Notes for Writing Language Targets
zproject is a community project, like most ZeroMQ projects, built using the C4.1 process, and licensed under MPL v2. It solves the Makefile problem really well. It is unashamedly for C, and more pointedly, for that modern C dialect we call CLASS. CLASS is the Minecraft of C: fun, easy, playful, mind-opening, and social. Read more about it hintjens#79.
zproject grew out of the work that has been done to automatically generate the build environment in CZMQ. It allows to share these automations with other projects like zyre, malamute or hydra and at the same time keep everything in sync.
zproject has these primary goals:
All you need is a project.xml file in the project's root directory which is your
One file to rule them all
At least the following build environments are currently supported:
Thanks to the ZeroMQ community, you can do all the heavy lifting in C and then easily generate bindings in the following languages:
The language bindings are minimal, meant to be wrapped in a handwritten idiomatic layer later.
To understand step by step what zproject can do for you, read chapter 3 of @hintjens book Scalable C. Note that the book is still work in progress!
zproject uses the universal code generator called GSL to process its XML inputs and create its outputs. Before you start you'll need to install GSL (https://github.com/zeromq/gsl) on your system.
git clone https://github.com/zeromq/gsl.git
cd gsl/src
make
make install
GSL must be able to find the zproject resources on your system. Therefore you'll
need to install them. The following will install the zproject files to
/usr/local/bin
.
git clone https://github.com/zeromq/zproject.git
cd zproject
./autogen.sh
./configure
make
make install
NB: You may need to use the sudo
command when running make install
to elevate your privileges, e.g.
sudo make install
NB: If you don't have superuser rights on a system you'll have to make sure zproject's gsl scripts can be found on your PATH.
The easiest way to start is to create a minimal project.xml.
<project script = "zproject.gsl">
<use project = "czmq" />
<main name = "hello" private = "1" />
</project>
Once you're done you can create your project's build environment and start compiling:
gsl project.xml
autogen.sh
configure.sh
make
NB: To get a more comprehensive example copy zproject's project.xml. It contains all possible configurations and according documentation.
Licensing your project is important thus you'll need a license file. Here's an overview that might help you decide to choose a license. zproject allows you to add an appropriate disclaimer of your license as a xml file, e.g. license.xml:
<license>
Your license disclaimer goes here!
</license>
This disclaimer can be included in your project.xml and is used whenever zproject is generating new files e.g. CLASS skeletons or bindings.
<include filename = "license.xml" />
zproject's project.xml
contains an extensive description of the available configuration: The following snippet is taken from the project.xml
:
<!--
The project.xml generates build environments for:
autotools GNU build system (default)
cmake CMake build system (default)
android Native shared library for Android
cucumber Integration with cucumber-c
cygwin Cygwin build system
debian packaging for Debian
delphi Delphi binding
docker packaging for Docker
ios Native library for iOS
java Java JNI binding
java-msvc MSVC builds for Java JNI binding
jenkins Jenkins pipeline build
mingw32 Mingw32 build system
nuget Packaging for NuGet
python Python binding
qml QML binding
qt Qt binding
redhat Packaging for RedHat
ruby Ruby binding
gh_actions Github Actions configuration (same options as travis)
travis Travis CI scripts
<option name="dist" value="trusty" /> Select a Linux distribution to use by default on Travis CI, also impacts the OBS-served repository of ZMQ-family packages to use (if not building from source all the time per use_pkg_deps_prereqs_source below). By default it would be "xenial" as of now.
<option name="distcheck" value="0" /> "0" will disable run of make distcheck in Travis CI, "2" will enable it as a special testcase allowed to fail (default: 1 to enable and require to pass)
<option name="use_pkg_deps_prereqs_source" value="0" /> "0" will disable use of use_pkg_deps_prereqs_source list in Travis CI and so cause rebuild of everything from scratch (default: 1, recently packaged prereqs must exist then)
<option name="use_cmake" value="0" /> "0" will disable use of CMake recipes in Travis CI (default: 1)
<option name="require_gitignore" value="1" /> "1" will require that the workspace is clean with regard to .gitignore settings after build (default: 0)
<option name="clangformat_allow_failures" value="0" /> "1" will generate the option allowing non-fatal failure of clang-format test in Travis CI (default: 1)
<option name="clangformat_require_good" value="0" /> "1" will generate the option allowing to report and not ignore failure of clang-format test in Travis CI (otherwise "0" hides the failure, and devs must look in test logs) (default: same as allow_failures)
<option name="clangformat_implem" value="cmake|autotools" /> will pick one of two implems of the clang-format test in Travis CI (cmake is default and faster if available, since autotools needs to configure first)
<option name="check_abi_compliance" value="0" /> "1" will compare the currently tested commit's ABI to the one in a "latest_release" branch or tag, using packaged prerequisites. Due to these limitations, the option is off by default.
<option name="check_zproject" value="0" /> "1" will regenerate the zproject of the tested commit, and will verify that nothing changed, "2" will enable it as a special testcase allowed to fail. Many projects do customize their originally generated codebase, so to avoid surprises this option is off by default.
<option name="shadow_gcc" value="0" /> "1" will enable builds with warnings configured as fatal in additional recent versions of GCC, and "2" will make failures in these cases non-fatal so you can take time to modernize your code with modern best practices in mind. This is off "0" by default.
<option name="shadow_clang" value="0" /> "1" will enable builds with warnings configured as fatal in additional recent versions of CLANG, and "2" will make failures in these cases non-fatal so you can take time to modernize your code with modern best practices in mind. This is off "0" by default.
vs2008 Microsoft Visual Studio 2008
vs2010 Microsoft Visual Studio 2010
vs2012 Microsoft Visual Studio 2012
vs2013 Microsoft Visual Studio 2013
vs2015 Microsoft Visual Studio 2015
Classes are automatically added to all build environments. Further as you
add new classes to your project you can generate skeleton header and source
files according to http://rfc.zeromq.org/spec:21.
script := The gsl script to generate all the stuff !!! DO NOT CHANGE !!!
name := The name of your project (optional)
description := A short description for your project (optional)
email := The email address where to reach you (optional)
url := The website or similar resource about the project or its ecosystem (optional)
repository := git repository holding project (optional)
unique_class_name := "0"|"1" (optional, defaults to 0) As a failsafe, forbid naming agents or classes same as the project itself (can cause conflicts in generated header filenames). Disable explicitly (set to 0) only in legacy projects that can not regenerate otherwise, and try to fix those.
license := optional common tag of the project's license ("MPLv2", "GPL-2.0+", "CompanyName Proprietary" etc.); see also license.xml for longer wording
check_license_years := "0"|"1"|"2" (optional, defaults to 0) When a project is regenerated, and if any license text(s) are defined, we check that at least one Copyright line in at least one license text contains the current year, and warn if not. If this option is set to "1", we also pause so that interactive developers can see this warning better and intervene. With "2" require that the year is mentioned, abort GSL with year if it is not.
-->
<project script = "zproject.gsl" name = "zproject"
email = "zeromq-dev@lists.zeromq.org"
license = "MPL-2.0"
check_license_years = "0"
url = "https://github.com/zeromq/zproject"
repository = "https://github.com/zeromq/zproject">
<!--
Includes are processed first, so XML in included files will be
part of the XML tree. This file can provide content of such tags
as <license> (detailed text to put in generated file headers)
and <starting_year> (a number to put in packaging copyright
summaries). Note that a verbatim "license.xml" file would be
created if it is currently missing but the tag is present, and
then it would be seeded with a current starting_year and some
boilerplate reminder to specify a real license and copyright.
-->
<include filename = "license.xml" />
<!--
Current version of your project.
This will be used to package your distribution
-->
<version major = "1" minor = "1" patch = "0" />
<!--
Current libtool ABI version of your project's shared library.
Start at 0:0:0 and see:
http://www.gnu.org/software/libtool/manual/html_node/Updating-version-info.html
for details on how/when to increment it.
If not defined 0:0:0 will be used.
<abi current = "0" revision = "0" age = "0" />
-->
<!--
Check that the <symbol> is available after including a given <header>
and store the result in a macro HAVE_DECL_SYMBOL. When the symbol is
declared, HAVE_DECL_SYMBOL is defined to '1' otherwise '0'. Use
HAVE_DECL_SYMBOL in #if:
#if HAVE_DECL_SYMBOL
// Do something with the symbol
#endif
#if !HAVE_DECL_SYMBOL
// Alternative action without the symbol
#endif
<check_symbol_exists symbol = AI_V4MAPPED"" header = "netdb.h" />
-->
<!--
Specify which other projects this depends on.
These projects must be known by zproject, and the list of
known projects is maintained in the zproject_known_projects.xml model.
You need not specify sub-dependencies if they are implied.
Dependencies that support the autotools build system are automatically
built by travis ci if you supply a git repository or a tarball URI.
Set type to "runtime" to have the packages install-depend on it rather
than build-depend (default type is "build").
The travis ci will use the installed packages when building instead of
rebuilding if available.
<use project = "zyre" min_major= "1" min_minor = "1" min_patch = "0" />
<use project = "czmq"
min_major= "3" min_minor = "0" min_patch = "2"
next_incompatible_major = "4"
/>
<use project = "uuid" optional= "1" implied = "1" />
<use project = "myfirstlib" repository = "http://myfirstlib.org/myfirstlib.git" />
<use project = "mysecondlib" tarball = "http://mysecondlib.org/mysecondlib-1.2.3.tar.gz" />
<use project = "lua-5.1" am_lib_macro = "LUA_5_1" tarball = "..." />
-->
<use project = "gsl" type = "runtime" />
<!-- Header Files
name := The name the header file to include without file ending
<header name = "myproject_prelude" />
-->
<!--
Classes, if the class header or source file doesn't exist, this will
generate a skeletons for them.
Use private = "1" for internal classes
Use selftest = "0" to not generate selftest code
<class name = "myclass">Public class description</class>
<class name = "someother" private = "1">Private class description</class>
-->
<!--
Actors, are built using the simple actor framework from czmq. If the
actors class header or source file doesn't exist, this will generate a
skeleton for them. The generated test method of the actor will teach
you how to use them. Also have a look at the CZMQ docs to learn more
about actors.
Use selftest = "0" to not generate selftest code
<actor name = "myactor">Public actor description</actor>
<actor name = "someactor" private = "1">Private actor description</actor>
-->
<!--
Main programs built by the project
use private = "1" for internal tools
<main name = "progname">Exported public tool</main>
<main name = "progname" private = "1">Internal tool</main>
<main name = "progname" service = "1">Installed as system service, single-instance</main>
<main name = "progname" service = "2">Installed as system service, multi-instance (@)</main>
<main name = "progname" service = "3">Installed as system service, both single and multi-instance (@)</main>
<main name = "progname" timer = "3">Installed as system timer unit, both single and multi-instance (@)</main>
<main name = "progname" service = "1" timer = "1">Installed with both system timer and service units, single-instance - probably the former triggers the latter occasionally</main>
Note that <bin> tags for secondary distributed programs (or scripts)
now also support the service and timer attributes with same semantics.
-->
<!--
Benchmark programs built by the project
<bench name = "benchname">Benchmark for class/function...</main>
-->
<!--
Models that we build using GSL.
This will generate a 'make code' target to build the models.
<model name = "sockopts" />
<model name = "zgossip" />
<model name = "zgossip_msg" />
If a model should be generated using a specific gsl script,
this can be set through the script attribute:
<model name = "hydra_msg" script = "zproto_codec_java.gsl" />
Additional parameters to the script can be set via nested
param elements:
<model name = "hydra_msg" script = "zproto_codec_java.gsl">
<param name = "root_path" value = "../main" />
</model>
-->
<!-- Other source files that we need to package
<extra name = "some_resource" />
-->
<!-- Specify targets to build; autotools and cmake are
built in all cases.
<target name = "cmake" />
<target name = "autotools" />
-->
<!-- Targets may be customizable with their own options -->
<target name = "cmake">
<option name = "single setting" value = "value" />
<option name = "list setting">
<item name = "item name" value = "item value" />
</option>
</target>
<target name = "obs" />
<target name = "debian" />
<target name = "redhat" />
<!-- Cucumber target
<target name = "cucumber">
For each step_defs a cucumber steps runner will be registered
in the build scripts and the project's cucumber_selftest is
generated appropriately. Points the the source file
$(step_defs.name)_step_defs.c
<step_defs name = "brilliant_ideas" />
</target>
-->
<!-- Note: zproject itself uses a customized CI-testing routine
on Travis CI, not a generated one, so DO NOT ENABLE this one:
<target name = "travis" />
-->
<!-- Jenkins target creates jenkins pipeline
Pipeline file is not overwritten if it exists.
Your projects can build under a docker container OR agents
matched by a label OR under an "any" agent by default.
If you specify a complex label expression, be sure to use
XML escaping of the ampersand character (&) if some of
your tooling expects project.xml to be valid XML (the GSL
parser accepts a verbatim ampersand character as well).
The agent_single option is a flag that enables parallel
builds of this component on several agents (specified by
label or docker) vs. a sequential build on a single agent.
Similarly, a check_sequential option can be defined so that
self-testing stages would run sequentially. This can be needed
at early stages of a project's evolution, where hard-coding is
prevalent so parallel runs in same operating environment cause
conflicts to each other. Ultimately a project should remove
this flag ;)
The build_* and test_* options influence the default setting
of corresponding build arguments for the project. You can
still run a custom Jenkins Build with Arguments with other
checkboxes clicked, e.g. while developing a missing feature.
If not explicitly set to 0, most of these options are assumed
"true", as normally a project should be capable of all these
aspects. Note however that a project with no classes marked
"stable" would by default not test non-DRAFT builds as the
configure.ac script would have no support for those anyway.
The require_gitignore option (enabled by default) also causes
the test to fail, rather than warn, if untracked or changed
files are found as a result of some build or test stage.
Also note, that after successful build and test steps, the
job generated by this Jenkinsfile can optionally trigger
some other job specific to your installation of a Jenkins
server, to handle the deployment of tested code (whichever
way you'd define that). For this optional feature, your
Jenkins master should define (and propagate to its agents)
the environment values DEFAULT_DEPLOY_BRANCH_PATTERN (regex)
and DEFAULT_DEPLOY_JOB_NAME (note to start with a slash for
absolute naming; jobs in a folder may use relative paths too).
That job should accept parameters DEPLOY_GIT_URL (URL of repo),
DEPLOY_GIT_BRANCH (name for decision-making), DEPLOY_GIT_COMMIT
(actual commit to check out and shrink-wrap into packaging.
The test_install check tries to "make DESTDIR=... install" where
the DESTDIR is test_install_DESTDIR value (must be an absolute
path), or BUILD_DIR/tmp/_inst if the option is unspecified/empty.
The test_cppcheck is different, as it calls the "cppcheck" tool
which may be not installed on a particular Jenkins deployment.
The `make cppcheck` recipe is safe to call in either case, so by
default this option is enabled if not set explicitly. Same idea
goes for build_docs as it requires asciidoc and xmlto toolkits,
except it is off by default to avoid churning CPUs with no tools.
A further dist_docs enables preparation of a "dist" tarball from
the workspace configured with docs, so you can forward it to the
publishing helper job and avoid rebuilding man pages for packaging.
Similarly, a test_check_clang_format requires an external tool,
the clang-format-5.0 (or newer) to process the codebase and decide
if it is stylish. By default the test is enabled but not required
to pass (is just informative) and will run if the tool is available
in the build system. Eventually, a project should define and uphold
its coding style -- then this test can become one of requirements
for new pull requests.
The triggers_pollSCM option sets up the pipeline-generated job
for regular polling of the original SCM repository, using the
Jenkins cron syntax. The default is approximately every 5 minutes
with a spread to minimize burst-loads vs quiet times. An explicit
empty string disables polling, so you'd only run the job manually.
Note that the most frequent working setting is "H/2", NOT a "H/1".
On the Jenkins setup used by generated projects, sometimes it was
re-scheduling the same commits over and over and even overlapping.
Usually this was linked to some lagginess of the build system or
its internet connection, but the result was a growing queue of
same (and redundant) builds. To remedy this, projects can set a
few experimental options now (and regenerate their Jenkinsfile):
* use_earlymilestone -- uses a milestone to cancel builds that
got to it later than the running one
* use_deploymilestone -- uses a milestone to cancel builds that
got to the 'deploy if appropriate' phase later than the
running one
* use_build_nonconcurrent -- sets a disableConcurrentBuilds option
* use_checkout_explicit -- sets a skipDefaultCheckout option and
defines a step to check out code explicitly; it is believed
this may better succeed in recording which commits are already
being processed by the server
The use_test_timeout option sets up the default timeout for test
steps (further configurable at run-time as a build argument).
Generally unit tests should not take pathologically long, so the
default of 30 minutes should commonly suffice even for distchecks.
If your selftests are known to take a lot of time, perhaps due to
using an occasionally overloaded Jenkins CI farm, set this option.
A use_test_retry option allows to retry each failing test step
for the specified amount of attempts; it is deemed good if the
test passes at least once. This option should not normally need
to be used -- only if selftests somehow depend on environmental
circumstances and fail occasionally but not always. Ultimately,
project developers should find and fix the issue in tests (or in
the production codebase) so it always works on the first try,
bulletproof.
As a workaround for some versions of Jenkins, if your project uses
"weird" (generally non-ASCII) filenames in the build directory,
their removal with Pipeline deleteDir() can fail even though it
should not. If this bites you, set use_deleteDir_rm_first=1 in
the project, so the OS native "rm" is tried first.
The two options do_cleanup_after_build (for parallelized tests)
and do_cleanup_after_job control whether the pipeline would by
default remove the build/test subdirectory after successful end
of stage, and/or cleans the build workspace after the whole job
succeeded, respectively. If not set, cleanup is enabled for both
and in either case the active options are among build parameters.
In opposite fashion, a do_cleanup_after_failed_build is disabled
by default to allow post-mortem inspection of errors on CI server.
You might want to keep the built sources to analyze the behavior
of your build recipes in a particular environment, thought at a
risk of using excessive disk space there. In case of failure the
workspace remains on disk to make an in-place analysis possible,
and would eat space until you clean it up manually or it would
expire according to your Jenkins old-build retention policies.
<target name = "jenkins">
<option name = "file" value = "Jenkinsfile" />
<option name = "agent_docker" value = "zeromqorg/czmq" />
<option name = "agent_label" value = "linux || macosx || bsd || solaris || posix || windows" />
<option name = "agent_single" value = "1" />
<option name = "check_sequential" value = "1" />
<option name = "triggers_pollSCM" value = "H/5 * * * *" />
<option name = "build_without_draft_api" value = "0" />
<option name = "build_with_draft_api" value = "0" />
<option name = "build_docs" value = "1" />
<option name = "dist_docs" value = "1" />
<option name = "require_gitignore" value = "0" />
<option name = "use_deleteDir_rm_first" value = "1" />
<option name = "use_test_timeout" value = "60" />
<option name = "use_test_retry" value = "3" />
<option name = "test_check" value = "0" />
<option name = "test_memcheck" value = "0" />
<option name = "test_distcheck" value = "0" />
<option name = "test_install" value = "0" />
<option name = "test_install_DESTDIR" value = "/tmp/proto-area" />
<option name = "test_cppcheck" value = "1" />
<option name = "test_check_clang_format" value = "1" />
<option name = "use_clang_format_prog" value = "clang-format-5.0" />
<option name = "require_good_clang_format" value = "0" />
</target>
-->
<target name = "jenkins" >
<option name = "agent_label" value = "linux || macosx || bsd || solaris || posix || windows" />
<option name = "agent_single" value = "1" />
<!-- Note: for zproject itself, all the *check jobs are
essentially a loopback to distcheck itself -->
<option name = "test_check" value = "1" />
<option name = "test_memcheck" value = "0" />
<option name = "test_distcheck" value = "0" />
<option name = "test_cppcheck" value = "0" />
</target>
<!-- In order loaded by zproject.gsl -->
<bin name = "zproject.gsl" />
<bin name = "zproject_projects.gsl" />
<bin name = "zproject_class_api.gsl" />
<!-- Mainline generation code -->
<bin name = "zproject_skeletons.gsl" />
<bin name = "zproject_bench.gsl" />
<bin name = "zproject_class.gsl" />
<bin name = "zproject_git.gsl" />
<bin name = "zproject_valgrind.gsl" />
<!-- Targets -->
<bin name = "zproject_android.gsl" />
<bin name = "zproject_autotools.gsl" />
<bin name = "zproject_cmake.gsl" />
<bin name = "zproject_cucumber.gsl" />
<bin name = "zproject_cygwin.gsl" />
<bin name = "zproject_debian.gsl" />
<bin name = "zproject_delphi.gsl" />
<bin name = "zproject_docker.gsl" />
<bin name = "zproject_gh_actions.gsl" />
<bin name = "zproject_gyp.gsl" />
<bin name = "zproject_ios.gsl" />
<bin name = "zproject_java.gsl" />
<bin name = "zproject_java_lib.gsl" />
<bin name = "zproject_java_msvc.gsl" />
<bin name = "zproject_jenkins.gsl" />
<bin name = "zproject_lua_ffi.gsl" />
<bin name = "zproject_mingw32.gsl" />
<bin name = "zproject_nodejs.gsl" />
<bin name = "zproject_nuget.gsl" />
<bin name = "zproject_obs.gsl" />
<bin name = "zproject_python.gsl" />
<bin name = "zproject_python_cffi.gsl" />
<bin name = "zproject_qml.gsl" />
<bin name = "zproject_qt.gsl" />
<bin name = "zproject_redhat.gsl" />
<bin name = "zproject_rpi.gsl" />
<bin name = "zproject_ruby.gsl" />
<bin name = "zproject_systemd.gsl" />
<bin name = "zproject_travis.gsl" />
<bin name = "zproject_vagrant.gsl" />
<bin name = "zproject_vs2008.gsl" />
<bin name = "zproject_vs20xx.gsl" />
<bin name = "zproject_vs20xx_props.gsl" />
<bin name = "zproject_known_projects.xml" />
</project>
zproject's use
element defines project dependencies.
Model is described in zproject_known_projects.xml
file:
<known_projects>
<!-- ZeroMQ Projects -->
<!--
Problem: naming style is inconsistent
we sometimes use libxxx and sometimes xxx; the git repo name
is unpredictable; sometimes we override with the prefix and
sometimes with libname.
Proposed solution: project name should always be git repo
name; prefix and libname should always be specified. For
compatibility, we can define aliases. E.g.:
Also, 'cmake name' is target specific and must go.
Suggested model:
<use
project = "libzmq" required
master = "https://github.com/zeromq"
required
libname = "libzmq" default = lib<prefix>
prefix = "zmq" default = project
test = "zmq_init" required same as AC_CHECK_LIB in autoconf
release = "<tagname>" default = "master"
abi = "version" default = "0:0:0"
header = "<filename>" default = <prefix>.h
language = "C|C++" default = "C"
optional = "1" default = "0"
debian_name = "libzmq5-dev" default = lib<name>-dev
redhat_name = "zeromq-devel" default = <name>-devel
<add_config_opts>--with-dep1=nuance</add_config_opts>
<add_config_opts>--enable-feature2</add_config_opts>
</use>
-->
<use project = "libzmq" prefix = "zmq" debian_name = "libzmq3-dev" redhat_name = "zeromq-devel" brew_name = "zeromq"
repository = "https://github.com/zeromq/libzmq.git"
test = "zmq_init" />
<!-- Note: if your project requires an older CZMQ (e.g. if you need
`release = "v3.0.2"`), you may need to `test = "zctx_test"`.
Also note that you can instead require particular package
version (as reported by pkg-config records). -->
<use project = "czmq" libname = "libczmq"
repository = "https://github.com/zeromq/czmq.git"
test = "zhashx_test">
<use project = "libzmq" />
</use>
<use project = "zyre" libname = "libzyre"
repository = "https://github.com/zeromq/zyre.git"
test = "zyre_test">
<use project = "czmq" />
</use>
<use project = "malamute" libname = "libmlm"
repository = "https://github.com/zeromq/malamute.git"
header = "malamute.h"
prefix = "mlm"
test = "mlm_server_test">
<use project = "libzmq" />
<use project = "czmq" />
</use>
<use project = "gsl" libname = ""
repository = "https://github.com/zeromq/gsl.git"
debian_name = "generator-scripting-language"
redhat_name = "generator-scripting-language">
</use>
<!-- Edgenet Projects -->
<use project = "drops" libname = "libdrops"
repository = "https://github.com/edgenet/drops.git"
test = "drops_test">
<use project = "czmq" />
<use project = "zyre" />
</use>
<use project = "hydra" libname = "libhydra"
repository = "https://github.com/edgenet/hydra.git"
test = "hydra_server_test">
<use project = "czmq" />
</use>
<!-- Various known third-party projects
(If you're unsure of where a project belongs, add it here) -->
<use project = "cucumber"
header = "cucumber_c.h"
test = "cucumber_new"
repository = "https://github.com/sappo/cucumber-c">
<use project = "gherkin" private = "1" />
<use project = "cJSON" private = "1" />
</use>
<use project = "gherkin"
header = "compiler.h"
repository = "https://github.com/cucumber/gherkin-c"
test = "Compiler_new" />
<use project = "cJSON"
debian_name = "libcjson-dev"
header = "cjson/cJSON.h"
repository = "https://github.com/DaveGamble/cJSON"
test = "cJSON_Parse" />
<use project = "libsodium" prefix = "sodium"
repository = "https://github.com/jedisct1/libsodium.git"
release = "stable"
test = "sodium_init" />
<use project = "libcurl"
prefix = "curl"
repository = "https://github.com/curl/curl.git"
debian_name = "libcurl4-nss-dev"
brew_name = "curl"
test = "curl_easy_init"
header = "curl/curl.h" />
<use project = "libmicrohttpd"
brew_name = "libmicrohttpd"
prefix = "microhttpd"
repository = "https://git.gnunet.org/libmicrohttpd.git"
tarball = "http://ftp.gnu.org/gnu/libmicrohttpd/libmicrohttpd-0.9.44.tar.gz"
test = "MHD_start_daemon" />
<use project = "editline"
repository = "https://github.com/troglobit/editline.git"
test = "readline" />
<use project = "fuse"
repository = "http://git.code.sf.net/p/fuse/fuse.git"
test = "fuse_main" />
<use project = "jansson"
repository = "https://github.com/akheron/jansson.git"
test = "json_object" />
<use project = "jemalloc"
repository = "https://github.com/jemalloc/jemalloc.git"
test = "malloc"
header = "jemalloc/jemalloc.h" />
<use project = "msgpack"
repository = "https://github.com/msgpack/msgpack-c.git"
test = "msgpack_version" />
<use project = "uuid"
test = "uuid_generate"
header = "uuid/uuid.h"
brew_name = "ossp-uuid"
redhat_name = "libuuid-devel"
debian_name = "uuid-dev" />
<use project = "asound"
test = "snd_asoundlib_version"
header = "alsa/asoundlib.h" />
<use project = "zdb"
repository = "https://bitbucket.org/tildeslash/libzdb.git"
test = "ConnectionPool_start" />
<use project = "json-c"
header = "json-c/json.h"
test = "json_object_to_json_string" />
<use project = "libfastjson"
repository = "https://github.com/rsyslog/libfastjson/"
header = "libfastjson/json.h"
test = "json_object_to_json_string" />
<use project = "lognorm"
repository = "https://github.com/rsyslog/liblognorm/"
test = "ln_initCtx">
<use project = "libfastjson" />
</use>
<use project = "zdiscgo"
repository = "https://github.com/zeromq/zdiscgo.git"
test = "zdiscgoplugin_new" />
<use project = "systemd"
libname = "libsystemd"
prefix = "libsystemd"
linkname = "systemd"
header = "systemd/sd-daemon.h"
test = "sd_listen_fds" />
<use project = "protobuf-c"
repository = "https://github.com/protobuf-c/protobuf-c/"
test = "protobuf_c_version"
header = "protobuf-c/protobuf-c.h"/>
<!-- 42ITY project https://github.com/42ity https://42ity.org -->
<use project = "fty-proto" libname = "libfty_proto" header="ftyproto.h"
repository = "https://github.com/42ity/fty-proto"
test = "fty_proto_test">
<use project = "libzmq"/>
<use project = "czmq"/>
<use project = "malamute"/>
</use>
<!-- OS packagers make life hard by renaming the package, binaries and
even library SONAMEs - so we have to guess a bit; note that for
practical purposes, lua-5.2 suffices as lua-5.1 (if fixes happen
to be needed, they are trivial and googlable) -->
<use project = "lua-5.1" libname = "lua" prefix="lua"
optional = "0" am_lib_macro = "LUA_5_1"
min_major = "5" min_minor = "1" min_patch = "0"
debian_name="liblua5.1-0-dev" redhat_name="lua-devel"
test = "lua_close">
<linkname>lua5.2</linkname>
<linkname>lua52</linkname>
<linkname>lua5.1</linkname>
<linkname>lua51</linkname>
<linkname>lua</linkname>
<pkgconfig>lua5.2</pkgconfig>
<pkgconfig>lua52</pkgconfig>
<pkgconfig>lua5.1</pkgconfig>
<pkgconfig>lua51</pkgconfig>
<pkgconfig>lua</pkgconfig>
</use>
<use project = "lz4"
libname = "liblz4"
redhat_name = "liblz4-devel"
header = "lz4.h"
test = "LZ4_decompress_safe" />
<use project = "nss"
debian_name = "libnss3-dev"
redhat_name = "nss-devel"
header = "sechash.h"
test = "HASH_Create" />
</known_projects>
Example:
<classfilename use-cxx = "true" use-cxx-gcc-4-9 = "true" pkgincludedir = "false" keep-tree = "true" pretty-print = "no" source-extension = "cpp" header-extension = "hpp" />
Default value :
Each target produces scripts and code for a specific build system, platform, or language binding.
To see a list of available targets:
gsl -target:? project.xml
To build a specific target:
gsl -target:android project.xml
To run zproject without building any targets:
gsl -target:- project.xml
To request specific targets in your project.xml file (autotools and cmake are automatic):
<target name = "android" />
<target name = "java" />
To request all targets in your project.xml file:
<target name = "*" />
A target can accept options via project.xml like this:
<project
name = "..."
>
...
<target name = "*" />
<target name = "nuget">
<option name = "id" value = "czmq_vc120" />
<option name = "dependency">
<item name = "libzmq_vc120" value = "4.2.0.0" />
</option>
</target>
</project>
This generates all targets (name = "*"
) and then configures the nuget
target with options. Zproject aare provided to the target handler as:
project.nuget_id = "czmq_vc120"
project.nuget_dependency.name = "libzmq_vc120"
project.nuget_dependency.value = "4.2.0.0"
The target android
accepts the following options:
<target name = "android" >
<option name = "ndk_version" value = "nnn" />
<option name = "min_sdk_version" value = "sss" />
</target>
Generated files will have their default values like:
project.android_ndk_version = "nnn"
project.android_min_sdk_version = "sss"
Note: these 2 default values can be overridden via the export
mechanism
as explained in generated builds/android/README.md
and
bindings/jni/README.md
.
If these options are not provided, default hard-coded values are applied
from zproject_android.gsl
code.
Each target works in its own copy of 'project'. It can therefore modify and extend 'project' as wanted, without affecting other targets.
You may encounter a warning in a file you want to modify like this:
################################################################################
# THIS FILE IS 100% GENERATED BY ZPROJECT; DO NOT EDIT EXCEPT EXPERIMENTALLY #
# Read the zproject/README.md for information about making permanent changes. #
################################################################################
If that happens, you need to follow these steps to make the modifications and then regenerate the code for czmq, malamute and zyre (all zeromq projects).
~/git/zproject$ ./tstgenbld.sh > ../before.log
~/git/zproject$ ./tstgenbld.sh > ../after.log
~/git/zproject$ meld ../after.log ../before.log
Using an API model zproject can generate the @interface
section your class
headers. Further it allows zproject to generate various language bindings on top
of your CLASS project.
All API models are placed into the api
directory which resides in the root
directory of your project. For example, if your project.xml
contains
<class name = "myclass"/>
, you could create the following api/myclass.api
file:
<class name = "myclass">
<!--
This model defines a public API for binding.
It shows a language binding developer what to expect from the API XML
files.
-->
My Feature-Rich Class
<include filename = "license.xml" />
<constant name = "default port" value = "8080">registered with IANA</constant>
<constant name = "normal" value = "1" />
<constant name = "fast" value = "2" />
<constant name = "safe" value = "3" />
<!-- Constructor is optional; default one has no arguments -->
<constructor>
Create a new myclass with the given name.
<argument name = "name" type = "string" />
</constructor>
<!-- Destructor is optional; default one follows standard style -->
<destructor>
Destructors implicitly get a new argument prepended, which:
* is called `self_p`
* is of this class' type
* is passed by reference
* is marked as the self pointer for the destructor (`destructor_self = "1"`)
</destructor>
<!-- This models an CZMQ actor. By default the actor method equals the
class name.
-->
<actor>
To work with my_actor, use the CZMQ zactor API:
Create new my_actor instance.
zactor_t *actor = zactor_new (my_actor, NULL);
Destroy my_actor instance
zactor_destroy (&actor);
Enable verbose logging of commands and activity:
zstr_send (actor, "VERBOSE");
</actor>
<!-- This models a method with no return value -->
<method name = "sleep">
Put the myclass to sleep for the given number of milliseconds.
No messages will be processed by it during this time.
<argument name = "duration" type = "integer" />
</method>
<!-- This models an accessor method -->
<method name = "has feature">
Return true if the myclass has the given feature.
<argument name = "feature" type = "string" />
<return type = "boolean" />
</method>
<method name = "send strings">
This does something with a series of strings (until NULL). The strings
won't be touched.
Because the next method has the same name with a prepended "v", it's
recognized as this method's `va_list` sibling (in GSL:
`method.has_va_list_sibling = "1"`). This information might be used by
the various language bindings.
<argument name = "string" type = "string" variadic = "1" />
<return type = "boolean" />
</method>
<method name = "vsend strings">
This does something with a series of strings (until NULL). The strings
won't be touched (they're declared immutable by default).
<argument name = "string" type = "string" variadic = "1" />
<return type = "boolean" />
</method>
<!-- Callback typedefs can be declared like methods -->
<callback_type name = "handler_fn">
<argument name = "self" type = "myclass" />
<argument name = "action" type = "string" />
<return type = "boolean" />
</callback_type>
<!-- Callback types can be used as method arguments -->
<method name = "add handler">
Store the given callback function for later
<argument name = "handler" type = "my_class_handler_fn" callback = "1" />
</method>
<!-- If singleton = "1", no class struct pointer is required. -->
<method name = "test" singleton = "1">
Self test of this class
<argument name = "verbose" type = "boolean" />
</method>
<method name = "new thing" singleton = "1" >
Creates a new myclass. The caller is responsible for destroying it when
finished with it.
<return type = "myclass" fresh = "1" />
</method>
<method name = "free" singleton = "1">
Frees a provided string, and nullify the parent pointer. Setting
`mutable = "1"` is not needed here, because transfering ownership from
the caller to the function using `by_reference = "1"` implies that it's
mutable.
<argument name = "string pointer" type = "string" by_reference = "1" />
</method>
<method name = "rotate" singleton = "1">
Rotates the characters in `data` in-place. This means that all
characters are shifted to the left by one, removing the left-most
character and appending it to the end.
<argument name = "data" type = "string" mutable = "1" />
</method>
<!-- These are the types we support
Not all of these are supported in all language bindings;
see each language binding's file for supported types in that
language, and add more types as needed where appropriate.
Also, see zproject_class_api.gsl to see how they're handled exactly.
-->
<method name = "tutorial">
<argument name = "void pointer" type = "anything" />
<argument name = "standard int" type = "integer" />
<argument name = "default float" type = "real" />
<argument name = "standard float" type = "real" size = "4" />
<argument name = "standard double" type = "real" size = "8" />
<argument name = "standard bool" type = "boolean" />
<argument name = "fixed size unsigned integer" type = "number" size = "4">
Supported sizes are 1, 2, 4, and 8.
</argument>
<argument name = "a byte" type = "byte" />
<argument name = "conversion mode" type = "integer" />
<argument name = "char pointer to C string" type = "string" />
<argument name = "byte pointer to buffer" type = "buffer" />
<argument name = "buffer size" type = "size" />
<argument name = "file handle" type = "FILE" />
<argument name = "file size" type = "file_size" />
<argument name = "time" type = "time" />
<argument name = "format" type = "format">
This makes the function is variadic (will cause a new argument to be
added to represent the variadic arguments).
</argument>
<argument name = "variadic list argument" type = "va_list" />
<argument name = "custom pointer" type = "my custom class">
Any other type is valid, as long as there is a corresponding C
type, in this case `my_custom_class_t`.
</argument>
<return type = "nothing">void method</return>
</method>
<method name = "set foo" polymorphic = "1">
Set attribute foo to a new value. Note that this method takes a
polymorphic reference (`void *`) as its first argument, which could point
to structs of different types.
This also means that high-level bindings might give you the choice to
call this method directly on an instance, or with an explicit receiver.
<argument name = "new value" type="integer" />
</method>
<method name = "set bar">
This method takes an argument type of the (descriptive) type `foo`, but
resolving it to a corresponding C type will be skipped because it's
overridden to `foobarbaz_t` by the `c_type` attribute.
<argument name = "new foo" type="foo" c_type="foobarbaz_t" />
</method>
</class>
This model will cause the following @interface
to be generated inside of
include/myclass.h
. Note that if include/myclass.h
has other handwritten
content outside the @interface
section this content will be retained. If
the header file does not exist zproject will create it.
// @warning THE FOLLOWING @INTERFACE BLOCK IS AUTO-GENERATED BY ZPROJECT!
// @warning Please edit the model at "api/myclass.api" to make changes.
// @interface
// Create a new myclass with the given name.
MYPROJECT_EXPORT myclass_t *
myclass_new (const char *name);
// Destroy the myclass.
MYPROJECT_EXPORT void
myclass_destroy (myclass_t **self_p);
// Return true if the myclass has the given feature.
MYPROJECT_EXPORT bool
myclass_has_feature (myclass_t *self, const char *feature);
// Put the myclass to sleep for the given number of milliseconds.
// No messages will be processed by the actor during this time.
MYPROJECT_EXPORT void
myclass_sleep (myclass_t *self, int duration);
// Self test of this class
MYPROJECT_EXPORT void
myclass_test (bool verbose);
// @end
The following attributes are supported for methods:
name
- the name of the method (mandatory).singleton = "1"
- the method is not invoked within the context of a specific instance of an object. Use this if your method does not need to be passed a self
pointer as the first argument as normal. Implicit for all constructor
s and destructor
s and for the implicit test
method.The following attributes are supported for arguments and return values:
type
- the conceptual type or class name of the argument or return value (default: "nothing"
, which translates to void
in C).mutable = "1"
- the argument or the return value can be modified. All string, format, and buffer arguments are immutable by default.by_reference = "1"
- ownership of the argument (and responsibility for freeing it) is transferred from the caller to the function - in practice, the implementation code should also nullify the caller's reference, though this is not enforced by the API model. If a string or buffer is passed by reference, it is also mutable by default.fresh = "1"
- the return value is freshly allocated, and the caller receives ownership of the object and the responsibility for destroying it. Implies mutable = "1".variadic = "1"
- used for representing variadic arguments.For integer arguments you can specify one or more 'map' values, which a binding target can use to generate alternative methods. For example:
<argument name = "socket type" type = "integer">
<map name = "PAIR" value = "ZMQ_PAIR" />
<map name = "PUB" value = "ZMQ_PUB" />
<map name = "SUB" value = "ZMQ_SUB" />
</argument>
The value should be a constant that the binding code has access to.
The following attributes are supported for arguments:
polymorphic
- indicates that the passed class instance is a sockish
type. For an example see CZMQ's zsock class.This is an incomplete list of API types:
"nothing" -- for return only, means "void" in C.
"anything" -- means "void *" in C.
"size" -- long size (64 bits), "size_t" in C.
"time" -- long time (64 bits), "time_t" in C.
"msecs" -- long number of msecs, "int64_t" in C.
"file_size" -- long file size (64 bits).
"boolean" -- Boolean.
"byte" -- single octet.
"char" -- single character (possibly multibyte, do we care?)
"integer" -- 32-bit signed integer.
"number" -- unsigned number, with 'size = "1|2|4|8"'.
"real" -- single-precision floating point with 'size = "4"' (default) or double-precision with 'size = "8"'.
"buffer" -- byte array. When passing a buffer argument, if the next argument has type 'size', the binding may fill the size automatically. To return a buffer, you should specify 'size' attribute that defines how to set the buffer size. This can be a constant, 'size = "ZUUID_LEN"', or a dot followed by method name in the same class, e.g. 'size = ".size"'.
"string" -- character array.
"sockish" -- a variant socket type, may be a zsock_t, libzmq void *, or an actor handle.
"format" -- printf format, followed by zero or more arguments.
"FILE", "va_list", "zmq_pollitem", "socket" -- literally that, in C. (Not sure if it is wise to use raw C types.)
callbacks - tbd.
Names of classes, e.g. zmsg.
At any time, you can examine a resolved model as an XML string with all of its children and attributes using the appropriate GSL functions:
# if the `method` variable is a <method/> entity:
echo method.string() # will print the model as an XML string.
method.save(filename) # will save the model as an XML string to the given file.
You can save a snapshot of the entire resolved project model using this syntax:
gsl -save:1 project.xml
Writing API model for bigger project with a lot of classes can be tedious job. There mkapi.py, which automates most of the task.
In order to use it, you must install zproject itself and then pycparser. For most of real world code, you must have fake_libc_includes available too.
virtualenv/venv mkapi
source mkapi/bin/activate
pip install pycparser
git clone https://github.com/eliben/pycparser.git
Then from root directory of your project (for example czmq), type following
mkapi.py -I /path/to/your/pycparser/utils/fake_libc_include include/czmq.h
Note you must use top-level include as pycparser fails if it does not know any definition.
The tool might expect -DWITH_DRAFTS
parameter if the class is not marked as a stable.
The tool can't distinguish methods which allocates new object. It does print a comment about adding fresh = "1" attribute to each method, which return non const pointer. However the final assigment must be done manually.
Skips methods that it cannot handle properly.
To build, you need gradle (or equivalent). Run 'gradle build jar' in the bindings/jni directory.
To install, run 'gradle install'. This puts the files into $HOME/.m2/repository.
zproject lets you mark classes and methods as 'draft' so that they are not installed by default in stable builds. This lets you deliver draft APIs to your users, and change them later.
By default, all classes and methods are draft, unless you specify otherwise. To mark the state of a class or method, specify in the project.xml:
<class name = "classname" state = "stable" />
Or in the class API XML file:
<class name = "classname" state = "stable">
...
<method name = "methodname" state = "stable">
...
</method>
</class>
The method will inherit the class state unless it has its own 'state' attribute.
The allowed states are:
Using autotools or CMake, you can specify --with-drafts to enable draft APIs, and --without-drafts to disable them. By default, drafts are built and installed when you work in a git repository (if the directory ".git" is present), and otherwise they are not. That means, if you build from a tarball, drafts are disabled by default.
make uninstall
Installation of third party files is a hard problem. It is not platform independent, became hard to maintain and impossible to use correctly. One of zproject's goals is a simplicity. There is a simple installation model
<main name = "MAIN">
<install type = "systemd-tmpfiles" />
<install type = "config" name = "MAIN-ldap-integration.cfg.example" />
</main>
systemd-tmpfiles This will add install information about systemd tmpfiles.d configuration files to autotools, packaging, and so. The resulting file /usr/lib/tmpfiles.d/MAIN.conf will be installed only if configure was called with --with-systemd-units.
config This will install additional configuration files to $(sysconfdir)/$(project.name)/$(name).
If you write a new target or extend one you might be in the situation where you
need to put code fragments into files which are not specific to your target. For
example the systemd
target has to extend files from the autotools
, debian
and redhat
targets. In order to keep those files as maintainable as possible
you'll include a snippet which is pull from your targets file. To include
a snippet call:
insert_snippet (target)
Where target is the identifier for the insertion point i.e. the filename. To register a snippet to be inserted simply call.
register_snippet (target, name)
Target is must match the one in insert_snippet
and the name identifies your
snippet. Then you can create a function or macro with the following form
(without the brackets):
function snippet_<target>_<name>
.macro snippet_<target>_<name>
This function will be called by the insert_snippet
function. You can have an
arbitrary amount of registered snippets per insertion point which will be
inserted in arbitrary order so don't make any assumption on the order of the
snippets per insertion point.
This is the general form of a target:
register_target ("somename", "Decription of target")
function target_somename
\.macro generate_something
...
\.endmacro
project.topdir = "someplace/somename"
directory.create (project.topdir)
generate_something ()
endfunction
class
es SHALL be in the project model (project.xml
).class
MAY have a corresponding API model (api/{class name}.api
).class
es with an API model (where defined (class.api)
).zproject_class_api
script). Both kinds of information will already be resolved (and indistinguishable) when each language binding generator is invoked.class
entity at the top level.class
SHALL have a name
attribute.class
MAY have one or more method
entities.class
MAY have one or more constructor
entities.class
MAY have one or more destructor
entities.method
, constructor
, and destructor
MAY have one or more argument
entities.method
, constructor
, and destructor
SHALL at least one return
entity, and if more than one return
entity exist, only the first SHOULD be considered. The return
entity MAY be ignored if it has type = "nothing"
(the default when no type
is given).A class
is always the top-level entity in an API model, and it will be merged with the corresponding class
entity defined in the project model. A class contains method
s, constructor
s, and destructor
s (collectively, "method"s), and methods contain argument
s and return
s (collectively, "container"s). Each entity will contain both semantic attributes and language-specific implementation attributes.
Semantic attributes describe something intrinsic about the container.
For example, arguments may be described as passed by_reference
to indicate that ownership is transferred from the caller. Similarly, return values may be described as fresh
to indicate that ownership is transferred to the caller, which must destroy the object when it is finished with it. It's important to remember that these attributes are primarily meant to be an abstraction that describes conceptual information, leaving the details of how code generators interpret (or ignore) each attribute up to the authors.
Semantic attributes may be implicit (not given a value in the written model). In this case, it is up to the zproject_class_api
script to fully resolve default values for all attributes. Downstream code generators should never resolve or alter semantic attributes, as this could change the behavior of any code generator that is run after the errant code generator.
These are the semantic attributes for each kind of entity that will be resolved before language bindings generators are invoked:
class.name # string (as given in the API model)
class.description # string (comment in the API model, or empty string)
method.name # string (as given in the API model, or a default value)
method.description # string (comment in the API model, or a default value)
method.singleton # 0/1 (default: 0, but 1 for constructors/destructors)
method.is_constructor # 0/1 (default: 0, but 1 for constructors)
method.is_destructor # 0/1 (default: 0, but 1 for destructors)
method.has_va_list_sibling # 0/1 (default: 0)
container.name # string (as given in the API model, or "_")
container.type # string (as given, or "nothing")
container.mutable # 0/1 (default: 0)
container.by_reference # 0/1 (default: 0)
container.callback # 0/1 (default: 0)
container.fresh # 0/1 (default: 0)
container.variadic # 0/1 (default: 0)
container.va_start # string - that holds the argment name for va_start ()
container.optional # 0/1 (default: 0), up to binding generator to use
The contributors are listed in AUTHORS. This project uses the MPL v2 license, see LICENSE.
zproject uses the C4.1 (Collective Code Construction Contract) process for contributions.
To report an issue, use the zproject issue tracker at github.com.
The copyright of the output of zproject is by default property of the users. The license.xml file must be set up by the users to specify a license of their choosing.
Make sure that the project model hides all details of backend scripts. For example don't make a user enter a header file because autoconf needs it.
Do read your code after you write it and ask, "Can I make this simpler?" We do use a nice minimalist and yet readable style. Learn it, adopt it, use it.
Before opening a pull request read our contribution guidelines. Thanks!
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