Version 4 (modified by simonmar, 5 years ago) (diff)


Commentary: The Package System


GHC maintains a package database, that is basically a list of InstalledPackageInfo. The InstalledPackageInfo type is defined in Distribution.InstalledPackageInfo in Cabal, and both ghc-pkg and GHC itself import it directly from there.

There are four main components of the package system:

Cabal is a Haskell library, which provides basic datatypes for the package system, and support for building, configuring, and installing packages.
GHC itself
GHC reads the package database(s), understands the flags -package, -hide-package, etc., and uses the package database to find .hi files and library files for packages. GHC imports modules from Cabal.
The ghc-pkg tool manages the package database, including registering/unregistering packages, queries, and checking consistency. ghc-pkg also imports modules from Cabal.
A tool built on top of Cabal, which adds support for downloading packages from Hackage, and building and installing multiple packages with a single command.

For the purposes of this commentary, we are mostly concerned with GHC and ghc-pkg.

Identifying Packages

A string, e.g. "base". Defined in Distribution.Package. Does not uniquely identify a package: the package database can contain several packages with the same name.
A PackageName plus a Version. Does uniquely identify a package, but only by convention (we may lift this restriction in the future). InstalledPackageInfo contains the field package :: PackageIdentifier.
An opaque string. Each package is uniquely identified by its InstalledPackageId. Dependencies between installed packages are also identified by the InstalledPackageId.
Inside GHC, we use the type PackageId, which is a FastString. The (Z-encoding of) PackageId prefixes each external symbol in the generated code, so that the modules of one package do not clash with those of another package, even when the module names overlap.

Design constraints

  1. We want Commentary/Compiler/RecompilationAvoidance to work. So that means symbol names should not contain any information that varies too often, such as the ABI hash of the module or package. The ABI of an entity should depend only on its definition, and the definitons of the things it depends on.
  1. We want to be able to detect ABI incompatibility. If a package is recompiled and installed over the top of the old one, and the new version is ABI-incompatible with the old one, then packages that depended on the old version should be detectably broken using the tools.
  1. ABI compatibility:
    • We want repeatable compilations. Compiling a package with the same inputs should yield the same outputs.
    • Furthermore, we want to be able to make compiled packages that expose an ABI that is compatible (e.g. a superset) of an existing compiled package.
    • Modular upgrades: we want to be able to upgrade an existing package without recompiling everything that depends on it, by ensuring that the replacement is ABI-compatible.
    • Shared library upgrades. We want to be able to substitute a new ABI-compatible shared library for an old one, and all the existing binaries linked against the old version continue to work.
    • ABI compatibility is dependent on GHC too; changes to the compiler and RTS can introduce ABI incompatibilities. We guarantee to only make ABI incompatible changes in a major release of GHC. Between major releases, ABI compatibilty is ensured; so for example it should be possible to use GHC 6.12.2 with the packages that came with GHC 6.12.1.

Right now, we do not have repeatable compilations, so while we cannot do (3), we keep it in mind.

The Plan

We need to talk about some more package Ids:

  • InstalledPackageId: the identifier of a package in the package database. The InstalledPackageId is just a string, but it may contain the package name and API version for documentation.
  • PackageSymbolId: the symbol prefix used in compiled code.
  • PackageLibId: the package Id in the name of a compiled library file (static and shared).

Detecting ABI incompatibility

  • in the package database, dependencies specify the InstalledPackageId.
  • The package database will contain at most one instance of a given package/version combination. The tools are not currently able to cope with multiple instances (e.g. GHC's -package flag selects by name/version).
  • If, say, package P-1.0 is recompiled and re-installed, the new instance of the package will almost certainly have an incompatible ABI from the previous version. We give the new package a distinct InstalledPackageId, so that packages that depend on the old P-1.0 will now be detectably broken.
  • PackageSymbolId: We do not use the InstalledPackageId as the symbol prefix in the compiled code, because that interacts badly with Commentary/Compiler/RecompilationAvoidance. Every time we pick a new unique InstalledPackageId (e.g. when reconfiguring the package), we would have to recompile the entire package. Hence, the PackageSymbolId is picked deterministically for the package, e.g. it can be the PackageIdentifier.
  • PackageLibId: we do want to put the InstalledPackageId in the name of a library file, however. This allows ABI incompatibility to be detected by the linker. This is important for shared libraries too: we want an ABI-incompatible shared library upgrade to be detected by the dynamic linker. Hence, PackageLibId == InstalledPackageId.

Allowing ABI compatibilty

  • The simplest scheme is to have an identifier for each distinct ABI, e.g. a pair of the package name and an integer that is incremented each time an ABI change of any kind is made to the package. The ABI identifier is declared by the package, and is used as the PackageSymbolId. Since packages with the same ABI identifier are ABI-compatible, the PackageLibId can be the same as the PackageSymbolId.
  • The previous scheme does not allow ABI-compatible changes (e.g. ABI extension) to be made. Hence, we could generalise it to a major/minor versioning scheme.
    • the ABI major version is as before, the package name + an integer. This is also the PackageSymbolId.
    • the ABI minor version is an integer that is incremented each time the ABI is extended in a compatible way.
    • package dependencies in the database specify the major+minor ABI version they require, in addition to the InstalledPackageId. They may be satisfied by a greater minor version; when upgrading a package with an ABI-compatible replacement, ghc-pkg updates dependencies to point to the new InstalledPackageId.
    • PackageLibId is the major version. In the case of shared libraries, we may name the library using the major + minor versions, with a symbolic link from the major version to major+minor.
    • the shared library SONAME is the major version.
  • The previous scheme only allows ABI-compatible changes to be made in a linear sequence. If we want a tree-shaped compatibility structure, then something more complex is needed (ToDo).
  • The previous schemes only allow compatible ABI changes to be made. If we want to allow incompatible changes to be made, then we need something like ELF's symbol versioning. This is probably overkill, since we will be making incompatible ABI changes in the compiler and RTS at regular intervals anyway. ABI compatibility is more important between major releases of the compiler.