ffigen 19.1.0 
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tools.dart.devGenerator for FFI bindings, using LibClang to parse C, Objective-C, and Swift files.
Binding generator for FFI bindings.
Note: ffigen only supports parsing
Cheaders, notC++headers.
This bindings generator can be used to call C code -- or code in another language that compiles to C modules that follow the C calling convention -- such as Go or Rust. For more details, see: https://dart.cn/guides/libraries/c-interop
ffigen also has experimental support for calling ObjC and Swift code; for details see: https://dart.cn/guides/libraries/objective-c-interop
Example #
For some header file example.h:
int sum(int a, int b);
Add configurations to Pubspec File:
ffigen:
output: 'generated_bindings.dart'
headers:
entry-points:
- 'example.h'
Output (generated_bindings.dart).
import 'dart:ffi' as ffi;
class NativeLibrary {
final ffi.Pointer<T> Function<T extends ffi.NativeType>(String symbolName)
_lookup;
NativeLibrary(ffi.DynamicLibrary dynamicLibrary)
: _lookup = dynamicLibrary.lookup;
NativeLibrary.fromLookup(
ffi.Pointer<T> Function<T extends ffi.NativeType>(String symbolName)
lookup)
: _lookup = lookup;
int sum(int a, int b) {
return _sum(a, b);
}
late final _sumPtr = _lookup<ffi.NativeFunction<ffi.Int Function(ffi.Int, ffi.Int)>>('sum');
late final _sum = _sumPtr.asFunction<int Function(int, int)>();
}
}
Using this package #
- Add
ffigenunderdev_dependenciesin yourpubspec.yaml(rundart pub add -d ffigen). - Add
package:ffiunderdependenciesin yourpubspec.yaml(rundart pub add ffi). - Install LLVM (see Installing LLVM).
- Configurations must be provided in
pubspec.yamlor in a custom YAML file (see configurations). - Run the tool-
dart run ffigen.
Jump to FAQ.
Installing LLVM #
package:ffigen uses LLVM. Install LLVM (9+) in the following way.
Linux
-
Install libclangdev.
With apt-get:
sudo apt-get install libclang-dev.With dnf:
sudo dnf install clang-devel.
Windows
- Install Visual Studio with C++ development support.
- Install LLVM or
winget install -e --id LLVM.LLVM.
MacOS
- Install Xcode.
- Install Xcode command line tools -
xcode-select --install.
Configurations #
Configurations can be provided in 2 ways-
- In the project's
pubspec.yamlfile under the keyffigen. - Via a custom YAML file, then specify this file while running -
dart run ffigen --config config.yaml
The following configuration options are available-
| Key | Explaination | Example |
|---|---|---|
| output (Required) |
Output path of the generated bindings. |
or |
| llvm-path | Path to llvm folder. ffigen will sequentially search for `lib/libclang.so` on linux, `lib/libclang.dylib` on macOs and `bin\libclang.dll` on windows, in the specified paths. Complete path to the dynamic library can also be supplied. Required if ffigen is unable to find this at default locations. |
|
| headers (Required) |
The header entry-points and include-directives. Glob syntax is allowed. If include-directives are not specified ffigen will generate everything directly/transitively under the entry-points. |
|
| name (Prefer) |
Name of generated class. |
|
| description (Prefer) |
Dart Doc for generated class. |
|
| compiler-opts | Pass compiler options to clang. You can also pass these via the command line tool. |
and/or via the command line - |
| compiler-opts-automatic.macos.include-c-standard-library | Tries to automatically find and add C standard library path to
compiler-opts on macos. Default: true |
|
|
functions structs unions enums unnamed-enums macros globals |
Filters for declarations. Default: all are included. Options - - Include/Exclude declarations. - Rename declarations. - Rename enum, struct, and union members, function parameters, and ObjC interface and protocol methods and properties. - Expose symbol-address for functions and globals. |
|
| typedefs | Filters for referred typedefs. Options - - Include/Exclude (referred typedefs only). - Rename typedefs. Note: By default, typedefs that are not referred to anywhere will not be generated. |
|
| include-unused-typedefs |
Also generate typedefs that are not referred to anywhere.
Default: false |
|
| functions.expose-typedefs | Generate the typedefs to Native and Dart type of a function Default: Inline types are used and no typedefs to Native/Dart type are generated. |
|
| functions.leaf | Set isLeaf:true for functions. Default: all functions are excluded. |
|
| functions.variadic-arguments | Generate multiple functions with different variadic arguments. Default: var args for any function are ignored. |
|
| structs.pack | Override the @Packed(X) annotation for generated structs. Options - none, 1, 2, 4, 8, 16 You can use RegExp to match with the generated names. Note: Ffigen can only reliably identify packing specified using __attribute__((__packed__)). However, structs packed using `#pragma pack(...)` or any other way could potentially be incorrect in which case you can override the generated annotations. |
|
| comments | Extract documentation comments for declarations. The style and length of the comments recognized can be specified with the following options- style: doxygen(default) | any length: brief | full(default) If you want to disable all comments you can also pass comments: false. |
|
| structs.dependency-only unions.dependency-only |
If `opaque`, generates empty `Opaque` structs/unions if they
were not included in config (but were added since they are a dependency) and
only passed by reference(pointer). Options - full(default) | opaque |
|
| sort | Sort the bindings according to name. Default: false, i.e keep the order as in the source files. |
|
| use-supported-typedefs | Should automatically map typedefs, E.g uint8_t => Uint8, int16_t => Int16, size_t => Size etc. Default: true |
|
| use-dart-handle | Should map `Dart_Handle` to `Handle`. Default: true |
|
| ignore-source-errors | Where to ignore compiler warnings/errors in source header files. Default: false |
and/or via the command line - |
| silence-enum-warning | Where to silence warning for enum integer type mimicking. The integer type used for enums is implementation-defined, and not part of the ABI. FFIgen tries to mimic the integer sizes chosen by the most common compilers for the various OS and architecture combinations. Default: false |
|
| exclude-all-by-default |
When a declaration filter (eg `functions:` or `structs:`) is empty or
unset, it defaults to including everything. If this flag is enabled, the
default behavior is to exclude everything instead. Default: false |
|
| preamble | Raw header of the file, pasted as-it-is. |
|
| library-imports | Specify library imports for use in type-map. Note: ffi (dart:ffi) is already available as a predefined import. |
|
| type-map | Map types like integers, typedefs, structs, unions to any other type. Sub-fields - typedefs, structs, unions, ints lib must be specified in library-imports or be one of a predefined import. |
|
| ffi-native |
WARNING: Native support is EXPERIMENTAL. The API may change
in a breaking way without notice.
Generate `@Native` bindings instead of bindings using `DynamicLibrary` or `lookup`. |
|
| language |
WARNING: Other language support is EXPERIMENTAL. The API may change
in a breaking way without notice.
Choose the input langauge. Must be one of 'c', or 'objc'. Defaults to 'c'. |
|
| output.objc-bindings |
Choose where the generated ObjC code (if any) is placed. The default path
is `'${output.bindings}.m'`, so if your Dart bindings are in
`generated_bindings.dart`, your ObjC code will be in
`generated_bindings.dart.m`.
This ObjC file will only be generated if it's needed. If it is generated, it must be compiled into your package, as part of a flutter plugin or build.dart script. If your package already has some sort of native build, you can simply add this generated ObjC file to that build. |
|
| output.symbol-file | Generates a symbol file yaml containing all types defined in the generated output. |
|
| import.symbol-files | Import symbols from a symbol file. Used for sharing type definitions from other pacakges. |
|
| external-versions |
Interfaces, methods, and other API elements may be marked with
deprecation annotations that indicate which platform version they were
deprecated in. If external-versions is set, APIs that were
deprecated as of the minimum version will be omitted from the
generated bindings.
The minimum version is specified per platform, and an API will be generated if it is available on *any* of the targeted platform versions. If a version is not specified for a particular platform, the API's inclusion will be based purely on the platforms that have a specified minimum version. Current support OS keys are ios and macos. If you have a use case for version checking on other OSs, please file an issue. |
|
Objective-C config options #
| Key | Explaination | Example |
|---|---|---|
|
objc-interfaces objc-protocols objc-categories |
Filters for Objective C interface, protocol, and category declarations. This option works the same as other declaration filters like `functions` and `structs`. |
|
|
objc-interfaces.module objc-protocols.module |
Adds a module prefix to the interface/protocol name when loading it
from the dylib. This is only relevent for ObjC headers that are generated
wrappers for a Swift library. See example/swift for more information.
This is not necessary for objc-categories. |
|
|
objc-interfaces.member-filter objc-protocols.member-filter objc-categories.member-filter |
Filters interface and protocol methods and properties. This is a map from interface name to a list of method include and exclude rules. The interface name can be a regexp. The include and exclude rules work exactly like any other declaration. See below for more details. |
|
|
include-transitive-objc-interfaces include-transitive-objc-protocols |
By default, Objective-C interfaces and protocols that are not directly
included by the inclusion rules, but are transitively depended on by
the inclusions, are not fully code genned. Transitively included
interfaces are generated as stubs, and transitive protocols are omitted.
If these flags are enabled, transitively included interfaces and protocols are fully code genned. Default: false |
|
| include-transitive-objc-categories |
By default, if an Objective-C interface is included in the bindings, all
the categories that extend it are also included. To filter them, set this
flag to false, then use objc-categories to include/exclude particular
categories.
Transitive categories are generated by default because it's not always obvious from the Apple documentation which interface methods are declared directly in the interface, and which are declared in categories. So it may appear that the interface is missing methods, when in fact those methods are part of a category. This would be a difficult problem to diagnose if transitive categories were not generated by default. Default: true |
|
Trying out examples #
cd examples/<example_u_want_to_run>, Rundart pub get.- Run
dart run ffigen.
Running Tests #
See test/README.md
FAQ #
Can ffigen be used for removing underscores or renaming declarations? #
Ffigen supports regexp based renaming, the regexp must be a
full match, for renaming you can use regexp groups ($1 means group 1).
E.g - For renaming clang_dispose_string to string_dispose.
We can can match it using clang_(.*)_(.*) and rename with $2_$1.
Here's an example of how to remove prefix underscores from any struct and its members.
structs:
...
rename:
'_(.*)': '$1' # Removes prefix underscores from all structures.
member-rename:
'.*': # Matches any struct.
'_(.*)': '$1' # Removes prefix underscores from members.
How to generate declarations only from particular headers? #
The default behaviour is to include everything directly/transitively under
each of the entry-points specified.
If you only want to have declarations directly particular header you can do so
using include-directives. You can use glob matching to match header paths.
headers:
entry-points:
- 'path/to/my_header.h'
include-directives:
- '**my_header.h' # This glob pattern matches the header path.
Can ffigen filter declarations by name? #
Ffigen supports including/excluding declarations using full regexp matching.
Here's an example to filter functions using names
functions:
include:
- 'clang.*' # Include all functions starting with clang.
exclude:
- '.*dispose': # Exclude all functions ending with dispose.
This will include clang_help. But will exclude clang_dispose.
Note: exclude overrides include.
How does ffigen handle C Strings? #
Ffigen treats char* just as any other pointer,(Pointer<Int8>).
To convert these to/from String, you can use package:ffi. Use ptr.cast<Utf8>().toDartString() to convert char* to dart string and "str".toNativeUtf8() to convert string to char*.
How are unnamed enums handled? #
Unnamed enums are handled separately, under the key unnamed-enums, and are generated as top level constants.
Here's an example that shows how to include/exclude/rename unnamed enums
unnamed-enums:
include:
- 'CX_.*'
exclude:
- '.*Flag'
rename:
'CXType_(.*)': '$1'
How can I handle unexpected enum values? #
Native enums are, by default, generated into Dart enums with int get value and fromValue(int).
This works well in the case that your enums values are known in advance and not going to change,
and in return, you get the full benefits of Dart enums like exhaustiveness checking.
However, if a native library adds another possible enum value after you generate your bindings,
and this new value is passed to your Dart code, this will result in an ArgumentError at runtime.
To fix this, you can regenerate the bindings on the new header file, but if you wish to avoid this
issue entirely, you can tell ffigen to generate plain Dart integers for your enum instead. To do
this, simply list your enum's name in the as-int section of your ffigen config:
enums:
as-int:
include:
- MyIntegerEnum
- '*IntegerEnum'
exclude:
- FakeIntegerEnum
Functions that accept or return these enums will now accept or return integers instead, and it will be up to your code to map integer values to behavior and handle invalid values. But your code will be future-proof against new additions to the enums.
Why are some struct/union declarations generated even after excluded them in config? #
This happens when an excluded struct/union is a dependency to some included declaration. (A dependency means a struct is being passed/returned by a function or is member of another struct in some way)
Note: If you supply structs.dependency-only as opaque ffigen will generate
these struct dependencies as Opaque if they were only passed by reference(pointer).
structs:
dependency-only: opaque
unions:
dependency-only: opaque
How to expose the native pointers? #
By default the native pointers are private, but you can use the
symbol-address subkey for functions/globals and make them public by matching with its name. The pointers are then accesible via nativeLibrary.addresses.
Example -
functions:
symbol-address:
include:
- 'myFunc' # Match function name.
- '.*' # Do this to expose all function pointers.
exclude: # If you only use exclude, then everything not excluded is generated.
- 'dispose'
How to get typedefs to Native and Dart type of a function? #
By default these types are inline. But you can use the expose-typedef subkey
for functions to generate them. This will expose the Native and Dart type.
E.g - for a function named hello, the generated typedefs are named
as NativeHello and DartHello.
Example -
functions:
expose-typedefs:
include:
- 'myFunc' # Match function name.
- '.*' # Do this to expose types for all function.
exclude: # If you only use exclude, then everything not excluded is generated.
- 'dispose'
How are Structs/Unions/Enums that are reffered to via typedefs handled? #
Named declarations use their own names even when inside another typedef. However, unnamed declarations inside typedefs take the name of the first typedef that refers to them.
Why are some typedefs not generated? #
The following typedefs are not generated -
- They are not referred to anywhere in the included declarations.
- They refer to a struct/union having the same name as itself.
- They refer to a boolean, enum, inline array, Handle or any unsupported type.
How are macros handled? #
ffigen uses clang's own compiler frontend to parse and traverse the C header files. ffigen expands the macros using clang's macro expansion and then traverses the expanded code. To do this, ffigen generates temporary files in a system tmp directory.
A custom temporary directory can be specified by setting the TEST_TMPDIR environment variable.
What are these logs generated by ffigen and how to fix them? #
Ffigen can sometimes generate a lot of logs, especially when it's parsing a lot of code.
SEVERElogs are something you definitely need to address. They can be caused due to syntax errors, or more generally missing header files (which need to be specified usingcompiler-optsin config)WARNINGlogs are something you can ignore, but should probably look into. These are mostly indications of declarations ffigen couldn't generate due to limitations of dart:ffi, private declarations (which can be resolved by renaming them via ffigen config) or other minor issues in the config file itself.- Everything else can be safely ignored. It's purpose is to simply let you know what ffigen is doing.
- The verbosity of the logs can be changed by adding a flag with
the log level. E.g -
dart run ffigen --verbose <level>. Level options are -[all, fine, info (default), warning, severe]. Theallandfinewill print a ton of logs are meant for debugging purposes only.
How can type definitions be shared? #
Ffigen can share type definitions using symbol files.
- A package can generate a symbol file using the
output.symbol-fileconfig. - And another package can then import this, using
import.symbol-filesconfig. - Doing so will reuse all the types such as Struct/Unions, and will automatically exclude generating other types (E.g functions, enums, macros).
Checkout examples/shared_bindings for details.
For manually reusing definitions from another package, the library-imports
and type-map config can be used.
How does ObjC method filtering work? #
Methods and properties on ObjC interfaces and protocols can be filtered using
the member-filter option under objc-interfaces and objc-protocols. For
simplicity we'll focus on interface methods, but the same rules apply to
properties and protocols. There are two parts to the filtering process: matching
the interface, and then filtering the method.
The syntax of member-filter is a YAML map from a pattern to some
include/exclude rules, and include and exclude are each a list of
patterns.
objc-interfaces:
member-filter:
MyInterface: # Matches an interface.
include:
- "someMethod:withArg:" # Matches a method.
exclude:
- someOtherMethod # Matches a method.
The interface matching logic is the same as the matching logic for the
member-rename option:
- The pattern is compared against the original name of the interface (before any renaming is applied).
- The pattern may be a string or a regexp, but in either case they must match the entire interface name.
- If the pattern contains only alphanumeric characters, or
_, it is treated as a string rather than a regex. - String patterns take precedence over regexps. That is, if an interface matches
both a regexp pattern, and a string pattern, it uses the string pattern's
include/excluderules.
The method filtering logic uses the same include/exclude rules as the rest
of the config:
includeandexcludeare a list of patterns.- The patterns are compared against the original name of the method, before renaming.
- The patterns can be strings or regexps, but must match the entire method name.
- The method name is in ObjC selector syntax, which means that the method name
and all the external parameter names are concatenated together with
:characters. This is the same name you'll see in ObjC's API documentation. - NOTE: Since the pattern must match the entire method name, and most ObjC
method names end with a
:, it's a good idea to surround the pattern with quotes,". Otherwise YAML will think you're defining a map key. - If no
includeorexcluderules are defined, all methods are included, regardless of the top levelexclude-all-by-defaultrule. - If only
includerules aredefined, all non-matching methods are excluded. - If only
excluderules aredefined, all non-matching methods are included. - If both
includeandexcluderules are defined, theexcluderules take precedence. That is, if a method name matches both anincluderule and anexcluderule, the method is excluded. All non-matching methods are also excluded.
The property filtering rules live in the same objc-interfaces.member-filter
option as the methods. There is no distinction between methods and properties in
the filters. The protocol filtering rules live in
objc-protocols.member-filter.
How do I generate bindings for Apple APIs? #
It can be tricky to locate header files containing Apple's ObjC frameworks, and
the paths can vary between computers depending on which version of Xcode you are
using and where it is installed. So ffigen provides the following variable
substitutions that can be used in the headers.entry-points list:
$XCODE: Replaced with the result ofxcode-select -p, which is the directory where Xcode's APIs are installed.$IOS_SDK: Replaced withxcrun --show-sdk-path --sdk iphoneos, which is the directory within$XCODEwhere the iOS SDK is installed.$MACOS_SDK: Replaced withxcrun --show-sdk-path --sdk macosx, which is the directory within$XCODEwhere the macOS SDK is installed.
For example:
headers:
entry-points:
- '$MACOS_SDK/System/Library/Frameworks/Foundation.framework/Headers/NSDate.h'
Metadata
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Metadata
Generator for FFI bindings, using LibClang to parse C, Objective-C, and Swift files.
Repository (GitHub)
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Contributing
Topics
Documentation
License
BSD-3-Clause (license)
Dependencies
args, cli_util, collection, dart_style, ffi, file, glob, logging, meta, package_config, path, pub_semver, quiver, yaml, yaml_edit
