PartialEq, Debug)]
struct ExternalAddress<'a> {
    name: &'a str,
    phone: ExternalPhoneNumber,
}

#[derive(LabelledGeneric, PartialEq, Debug)]
struct ExternalUser<'a> {
    age: usize,
    address: ExternalAddress<'a>,
    name: &'a str,
}

let internal_user = InternalUser {
    name: "John",
    age: 10,
    address: InternalAddress {
        is_whitelisted: true,
        name: "somewhere out there",
        phone: InternalPhoneNumber {
            main: 1234,
            secondary: None,
            emergency: Some(5678),
        },
    },
    is_banned: true,
};

/// Boilerplate-free conversion of a top-level InternalUser into an
/// ExternalUser, taking care of subfield conversions as well.
let external_user: ExternalUser = internal_user.transmogrify();

let expected_external_user = ExternalUser {
    name: "John",
    age: 10,
    address: ExternalAddress {
        name: "somewhere out there",
        phone: ExternalPhoneNumber {
            main: 1234,
        },
    }
};

assert_eq!(external_user, expected_external_user);

Note that as of writing, there are a couple of known limitations with transmogrify(), some of which may be addressed in the future:

  • If one of the fields is an identical type and derives LabelledGeneric, the compiler will tell you that it can't "infer an index" for transmogrify(); this is because impls of the Transmogrifier trait will clash. This may or may not change in the future (perhaps if we move to a pure procedural macro powered way of doing things?)
  • For types that contain many multiple deeply-nested fields that require transmogfiy()ing, using this technique will likely increase your compile time.
  • If you've balked at the the compile-time errors with transform_from when a transform is deemed impossible (e.g. missing field), the errors for transmogrify() are worse to the degree that recursive transmogrify() is required for your types.

For more information how Generic and Field work, check out their respective Rustdocs:

Path

One of the other things that LabelledGeneric-deriving structs can do is be generically traversed using Path and its companion trait PathTraverser. In some circles, this functionality is also called a Lens.

Path-based traversals are

  • Easy to use through the procedural macro path! (frunk_proc_macros)
    • Traversing multiple levels is familiar; just use dot . syntax (path!(nested.attribute.value))
  • Compile-time safe
  • Composable (add one to the other using +)
  • Allows you to get by value, get by reference or get by mutable reference, depending on the type of thing you pass it.
#[derive(LabelledGeneric)]
struct Dog<'a> {
    name: &'a str,
    dimensions: Dimensions,
}

#[derive(LabelledGeneric)]
struct Cat<'a> {
    name: &'a str,
    dimensions: Dimensions,
}

#[derive(LabelledGeneric)]
struct Dimensions {
    height: usize,
    width: usize,
    unit: SizeUnit,
}

#[derive(Debug, Eq, PartialEq)]
enum SizeUnit {
    Cm,
    Inch,
}

let mut dog = Dog {
    name: "Joe",
    dimensions: Dimensions {
        height: 10,
        width: 5,
        unit: SizeUnit::Inch,
    },
};

let cat = Cat {
    name: "Schmoe",
    dimensions: Dimensions {
        height: 7,
        width: 3,
        unit: SizeUnit::Cm,
    },
};

// generic, re-usable, compsable paths
let dimensions_lens = path!(dimensions);
let height_lens = dimensions_lens + path!(height); // compose multiple
let unit_lens = path!(dimensions.unit); // dot syntax to just do the whole thing at once

assert_eq!(*height_lens.get(&dog), 10);
assert_eq!(*height_lens.get(&cat), 7);
assert_eq!(*unit_lens.get(&dog), SizeUnit::Inch);
assert_eq!(*unit_lens.get(&cat), SizeUnit::Cm);

// modify by passing a &mut
*height_lens.get(&mut dog) = 13;
assert_eq!(*height_lens.get(&dog), 13);

There's also a Path! type-level macro for declaring shape-constraints. This allows you to write adhoc shape-dependent functions for LabelledGeneric types.

// Prints height as long as `A` has the right "shape" (e.g.
// has `dimensions.height: usize` and `dimension.unit: SizeUnit)
fn print_height<'a, A, HeightIdx, UnitIdx>(obj: &'a A) -> ()
where
    &'a A: PathTraverser<Path!(dimensions.height), HeightIdx, TargetValue = &'a usize>
        + PathTraverser<Path!(dimensions.unit), UnitIdx, TargetValue = &'a SizeUnit>,
{
    println!(
        "Height [{} {:?}]",
        path!(dimensions.height).get(obj),
        path!(dimensions.unit).get(obj)
    );
}

See examples/paths.rs to see how this works.

Coproduct

If you've ever wanted to have an adhoc union / sum type of types that you do not control, you may want to take a look at Coproduct. In Rust, thanks to enum, you could potentially declare one every time you want a sum type to do this, but there is a light-weight way of doing it through Frunk:

use frunk::prelude::*; // for the fold method

// Declare the types we want in our Coproduct
type I32F32Bool = Coprod!(i32, f32, bool);

let co1 = I32F32Bool::inject(3);
let get_from_1a: Option<&i32> = co1.get();
let get_from_1b: Option<&bool> = co1.get();

assert_eq!(get_from_1a, Some(&3));
// None because co1 does not contain a bool, it contains an i32
assert_eq!(get_from_1b, None);

// This will fail at compile time because i8 is not in our Coproduct type
let nope_get_from_1b: Option<&i8> = co1.get(); // <-- will fail
// It's also impossible to inject something into a coproduct that is of the wrong type
// (not contained in the coproduct type)
let nope_co = I32F32Bool::inject(42f64); // <-- will fail

// We can fold our Coproduct into a single value by handling all types in it
assert_eq!(
    co1.fold(hlist![|i| format!("int {}", i),
                    |f| format!("float {}", f),
                    |b| (if b { "t" } else { "f" }).to_string()]),
    "int 3".to_string());

For more information, check out the docs for Coproduct

Validated

Validated is a way of running a bunch of operations that can go wrong (for example, functions returning Result<T, E>) and, in the case of one or more things going wrong, having all the errors returned to you all at once. In the case that everything went well, you get an HList of all your results.

Mapping (and otherwise working with plain) Results is different because it will stop at the first error, which can be annoying in the very common case (outlined best by the Cats project).

To use Validated, first:

use frunk::prelude::*; // for Result::into_validated

Assuming we have a Person struct defined

#[derive(PartialEq, Eq, Debug)]
struct Person {
    age: i32,
    name: String,
    street: String,
}

Here is an example of how it can be used in the case that everything goes smoothly.

fn get_name() -> Result<String, Error> { /* elided */ }
fn get_age() -> Result<i32, Error> { /* elided */ }
fn get_street() -> Result<String, Error> { /* elided */ }

// Build up a `Validated` by adding in any number of `Result`s
let validation = get_name().into_validated() + get_age() + get_street();
// When needed, turn the `Validated` back into a Result and map as usual
let try_person = validation.into_result()
                           // Destructure our hlist
                           .map(|hlist_pat!(name, age, street)| {
                               Person {
                                   name: name,
                                   age: age,
                                   street: street,
                               }
                           });

assert_eq!(try_person.unwrap(),
           Person {
               name: "James".to_owned(),
               age: 32,
               street: "Main".to_owned(),
           }));
}

If, on the other hand, our Results are faulty:

/// This next pair of functions always return Recover::Err
fn get_name_faulty() -> Result<String, String> {
    Result::Err("crap name".to_owned())
}

fn get_age_faulty() -> Result<i32, String> {
    Result::Err("crap age".to_owned())
}

let validation2 = get_name_faulty().into_validated() + get_age_faulty();
let try_person2 = validation2.into_result()
                             .map(|_| unimplemented!());

// Notice that we have an accumulated list of errors!
assert_eq!(try_person2.unwrap_err(),
           vec!["crap name".to_owned(), "crap age".to_owned()]);

Semigroup

Things that can be combined.

use frunk::Semigroup;
use frunk::semigroup::All;

assert_eq!(Some(1).combine(&Some(2)), Some(3));

assert_eq!(All(3).combine(&All(5)), All(1)); // bit-wise &&
assert_eq!(All(true).combine(&All(false)), All(false));

Monoid

Things that can be combined and have an empty/id value.

use frunk::monoid::combine_all;

let t1 = (1, 2.5f32, String::from("hi"), Some(3));
let t2 = (1, 2.5f32, String::from(" world"), None);
let t3 = (1, 2.5f32, String::from(", goodbye"), Some(10));
let tuples = vec![t1, t2, t3];

let expected = (3, 7.5f32, String::from("hi world, goodbye"), Some(13));
assert_eq!(combine_all(&tuples), expected)

let product_nums = vec![Product(2), Product(3), Product(4)];
assert_eq!(combine_all(&product_nums), Product(24))

Features

Frunk comes with support for deriving serde serializer/deserializers for its core data structures. This can be enabled by adding the serde feature flag.

For example, if you'd like to use just frunk_core with serde

[dependencies]
frunk_core = { version = "$version", features = ["serde"] }

Or, if you'd like to use frunk with serde, you need to explicitly include frunk_core as well

[dependencies]
frunk = { version = "$version", features = ["serde"] }
frunk_core = { version = "$version", features = ["serde"] }

Benchmarks

Benchmarks are available in ./benches and can be run with:

$ rustup run nightly cargo bench

Benchmarks on master are also auto-generated, uploaded and available online.

Todo

Stabilise interface, general cleanup

Before a 1.0 release, would be best to revisit the design of the interfaces and do some general code (and test cleanup).

Not yet implemented

Given that Rust has no support for Higher Kinded Types, I'm not sure if these are even possible to implement. In addition, Rustaceans are used to calling iter() on collections to get a lazy view, manipulating their elements with map or and_then, and then doing a collect() at the end to keep things efficient. The usefulness of these following structures maybe limited in that context.

  1. Functor
  2. Monad
  3. Apply
  4. Applicative

Contributing

Yes please !

The following are considered important, in keeping with the spirit of Rust and functional programming:

  • Safety (type and memory)
  • Efficiency
  • Correctness

Inspirations

Scalaz, Shapeless, Cats, Haskell, the usual suspects ;)

Maintainers

A.k.a. people whom you can bug/tag/@ on Gitter :D

  1. lloydmeta
  2. Centril
  3. ExpHP

Dependencies

~205–640KB
~15K SLoC