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- ================================
- Nim Backend Integration
- ================================
- :Author: Puppet Master
- :Version: |nimversion|
- .. contents::
- "Heresy grows from idleness." -- Unknown.
- Introduction
- ============
- The `Nim Compiler User Guide <nimc.html>`_ documents the typical
- compiler invocation, using the ``compile`` or ``c`` command to transform a
- ``.nim`` file into one or more ``.c`` files which are then compiled with the
- platform's C compiler into a static binary. However there are other commands
- to compile to C++, Objective-C or JavaScript. This document tries to
- concentrate in a single place all the backend and interfacing options.
- The Nim compiler supports mainly two backend families: the C, C++ and
- Objective-C targets and the JavaScript target. `The C like targets`_ creates
- source files which can be compiled into a library or a final executable. `The
- JavaScript target`_ can generate a ``.js`` file which you reference from an
- HTML file or create a `standalone nodejs program <http://nodejs.org>`_.
- On top of generating libraries or standalone applications, Nim offers
- bidirectional interfacing with the backend targets through generic and
- specific pragmas.
- Backends
- ========
- The C like targets
- ------------------
- The commands to compile to either C, C++ or Objective-C are:
- //compileToC, cc compile project with C code generator
- //compileToCpp, cpp compile project to C++ code
- //compileToOC, objc compile project to Objective C code
- The most significant difference between these commands is that if you look
- into the ``nimcache`` directory you will find ``.c``, ``.cpp`` or ``.m``
- files, other than that all of them will produce a native binary for your
- project. This allows you to take the generated code and place it directly
- into a project using any of these languages. Here are some typical command
- line invocations::
- $ nim c hallo.nim
- $ nim cpp hallo.nim
- $ nim objc hallo.nim
- The compiler commands select the target backend, but if needed you can
- `specify additional switches for cross compilation
- <nimc.html#cross-compilation>`_ to select the target CPU, operative system
- or compiler/linker commands.
- The JavaScript target
- ---------------------
- Nim can also generate `JavaScript`:idx: code through the ``js`` command.
- However, the JavaScript code generator is experimental!
- Nim targets JavaScript 1.5 which is supported by any widely used browser.
- Since JavaScript does not have a portable means to include another module,
- Nim just generates a long ``.js`` file.
- Features or modules that the JavaScript platform does not support are not
- available. This includes:
- * manual memory management (``alloc``, etc.)
- * casting and other unsafe operations (``cast`` operator, ``zeroMem``, etc.)
- * file management
- * most modules of the Standard library
- * proper 64 bit integer arithmetic
- * unsigned integer arithmetic
- However, the modules `strutils <strutils.html>`_, `math <math.html>`_, and
- `times <times.html>`_ are available! To access the DOM, use the `dom
- <dom.html>`_ module that is only available for the JavaScript platform.
- To compile a Nim module into a ``.js`` file use the ``js`` command; the
- default is a ``.js`` file that is supposed to be referenced in an ``.html``
- file. However, you can also run the code with `nodejs`:idx:, a `software
- platform for easily building fast, scalable network applications
- <http://nodejs.org>`_::
- nim js -d:nodejs -r examples/hallo.nim
- Interfacing
- ===========
- Nim offers bidirectional interfacing with the target backend. This means
- that you can call backend code from Nim and Nim code can be called by
- the backend code. Usually the direction of which calls which depends on your
- software architecture (is Nim your main program or is Nim providing a
- component?).
- Nim code calling the backend
- ----------------------------
- Nim code can interface with the backend through the `Foreign function
- interface <manual.html#foreign-function-interface>`_ mainly through the
- `importc pragma <manual.html#importc-pragma>`_. The ``importc`` pragma is the
- *generic* way of making backend symbols available in Nim and is available
- in all the target backends (JavaScript too). The C++ or Objective-C backends
- have their respective `ImportCpp <manual.html#implementation-specific-pragmas-importcpp-pragma>`_ and
- `ImportObjC <manual.html#implementation-specific-pragmas-importobjc-pragma>`_ pragmas to call methods from
- classes.
- Whenever you use any of these pragmas you need to integrate native code into
- your final binary. In the case of JavaScript this is no problem at all, the
- same html file which hosts the generated JavaScript will likely provide other
- JavaScript functions which you are importing with ``importc``.
- However, for the C like targets you need to link external code either
- statically or dynamically. The preferred way of integrating native code is to
- use dynamic linking because it allows you to compile Nim programs without
- the need for having the related development libraries installed. This is done
- through the `dynlib pragma for import
- <manual.html#dynlib-pragma-for-import>`_, though more specific control can be
- gained using the `dynlib module <dynlib.html>`_.
- The `dynlibOverride <nimc.html#dynliboverride>`_ command line switch allows
- to avoid dynamic linking if you need to statically link something instead.
- Nim wrappers designed to statically link source files can use the `compile
- pragma <nimc.html#compile-pragma>`_ if there are few sources or providing
- them along the Nim code is easier than using a system library. Libraries
- installed on the host system can be linked in with the `PassL pragma
- <nimc.html#passl-pragma>`_.
- To wrap native code, take a look at the `c2nim tool <c2nim.html>`_ which helps
- with the process of scanning and transforming header files into a Nim
- interface.
- C invocation example
- ~~~~~~~~~~~~~~~~~~~~
- Create a ``logic.c`` file with the following content:
- .. code-block:: c
- int addTwoIntegers(int a, int b)
- {
- return a + b;
- }
- Create a ``calculator.nim`` file with the following content:
- .. code-block:: nim
- {.compile: "logic.c".}
- proc addTwoIntegers(a, b: cint): cint {.importc.}
- when isMainModule:
- echo addTwoIntegers(3, 7)
- With these two files in place, you can run ``nim c -r calculator.nim`` and
- the Nim compiler will compile the ``logic.c`` file in addition to
- ``calculator.nim`` and link both into an executable, which outputs ``10`` when
- run. Another way to link the C file statically and get the same effect would
- be remove the line with the ``compile`` pragma and run the following typical
- Unix commands::
- $ gcc -c logic.c
- $ ar rvs mylib.a logic.o
- $ nim c --passL:mylib.a -r calculator.nim
- Just like in this example we pass the path to the ``mylib.a`` library (and we
- could as well pass ``logic.o``) we could be passing switches to link any other
- static C library.
- JavaScript invocation example
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- Create a ``host.html`` file with the following content:
- .. code-block::
- <html><body>
- <script type="text/javascript">
- function addTwoIntegers(a, b)
- {
- return a + b;
- }
- </script>
- <script type="text/javascript" src="calculator.js"></script>
- </body></html>
- Create a ``calculator.nim`` file with the following content (or reuse the one
- from the previous section):
- .. code-block:: nim
- proc addTwoIntegers(a, b: int): int {.importc.}
- when isMainModule:
- echo addTwoIntegers(3, 7)
- Compile the Nim code to JavaScript with ``nim js -o:calculator.js
- calculator.nim`` and open ``host.html`` in a browser. If the browser supports
- javascript, you should see the value ``10``. In JavaScript the `echo proc
- <system.html#echo>`_ will modify the HTML DOM and append the string. Use the
- `dom module <dom.html>`_ for specific DOM querying and modification procs.
- Backend code calling Nim
- ------------------------
- Backend code can interface with Nim code exposed through the `exportc
- pragma <manual.html#exportc-pragma>`_. The ``exportc`` pragma is the *generic*
- way of making Nim symbols available to the backends. By default the Nim
- compiler will mangle all the Nim symbols to avoid any name collision, so
- the most significant thing the ``exportc`` pragma does is maintain the Nim
- symbol name, or if specified, use an alternative symbol for the backend in
- case the symbol rules don't match.
- The JavaScript target doesn't have any further interfacing considerations
- since it also has garbage collection, but the C targets require you to
- initialize Nim's internals, which is done calling a ``NimMain`` function.
- Also, C code requires you to specify a forward declaration for functions or
- the compiler will assume certain types for the return value and parameters
- which will likely make your program crash at runtime.
- The Nim compiler can generate a C interface header through the ``--header``
- command line switch. The generated header will contain all the exported
- symbols and the ``NimMain`` proc which you need to call before any other
- Nim code.
- Nim invocation example from C
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- Create a ``fib.nim`` file with the following content:
- .. code-block:: nim
- proc fib(a: cint): cint {.exportc.} =
- if a <= 2:
- result = 1
- else:
- result = fib(a - 1) + fib(a - 2)
- Create a ``maths.c`` file with the following content:
- .. code-block:: c
- #include "fib.h"
- #include <stdio.h>
- int main(void)
- {
- NimMain();
- for (int f = 0; f < 10; f++)
- printf("Fib of %d is %d\n", f, fib(f));
- return 0;
- }
- Now you can run the following Unix like commands to first generate C sources
- form the Nim code, then link them into a static binary along your main C
- program::
- $ nim c --noMain --noLinking --header:fib.h fib.nim
- $ gcc -o m -Inimcache -Ipath/to/nim/lib nimcache/*.c maths.c
- The first command runs the Nim compiler with three special options to avoid
- generating a ``main()`` function in the generated files, avoid linking the
- object files into a final binary, and explicitly generate a header file for C
- integration. All the generated files are placed into the ``nimcache``
- directory. That's why the next command compiles the ``maths.c`` source plus
- all the ``.c`` files form ``nimcache``. In addition to this path, you also
- have to tell the C compiler where to find Nim's ``nimbase.h`` header file.
- Instead of depending on the generation of the individual ``.c`` files you can
- also ask the Nim compiler to generate a statically linked library::
- $ nim c --app:staticLib --noMain --header fib.nim
- $ gcc -o m -Inimcache -Ipath/to/nim/lib libfib.nim.a maths.c
- The Nim compiler will handle linking the source files generated in the
- ``nimcache`` directory into the ``libfib.nim.a`` static library, which you can
- then link into your C program. Note that these commands are generic and will
- vary for each system. For instance, on Linux systems you will likely need to
- use ``-ldl`` too to link in required dlopen functionality.
- Nim invocation example from JavaScript
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- Create a ``mhost.html`` file with the following content:
- .. code-block::
- <html><body>
- <script type="text/javascript" src="fib.js"></script>
- <script type="text/javascript">
- alert("Fib for 9 is " + fib(9));
- </script>
- </body></html>
- Create a ``fib.nim`` file with the following content (or reuse the one
- from the previous section):
- .. code-block:: nim
- proc fib(a: cint): cint {.exportc.} =
- if a <= 2:
- result = 1
- else:
- result = fib(a - 1) + fib(a - 2)
- Compile the Nim code to JavaScript with ``nim js -o:fib.js fib.nim`` and
- open ``mhost.html`` in a browser. If the browser supports javascript, you
- should see an alert box displaying the text ``Fib for 9 is 34``. As mentioned
- earlier, JavaScript doesn't require an initialisation call to ``NimMain`` or
- similar function and you can call the exported Nim proc directly.
- Nimcache naming logic
- ---------------------
- The `nimcache`:idx: directory is generated during compilation and will hold
- either temporary or final files depending on your backend target. The default
- name for the directory is ``nimcache`` but you can use the ``--nimcache``
- `compiler switch <nimc.html#command-line-switches>`_ to change it.
- Nimcache and C like targets
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~
- The C like backends will place their temporary ``.c``, ``.cpp`` or ``.m`` files
- in the ``nimcache`` directory. The naming of these files follows the pattern
- ``nimblePackageName_`` + ``nimSource``:
- * Filenames for modules imported from `nimble packages
- <https://github.com/nim-lang/nimble>`_ will end up with
- ``nimblePackageName_module.c``. For example, if you import the
- ``argument_parser`` module from the same name nimble package you
- will end up with a ``argument_parser_argument_parser.c`` file
- under ``nimcache``. The name of the nimble package comes from the
- ``proj.nimble`` file, the actual contents are not read by the
- compiler.
- * Filenames for non nimble packages (like your project) will be
- renamed from ``.nim`` to have the extension of your target backend
- (from now on ``.c`` for these examples), but otherwise nothing
- else will change. This will quickly break if your project consists
- of a main ``proj.nim`` file which includes a ``utils/proj.nim``
- file: both ``proj.nim`` files will generate the same name ``proj.c``
- output in the ``nimcache`` directory overwriting themselves!
- * Filenames for modules found in the standard library will be named
- ``stdlib_module.c``. Unless you are doing something special, you
- will end up with at least ``stdlib_system.c``, since the `system
- module <system.html>`_ is always imported automatically. Same for
- the `hashes module <hashes.html>`_ which will be named
- ``stdlib_hashes.c``. The ``stdlib_`` prefix comes from the *fake*
- ``lib/stdlib.nimble`` file.
- To find the name of a nimble package the compiler searches for a ``*.nimble``
- file in the parent directory hierarchy of whatever module you are compiling.
- Even if you are in a subdirectory of your project, a parent ``*.nimble`` file
- will influence the naming of the nimcache name. This means that on Unix systems
- creating the file ``~/foo.nimble`` will automatically prefix all nimcache files
- not part of another package with the string ``foo_``.
- Nimcache and the Javascript target
- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
- Unless you explicitly use the ``-o:filename.js`` switch as mentioned in the
- previous examples, the compiler will create a ``filename.js`` file in the
- ``nimcache`` directory using the name of your input nim file. There are no
- other temporary files generated, the output is always a single self contained
- ``.js`` file.
- Memory management
- =================
- In the previous sections the ``NimMain()`` function reared its head. Since
- JavaScript already provides automatic memory management, you can freely pass
- objects between the two language without problems. In C and derivate languages
- you need to be careful about what you do and how you share memory. The
- previous examples only dealt with simple scalar values, but passing a Nim
- string to C, or reading back a C string in Nim already requires you to be
- aware of who controls what to avoid crashing.
- Strings and C strings
- ---------------------
- The manual mentions that `Nim strings are implicitly convertible to
- cstrings <manual.html#cstring-type>`_ which makes interaction usually
- painless. Most C functions accepting a Nim string converted to a
- ``cstring`` will likely not need to keep this string around and by the time
- they return the string won't be needed any more. However, for the rare cases
- where a Nim string has to be preserved and made available to the C backend
- as a ``cstring``, you will need to manually prevent the string data from being
- freed with `GC_ref <system.html#GC_ref>`_ and `GC_unref
- <system.html#GC_unref>`_.
- A similar thing happens with C code invoking Nim code which returns a
- ``cstring``. Consider the following proc:
- .. code-block:: nim
- proc gimme(): cstring {.exportc.} =
- result = "Hey there C code! " & $random(100)
- Since Nim's garbage collector is not aware of the C code, once the
- ``gimme`` proc has finished it can reclaim the memory of the ``cstring``.
- However, from a practical standpoint, the C code invoking the ``gimme``
- function directly will be able to use it since Nim's garbage collector has
- not had a chance to run *yet*. This gives you enough time to make a copy for
- the C side of the program, as calling any further Nim procs *might* trigger
- garbage collection making the previously returned string garbage. Or maybe you
- are `yourself triggering the collection <gc.html>`_.
- Custom data types
- -----------------
- Just like strings, custom data types that are to be shared between Nim and
- the backend will need careful consideration of who controls who. If you want
- to hand a Nim reference to C code, you will need to use `GC_ref
- <system.html#GC_ref>`_ to mark the reference as used, so it does not get
- freed. And for the C backend you will need to expose the `GC_unref
- <system.html#GC_unref>`_ proc to clean up this memory when it is not required
- any more.
- Again, if you are wrapping a library which *mallocs* and *frees* data
- structures, you need to expose the appropriate *free* function to Nim so
- you can clean it up. And of course, once cleaned you should avoid accessing it
- from Nim (or C for that matter). Typically C data structures have their own
- ``malloc_structure`` and ``free_structure`` specific functions, so wrapping
- these for the Nim side should be enough.
- Thread coordination
- -------------------
- When the ``NimMain()`` function is called Nim initializes the garbage
- collector to the current thread, which is usually the main thread of your
- application. If your C code later spawns a different thread and calls Nim
- code, the garbage collector will fail to work properly and you will crash.
- As long as you don't use the threadvar emulation Nim uses native thread
- variables, of which you get a fresh version whenever you create a thread. You
- can then attach a GC to this thread via
- .. code-block:: nim
- system.setupForeignThreadGc()
- It is **not** safe to disable the garbage collector and enable it after the
- call from your background thread even if the code you are calling is short
- lived.
- Before the thread exits, you should tear down the thread's GC to prevent memory
- leaks by calling
- .. code-block:: nim
- system.tearDownForeignThreadGc()
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