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Interacting with code
If you are looking for how compiled code interacts with the browser environment, see Emscripten Browser Environment.
It's easy to call compiled code from normal JavaScript. For example, run this command in the Emscripten home directory:
./emcc tests/hello_function.cpp -o function.html
Open the page in a web browser. Nothing will happen because you compiled a function, and there is no main
so nothing will be run by default. But, open a JavaScript environment (Control-Shift-K on Firefox, Control-Shift-J on Chrome), then type (as three separate commands, pressing Enter after each one):
int_sqrt = Module.cwrap('int_sqrt', 'number', ['number'])
int_sqrt(12)
int_sqrt(28)
You should get the results 3, 5
, which are the correct output: The compiled function does a square root operation, but acts on integers. Open tests/hello_function.cpp
to see the source code that you just called here.
cwrap
which was used in this example will wrap a compiled C function, returning a JavaScript function you can call normally. cwrap
gets as its first parameter the name of the function to be wrapped, then the return type of the function, then an array of parameter types (the array can be omitted if there are no parameters). The types are native JavaScript types, "number" (for a C integer, float, or general pointer) or "string" (for a C char*
that represents a string).
There is also ccall
, which is like cwrap
but receives another parameter with the parameters to pass to the function, and calls the function. cwrap
is useful to wrap a function once and call it several times, while ccall
is useful for a single call to a function.
Some things to keep in mind with ccall
and cwrap
:
- In the example above, we compiled a C function. That's easier than C++ because C++ functions are name-mangled.
- By default Emscripten does dead code elimination to minimize code size. See the FAQ entry on "Functions in my C/C++ source code vanish when I compile to JavaScript..?"
- In
-O2
and above, closure compiler is run, which minifies function names - which means you won't be able to find your compiled functions. To prevent that, run emcc with-s EXPORTED_FUNCTIONS="['_main','_other_function']"
. Exported functions will retain their names even through closure compiler. Note that you need_
at the beginning of the functions, and note also that you need to useModule.ccall
and notccall
by itself, since closure will minify the function name, leaving only the Module object where we export names.
You can access memory using getValue(ptr, type)
and setValue(ptr, value, type)
. The first argument is a pointer, a number representing a memory address. type
must be an LLVM IR type, one of i8,i16,i32,i64,float,double
or a pointer type like i8*
(or just *
). Note that the types here are not as in ccall
and cwrap
- this is a lower-level operation, and we do need to care what specific integer etc. type is being used.
You can also access memory 'directly' by manipulating the arrays that represent memory. This is not recommended unless you are sure you know what you are doing, and need the additional speed over getValue/setValue
. A case where you might need this is if you want to import a large amount of data from JS to be processed by compiled code, then you might do something like this:
var buf = Module._malloc(SIZE);
Module.HEAPU8.set(myTypedArray, buf);
Module.ccall('my_function', 'number', ['number'], [buf]);
Module._free(buf);
That allocates a buffer, copies in some data, then calls a C function to process the data, and finally frees the buffer.
The most direct way is to just use emscripten_run_script
, which basically runs some JS code from C/C++ using eval. So emscripten_run_script("alert('hi')");
will show an alert with 'hi'. This is not very fast though.
More generally, our entire libc, SDL etc. implementations are exactly JS code that is called from C/C++ using a C API. You can add your own libraries as well. For example, if you have some C code like this
extern void my_js();
int main() {
my_js();
return 1;
}
then you can implement my_js
in JS by simply adding
my_js: function() {
alert('hi');
},
to library.js. How this works is that when there is an external symbol, the compiler looks in the JS libraries and pulls in the relevant symbols. See the library*.js files for more details and examples.
You can use the emcc option --js-library
to add a file with such code, instead of placing it inside library.js. This lets you be more modular. See test_js_libraries
in tests/runner.py
for a complete working example, including the syntax you should use inside the JS library file.
You can directly interact in various other ways with the compiled code:
- Functions in the original source become JS functions, so you can call them directly if you do type translations yourself - this will be faster than using
ccall
orcwrap
, but a little more complex. Note that you need to prefix function calls with '_' (all compiled functions have that added).- The types of the parameters you pass to functions need to make sense. Integers and floating point values can be passed as is. Aside from those, there are pointers, which are simply integers in the generated code.
- Strings in JavaScript must be converted to pointers for compiled code, the relevant functions are
Pointer_stringify
which given a pointer returns a JavaScript string, and the other direction can be accomplished byallocate(intArrayFromString(someString), 'i8', ALLOC_STACK)
which will convert a JavaScript stringsomeString
to a pointer. Note that conversion to a pointer allocates memory (that's the call toallocate
there).
- There are various other convenience functions, see preamble.js (that file will be included with the generated code).
- The bindings generator can generate convenient JS classes from C++ headers. See the bindings test in the test runner,
test_scriptaclass_2
, for a concrete example of the process (test_scriptaclass
has a more detailed testcase). Also see the ammo.js and box2d.js projects (the main consumers of that tool). Note however that the bindings generator is considered experimental, and has various inherent limitations that stem from objects in C++ not being the same as in JS: In general, it is recommended to interact with your code through a C API and ccall/cwrap. - For filesystem-related manners, see the Filesystem Guide.
You can affect how code runs by creating an object called Module
before the compiled script. Certain properties on Module
can then have various effects:
-
arguments
: The commandline arguments (if the compiled code checksargc
,argc
, it will be seeingarguments
) -
print
: Called when something is printed to standard output. -
preInit
: A function (or array of functions) to call before global initializers run, but after basic initialization of the JS runtime (so you can doFS.*
stuff, but no C++ initializers were called yet). -
preRun
: A function (or array of functions) to call right before callingrun
, but after defining and setting up the environment, including global initializers. This is useful, for example, to set up directories and files using the FileSystem API (since that needs the FileSystem API to be defined, but also needs to be done before the program starts to run; if you need to affect global initializers, though, you should use preInit). -
noInitialRun
: If set to true,run
will not be called (so memory will not be initialized and the compiled code'smain
is not executed), and you should call it yourself later. -
noExitRuntime
: If set to true, the runtime is not shut down afterrun
is called. Shutting down the runtime calls shutdown callbacks, for exampleatexit
calls. If you want to be able to continue to use the code afterrun
finishes, it is safer to set this.
For example,
var Module = {
'print': function(text) { alert(text) }
};
This will cause all printouts from the program to be calls to alert
.
Important: If you run closure compiler on your code (which is done by default in -O2
and above), you will need quotation marks around the properties of Module
as in the example above (and you need to run closure on the compiled code together with the declaration of Module
).
When generating just JavaScript, no Module object is created. So you can use emcc's --pre-js
to add some JS code that defines the Module object with the stuff you need.
When generating HTML, a Module object is created for you and filled with some defaults for printing, etc. (compile a little hello world example to see, or view src/shell.html
). The simplest thing is to use --pre-js
to add some JS code that adds properties to that existing Module object.