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authorVincent Ambo <tazjin@google.com>2019-07-04T10·18+0100
committerVincent Ambo <tazjin@google.com>2019-07-04T10·18+0100
commitf723b8b878a3c4a4687b9e337a875500bebb39b1 (patch)
treee85204cf042c355e90cff61c111e7d8cd15df311 /third_party/bazel/rules_haskell/docs/haskell-use-cases.rst
parent2eb1dc26e42ffbdc168f05ef744bd4b4f3e4c36f (diff)
feat(third_party/bazel): Check in rules_haskell from Tweag r/17
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+.. _use-cases:
+
+Common Haskell Build Use Cases
+==============================
+
+Picking a compiler
+------------------
+
+Unlike Bazel's native C++ rules, rules_haskell does not auto-detect
+a Haskell compiler toolchain from the environment. This is by design.
+We require that you declare a compiler to use in your ``WORKSPACE``
+file.
+
+There are two common sources for a compiler. One is to use the
+official binary distributions from `haskell.org`_. This is done using
+the `ghc_bindist`_ rule.
+
+The compiler can also be pulled from Nixpkgs_, a set of package
+definitions for the `Nix package manager`_. Pulling the compiler from
+Nixpkgs makes the build more hermetic, because the transitive closure
+of the compiler and all its dependencies is precisely defined in the
+``WORKSPACE`` file. Use `rules_nixpkgs`_ to do so (where ``X.Y.Z``
+stands for any recent release)::
+
+  load("@bazel_tools//tools/build_defs/repo:http.bzl", "http_archive")
+
+  http_archive(
+      name = "io_tweag_rules_nixpkgs",
+      strip_prefix = "rules_nixpkgs-X.Y.Z",
+      urls = ["https://github.com/tweag/rules_nixpkgs/archive/vX.Y.Z.tar.gz"],
+  )
+
+  load(
+      "@io_tweag_rules_nixpkgs//nixpkgs:nixpkgs.bzl",
+      "nixpkgs_git_repository",
+      "nixpkgs_package"
+  )
+
+  nixpkgs_git_repository(
+      name = "nixpkgs",
+      revision = "18.09", # Any tag or commit hash
+  )
+
+  nixpkgs_package(
+      name = "ghc",
+      repositories = { "nixpkgs": "@nixpkgs//:default.nix" }
+      attribute_path = "haskell.compiler.ghc843", # Any compiler version
+      build_file = "@io_tweag_rules_haskell//haskell:ghc.BUILD",
+  )
+
+  register_toolchains("//:ghc")
+
+This workspace description specifies which Nixpkgs version to use,
+then exposes a Nixpkgs package containing the GHC compiler. The
+description assumes that there exists a ``BUILD`` file at the root of
+the repository that includes the following::
+
+  haskell_toolchain(
+    name = "ghc",
+    # Versions here and in WORKSPACE must match.
+    version = "8.4.3",
+    # Use binaries from @ghc//:bin to define //:ghc toolchain.
+    tools = ["@ghc//:bin"],
+  )
+
+.. _Bazel+Nix blog post: https://www.tweag.io/posts/2018-03-15-bazel-nix.html
+.. _Nix package manager: https://nixos.org/nix
+.. _Nixpkgs: https://nixos.org/nixpkgs/manual/
+.. _ghc_bindist: http://api.haskell.build/haskell/ghc_bindist.html#ghc_bindist
+.. _haskell.org: https://haskell.org
+.. _haskell_binary: http://api.haskell.build/haskell/haskell.html#haskell_binary
+.. _haskell_library: http://api.haskell.build/haskell/haskell.html#haskell_library
+.. _rules_nixpkgs: https://github.com/tweag/rules_nixpkgs
+
+Loading targets in a REPL
+-------------------------
+
+Rebuilds are currently not incremental *within* a binary or library
+target (rebuilds are incremental across targets of course). Any change
+in any source file will trigger a rebuild of all source files listed
+in a target. In Bazel, it is conventional to decompose libraries into
+small units. In this way, libraries require less work to rebuild.
+Still, for interactive development full incrementality and fast
+recompilation times are crucial for a good developer experience. We
+recommend making all development REPL-driven for fast feedback when
+source files change.
+
+Every `haskell_binary`_ and every `haskell_library`_ target has an
+optional executable output that can be run to drop you into an
+interactive session. If the target's name is ``foo``, then the REPL
+output is called ``foo@repl``.
+
+Consider the following binary target::
+
+  haskell_binary(
+      name = "hello",
+      srcs = ["Main.hs", "Other.hs"],
+      deps = ["//lib:some_lib"],
+  )
+
+The target above also implicitly defines ``hello@repl``. You can call
+the REPL like this (requires Bazel 0.15 or later)::
+
+  $ bazel run //:hello@repl
+
+This works for any ``haskell_binary`` or ``haskell_library`` target.
+Modules of all libraries will be loaded in interpreted mode and can be
+reloaded using the ``:r`` GHCi command when source files change.
+
+Building code with Hackage dependencies (using Nix)
+---------------------------------------------------
+
+Each Haskell library or binary needs a simple build description to
+tell Bazel what source files to use and what the dependencies are, if
+any. Packages on Hackage don't usually ship with `BUILD.bazel` files.
+So if your code depends on them, you either need to write a build
+description for each package, generate one (see next section), or
+decide not to use Bazel to build packages published on Hackage. This
+section documents one way to do the latter.
+
+Nix is a package manager. The set of package definitions is called
+Nixpkgs. This repository contains definitions for most actively
+maintained Cabal packages published on Hackage. Where these packages
+depend on system libraries like zlib, ncurses or libpng, Nixpkgs also
+contains package descriptions for those, and declares those as
+dependencies of the Cabal packages. Since these definitions already
+exist, we can reuse them instead of rewriting these definitions as
+build definitions in Bazel. See the `Bazel+Nix blog post`_ for a more
+detailed rationale.
+
+To use Nixpkgs in Bazel, we need `rules_nixpkgs`_. See `Picking
+a compiler`_ for how to import Nixpkgs rules into your workspace and
+how to use a compiler from Nixpkgs. To use Cabal packages from
+Nixpkgs, replace the compiler definition with the following::
+
+  nixpkgs_package(
+      name = "ghc",
+      repositories = { "nixpkgs": "@nixpkgs//:default.nix" },
+      nix_file = "//:ghc.nix",
+      build_file = "@io_tweag_rules_haskell//haskell:ghc.BUILD",
+  )
+
+This definition assumes a ``ghc.nix`` file at the root of the
+repository. In this file, you can use the Nix expression language to
+construct a compiler with all the packages you depend on in scope::
+
+  with (import <nixpkgs> {});
+
+  haskellPackages.ghcWithPackages (p: with p; [
+    containers
+    lens
+    text
+  ])
+
+Each package mentioned in ``ghc.nix`` can then be imported using
+`haskell_toolchain_library`_ in ``BUILD`` files.
+
+.. _haskell_toolchain_library: http://api.haskell.build/haskell/haskell.html#haskell_toolchain_library
+
+Building code with Hackage dependencies (using Hazel)
+-----------------------------------------------------
+
+.. todo::
+
+   Explain how to use Hazel instead of Nix
+
+Generating API documentation
+----------------------------
+
+The `haskell_doc`_ rule can be used to build API documentation for
+a given library (using Haddock). Building a target called
+``//my/pkg:mylib_docs`` would make the documentation available at
+``bazel-bin/my/pkg/mylib_docs/index/index.html``.
+
+Alternatively, you can use the
+``@io_tweag_rules_haskell//haskell:haskell.bzl%haskell_doc_aspect``
+aspect to ask Bazel from the command-line to build documentation for
+any given target (or indeed all targets), like in the following:
+
+.. code-block:: console
+
+  $ bazel build //my/pkg:mylib \
+      --aspects @io_tweag_rules_haskell//haskell:haskell.bzl%haskell_doc_aspect
+
+.. _haskell_doc: http://api.haskell.build/haskell/haddock.html#haskell_doc
+
+Linting your code
+-----------------
+
+The `haskell_lint`_ rule does not build code but runs the GHC
+typechecker on all listed dependencies. Warnings are treated as
+errors.
+
+Alternatively, you can directly check a target using
+
+.. code-block:: console
+
+  $ bazel build //my/haskell:target \
+      --aspects @io_tweag_rules_haskell//haskell:haskell.bzl%haskell_lint_aspect
+
+.. _haskell_lint: http://api.haskell.build/haskell/lint.html#haskell_lint
+
+Checking code coverage
+----------------------
+
+"Code coverage" is the name given to metrics that describe how much source 
+code is covered by a given test suite.  A specific code coverage metric 
+implemented here is expression coverage, or the number of expressions in 
+the source code that are explored when the tests are run.
+
+Haskell's ``ghc`` compiler has built-in support for code coverage analysis, 
+through the hpc_ tool. The Haskell rules allow the use of this tool to analyse 
+``haskell_library`` coverage by ``haskell_test`` rules. To do so, you have a 
+few options. You can add 
+``expected_covered_expressions_percentage=<some integer between 0 and 100>`` to
+the attributes of a ``haskell_test``, and if the expression coverage percentage
+is lower than this amount, the test will fail. Alternatively, you can add
+``expected_uncovered_expression_count=<some integer greater or equal to 0>`` to
+the attributes of a ``haskell_test``, and instead the test will fail if the
+number of uncovered expressions is greater than this amount. Finally, you could
+do both at once, and have both of these checks analyzed by the coverage runner.
+To see the coverage details of the test suite regardless of if the test passes
+or fails, add ``--test_output=all`` as a flag when invoking the test, and there 
+will be a report in the test output. You will only see the report if you
+required a certain level of expression coverage in the rule attributes.
+
+For example, your BUILD file might look like this: ::
+
+  haskell_library(
+    name = "lib",
+    srcs = ["Lib.hs"],
+    deps = [
+        "//tests/hackage:base",
+    ],
+  )
+
+  haskell_test(
+    name = "test",
+    srcs = ["Main.hs"],
+    deps = [
+        ":lib",
+        "//tests/hackage:base",
+    ],
+    expected_covered_expressions_percentage = 80,
+    expected_uncovered_expression_count = 10,
+  )
+
+And if you ran ``bazel coverage //somepackage:test --test_output=all``, you 
+might see a result like this: ::
+
+  INFO: From Testing //somepackage:test:
+  ==================== Test output for //somepackage:test:
+  Overall report
+  100% expressions used (9/9)
+  100% boolean coverage (0/0)
+      100% guards (0/0)
+      100% 'if' conditions (0/0)
+      100% qualifiers (0/0)
+  100% alternatives used (0/0)
+  100% local declarations used (0/0)
+  100% top-level declarations used (3/3)
+  =============================================================================
+
+Here, the test passes because it actually has 100% expression coverage and 0
+uncovered expressions, which is even better than we expected on both counts.
+
+There is an optional ``haskell_test`` attribute called
+``strict_coverage_analysis``, which is a boolean that changes the coverage
+analysis such that even having better coverage than expected fails the test.
+This can be used to enforce that developers must upgrade the expected test
+coverage when they improve it. On the other hand, it requires changing the
+expected coverage for almost any change.
+
+There a couple of notes regarding the coverage analysis functionality:
+
+- Coverage analysis currently is scoped to all source files and all
+  locally-built Haskell dependencies (both direct and transitive) for a given
+  test rule.
+- Coverage-enabled build and execution for ``haskell_test`` targets may take
+  longer than regular. However, this has not effected regular ``run`` /
+  ``build`` / ``test`` performance.
+
+.. _hpc: <http://hackage.haskell.org/package/hpc>