dpp 0.5.4
Include C/C++ headers directly in D files
To use this package, run the following command in your project's root directory:
Manual usage
Put the following dependency into your project's dependences section:
d++ - #include C and C++ headers in D files
Goal
To directly #include
C and C++ headers in D files and have the same semantics and ease-of-use
as if the file had been #included
from C or C++ themselves. Warts and all, meaning that C enum
declarations
will pollute the global namespace, just as it does "back home".
This work was supported by Symmetry Investments.
Example
// c.h
#ifndef C_H
#define C_H
#define FOO_ID(x) (x*3)
int twice(int i);
#endif
// c.c
int twice(int i) { return i * 2; }
// foo.dpp
#include "c.h"
void main() {
import std.stdio;
writeln(twice(FOO_ID(5))); // yes, it's using a C macro here!
}
At the shell:
$ gcc -c c.c
$ d++ foo.dpp c.o
$ ./foo
$ 30
C++ support
C++ support is currently limited. Including any header from the C++
standard library is unlikely to work. Simpler headers might, the
probability rising with how similar the C++ dialect used is to
C. Despite that, dpp currently does try to translate classes,
templates and operator overloading. It's unlikely to work on
production headers without judicious use of the --ignore-cursor
and
--ignore-namespace
command-line options. When using these, the user
can then define their own versions of problematic declarations such as
std::vector
.
Limitations
- Only known to work on Linux with libclang versions 6 and up. It might work in different conditions.
- When used on multiple files, there might be problems with duplicate definitions depending on imports.
It is recommended to put all
#include
s in one.dpp
file and import the resulting D module. - Not currently able to translate Linux kernel headers.
Success stories
Known project headers whose translations produce D code that compiles:
- nanomsg/nn.h, nanomsg/pubsub.h
- curl/curl.h
- stdio.h, stdlib.h
- pthread.h
- julia.h
- xlsxwriter.h
- libvirt/libvirt.h, libvirt/virterror.h
- libzfs
- openssl/ssl.h
- imapfilter.h
- libetpan/libetpan.h
- Python.h
Compilation however doesn't guarantee they work as expected and YMMV. Please consult the examples.
Command-line arguments
It is likely that the header or headers need -I
flags to indicate paths to be searched,
both by this executable and by libclang itself. The --include-path
option can be
used for that, once for each such path.
Use -h
or --help
to learn more.
Details
d++
is an executable that wraps a D compiler such as dmd (the default) so that D files with #include
directives can be compiled.
It takes a .dpp
file and outputs a valid D file that can be compiled. The original can't since D
has no preprocessor, so the .dpp
file is "quasi-D", or "D with #include directives".
The only supported C preprocessor directive is #include
.
The input .dpp
file may also use C preprocessor macros defined in the file(s) it #include
s, just as a C/C++
program would (see the example above). It may not, however, define macros of its own.
d++
goes through the input file line-by-line, and upon encountering an #include
directive, parses
the file to be included with libclang, loops over the definitions of data structures and functions
therein and expands in-place the relevant D translations. e.g. if a header contains:
uint16_t foo(uint32_t a);
The output file will contain:
ushort foo(uint a);
d++ will also enclose each one of these original #include
directives with either
extern(C) {}
or extern(C++) {}
depending on the header file name and/or command-line options.
As part of expanding the #include
, and as well as translating declarations, d++ will also
insert text to define macros originally defined in the #include
d translation unit so that these
macros can be used by the D program. The reason for this is that nearly every non-trivial
C API requires the preprocessor to use properly. It is possible to mimic this usage in D
with enums and CTFE, but the result is not guaranteed to be the same. The only way to use a
C or C++ API as it was intended is by leveraging the preprocessor.
Trivial literal macros however(e.g. #define THE_ANSWER 42
) are translated as
D enums.
As a final pass before writing the output D file, d++ will run the C
preprocessor (currently the cpp binary installed on the system) on the
intermediary result of expanding all the #include
directives so that
any used macros are expanded, and the result is a D file that can be compiled.
In this fashion a user can write code that's not-quite-D-but-nearly that can "natively"
call into a C/C++ API by #include
ing the appropriate header(s).
Translation notes
enum
For convenience, this declaration:
enum Enum { foo, bar, baz }
Will generate this translation:
enum Enum { foo, bar, baz }
enum foo = Enum.foo;
enum bar = Enum.bar;
enum baz = Enum.baz;
This is to mimic C semantics with regards to the global namespace whilst also allowing one to, say, reflect on the enum type.
Renaming enums
There is the ability to rename C enums. With the following C definition:
enum FancyWidget { Widget_foo, Widget_bar }
Then adding this to your .dpp file after the #include
directive:
mixin dpp.EnumD!("Widget", // the name of the new D enum
FancyWidget, // the name of the original C enum
"Widget_"); // the prefix to cut out
will yield this translation:
enum Widget { foo, bar }
Names of structs, enums and unions
C has a different namespace for the aforementioned user-defined types. As such, this is legal C:
struct foo { int i; };
extern int foo;
The D translations just use the short name for these aggregates, and if there is a name collision
with a variable or function, the latter two get renamed and have a pragma(mangle)
added to
avoid linker failures:
struct foo { int i; }
pragma(mangle, "foo") extern export __gshared int foo_;
Functions or variables with a name that is a D keyword
Similary to name collisions with aggregates, they get an underscore
appended and a pragma(mangle)
added so they link:
void debug(const char* msg);
Becomes:
pragma(mangle, "debug")
void debug_(const(char)*);
Build Instructions
dub install dpp
After the instructions for your OS (see below), you can use this commands to run dpp:
dub run dpp -- yoursourcefilenamehere.dpp
Note: for a reproducible and cross-platform build environment, you can run setup-cpp with --llvm=11.0.0
. This will set up LLVM 11.0.0 and the proper environment variables.
Windows
Install LLVM into C:\Program Files\LLVM\
, making sure to tick the "Add LLVM to the system PATH for all users" option.
If libclang.lib
was not found, put the lib
folder of the llvm directory on the PATH.
Linux
If libclang
is not installed, install libclang-10-dev
with apt: sudo apt-get install -y -qq libclang-10-dev
If libclang.so
was not found, link it using the following command (adjust the installation path and the llvm version):
sudo ln -s path_to_llvm/lib/libclang-12.so.1 /lib/x86_64-linux-gnu/libclang.so
MacOS
If using an external LLVM installation, add these to your ~/.bash_profile
LLVM_PATH="/usr/local/opt/llvm/" # or any other path
LLVM_VERSION="11.0.0"
export PATH="$LLVM_PATH:$PATH"
export SDKROOT=$(xcrun --sdk macosx --show-sdk-path)
export LD_LIBRARY_PATH="$LLVM_PATH/lib/:$LD_LIBRARY_PATH"
export DYLD_LIBRARY_PATH="$LLVM_PATH/lib/:$DYLD_LIBRARY_PATH"
export CPATH="$LLVM_PATH/lib/clang/$LLVM_VERSION/include/"
export LDFLAGS="-L$LLVM_PATH/lib"
export CPPFLAGS="-I$LLVM_PATH/include"
export CC="$LLVM_PATH/bin/clang"
export CXX="$LLVM_PATH/bin/clang++"
(adjust the clang version and the external llvm installation path.)
Then run source ~/.bash_profile
If libclang.dylib
was not found, link it using the following command (adjust the installation path):
ln -s path_to_llvm/lib/libclang.dylib /usr/local/opt/llvm/lib/libclang.dylib
- Registered by Atila Neves
- 0.5.4 released a year ago
- atilaneves/dpp
- boost
- Copyright © 2017-2018, Atila Neves
- Authors:
- Dependencies:
- libclang, sumtype
- Versions:
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