Public and Private packages

We just saw in the previous section that it was possible to have multiple versions of the same package, as long as we create independant virtual packages called buckets. Oftentimes, creating buckets with fixed version boundaries and which are shared among the whole dependency system can cause versions mismatches in dependency chains. This is for example the case with a chain of packages publicly re-exporting types of their dependencies and interacting with each other. Concretely, let's say that we depend on two packages "a" and "b", with "a" also depending on "b" but at a different version.

  • "root" depends on "a" @ 1
  • "root" depends on "b" @ 1
  • "a" @ 1 depends on "b" @ 2

Without buckets, there is no solution since "b" is depended on at two different versions. If we introduce buckets with boundaries at major versions, we have a solution since "root" depends on "b#1" while "a#1" depends on bucket "b#2".

But, what if package "a" re-exports in its public interface a type coming from its "b" dependency? If we feed a function of "a" with a type from "b#1", compilation will fail, complaining about the argument being of the wrong type. Currently in the rust compiler, this creates cryptic error messages of the kind "Expected type T, found type T", where "T" is exactly the same thing. Of course, those compiler errors should be improved, but there is a way of preventing that situation entirely at the time of solving dependencies instead of at compilation time. We can call that the public/private scheme. It consists in marking dependencies with re-exported types as "public", while other dependencies are considered "private" since they don't leak their types. So instead of saying that "a" depends on "b", we say that "a" publicly depends on "b". Therefore public dependencies must be unique even across multiple major versions.

Note that there is one inconvenience though, which is that we could have false positives, i.e. reject situations that the compiler would have accepted to compile. Indeed, it's not because "a" has public types of "b" exposed that we are necessarily using them! Now let's detail a bit more the public/private scheme and how it could be implemented with PubGrub.

Public subgraph

Two versions of a package can only conflict with each other if they interact through a chain of publicly connected dependencies. This means that any private dependency can cut the chain of public dependencies. If "a" privately depends on "b", dependencies of "b" are guaranteed to be independant (usage wise) of the rest of the dependency graph above package "a". This means that there is not one list of public packages, but rather multiple subgraphs of publicly connected packages, which start either at the root, or at a private dependency frontier. And in each public subgraph, there can only be one version of each package.

Seed markers

Since dependencies form a directed graph, each public subgraph can be uniquely identified by a root package, that we will call the "seed" of the public subgraph. This "seed" is in fact the source package of a private dependency link, and all publicly connected packages following the target package of the private dependency link can be marked with that seed. In addition, all packages behind a private link can only be accessed by the source package of that private dependency, so all seed markers existing previous to the private link can be cleared, leaving only seed marker of the source package. The diagram below provides a visual example of dependency graphs where seed markers are annotated next to each package.

In fact, as soon as a package has at least one private dependency, all dependency branches must be marked with the seed marker of the source package. This is because all branches contain code that is used by the source package. As a result, if a package has both a private dependency and a public dependency, the public dependency will inherit all markers of the source package plus a new seed marker for the source package itself. Therefore, the number of seed markers along a public dependency chain grows with the number of branches that also contain private dependencies, as visible in the diagram below.

Example

Let's consider the previous branching example where "b" is depended on both by our root package and by our dependency "a". If we note seed markers with a dollar symbol "$" that example can be adapted to the following system.

  • "root" depends on "a$root" @ 1
  • "root" depends on "b$root" @ 1
  • "a$root" @ 1 depends privately on "b$a@1" @ 2

Seed markers must correspond to an exact package version because multiple versions of a given package will have different dependency graphs, and we don't want to wrongly assume that all subgraphs are the same for all versions. Here, since "a" depends privately on "b", "b" is marked with the seed "$a@1". Thus, this system has the following solution.

  • "a$root" @ 1
  • "b$root" @ 1
  • "b$a@1" @ 2

If instead of a private dependency, "a" had a public dependency on "b", there would be no new seed marker and it would read:

  • "a$root" @ 1 depends publicly on "b$root" @ 2

Leading to no solution, since the package "b$root" is now required both at version 1 and 2.

Example implementation

The seed markers scheme presented above can easily be implemented with pubgrub by keeping seed markers together with package names in the Package type involved in the DependencyProvider. A complete example implementation of this extension allowing public and private dependencies is available in the public-private crate of the advanced_dependency_providers repository. In that example, packages are of the type String and versions of the type SemanticVersion defined in pubgrub, which does not account for pre-releases, just the (Major, Minor, Patch) format of versions.

Defining an index of packages

Inside the index.rs module, we define a very basic Index, holding all packages known, as well as a helper function add_deps easing the writing of tests.


#![allow(unused)]
fn main() {
/// Each package is identified by its name.
pub type PackageName = String;
/// Alias for dependencies.
pub type Deps = Map<PackageName, (Privacy, Range<SemVer>)>;
/// Privacy indicates if a dependency is public or private.
pub enum Privacy { Public, Private }

/// Global registry of known packages.
pub struct Index {
    /// Specify dependencies of each package version.
    pub packages: Map<PackageName, BTreeMap<SemVer, Deps>>,
}

// Initialize an empty index.
let mut index = Index::new();
// Add package "a" to the index at version 1.0.0 with no dependency.
index.add_deps::<R>("a", (1, 0, 0), &[]);
// Add package "a" to the index at version 2.0.0 with a private dependency to "b" at versions >= 1.0.0.
index.add_deps("a", (2, 0, 0), &[("b", Private, (1, 0, 0)..)]);
// Add package "a" to the index at version 3.0.0 with a public dependency to "b" at versions >= 1.0.0.
index.add_deps("a", (3, 0, 0), &[("b", Public, (1, 0, 0)..)]);
}

Implementing a dependency provider for the index

Since our Index is ready, we now have to implement the DependencyProvider trait for it. As explained previously, we need to identify which public subgraphs a given dependency belongs to. That is why each package also holds seed markers, which are the identifiers of the "seed" packages at the origin of each public subgraph this package belongs to. Since we need a unique hash for each package for each seed, and there can be multiple seed markers, the PkgSeeds type is actually an enum where a Markers variant will have exactly one dependency to a Constraint variant per seed listed in its markers, in addition to the dependencies registered in the index. And as its name suggests, the Constraint variant of a PkgSeeds package is only there to make sure that the "1-version-per-seed" constraint is satisfied and does not have any dependency. Thanks to that, we guarantee that there can only be one version of each package per public subgraph.


#![allow(unused)]
fn main() {
/// A package is identified by its name and by the public subgraphs
/// it belongs to, themselves identified by "seeds".
pub struct Package {
    name: String,
    seeds: PkgSeeds,
}

/// Each public subgraph is identified by a seed,
/// and some packages belong to multiple public subgraphs
/// and can thus have multiple seed markers.
/// Since we also need to have a unique hash per package, per public subgraph,
/// Each `Markers` variant of a package will also have a dependency on
/// one `Constraint` variant per seed, resulting in one unique identifier
/// per public subgraph that PubGrub can use to check constraints on versions.
///
/// Remark: `Markers.pkgs` is just an implementation detail to prevent cycles
/// with seeds of different versions and same package,
/// which is impossible since we cannot pick two different versions
/// of the same package in the same public subgraph.
pub enum PkgSeeds {
    Constraint(Seed),
    Markers {
        seed_markers: Set<Seed>,
        pkgs: Set<String>,
    },
}

/// A seed is the identifier associated with the private package
/// at the origin of a public subgraph.
pub struct Seed {
    /// Seed package identifier
    pub name: String,
    /// Seed version identifier
    pub version: SemVer,
}
}

Implementing choose_package_version is trivial if we simply use the function choose_package_with_fewest_versions provided by pubgrub. Implementing get_dependencies is slightly more complicated. Have a look at the complete implementation if needed, the main ideas are the following.


#![allow(unused)]
fn main() {
fn get_dependencies(&self, package: &Package, version: &SemVer)
-> Result<Dependencies<Package, SemVer>, ...> {
    match &package.seeds {
        // A Constraint variant does not have any dependency
        PkgSeeds::Constraint(_) => Ok(Dependencies::Known(Map::default())),
        // A Markers variant has dependencies to:
        // - one Constraint variant per seed marker
        // - one Markers variant per original dependency
        PkgSeeds::Markers { seed_markers, pkgs } => {
            // Seed constraints, one per seed for this package@version.
            let seed_constraints = ...;
            // Figure out if there are private dependencies.
            let has_private = ...;
            Ok(Dependencies::Known(
                // Chain the seed constraints with actual dependencies.
                seed_constraints
                    .chain(index_deps.iter().map(|(p, (privacy, r))| {
                        let seeds = if privacy == &Privacy::Private {
                            // make a singleton seed package
                        } else if has_private {
                            // this is public but there is also a private dep,
                            // so add the source package to the seed markers
                        } else {
                            // simply reuse the parent seed markers
                        };
                        ( Package { name: p, seeds }, r )
                    }))
                    .collect(),
            ))
        }
    }
}
}