Utilities¶
The distribution provides utilities to simplify some tedious works beside proof development, tactics writing or documentation.
Using Coq as a library¶
In previous versions, coqmktop
was used to build custom
toplevels - for example for better debugging or custom static
linking. Nowadays, the preferred method is to use ocamlfind
.
The most basic custom toplevel is built using:
% ocamlfind ocamlopt -thread -rectypes -linkall -linkpkg \
-package coq.toplevel \
topbin/coqtop_bin.ml -o my_toplevel.native
For example, to statically link L
tac, you can just do:
% ocamlfind ocamlopt -thread -rectypes -linkall -linkpkg \
-package coq.toplevel,coq.plugins.ltac \
topbin/coqtop_bin.ml -o my_toplevel.native
and similarly for other plugins.
Building a Coq project¶
As of today it is possible to build Coq projects using two tools:
coq_makefile
, which is distributed by Coq and is based on generating a makefile,Dune, the standard OCaml build tool, which, since version 1.9, supports building Coq libraries.
Building a Coq project with coq_makefile¶
The majority of Coq projects are very similar: a collection of .v
files and eventually some .ml
ones (a Coq plugin). The main piece of
metadata needed in order to build the project are the command line
options to coqc
(e.g. -R
, -Q
, -I
, see command
line options). Collecting the list of files
and options is the job of the _CoqProject
file.
A _CoqProject
file may contain the following kinds of entries in any order,
separated by whitespace:
Selected options of coqc, which are forwarded directly to it. Currently these are
-Q
,-I
,-R
and-native-compiler
.-arg
options for other options of coqc that don’t fall in the above set.Options specific to
coq_makefile
. Currently this is only-docroot
.Paths to files belonging to the project.
Comments, started with an unquoted
#
and continuing to the end of the line.
A simple example of a _CoqProject
file follows:
-R theories/ MyCode
-arg "-w all"
theories/foo.v
theories/bar.v
-I src/
src/baz.mlg
src/bazaux.ml
src/qux_plugin.mlpack
-generate-meta-for-package my-package
Lines in the form -arg foo
pass the argument foo
to coqc
: in the
example, this allows to pass the two-word option -w all
(see
command line options).
Note that it is mandatory to specify a -R/-Q
flag for your
project, so its modules are properly qualified. Omitting it will
generate object files that are not usable except for expert cases.
Also note that when a project includes a plugin it also needs to include a
META
file, as per findlib.
If the project includes exactly one plugin, the META
file is
generated automatically when the option -generate-meta-for-package my-package
is given. The generated file will make the plugin available
to the Declare ML Module
as my-package.plugin
. If this does not suite
you, or you project features more than one plugin, then a file named
META.my-package
must be hand written and listed in the _CoqProject
file.
One can use ocamlfind lint META.my-package
to lint the hand written file.
Typically my-package
is the name of the OPAM
package for your project.
The -native-compiler
option given in the _CoqProject
file will override
the global one passed at configure time.
CoqIDE, Proof General, VsCoq and Coqtail all
understand _CoqProject
files and can be used to invoke Coq with the desired options.
The coq_makefile
utility can be used to set up a build infrastructure
for the Coq project based on makefiles. The recommended way of
invoking coq_makefile
is the following one:
coq_makefile -f _CoqProject -o CoqMakefile
Such command generates the following files:
- CoqMakefile
is a makefile for
GNU Make
with targets to build the project (e.g. generate .vo or .html files from .v or compile .ml* files) and install it in theuser-contrib
directory where the Coq library is installed.- CoqMakefile.conf
contains make variables assignments that reflect the contents of the
_CoqProject
file as well as the path relevant to Coq.
Run coq_makefile --help
for a description of command line options.
The recommended approach is to invoke CoqMakefile
from a standard
Makefile
of the following form:
Example
# KNOWNTARGETS will not be passed along to CoqMakefile
KNOWNTARGETS := CoqMakefile extra-stuff extra-stuff2
# KNOWNFILES will not get implicit targets from the final rule, and so
# depending on them won't invoke the submake
# Warning: These files get declared as PHONY, so any targets depending
# on them always get rebuilt
KNOWNFILES := Makefile _CoqProject
.DEFAULT_GOAL := invoke-coqmakefile
CoqMakefile: Makefile _CoqProject
$(COQBIN)coq_makefile -f _CoqProject -o CoqMakefile
invoke-coqmakefile: CoqMakefile
$(MAKE) --no-print-directory -f CoqMakefile $(filter-out $(KNOWNTARGETS),$(MAKECMDGOALS))
.PHONY: invoke-coqmakefile $(KNOWNFILES)
####################################################################
## Your targets here ##
####################################################################
# This should be the last rule, to handle any targets not declared above
%: invoke-coqmakefile
@true
The advantage of a wrapper, compared to directly calling the generated
Makefile
, is that it
provides a target independent of the version of Coq to regenerate a
Makefile
specific to the current version of Coq. Additionally, the
master Makefile
can be extended with targets not specific to Coq.
Including the generated makefile with an include directive is
discouraged, since the contents of this file, including variable names and
status of rules, may change in the future.
Use the optional file CoqMakefile.local
to extend
CoqMakefile
. In particular, you can declare custom actions to run
before or after the build process. Similarly you can customize the
install target or even provide new targets. See
CoqMakefile.local for extension-point documentation. Although
you can use all variables defined in CoqMakefile
in the recipes
of rules that you write and in the definitions of any variables that
you assign with =
, many variables are not available for use if you
assign variable values with :=
nor to define the targets of
rules nor in top-level conditionals such as ifeq
. Additionally,
you must use secondary expansion
to make use of such variables in the prerequisites of rules. To access
variables defined in CoqMakefile
in rule target computation,
top-level conditionals, and :=
variable assignment, for example to
add new dependencies to compiled outputs, use the optional file
CoqMakefile.local-late
. See CoqMakefile.local-late for a
non-exhaustive list of variables.
The extensions of files listed in _CoqProject
determine
how they are built. In particular:
Coq files must use the
.v
extensionOCaml files must use the
.ml
or.mli
extensionOCaml files that require pre processing for syntax extensions (like
VERNAC EXTEND
) must use the.mlg
extensionIn order to generate a plugin one has to list all OCaml modules (i.e.
Baz
forbaz.ml
) in a.mlpack
file (or.mllib
file).
The use of .mlpack
files has to be preferred over .mllib
files,
since it results in a “packed” plugin: All auxiliary modules (as
Baz
and Bazaux
) are hidden inside the plugin’s "namespace"
(Qux_plugin
). This reduces the chances of begin unable to load two
distinct plugins because of a clash in their auxiliary module names.
Comments¶
#
outside of double quotes starts a comment that continues to the end of the
line. Comments are ignored.
Quoting arguments to coqc¶
Any string in a _CoqProject
file may be enclosed in double quotes to include
whitespace characters or #
. For example, use -arg "-w all"
to pass the
argument -w all
to coqc. If the argument to coqc needs some quotes as well,
use single-quotes inside the double-quotes. For example -arg "-set 'Default
Goal Selector=!'"
gets passed to coqc as -set 'Default Goal Selector=!'
.
But note, that single-quotes in a _CoqProject
file are only special
characters if they appear in the string following -arg
. And on their own
they don't quote spaces. For example -arg 'foo bar'
in _CoqProject
is
equivalent to -arg foo "bar'"
(in _CoqProject
notation). -arg "'foo
bar'"
behaves differently and passes 'foo bar'
to coqc.
Forbidden filenames¶
The paths of files given in a _CoqProject
file may not contain any of the
following characters: \n
, \t
, space, \
, '
, "
, #
, $
,
%
. These characters have special meaning in Makefiles and
coq_makefile
doesn't support encoding them correctly.
Warning: No common logical root¶
When a _CoqProject
file contains something like -R theories Foo
theories/Bar.v
, the install-doc
target installs the documentation
generated by coqdoc
into user-contrib/Foo/
, in the folder where Coq was
installed.
But if the _CoqProject
file contains something like:
-R theories/Foo Foo
-R theories/Bar Bar
theories/Foo/Foo.v
theories/Bar/Bar.v
the Coq files of the project don’t have a logical path in common and
coq_makefile
doesn’t know where to install the documentation. It will give
a warning: "No common logical root" and generate a Makefile that installs the
documentation in some folder beginning with "orphan", in the above example,
it'd be user-contrib/orphan_Foo_Bar
.
In this case, specify the -docroot
option in _CoqProject to override
the automatically selected logical root.
CoqMakefile.local¶
The optional file CoqMakefile.local
is included by the generated
file CoqMakefile
. It can contain two kinds of directives.
Variable assignment
The variable must belong to the variables listed in the Parameters
section of the generated makefile. These include:
- CAMLPKGS
can be used to specify third party findlib packages, and is passed to the OCaml compiler on building or linking of modules. Eg:
-package yojson
.- CAMLFLAGS
can be used to specify additional flags to the OCaml compiler, like
-bin-annot
or-w
....- OCAMLWARN
it contains a default of
-warn-error +a-3
, useful to modify this setting; beware this is not recommended for projects in Coq's CI.- COQC, COQDEP, COQDOC
can be set in order to use alternative binaries (e.g. wrappers)
- COQ_SRC_SUBDIRS
can be extended by including other paths in which
*.cm*
files are searched. For exampleCOQ_SRC_SUBDIRS+=user-contrib/Unicoq
lets you build a plugin containing OCaml code that depends on the OCaml code ofUnicoq
- COQFLAGS
override the flags passed to
coqc
. By default-q
.- COQEXTRAFLAGS
extend the flags passed to
coqc
- COQCHKFLAGS
override the flags passed to
coqchk
. By default-silent -o
.- COQCHKEXTRAFLAGS
extend the flags passed to
coqchk
- COQDOCFLAGS
override the flags passed to
coqdoc
. By default-interpolate -utf8
.- COQDOCEXTRAFLAGS
extend the flags passed to
coqdoc
- COQLIBINSTALL, COQPLUGININSTALL, COQDOCINSTALL
specify where the Coq libraries, plugins and documentation will be installed. By default a combination of
$(DESTDIR)
(if defined) with$(COQLIB)/user-contrib
,$(COQCORELIB)/..
and$(DOCDIR)/coq/user-contrib
.
Use CoqMakefile.local-late instead to access more variables.
Rule extension
The following makefile rules can be extended.
Example
pre-all::
echo "This line is print before making the all target"
install-extra::
cp ThisExtraFile /there/it/goes
pre-all::
run before the
all
target. One can use this to configure the project, or initialize sub modules or check dependencies are met.post-all::
run after the
all
target. One can use this to run a test suite, or compile extracted code.install-extra::
run after
install
. One can use this to install extra files.install-doc::
One can use this to install extra doc.
uninstall::
uninstall-doc::
clean::
cleanall::
archclean::
merlin-hook::
One can append lines to the generated
.merlin
file extending this target.
CoqMakefile.local-late¶
The optional file CoqMakefile.local-late
is included at the end of the generated
file CoqMakefile
. The following is a partial list of accessible variables:
- COQ_VERSION
the version of
coqc
being used, which can be used to provide different behavior depending on the Coq version- COQMAKEFILE_VERSION
the version of Coq used to generate the Makefile, which can be used to detect version mismatches
- ALLDFILES
the list of generated dependency files, which can be used, for example, to cause
make
to recompute dependencies when files change by writing$(ALLDFILES): myfiles
or to indicate that files must be generated before dependencies can be computed by writing$(ALLDFILES): | mygeneratedfiles
- VOFILES, GLOBFILES, CMOFILES, CMXFILES, OFILES, CMAFILES, CMXAFILES, CMIFILES, CMXSFILES
lists of files that are generated by various invocations of the compilers
In addition, the following variables may be useful for
deciding what targets to present via $(shell ...)
; these
variables are already accessible in recipes for rules added in
CoqMakefile.local
, but are only accessible from top-level $(shell
...)
invocations in CoqMakefile.local-late
:
- COQC, COQDEP, COQDOC, CAMLC, CAMLOPTC
compiler binaries
- COQFLAGS, CAMLFLAGS, COQLIBS, COQDEBUG, OCAMLLIBS
flags passed to the Coq or OCaml compilers
Timing targets and performance testing¶
The generated Makefile
supports the generation of two kinds of timing
data: per-file build-times, and per-line times for an individual file.
The following targets and Makefile variables allow collection of per- file timing data:
TIMED=1
passing this variable will cause
make
to emit a line describing the user-space build-time and peak memory usage for each file built.Note
On
Mac OS
, this works best if you’ve installedgnu-time
.Example
For example, the output of
make TIMED=1
may look like this:COQDEP Fast.v COQDEP Slow.v COQC Slow.v Slow.vo (user: 0.34 mem: 395448 ko) COQC Fast.v Fast.vo (user: 0.01 mem: 45184 ko)
pretty-timed
this target stores the output of
make TIMED=1
intotime-of-build.log
, and displays a table of the times and peak memory usages, sorted from slowest to fastest, which is also stored intime-of-build-pretty.log
. If you want to construct thelog
for targets other than the default one, you can pass them via the variableTGTS
, e.g.,make pretty-timed TGTS="a.vo b.vo"
.Note
This target requires
python
to build the table.Note
This target will append to the timing log; if you want a fresh start, you must remove the file
time-of-build.log
orrun make cleanall
.Note
By default the table displays user times. If the build log contains real times (which it does by default), passing
TIMING_REAL=1
tomake pretty-timed
will use real times rather than user times in the table.Note
Passing
TIMING_INCLUDE_MEM=0
tomake
will result in the tables not including peak memory usage information. PassingTIMING_SORT_BY_MEM=1
tomake
will result in the tables be sorted by peak memory usage rather than by the time taken.Example
For example, the output of
make pretty-timed
may look like this:COQDEP VFILES COQC Slow.v Slow.vo (real: 0.52, user: 0.39, sys: 0.12, mem: 394648 ko) COQC Fast.v Fast.vo (real: 0.06, user: 0.02, sys: 0.03, mem: 56980 ko) Time | Peak Mem | File Name -------------------------------------------- 0m00.41s | 394648 ko | Total Time / Peak Mem -------------------------------------------- 0m00.39s | 394648 ko | Slow.vo 0m00.02s | 56980 ko | Fast.vo
print-pretty-timed-diff
this target builds a table of timing changes between two compilations; run
make make-pretty-timed-before
to build the log of the “before” times, and runmake make-pretty-timed-after
to build the log of the “after” times. The table is printed on the command line, and stored intime-of-build-both.log
. This target is most useful for profiling the difference between two commits in a repository.Note
This target requires
python
to build the table.Note
The
make-pretty-timed-before
andmake-pretty-timed-after
targets will append to the timing log; if you want a fresh start, you must remove the filestime-of-build-before.log
andtime-of-build-after.log
or runmake cleanall
before building either the “before” or “after” targets.Note
The table will be sorted first by absolute time differences rounded towards zero to a whole-number of seconds, then by times in the “after” column, and finally lexicographically by file name. This will put the biggest changes in either direction first, and will prefer sorting by build-time over subsecond changes in build time (which are frequently noise); lexicographic sorting forces an order on files which take effectively no time to compile.
If you prefer a different sorting order, you can pass
TIMING_SORT_BY=absolute
to sort by the total time taken, orTIMING_SORT_BY=diff
to sort by the signed difference in time.Note
Just like
pretty-timed
, this table defaults to using user times. PassTIMING_REAL=1
tomake
on the command line to show real times instead.Note
Just like
pretty-timed
, passingTIMING_INCLUDE_MEM=0
tomake
will result in the tables not including peak memory usage information. PassingTIMING_SORT_BY_MEM=1
tomake
will result in the tables be sorted by peak memory usage rather than by the time taken.Example
For example, the output table from
make print-pretty-timed-diff
may look like this:After | Peak Mem | File Name | Before | Peak Mem || Change || Change (mem) | % Change | % Change (mem) ----------------------------------------------------------------------------------------------------------------------------- 0m00.43s | 394700 ko | Total Time / Peak Mem | 0m00.41s | 394648 ko || +0m00.01s || 52 ko | +4.87% | +0.01% ----------------------------------------------------------------------------------------------------------------------------- 0m00.39s | 394700 ko | Fast.vo | 0m00.02s | 56980 ko || +0m00.37s || 337720 ko | +1850.00% | +592.69% 0m00.04s | 56772 ko | Slow.vo | 0m00.39s | 394648 ko || -0m00.35s || -337876 ko | -89.74% | -85.61%
The following targets and Makefile
variables allow collection of per-
line timing data:
TIMING=1
passing this variable will cause
make
to usecoqc -time
to write to a.v.timing
file for each.v
file compiled, which contains line-by-line timing information.Example
For example, running
make all TIMING=1
may result in a file like this:Chars 0 - 26 [Require~Coq.ZArith.BinInt.] 0.157 secs (0.128u,0.028s) Chars 27 - 68 [Declare~Reduction~comp~:=~vm_c...] 0. secs (0.u,0.s) Chars 69 - 162 [Definition~foo0~:=~Eval~comp~i...] 0.153 secs (0.136u,0.019s) Chars 163 - 208 [Definition~foo1~:=~Eval~comp~i...] 0.239 secs (0.236u,0.s)
print-pretty-single-time-diff
print-pretty-single-time-diff AFTER=path/to/file.v.after-timing BEFORE=path/to/file.v.before-timing
this target will make a sorted table of the per-line timing differences between the timing logs in the
BEFORE
andAFTER
files, display it, and save it to the file specified by theTIME_OF_PRETTY_BUILD_FILE
variable, which defaults totime-of-build-pretty.log
. To generate the.v.before-timing
or.v.after-timing
files, you should passTIMING=before
orTIMING=after
rather thanTIMING=1
.Note
The sorting used here is the same as in the
print-pretty-timed-diff
target.Note
This target requires python to build the table.
Note
This target follows the same sorting order as the
print-pretty-timed-diff
target, and supports the same options for theTIMING_SORT_BY
variable.Note
By default, two lines are only considered the same if the character offsets and initial code strings are identical. Passing
TIMING_FUZZ=N
relaxes this constraint by allowing the character locations to differ by up toN
, as long as the total number of characters and initial code strings continue to match. This is useful when there are small changes to a file, and you want to match later lines that have not changed even though the character offsets have changed.Note
By default the table picks up real times, under the assumption that when comparing line-by-line, the real time is a more accurate representation as it includes disk time and time spent in the native compiler. Passing
TIMING_REAL=0
tomake
will use user times rather than real times in the table.Example
For example, running
print-pretty-single-time-diff
might give a table like this:After | Code | Before || Change | % Change --------------------------------------------------------------------------------------------------- 0m00.50s | Total | 0m04.17s || -0m03.66s | -87.96% --------------------------------------------------------------------------------------------------- 0m00.145s | Chars 069 - 162 [Definition~foo0~:=~Eval~comp~i...] | 0m00.192s || -0m00.04s | -24.47% 0m00.126s | Chars 000 - 026 [Require~Coq.ZArith.BinInt.] | 0m00.143s || -0m00.01s | -11.88% N/A | Chars 027 - 068 [Declare~Reduction~comp~:=~nati...] | 0m00.s || +0m00.00s | N/A 0m00.s | Chars 027 - 068 [Declare~Reduction~comp~:=~vm_c...] | N/A || +0m00.00s | N/A 0m00.231s | Chars 163 - 208 [Definition~foo1~:=~Eval~comp~i...] | 0m03.836s || -0m03.60s | -93.97%
all.timing.diff
,path/to/file.v.timing.diff
The
path/to/file.v.timing.diff
target will make a.v.timing.diff
file for the corresponding.v
file, with a table as would be generated by theprint-pretty-single-time-diff
target; it depends on having already made the corresponding.v.before-timing
and.v.after-timing
files, which can be made by passingTIMING=before
andTIMING=after
. Theall.timing.diff
target will make such timing difference files for all of the.v
files that theMakefile
knows about. It will fail if some.v.before-timing
or.v.after-timing
files don’t exist.Note
This target requires python to build the table.
Building a subset of the targets with -j
¶
To build, say, two targets foo.vo and bar.vo in parallel one can use
make only TGTS="foo.vo bar.vo" -j
.
Note
make foo.vo bar.vo -j
has a different meaning for the make
utility, in particular it may build a shared prerequisite twice.
Precompiling for native_compute
¶
To compile files for native_compute
, one can use the
-native-compiler yes
option of Coq, by putting it in the _CoqProject
file.
The generated installation target of CoqMakefile
will then take care of
installing the extra .coq-native
directories.
Note
As an alternative to modifying _CoqProject
, one can set an
environment variable when calling make
:
COQEXTRAFLAGS="-native-compiler yes" make
This can be useful when files cannot be modified, for instance when
installing via OPAM a package built with coq_makefile
:
COQEXTRAFLAGS="-native-compiler yes" opam install coq-package
Note
This requires all dependencies to be themselves compiled with
-native-compiler yes
.
The grammar of _CoqProject¶
A _CoqProject
file encodes a list of strings using the following syntax:
CoqProject::=
blankcommentquoted_stringunquoted_string*blank
::=
spacehorizontal_tabnewlinecomment
::=
# comment_char* newlinequoted_string
::=
" quoted_char* "unquoted_string
::=
string_start_char unquoted_char*
where the following definitions apply:
space
,horizontal_tab
andnewline
stand for the corresponding ASCII characters.comment_char
is the set of all characters exceptnewline
.quoted_char
is the set of all characters except"
.string_start_char
is the set of all characters except those that matchblank
, or are"
or#
.unquoted_char
is the set of all characters except those that matchblank
or are#
.
The parser produces a list of strings in the same order as they were
encountered in _CoqProject
. Blanks and comments are removed
and the double quotes of quoted_string
tokens are removed as
well. The list is then treated as a list of command-line arguments of
coq_makefile
.
The semantics of -arg
are as follows: the string given as argument is split
on whitespace, but single quotes prevent splitting. The resulting list of
strings is then passed to coqc.
The current approach has a few limitations: Double quotes in a _CoqProject
file are only special characters at the start of a string. For lack of an
escaping mechanism, it is currently impossible to pass the following kinds of
strings to coq_makefile
using a _CoqProject
file:
strings starting with
"
strings starting with
#
and containing"
strings containing both whitespace and
"
In addition, it is impossible to pass strings containing '
to coqc via
-arg
.
Building a Coq project with Dune¶
Note
Dune's Coq support is still experimental; we strongly recommend using Dune 3.2 or later.
Note
The canonical documentation for the Coq Dune extension is maintained upstream; please refer to the Dune manual for up-to-date information. The documentation below is up to date for Dune 3.2
Building a Coq project with Dune requires setting up a Dune project
for your files. This involves adding a dune-project
and
pkg.opam
file to the root (pkg.opam
can be empty or generated
by Dune itself), and then providing dune
files in the directories
your .v
files are placed. For the experimental version "0.3" of
the Coq Dune language, Coq library stanzas look like:
(coq.theory
(name <module_prefix>)
(package <opam_package>)
(synopsis <text>)
(modules <ordered_set_lang>)
(libraries <ocaml_libraries>)
(flags <coq_flags>))
This stanza will build all .v
files in the given directory, wrapping
the library under <module_prefix>
. If you declare an
<opam_package>
, an .install
file for the library will be
generated; the optional (modules <ordered_set_lang>)
field allows
you to filter the list of modules, and (libraries
<ocaml_libraries>)
allows the Coq theory depend on ML plugins. For
the moment, Dune relies on Coq's standard mechanisms (such as
COQPATH
) to locate installed Coq libraries.
By default Dune will skip .v
files present in subdirectories. In
order to enable the usual recursive organization of Coq projects add
(include_subdirs qualified)
to you dune
file.
Once your project is set up, dune build
will generate the
pkg.install
files and all the files necessary for the installation
of your project.
Note that projects using Dune to build need to use the compatibility
syntax for Declare ML Module
, see example below:
Example
A typical stanza for a Coq plugin is split into two parts. An OCaml build directive, which is standard Dune:
(library
(name equations_plugin)
(public_name equations.plugin)
(flags :standard -warn-error -3-9-27-32-33-50)
(libraries coq.plugins.cc coq.plugins.extraction))
(coq.pp (modules g_equations))
And a Coq-specific part that depends on it via the libraries
field:
(coq.theory
(name Equations) ; -R flag
(package equations)
(synopsis "Equations Plugin")
(libraries coq.plugins.extraction equations.plugin)
(modules :standard \ IdDec NoCycle)) ; exclude some modules that don't build
(include_subdirs qualified)
For now, each .v
file that loads the plugin must use
the following special syntax on its Declare ML Module
command for compatibility with current Dune versions (as of Coq 8.16):
Declare ML Module "equations_plugin:equations.plugin".
Computing Module dependencies¶
In order to compute module dependencies (to be used by make
or
dune
), Coq provides the coqdep
tool.
coqdep
computes inter-module dependencies for Coq
programs, and prints the dependencies on the standard output in a
format readable by make. When a directory is given as argument, it is
recursively looked at.
Dependencies of Coq modules are computed by looking at Require
and Declare ML Module
commands.
See the man page of coqdep
for more details and options.
Both Dune and coq_makefile
use coqdep
to compute the
dependencies among the files part of a Coq project.
Split compilation of native computation files¶
Coq features a native_compute
tactic to provide fast computation in the
kernel. This process performs compilation of Coq terms to OCaml programs using
the OCaml compiler, which may cause an important overhead. Hence native
compilation is an opt-in configure flag.
When native compilation is activated, Coq generates the compiled files upfront,
i.e. during the coqc
invocation on the corresponding .v
file. This is
impractical because it means one must chose in advance whether they will use
a native-capable Coq installation. In particular, activating native compilation
forces the recompilation of the whole Coq installation. See
command line options for more details.
Starting from Coq 8.14, a new binary coqnative
is available. It allows
performing split native compilation by generating the native compute files out
of the compiled .vo
file rather than out of the source .v
file.
The coqnative
command takes a name file.vo as argument and tries to
perform native compilation on it. It assumes that the Coq libraries on which
file.vo depends have been first compiled to their native files, and will fail
otherwise. It accepts the -R
, -Q
, -I
and -nI
arguments with the
same semantics as if the native compilation process had been performed through
coqc
. In particular, it means that:
-R
and-Q
are equivalent-I
is a no-op that is accepted only for scripting convenience
Embedded Coq phrases inside LaTeX documents¶
When writing documentation about a proof development, one may want
to insert Coq phrases inside a LaTeX document, possibly together
with the corresponding answers of the system. We provide a mechanical
way to process such Coq phrases embedded in LaTeX files: the coq-tex
filter. This filter extracts Coq phrases embedded in LaTeX files,
evaluates them, and insert the outcome of the evaluation after each
phrase.
Starting with a file file.tex
containing Coq phrases, the coq-tex
filter produces a file named file.v.tex
with the Coq outcome.
There are options to produce the Coq parts in smaller font, italic,
between horizontal rules, etc. See the man page of coq-tex
for more
details.
Man pages¶
There are man pages for the commands coqdep
and coq-tex
. Man
pages are installed at installation time (see installation
instructions in file INSTALL
, step 6).