* Update rules_haskell: Generates version macros - rules_haskell now generates a version macros header file that is passed on to preprocessors such as c2hs or hsc2hs. - The haskell_import rule was also renamed to haskell_toolchain_library. * Drop unix-compat patch This was necessary to work around missing version macros.
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Haskell in Bazel
Finding your way around our Bazel build system from a Haskell developers' point of view might seem confusing at first. Going beyond just adding targets to BUILD.bazel
files requires a more detailed understanding of the system:
- Where rules come from;
- How toolchains and external dependencies are defined;
- Specifiying stock
bazel
command options.
For this, one needs awareness of four files at the root level of the DAML repository : WORKSPACE
, deps.bzl
, BUILD
and .bazelrc
.
.bazelrc
the Bazel configuration file
The bazel
command accepts many options. To avoid having to specify them manually for every build they can be collected into a .bazelrc
file. The root of daml.git
contains such a file. There doesn't seem to be anything in ours that is Haskell specific.
WORKSPACE
The root of daml.git
is a Bazel "workspace" : there exists a file WORKSPACE
. In short, in a WORKSPACE
we declare external packages and register toolchains. Visible in a WORKSPACE
are the targets of the BUILD.bazel
file at the same level as WORKSPACE
and any BUILD.bazel
files contained in sub-directories of the directory containing WORKSPACE
.
Bazel extensions are loaded by a load
statement. More or less the first couple of lines of our WORKSPACE
reads:
load("//:deps.bzl", "daml_deps")
daml_deps()
Much of the contents of the WORKSPACE
file have been factored out into deps.bzl
so that other projects can share the definitions contained there. Looking into deps.bzl
it begins:
load("@bazel_tools//tools/build_defs/repo:http.bzl", "http_archive")
load("@bazel_tools//tools/build_defs/repo:git.bzl", "git_repository")
This loads the contents of the files http.bzl
and git.bzl
from the external workspace bazel_tools
into the "environment". bazel_tools
is an external workspace builtin to Bazel and provides rules for working with archives and git.
[Note : Confusingly (?), //bazel_tools
is a DAML package (a sub-directory of the root package directory containing a BUILD.bazel
file). Don't confuse @bazel_tools//..
with //bazel_tools/..
].
Straight after the loading of those rules, deps.bzl
reads,
http_archive(
name = "io_tweag_rules_haskell",
strip_prefix = 'rules_haskell-%s' % rules_haskell_version,
urls = ["https://github.com/tweag/rules_haskell/archive/%s.tar.gz" % rules_haskell_version],
)
This defines the workspace io_tweag_rules_haskell
(we call this "rules_haskell
" informally - in short, build rules for Haskell) as an external workspace that is downloaded via http. From here on we can refer to things in that workspace by prefixing them with @io_tweag_rules_haskell
as in the next command from WORKSPACE
,
load("@io_tweag_rules_haskell//haskell:repositories.bzl", "haskell_repositories")
which has the effect of making the macro haskell_repositories
available in the environment which provides "all repositories necessary for rules_haskell
to function":
haskell_repositories()
As mentioned earlier, targets of any BUILD.bazel
file in a package are visible within WORKSPACE
. In fact, its a rule that toolchains can only be defined in BUILD.bazel
files and registered in WORKSPACE
files. register_toolchains
registers a toolchain created with the toolchain
rule so that it is available for toolchain resolution.
register_toolchains(
"//:ghc",
"//:c2hs-toolchain",
)
Those toolchains are defined in BUILD
(we'll skip listing their definitions here).
Rules for importing nix packages are provided in the workspace io_tweag_rules_nixpkgs
:
http_archive(
name = "io_tweag_rules_nixpkgs",
strip_prefix = "rules_nixpkgs-%s" % rules_nixpkgs_version,
urls = ["https://github.com/tweag/rules_nixpkgs/archive/%s.tar.gz" % rules_nixpkgs_version],
)
load(
"@io_tweag_rules_nixpkgs//nixpkgs:nixpkgs.bzl",
"nixpkgs_local_repository", "nixpkgs_git_repository", "nixpkgs_package", "nixpkgs_cc_configure",
)
nixpkgs_local_repository
creates an external repository representing the content of of a Nix package collection, based on Nix expressions stored in files in our //nix
directory.
nixpkgs_local_repository(
name = "nixpkgs",
nix_file = "//nix:bazel-nixpkgs.nix",
)
nixpkgs_local_repository(
name = 'dev_env_nix',
nix_file = '//nix:default.nix',
)
nixpkgs_cc_configure
tells Bazel to use compilers and linkers from the Nix package collection for the CC toolchain (overriding auto-detection from the current PATH
):
nixpkgs_cc_configure(
nix_file = "//nix:bazel-cc-toolchain.nix",
repositories = dev_env_nix_repos,
)
where,
dev_env_nix_repos = {
"nixpkgs": "@nixpkgs",
"damlSrc": "@dev_env_nix",
}
nixpkgs_package
provisions Bazel with our GHC toolchain from Nix:
nixpkgs_package(
name = "ghc",
attribute_path = "ghcWithC2hs",
nix_file = "//nix:default.nix",
repositories = dev_env_nix_repos,
build_file = "@ai_formation_hazel//:BUILD.ghc",
)
We see in the last macro invocation, forward reference to the ai_formation_hazel
workspace. Here's its definition:
http_archive(
name = "ai_formation_hazel",
strip_prefix = "hazel-{}".format(hazel_version),
# XXX: Switch to upstream once necessary changes are merged.
# urls = ["https://github.com/formationai/hazel/archive/{}.tar.gz".format(hazel_version)],
urls = ["https://github.com/DACH-NY/hazel/archive/{}.tar.gz".format(hazel_version)],
)
Hazel is a Bazel framework of build rules for third-party Haskell dependencies - it autogenerates Bazel rules from Cabal files. From the @ai_formation_hazel
workspace we load
load("@ai_formation_hazel//:hazel.bzl", "hazel_repositories", "hazel_custom_package_hackage")
Immediately thereafter we load from the DAML //hazel
"package":
load("//hazel:packages.bzl", "core_packages", "packages")
and from there we the DAML //bazel_tools
project the add_extra_packages
macro for packages on Hackage but not in Stackage:
load("//bazel_tools:haskell.bzl", "add_extra_packages")
The hazel_repositories
macro creates a separate external dependency for each package. It downloads Cabal tarballs from Hackage and constructs build rules for compiling the components of each such package:
hazel_repositories(
core_packages = core_packages (...),
packages = add_extra_packages (...),
...
)
Note that ghc-lib
is added here as one such "extra package".
We use hazel_custom_package_hackage
if the default Bazel build that Hazel generates won't quite work and needs some overrides. The overrides go into a file that is pointed at by the build_file
attribute:
hazel_custom_package_hackage(
package_name = "clock",
version = "0.7.2",
sha256 = "886601978898d3a91412fef895e864576a7125d661e1f8abc49a2a08840e691f",
build_file = "//3rdparty/haskell:BUILD.clock",
)
BUILD
At the root of the repository, alongside WORKSPACE
there exists the top-level package definition file BUILD
. The primary purpose of this BUILD
file is to define toolchains (but it does a couple of other little things as well).
The directive
package(default_visibility = ["//visibility:public"])
sets the default visibility property globally for our targets as public
. This means that our targets can freely be depended upon by other targets.
The load
statments
load("@io_tweag_rules_haskell//haskell:haskell.bzl",
"haskell_toolchain", "haskell_toolchain_library", "haskell_cc_import",
)
load("@io_tweag_rules_haskell//haskell:c2hs.bzl",
"c2hs_toolchain",
)
bring the macros haskell_toolchain
, haskell_toolchain_library
, haskell_cc_import
and c2hs_toolchain
into scope from rules_haskell
.
haskell_toolchain_library
:
- import a package that is prebuilt outside of Bazel
haskell_cc_import
:
- import a C library that is prebuilt outside of Bazel
haskell_toolchain
:
- declare a GHC compiler toolchain
c2hs_toolchain
:
- declare a Haskell
c2hs
toolchain
Lastly, there are some aliases defined here. For example,
alias(
name = "damlc",
actual = "//daml-foundations/daml-tools/da-hs-damlc-app"
)
Profiling
To produce a binary with profiling information, you need to pass -c dbg
to Bazel. E.g., bazel build -c dbg damlc
will build a profiled
version of damlc
. Note that by default Bazel won’t automatically add
cost centres in your code. To get cost centres, you can either add
cost centres manually
or use one of the
options provided by GHC
to add them automatically.
You can either add those options in the compiler_flags
section of a
specific target, modify the da_haskell_library
wrapper in
bazel_tools/haskell.bzl
to add a flag to all DAML targets and
libraries or use it for all targets by modifying the
compiler_flags
in the haskell_toolchain
.
Further reading:
- "Bazel User Guide" (DAML specific)
- "A Users's Guide to Bazel" (official documentation)
rules_haskell
documentation (core Haskell rules, Haddock support, Linting, Defining toolchains, Support for protocol buffers, Interop withcc_*
rules, Workspace rules)