Standalone C, C++, and/or Qt binding and wrapper generator.
Add the dependency to shard.yml
:
dependencies:
bindgen:
github: Papierkorb/bindgen
version: ~> 0.7.0
- How To
- Projects using bindgen
- Mapping behaviour
- Features
- Architecture of bindgen
- Processors
- Advanced configuration features
- Platform support
- Contributing
- License
When you have a Crystal project and want to bind to C, C++, or Qt libraries
with the help of bindgen
, do as follows:
- Add bindgen to your project's
shard.yml
as instructed above under "Installation" and then runshards
- Copy
lib/bindgen/assets/bindgen_helper.hpp
into yourext/
subdirectory, creating it if missing - Copy
lib/bindgen/TEMPLATE.yml
intoyour_template.yml
(adjust the name to your linking) and customize it for the library you want to bind to - Run
lib/bindgen/tool.sh your_template.yml
. This will generate the bindings, and by default place the outputs in theext/
subdirectory - Develop your Crystal application as usual
Note: If you ship the output produced by bindgen along with your application,
then bindgen
will not be not required to compile it. In that case, you can move
its entry in shard.yml
from dependencies
to development_dependencies
.
The .yml
file that you copy from TEMPLATE.yml
will contain the complete
configuration template along with accompanying documentation embedded in
the comments.
If you prefer working with shorter files, you can simply remove all the
comments.
You can use the following projects' .yml files as a source of ideas or syntax for your own bindings:
Have you created and published a usable binding with bindgen? Want to see it here? Send a PR!
The following rules are automatically applied to all bindings:
- Method names get underscored:
addWidget() -> #add_widget
- Setter methods are rewritten:
setWindowTitle() -> #window_title=
- Getter methods are rewritten:
getWindowTitle() -> #window_title
- Bool getters are rewritten:
getAwesome() -> #awesome?
is
getters are rewritten:isEmpty() -> #empty?
has
getters are rewritten:hasSpace() -> #has_space?
- Setter methods are rewritten:
- On signal methods (For Qt signals):
- Keep their name for the
emit
version:pressed() -> #pressed
- Get an
on_
prefix for the connect version:#on_pressed do .. end
- Keep their name for the
- Enum fields get title-cased if not already:
color0 -> Color0
Feature | Support |
---|---|
Automatic Crystal binding generation | YES |
Automatic Crystal wrapper generation | YES |
Mapping C++ classes | |
+- Member methods | YES |
+- Static methods | YES |
+- Getters and setters for instance variables | YES |
+- Getters and setters for static variables | YES |
+- Constructors | YES |
+- Overloaded operators | Partial |
+- Conversion functions | TBD |
Mapping C/C++ global functions | |
+- Mapping global functions | YES |
+- Wrapping as Crystal class | YES |
Overloaded methods (Also default arguments) | YES |
Copying default argument values | |
+- Integer, float, boolean types | YES |
+- String | YES |
Enumerations | YES |
Copying structures | YES |
Custom type conversions between C/++ and Crystal | YES |
Automatic type wrapping and conversion | YES |
Integration with Crystals GC | YES |
C++ Template instantiation for containers types | YES |
Virtual methods | YES |
Override virtual methods from Crystal | YES |
Abstract classes | YES |
Multiple inheritance wrapping | YES |
Qt integration | |
+- QObject signals | YES |
+- QFlags types | YES |
+- QMetaObject generation (mimic moc ) |
TBD |
#define macro support |
|
+- Mapping as enumeration | YES |
+- Mapping as constant (Including strings) | YES |
Copying in-source docs | TBD |
Platform specific type binding rules | YES |
Portable path finding for headers, libs, etc. | YES |
Bindgen employs a pipeline-inspired code architecture, which is strikingly similar to what most compilers use.
The code flow is basically Parser::Runner
to Graph::Builder
to
Processor::Runner
to Generator::Runner
.
An important data structure used throughout the program is the graph.
Code-wise, it's represented by Graph::Node
and its sub-classes. The nodes
can contain child nodes, making it a hierarchical structure.
This allows to represent (almost) arbitrary structures as defined by the user configuration.
Say we're wrapping GreetLib
. As any library, it comes with a bunch of
classes (Greeter
and Listener
), enums (Greetings
, Type
) and other stuff
like constants (PORT
). The configuration file could look like this:
module: GreetLib
classes: # We copy the structure of classes
Greeter: Greeter
Listener: Listener
enums: # But map the enums differently
Type: Greeter::Type
Greeter::Greetings: Greetings
Which will generate a graph looking like this:
Note: The concept is really similar to ASTs used by compilers.
This is the beginning of the actual execution pipeline. It calls out to the clang-based parser
tool () to read the C/C++ source code and write a JSON-formatted "database" onto
standard output. This is directly read by bindgen
and subsequently parsed
as Parser::Document
.
The second step takes the Parser::Document
and transforms it into a
Graph::Namespace
. This step is where the user configuration mapping is used.
The third step runs all configured processors in order. These work with the
Graph
and mostly add methods and Call
s so they can be bound later. But
they're allowed to do whatever they want really, which makes it a good place
to add more complex rewriting rules if desired.
Processors are responsible for many core features of bindgen. The TEMPLATE.yml
has an already set-up example pipeline.
The final step now takes the finalized graph and writes the result into an output of one or more files. Generators do not change the graph in any way, and also don't build anything on their own. They only write to output.
The processor pipeline can be configured through the processors:
array. Its
elements are run in the order they're defined, starting at the first element.
Note: Don't worry: The TEMPLATE.yml
file already comes with the
recommended pipeline pre-configured.
There are three kinds of processors:
- Refining ones modify the graph in some way, without a dependency to a later generator.
- Generation processors add data to the graph so that the generators run later have all data they need to work.
- Information processors don't modify the graph, but do checks or print data onto the screen for debugging purposes.
The order in the configured pipeline is to have Refining processors first, Generation processors second. Information processors can be run at any time.
The following processors are available, in alphabetical order:
- Kind: Refining
- Run after: No specific dependency
- Run before:
InstantiateContainers
When encountering a known container class on an instantiation that is not registered yet, registers it.
Container classes still need to be declared in the configuration, but don't
require an explicit instantiations
attribute anymore:
containers: # At the top-level of the config
- class: QList # Set the class name
type: Sequential # And its type
# instantiations: # Can be added, but doesn't need to be.
- Kind: Refining, but ran after generation processors!
- Run after:
CrystalWrapper
,Qt
- Run before: No specific dependency
Adds type parameters to ambiguous Crystal methods that take a single block
argument, so that these methods can be overloaded by passing the parameter types
of that argument to the method. Qt
needs it for several signal connection
methods.
cb = Qt::ComboBox.new
cb.on_activated(Int32) do |index| # Type argument added by this processor
puts "Int32 overload selected: #{index}"
end
cb.on_activated(String) do |text| # Type argument added by this processor
puts "String overload selected: #{text}"
end
- Kind: Refining
- Run after: No specific dependency
- Run before: No specific dependency
Copies structures of those types, that have copy_structure: true
set in the
configuration. A wrapper class of a copy_structure
type will host the
structure directly (instead of a pointer) to it.
- Kind: Generation
- Run after: Refining processors
- Run before:
CrystalBinding
Generates the C++ wrapper method Call
s.
- Kind: Generation
- Run after:
CppWrapper
,VirtualOverride
andCrystalWrapper
- Run before: No specific dependency
Generates the lib Binding
fun
s.
- Kind: Generation
- Run after: Refining processors
- Run before:
CrystalBinding
andVirtualOverride
Generates the Crystal methods in the wrapper classes.
- Kind: Refining
- Run after: No specific dependency
- Run before: No specific dependency
Clang doesn't expose default constructors methods for implicit default constructors. This processor finds these cases and adds an explicit constructor. Also, generates constructors for aggregate types.
- Kind: Information
- Run after: Any time
- Run before: Any time
Debugging processor dumping the current graph onto STDERR
.
- Kind: Refining
- Run after:
FunctionClass
- Run before: No specific dependency
Adds the copied enums to the graph. Should be run after other processors adding classes, so that enums can be added into classes.
- Kind: Refining
- Run after:
Functions
andFunctionClass
- Run before: No specific dependency
Checks if a method require a C/C++ wrapper. If not, marks the method to bind directly to the target method instead of writing a "trampoline" wrapper in C++.
Note: This processor is required for variadic functions to work. A
variadic function looks like this: void func(int c, ...);
A method can be bound directly if all of these are true:
- It uses the C ABI (
extern "C"
) - No argument uses a
to_cpp
converter - The return type doesn't use a
from_cpp
converter
Note: If all methods can be bound to directly, you can remove the cpp
generator completely from your configuration.
- Kind: Refining
- Run after: No specific dependency
- Run before: No specific dependency
Removes all methods using an argument, or returning something, which is
configured as ignore: true
. Also removes methods that show up in the
ignore_methods:
list.
This processor can be run at any time in theory, but should be run as first part of the pipeline.
- Kind: Refining
- Run after:
FunctionClass
andExternC
- Run before: No specific dependency
Maps C functions, configured through the functions:
map in the configuration.
- Kind: Refining
- Run after:
ExternC
- Run before:
Inheritance
andFunctions
Generates wrapper classes from OOP-like C APIs, using guidance from the user
through configuration in the functions:
map.
- Kind: Refining
- Run after:
FunctionClass
- Run before:
FilterMethods
andVirtualOverride
Implements Crystal wrapper inheritance and adds #as_X
conversion methods.
Also handles abstract classes in that it adds an Impl
class, so code can
return instances to the (otherwise) abstract class.
- Kind: Refining
- Run after: No specific dependency
- Run before: No specific dependency
Generates getter and setter methods for static and instance members.
- Kind: Refining
- Run after:
AutoContainerInstantiation
if used - Run before: No specific dependency
Adds the container instantiation classes and wrappers.
- Kind: Refining
- Run after: No specific dependency
- Run before: No specific dependency
Maps #define
macros into the graph. The mapping is configured by the user in
the macros:
list. Only value-macros ("object-like macros") are supported,
function-like macros are silently skipped.
// Okay:
#define SOME_INT 1
#define SOME_STRING "Hello"
#define SOME_BOOL true
// Not mapped:
#define SOME_FUNCTION(x) (x + 1)
- Kind: Refining
- Run after: No specific dependency
- Run before: No specific dependency
Performs special handling for operator methods.
- Kind: Refining
- Run after: No specific dependency
- Run before:
BlockOverloads
Adds Qt specific behaviour:
- Removes the
qt_check_for_QGADGET_macro
fake method. - Provides
#on_SIGNAL
signal connection method. - Removes
#meta_object
,#qt_metacast
, and#qt_metacall
from superclass wrappers, as these shouldn't be overridden by the user.
btn = Qt::PushButton.new
btn.on_clicked do |checked| # Generated by this processor
puts "Checked: #{checked}"
end
- Kind: Information
- Run after: Any time, as very last pipeline element is ideal.
- Run before: Any time
Does sanity checks on the graph, focusing on Crystal bindings and wrappers.
Checks are as follows:
- Name of enums, libs, structures, classes, modules and aliases are valid
- Name of constants are valid
- Name of methods are valid
- Enumerations have at least one constant
- Flag-enumerations don't have
All
norNone
constants - Crystal method overloads are unambiguous
- Method arguments and result types are reachable
- Variadic methods are directly bound
- Alias targets are reachable
- Class base-classes are reachable
- Kind: Refining, but ran after generation processors!
- Run after:
CrystalWrapper
! - Run before:
CrystalBinding
andCppWrapper
Adds C++ and Crystal wrapper code to allow overriding C++ virtual methods from
within Crystal. Requires the Inheritance
processor.
Important Note: Make sure to run this processor after CrystalWrapper
but
before CrystalBinding
.
It needs to modify the #initialize
methods, and generate lib
structures,
bindings, and C++ code too.
This is the recommended processor order:
processors:
# ...
- crystal_wrapper
- block_overloads
- virtual_override
- cpp_wrapper
- crystal_binding
After this, usage is the same as with any method:
class MyAdder < VirtualCalculator
# In C++: virtual int calculate(int a, int b) = 0;
# In Crystal:
def calculate(a, b) : Int32
a + b
end
end
Do NOT call super
in the body of a Crystal method that overrides a concrete
C++ virtual method! Due to Bindgen's limitations, doing so will result in a
stack overflow immediately. Instead, Bindgen provides a private #superclass
method in every concrete abstract class; it wraps the calling instance so that
the original C++ methods can be called, bypassing Crystal's overrides.
class MyLogger < Calculator
# In C++:
# virtual void clear_memory();
# virtual void add_memory(int m);
# In Crystal:
def clear_memory : Nil
puts "M = 0"
superclass.clear_memory
end
def add_memory(m) : Nil
puts "M += #{m}"
# unlike `super`, all arguments are mandatory
superclass.add_memory(m)
end
end
Bindgen's YAML configuration files support conditional definitions as well as loading external dependency files.
Apart from that extra logic, the configuration file is still valid YAML.
Note: Conditionals and dependencies are only supported in YAML
mappings (data structures equivalent to Hash
es in Crystal).
Any such syntax encountered in something other than a mapping will not
trigger special behaviour.
YAML documents can define conditional parts in mappings by having a conditional key with mapping value. If the condition matches, the mapping value will be transparently embedded. If it does not match, the value will be transparently skipped.
Condition keys look like if_X
or elsif_X
or else
. X
is the
condition, and it looks like Y_is_Z
or Y_match_Z
. You can also use
(one or more) spaces (
) instead of exactly one underscore (_
) to
separate the words.
Available conditions:
Y_is_Z
: true if the variable Y equals Z case-sensitively.Y_isnt_Z
: true if the variable Y doesn't equal Z case-sensitively.Y_match_Z
: true if the variable Y is matched by the regular expression inZ
. The regular expression is created case-sensitively.Y_newer_or_Z
: true when variable Y is newer or equals (>=) to Z. Variables are treated as versions.Y_older_or_Z
: true when variable Y is older or equals (=<) to Z. Variables are treated as versions.
A condition block is opened by the first if
. Later condition keys can
use elsif
or else
(or if
to open a new condition block).
Note: elsif
or else
without an if
will raise an exception.
Their behaviour is like in Crystal: if
starts a condition block, elsif
starts an alternative condition block, and else
is used if none of if
or
elsif
matched. It's possible to mix condition key-values with normal
key-values.
Note: Conditions can be used in every mapping, even in mappings of a conditional. Each mapping acts as its own scope.
Variables are set by the user of the class (probably through
ConfigReader.from_yaml
). All variable values are strings.
Variable names are case-sensitive. A missing variable will be treated
as having an empty value (""
).
foo: # A normal mapping
bar: 1
# A condition: Matches if `platform` equals "arm".
if_platform_is_arm: # In Crystal: `if platform == "arm"`
company: ARM et al
# You can mix in values between conditionals. It won't "break" following
# elsif or else blocks.
not_a_condition: Hello
# An elsif: It matches if
# 1) the previous conditions didn't match, and
# 2) its own condition matches.
elsif_platform_match_x86: # In Crystal: `elsif platform =~ /x86/`
company: Many different
# An else: Matches if all previous conditions didn't match.
else:
company: No idea
# At any time, you can start a new if sequence.
"if today is friday": # You can use spaces instead of underscores too
hooray: true
To modularize the configuration, you can require ("merge") external yaml files from within your configuration.
This is triggered by using a key named <<
, and writing the file name as
value: <<: my_dependency.yml
. The file-extension can also be omitted:
<<: my_dependency
in which case an .yml
extension is assumed.
The dependency path is relative to the currently processed YAML file.
You can also require multiple dependencies into the same mapping:
types:
Something: true # You can mix dependencies with normal fields.
<<: simple_types.yml
<<: complex_types.yml
<<: ignores.yml
The dependency will be embedded into the open mapping: It is transparent to the client code.
It's perfectly possible to mix conditionals with dependencies:
if_os_is_windows:
<<: windows-specific.yml
An exception will be raised if any of the following occur:
- The maximum dependency depth of
10
(MAX_DEPTH
) is exceeded. - The dependency name contains a dot:
../foo.yml
won't work. - The dependency name is absolute:
/foo/bar.yml
won't work.
Arch | System | CI | Clang version |
---|---|---|---|
x86_64 | ArchLinux | Travis | Rolling |
x86_64 | Debian 9 | Travis | 6.0, 7.0 |
x86_64 | Debian 7 | Travis | 4.0, 5.0 |
x86_64 | Ubuntu 17.04 | None | 5.0 |
x86_64 | Ubuntu 16.04 | Travis | 4.0, 5.0 |
Other systems | Help wanted | ? |
You require the LLVM and Clang development libraries and headers. If you don't
have them already installed, bindgen will tell you. These packages are usually
named after the following pattern on Debian-based systems:
clang-7 libclang-7-dev llvm-7 llvm-7-dev
.
- Open a new issue on the project to discuss what you're going to do and possibly receive comments
- Read the
STYLEGUIDE.md
for some tips. - Then do the rest, PR and all. You know the drill :)
- Papierkorb Stefan Merettig - creator
- docelic Davor Ocelic
- kalinon Holden Omans
- HertzDevil Quinton Miller
- ZaWertun Yaroslav Sidlovsky
This project (bindgen
) and all of its sources, except those otherwise noted,
all fall under the GPLv3
license. You can find a copy of its complete license
text in the LICENSE
file.
The configuration used to generate code, and all code generated by this project,
fall under the full copyright of the user of bindgen
. bindgen
does not
claim any copyright, legal or otherwise, on your work. Established projects
should define a license they want to use for the generated code and
configuration.