This page is intended to keep track of useful information for people who want to modify the Flambda backend. Jump to:
- Hacking on the Flambda backend
- Branches, pull requests, etc.
- Code formatting
- Rebuilding during dev work
- Updating magic numbers
- Running tests
- Running only part of the upstream testsuite
- Running tests with coverage analysis
- Running the compiler produced by "make hacking" on an example without the stdlib
- Using the OCaml debugger to debug the compiler
- Getting the compilation command for a stdlib file
- Bootstrapping
- Testing the compiler built locally with OPAM (new method)
- Testing the compiler built locally with OPAM (old method)
- How to add a new intrinsic to the compiler
- How to add a new command line option
- Installation tree comparison script
Pull requests should be submitted to the main
branch, which is the default.
PRs should not be merged unless all CI checks have passed unless there is a good reason. It is not necessary to wait for CI checks to pass after genuinely trivial changes to a PR that was previously passing CI.
There are also release microbranches (e.g. 5.2.0minus-1-microbranch
) which are
used for cutting production releases (which are all marked by git tags). These
branches should not be committed to without approval from the person responsible
for the next release.
The CI checks that all Flambda 2 code (in middle_end/flambda2/
) and
Cfg code (in backend/cfg/
) is
formatted correctly as per the provided .ocamlformat
file. To prepare
your environment for the correct version of ocamlformat
you can follow
the OPAM commands in the CI check. (Note that the OPAM compiler will not
be used for the Flambda backend build itself.) All of the code can be
formatted using make fmt
and the check can be run using make check-fmt
.
Note in particular that a recent (>= 1.10.0) version of the re
library is
required due to a bug in the parsing of .ocamlformat-enable
syntax.
Changes to .ocamlformat
should be made as pull requests that include
reformatting files as needed.
In the event that one needs to rebase a patch over formatting changes, here is a reasonably seamless way to proceed:
Assuming a specific formatting commit:
# main formatting commit for flambda2/ in the repository
format_commit=331c16734636a218261d4835fb77b38c5788f50a
Rebase as usual until its parent:
git rebase $format_commit~1
Then rebase once more on the commit itself:
git rebase $format_commit -Xtheirs --exec 'make fmt && git commit -a --amend --no-edit'
Each commit will be amended with formatting. Any conflict appearing can be resolved automatically by choosing our side (hence, theirs
on a rebase, surprisingly enough). This is correct assuming the commit contains no semantic changes.
Finally, finish the rebase as usual up to the desired point:
git rebase upstream/main
Depending on the initial changes, it might be necessary to do this multiple times for each relevant formatting commit.
To rebuild after making changes, you can just type make
. You need to
have a working OCaml 4.14 or 4.14.1 compiler on your PATH before doing so,
e.g. installed via OPAM. You also need to have dune and menhir.
menhir
should be pinned to a specific version: opam pin add menhir 20231231
.
There is a special target make hacking
which starts Dune in polling mode. The rebuild
performed here is equivalent to make ocamlopt
in the upstream distribution: it rebuilds the
compiler itself, but doesn't rebuild the stdlib or anything else with the new compiler.
This target is likely what you want for development of large features in the middle end or
backend. Rebuild times for this target should be very fast. (make hacking
can be
run directly after configure
, there is no need to do a full make
first.)
We should be able to use tools/bump-magic-numbers
going forward.
Prior to make install
you can do:
make runtest
to run the Flambda backend tests (which use dune);make runtest-upstream
to run the upstream testsuite. The upstream testsuite runs much faster if you install GNU parallel. This is likely already present on Linux machines. On macOS, install Homebrew, thenbrew install parallel
.
There is also a make ci
target which does a full build and test run.
Some of our tests are expect tests run using a custom tool called flexpect
.
Corrected outputs can be promoted using make promote
.
See HACKING.jst.adoc
for documentation on additional test-related
targets. Here are some examples of commands you can run:
$ make test-one TEST=typing-local/local.ml
$ make test-one-no-rebuild TEST=typing-local/local.ml
$ make promote-one TEST=typing-local/local.ml
$ make promote-one-no-rebuild TEST=typing-local/local.ml
# Promote failures from the last run
$ make promote-failed
# You can also use the full path from the root of the repo.
# This interacts better with tab completion.
$ make test-one TEST=testsuite/tests/typing-local/local.ml
This can be done from the _runtest
directory after it has been initialised by a previous make runtest-upstream
.
Any changes you have made to the tests in the real testsuite directory (testsuite/
) will need to be copied
into here first. Then you can do things like:
OCAMLSRCDIR=<FLAMBDA_BACKEND>/_runtest make one DIR=tests/runtime-errors
where <FLAMBDA_BACKEND>
is the path to your clone.
You may also need the CAML_LD_LIBRARY_PATH
setting depending on what you are testing (see Makefile.in
at the
root).
Coverage analysis is available for the Flambda backend tests (that is, just the
ones run by make runtest
), which are intended to provide good coverage on
their own. We use bisect_ppx
to perform the analysis. Since binaries
instrumented with bisect_ppx
have coverage enabled unconditionally, coverage
support is disabled by default at compile time.
Coverage requires the bisect_ppx
package to be installed in your OPAM switch.
Since no OPAM environment is available when building the final compiler, we
instead enable coverage on the boot compiler and run the tests directly on the
boot compiler.
To enable coverage, pass the --enable-coverage
flag to ./configure
.
(Remember to clean, as by git clean -dfX
, whenever re-running
./configure
). When coverage is enabled, make boot-runtest
will
run the tests on the boot compiler and produce coverage data, and
make coverage
will produce an HTML report in _coverage/
. Alternatively,
with coverage enabled, make ci
will build the boot compiler, run the
tests, and produce the report.
For small examples that don't need the stdlib or any other library provided by the
compiler distribution, it suffices to have run make hacking
, followed by
something like:
./_build/_bootinstall/bin/ocamlopt.opt -nostdlib -nopervasives -c test.ml
First, run make debug
. This completes four steps:
make install
- Sets up the
tools/debug_printers
script so that you cansource tools/debug_printers
during a debugging session to see otherwise-abstract variable values. - Symlinks
./ocamlc
and./ocamlopt
to point to the bytecode versions of those compilers. This is convenient for emacs integration, because emacs looks for sources starting in the directory containing the executable. - Creates a
.ocamldebug
file to automatically load the right search path and thedebug_printers
set up above.
Then it's time to run the debugger itself. The recommended workflow is to add
the elisp below to your emacs init file, and then use the command
ocamldebug-ocamlc
to debug ocamlc
or the command ocamldebug-ocamlopt
to
debug ocamlopt
. Running your built ocamldebug
file on ocamlc
or ocamlopt
should also work, if you wish to work outside emacs.
;; directly inspired by the ocamldebug implementation in ocamldebug.el
(require 'ocamldebug)
(defun ocamldebug-ocaml (cmd)
"Runs ocamldebug on the provided command"
(interactive)
(let* ((ocaml-dir (expand-file-name
(locate-dominating-file (buffer-file-name) ".git")))
(pgm-path (file-name-concat ocaml-dir cmd))
(comint-name (concat "ocamldebug-" cmd))
(buffer-name (concat "*" comint-name "*"))
(ocamldebug-command-name
(file-name-concat ocaml-dir "_build/install/main/bin/ocamldebug")))
(unless (file-exists-p ocamldebug-command-name)
(error "No debugger found; run `make debug` first."))
(pop-to-buffer buffer-name)
(unless (comint-check-proc buffer-name)
(setq default-directory ocaml-dir)
(setq ocamldebug-debuggee-args
(read-from-minibuffer (format "Args for ocamlc: ")
ocamldebug-debuggee-args))
;; In addition to the directories in .ocamldebug, use 'find' to
;; see also list directories with -I; this finds any new cmo directories
;; since the last 'make debug'
(let* ((cmo-top-dir (file-name-concat ocaml-dir "_build/main"))
(find-cmo-cmd (concat "find "
cmo-top-dir
" -name '*.cmo' -type f -printf '%h\n' | sort -u"))
(cmo-dirs (shell-command-to-string find-cmo-cmd)))
(setq cmo-dir-list (split-string cmo-dirs "\n" t)))
(let* ((user-args (split-string-shell-command ocamldebug-debuggee-args))
(includes (mapcan (lambda (dir) (list "-I" dir)) cmo-dir-list))
(args (append (list
comint-name
ocamldebug-command-name
nil
"-emacs"
"-cd" default-directory)
includes
(list pgm-path)
user-args)))
(apply #'make-comint args)
(set-process-filter (get-buffer-process (current-buffer))
#'ocamldebug-filter)
(set-process-sentinel (get-buffer-process (current-buffer))
#'ocamldebug-sentinel)
(ocamldebug-mode)))
(ocamldebug-set-buffer)))
(defun ocamldebug-ocamlc ()
"Runs ocamldebug on the ocamlc built from the source file in the active buffer"
(interactive)
(ocamldebug-ocaml "ocamlc"))
(defun ocamldebug-ocamlopt ()
"Runs ocamldebug on the ocamlopt built from the source file in the active buffer"
(interactive)
(ocamldebug-ocaml "ocamlopt"))
These commands will prompt you for the arguments to be passed to the compiler.
Usually this includes the location of a test .ml
file to be compiled (note
that ~
will not be expanded, so using a full path is often necessary).
Compiler command line flags may also be passed this way (e.g., -extension
flags).
Once at the ocamldebugger's (ocd)
prompt, you are ready to set breakpoints
in relevant compiler source files with C-x C-a C-b
and run
the debugger.
See the manual section for more information about the debugger.
Rather than using our elisp above, you can instead manually invoke the ocamldebug emacs mode as follows:
- Run
M-x camldebug RET
- Choose the
ocamlc
orocamlopt
symlink in the root of the repo. - Choose the arguments to pass to the compiler, likely a full path to a test
.ml
file. - Choose the built
ocamldebug
, in your install directory. - Set any breakpoints you want. The easiest way is to navigate to the line
where you want the breakpoint and use
C-x C-a C-b
in emacs. - Add relevant directories to
ocamldebug
's search path. (If you skip this, printing any value may produceCannot find module Misc.
or similar errors). If debuggingocamlc
, run:If debugging(ocd) directory _build/main/.ocamlcommon.objs/byte
ocamlopt
, you'll need various additional directories depending on your middle end. You can find the right directories by searching for cmo files corresponding to the module named in the error message. run
to your breakpoint.
The elisp ocamldebug-ocaml{c,opt}
functions automate steps 1, 2, 4, 6, and 7,
above.
For example because you need to get the -dflambda
output because of a bug.
rm -f _build/runtime_stdlib/stdlib/.stdlib.objs/native/std_exit.cmx
<DUNE> build --workspace=duneconf/runtime_stdlib.ws --verbose stdlib/.stdlib.objs/native/std_exit.cmx
where <DUNE>
is the path to the dune provided to configure
.
Bootstrapping is not required in flambda-backend. The system compiler is used for the first stage.
This is still under development, but should work!
opam repo add flambda-backend git+https://github.com/chambart/opam-repository-js.git#with-extensions
opam switch create 5.2.0+flambda2 --repos flambda-backend,default
eval $(opam env --switch=5.2.0+flambda2)
It is possible to create a OPAM switch with the Flambda backend compiler.
The first step is to choose where to put the switch. One possibility is to use a
local switch at the root of the tree, in which case the prefix will be
${flambda-backend-root-dir}/_opam
, but it's also possible to use a local switch elsewhere or
a global switch. For a global switch named flambda-backend
, the prefix will be
$(opam var root)/flambda-backend
.
The Flambda backend must then be configured with this switch as prefix:
./configure --prefix=${opam_switch_prefix} ...
Note that if the Flambda backend tree is already configured, it should be cleaned
thoroughly (e.g. git clean -dfX
) before reconfiguring with a different prefix.
Then build the compiler with the command make _install
(this is the default
target plus some setup in preparation for installation). As usual when building,
a 4.14 compiler (and dune and menhir) need to be in the path. See the warning above
about the version of menhir to use.
Now the build part is done, we don't need to stay in the build environment anymore; the switch creation will likely replace it if your terminal is setup to automatically follow the active opam switch.
The next step is to create the switch if it wasn't done already (if you already had created a switch from a previous attempt, you will need to remove it first):
# For a local switch:
opam switch create . --empty --repositories=flambda2=git+https://github.com/ocaml-flambda/flambda2-opam.git,default
# For a global switch:
opam switch create flambda-backend --empty --repositories=flambda2=git+https://github.com/ocaml-flambda/flambda2-opam.git,default
Then we can install the compiler. The recommended way is to use the opam-custom-install
plugin. See here
for instructions. The plugin can be installed in any existing OPAM switch,
for example a 4.14 switch used for building. Once installed, the plugin will be
available whatever the current active switch is.
Once the plugin is installed, we can use it to install the compiler:
opam custom-install ocaml-variants.4.14.0+flambda2 -- make -C ${flambda-backend-root-dir} install_for_opam
The -C ${flambda-backend-dir}
part can be omitted if we're still in the build directory.
Note that due to issues with some versions of the custom-install plugin,
it is recommended to run the command opam reinstall --forget-pending
after
every use of opam custom-install
, otherwise any subsequent opam
command
tries to rebuild the compiler from scratch.
To finish the installation, opam install ocaml.4.14.0
will install the remaining
auxiliary packages necessary for a regular switch. After that, normal opam
packages can be installed the usual way.
It is also possible to update the compiler after hacking, by running the
opam custom-install
command again. It also accepts a -n
flag to skip
recompilation of the packages which depend on the compiler, which can be useful
when the output of the compiler is unchanged apart from extra logging.
As opam-custom-install
is still experimental, it can sometimes be hard to install.
In this case, it is possible to use the more fragile opam install --fake
command:
opam install --fake ocaml-variants.4.14.0+flambda2
make -C ${flambda-backend-root-dir} install_for_opam
The main drawback of this approach is that there isn't any way to cleanup an
installation properly without deleting the whole switch; if the set of installed
files change between one make install_for_opam
command and the next, strange
bugs might appear.
The Flambda backend has a means of replacing calls to external functions with inline instruction sequences. This can be used to implement "intrinsic" operations that typically correspond to very few (often one) machine instruction. The external functions, typically written in C, can still be provided for portability.
Follow the steps below to first update the ocaml_intrinsics library, and then the compiler.
- Choose existing .ml file or add a new one.
- Add
external
declaration of the function with two C stubs: for bytecode and native implementations. Only C stubs for bytecode should be annotated with CAMLprim. Naming convention: start the stubs withcaml_
because the aim is to integrate them into the compiler. - Make sure that the C stubs work correctly on all support targets (architectures, operating systems, and compilers).
- Annotate with
[noalloc]
[@unboxed]
and[@untagged]
as appropriate. These annotations only apply to the native C stub. - Annotated with
[@@builtin]
which gives the compiler a permission to replace calls to the native C stub with instructions. - Annotate with
[@only_generative_effects]
,[@no_effects]
, and[@no_coeffects]
, described insemantics_of_primitives.mli
in the compiler. These annotations are used by middle-end optimizations and therefore apply to only to native compilation. Their use is currently inaccurate in the compiler when it comes to generative effects involving arguments and return values only. In particular, when the native C stub is[@@noalloc]
and its return value is[@unboxed]
, the function should be marked with[@only_generative_effects]
, but is it currently marked with[@no_effects]
, to be consistent with compiler builtins. This will be fixed in Flambda2. - Add tests and benchmarks for the new functions.
- Now, and only now, update the compiler. The intrinsics can be added in one
of the two places in
backend
directory: -- Cmm: Add an instruction to cmm and update cmmgen to emit it for the corresponding function application. The intrinsics will be applied on all supported architectures, but emitting it might involve changes in all the IRs below Cmm in all targets.Proc.operation_supported
make the process easier. -- Mach: add an architecture-specifc instruction by extending Ispecific, and update selection.ml. - Compile the library with the modified compiler, making sure that all tests pass. Check that functions calls are replaced with the corresponding instructions by manually inspecting the generated assembly code.
- There are currently no compiler tests for different intrinics. It
relies on the library tests to avoid duplication. Library tests use
Core
, but the library itself does not.
- Add a ref to
flambda_backend_flags.ml{i}
- Add the flag's constructor
mk_<flag>
inflambda_backend_args.ml
- Add the callback for the new flag to
Flambda_backend_options
module type inflambda_backend_args.ml{i}
- List the flag in the body of
Make_flambda_backend_options
functor - Implement the flag in
Flambda_backend_options_impl
by setting the corresponding ref in Flambda_backend_flags - Add the flag to
Extra_params
if it can be set viaOCAMLPARAM
A target make compare
exists to run a comparison script that finds differences
between the upstream and Flambda backend install trees. This script currently
only runs on Linux, although it shouldn't be hard to port to macOS, especially
if using GNU binutils. It is recommended to install the Jane Street patdiff
executable
before running make compare
. The comparison script has not been maintained since the
early releases of the Flambda backend; it was written as part of the acceptance process
for the initial release.