1 Overview
1.1 “Scheme” versus “Racket”
The old name for Racket was “PLT Scheme,” and the core compiler and run-time system used to be called “MzScheme.” The old names are entrenched in Racket internals, to the point that most C bindings defined in this manual start with scheme_. They all should be renamed to start racket_.
1.2 Building Racket from Source
The normal Racket distribution includes ".rkt" sources for collection-based libraries. After modifying library files, run raco setup (see raco setup: Installation Management) to rebuild installed libraries.
The normal Racket distribution does not include the C sources for Racket’s run-time system. To build Racket from scratch, download a source distribution, or get the latest from the git repository at https://github.com/plt/racket. Detailed build instructions are in the "README" file in the top-level "src" directory.
1.3 CGC versus 3m
Before mixing any C code with Racket, first decide whether to use the 3m variant of Racket, the CGC variant of Racket, or both:
3m : the main variant of Racket, which uses precise garbage collection instead of conservative garbage collection, and it may move objects in memory during a collection.
CGC : the original variant of Racket, where memory management depends on a conservative garbage collector. The conservative garbage collector can automatically find references to managed values from C local variables and (on some platforms) static variables.
At the C level, working with CGC can be much easier than working with 3m, but overall system performance is typically better with 3m.
1.4 Writing Racket Extensions
The process of creating an extension for 3m or CGC is essentially the same, but the process for 3m is most easily understood as a variant of the process for CGC.
1.4.1 CGC Extensions
To write a C/C++-based extension for Racket CGC, follow these steps:
For each C/C++ file that uses Racket library functions, #include the file "escheme.h".
This file is distributed with the Racket software in an "include" directory, but if raco ctool is used to compile, this path is found automatically.
Define the C function scheme_initialize, which takes a Scheme_Env* namespace (see Namespaces and Modules) and returns a Scheme_Object* Racket value.
This initialization function can install new global primitive procedures or other values into the namespace, or it can simply return a Racket value. The initialization function is called when the extension is loaded with load-extension the first time in a given place; the return value from scheme_initialize is used as the return value for load-extension. The namespace provided to scheme_initialize is the current namespace when load-extension is called.
Define the C function scheme_reload, which has the same arguments and return type as scheme_initialize.
This function is called if load-extension is called a second time (or more times) for an extension in a given place. Like scheme_initialize, the return value from this function is the return value for load-extension.
Define the C function scheme_module_name, which takes no arguments and returns a Scheme_Object* value, either a symbol or scheme_false.
The function should return a symbol when the effect of calling scheme_initialize and scheme_reload is only to declare a module with the returned name. This function is called when the extension is loaded to satisfy a require declaration.
The scheme_module_name function may be called before scheme_initialize and scheme_reload, after those functions, or both before and after, depending on how the extension is loaded and re-loaded.
Compile the extension C/C++ files to create platform-specific object files.
The raco ctool compiler, which is distributed with Racket, compiles plain C files when the --cc flag is specified. More precisely, raco ctool does not compile the files itself, but it locates a C compiler on the system and launches it with the appropriate compilation flags. If the platform is a relatively standard Unix system, a Windows system with either Microsoft’s C compiler or gcc in the path, or a Mac OS X system with Apple’s developer tools installed, then using raco ctool is typically easier than working with the C compiler directly. Use the --cgc flag to indicate that the build is for use with Racket CGC.
Link the extension C/C++ files with "mzdyn.o" (Unix, Mac OS X) or "mzdyn.obj" (Windows) to create a shared object. The resulting shared object should use the extension ".so" (Unix), ".dll" (Windows), or ".dylib" (Mac OS X).
The "mzdyn" object file is distributed in the installation’s "lib" directory. For Windows, the object file is in a compiler-specific sub-directory of "racket\lib".
The raco ctool compiler links object files into an extension when the --ld flag is specified, automatically locating "mzdyn". Again, use the --cgc flag with raco ctool.
Load the shared object within Racket using (load-extension path), where path is the name of the extension file generated in the previous step.
Alternately, if the extension defines a module (i.e., scheme_module_name returns a symbol), then place the shared object in a special directory with a special name, so that it is detected by the module loader when require is used. The special directory is a platform-specific path that can be obtained by evaluating (build-path "compiled" "native" (system-library-subpath)); see load/use-compiled for more information. For example, if the shared object’s name is "example_rkt.dll", then (require "example.rkt") will be redirected to "example_rkt.dll" if the latter is placed in the sub-directory (build-path "compiled" "native" (system-library-subpath)) and if "example.rkt" does not exist or has an earlier timestamp.
Note that (load-extension path) within a module does not introduce the extension’s definitions into the module, because load-extension is a run-time operation. To introduce an extension’s bindings into a module, make sure that the extension defines a module, put the extension in the platform-specific location as described above, and use require.
IMPORTANT: With Racket CGC, Racket values are garbage collected using a conservative garbage collector, so pointers to Racket objects can be kept in registers, stack variables, or structures allocated with scheme_malloc. However, static variables that contain pointers to collectable memory must be registered using scheme_register_extension_global (see Memory Allocation); even then, such static variables must be thread-local (in the OS-thread sense) to work with multiple places (see Racket and Places).
As an example, the following C code defines an extension that returns "hello world" when it is loaded:
#include "escheme.h" |
Scheme_Object *scheme_initialize(Scheme_Env *env) { |
return scheme_make_utf8_string("hello world"); |
} |
Scheme_Object *scheme_reload(Scheme_Env *env) { |
return scheme_initialize(env); /* Nothing special for reload */ |
} |
Scheme_Object *scheme_module_name() { |
return scheme_false; |
} |
Assuming that this code is in the file "hw.c", the extension is compiled on Unix with the following two commands:
(Note that the --cgc, --cc, and --ld flags are each prefixed by two dashes, not one.)
The "collects/mzscheme/examples" directory in the Racket distribution contains additional examples.
1.4.2 3m Extensions
To build an extension to work with Racket 3m, the CGC instructions must be extended as follows:
Adjust code to cooperate with the garbage collector as described in Cooperating with 3m. Using raco ctool with the --xform might convert your code to implement part of the conversion, as described in Local Pointers and raco ctool --xform.
In either your source in the in compiler command line, #define MZ_PRECISE_GC before including "escheme.h". When using raco ctool with the --cc and --3m flags, MZ_PRECISE_GC is automatically defined.
Link with "mzdyn3m.o" (Unix, Mac OS X) or "mzdyn3m.obj" (Windows) to create a shared object. When using raco ctool, use the --ld and --3m flags to link to these libraries.
For a relatively simple extension "hw.c", the extension is compiled on Unix for 3m with the following three commands:
Some examples in "collects/mzscheme/examples" work with Racket 3m in this way. A few examples are manually instrumented, in which case the --xform step should be skipped.
1.4.3 Declaring a Module in an Extension
To create an extension that behaves as a module, return a symbol from scheme_module_name, and have scheme_initialize and scheme_rename declare a module using scheme_primitive_module.
For example, the following extension implements a module named hello that exports a binding greeting:
#include "escheme.h" |
|
Scheme_Object *scheme_initialize(Scheme_Env *env) { |
Scheme_Env *mod_env; |
mod_env = scheme_primitive_module(scheme_intern_symbol("hi"), |
env); |
scheme_add_global("greeting", |
scheme_make_utf8_string("hello"), |
mod_env); |
scheme_finish_primitive_module(mod_env); |
return scheme_void; |
} |
|
Scheme_Object *scheme_reload(Scheme_Env *env) { |
return scheme_initialize(env); /* Nothing special for reload */ |
} |
|
Scheme_Object *scheme_module_name() { |
return scheme_intern_symbol("hi"); |
} |
This extension could be compiled for 3m on i386 Linux, for example, using the following sequence of mzc commands:
The resulting module can be loaded with
(require "hi.rkt")
1.5 Embedding Racket into a Program
Like creating extensions, the embedding process for Racket CGC or Racket 3m is essentially the same, but the process for Racket 3m is most easily understood as a variant of the process for Racket CGC.
1.5.1 CGC Embedding
To embed Racket CGC in a program, follow these steps:
Locate or build the Racket CGC libraries. Since the standard distribution provides 3m libraries, only, you will most likely have to build from source.
On Unix, the libraries are "libracket.a" and "libmzgc.a" (or "libracket.so" and "libmzgc.so" for a dynamic-library build, with "libracket.la" and "libmzgc.la" files for use with libtool). Building from source and installing places the libraries into the installation’s "lib" directory. Be sure to build the CGC variant, since the default is 3m.
On Windows, stub libraries for use with Microsoft tools are "libracketx.lib" and "libmzgcx.lib" (where x represents the version number) are in a compiler-specific directory in "racket\lib". These libraries identify the bindings that are provided by "libracketx.dll" and "libmzgcx.dll" —
which are typically installed in "racket\lib". When linking with Cygwin, link to "libracketx.dll" and "libmzgcx.dll" directly. At run time, either "libracketx.dll" and "libmzgcx.dll" must be moved to a location in the standard DLL search path, or your embedding application must “delayload” link the DLLs and explicitly load them before use. ("Racket.exe" and "GRacket.exe" use the latter strategy.) On Mac OS X, dynamic libraries are provided by the "Racket" framework, which is typically installed in "lib" sub-directory of the installation. Supply -framework Racket to gcc when linking, along with -F and a path to the "lib" directory. Beware that CGC and 3m libraries are installed as different versions within a single framework, and installation marks one version or the other as the default (by setting symbolic links); install only CGC to simplify accessing the CGC version within the framework. At run time, either "Racket.framework" must be moved to a location in the standard framework search path, or your embedding executable must provide a specific path to the framework (possibly an executable-relative path using the Mach-O @executable_path prefix).
For each C/C++ file that uses Racket library functions, #include the file "scheme.h".
The C preprocessor symbol SCHEME_DIRECT_EMBEDDED is defined as 1 when "scheme.h" is #included, or as 0 when "escheme.h" is #included.
The "scheme.h" file is distributed with the Racket software in the installation’s "include" directory. Building and installing from source also places this file in the installation’s "include" directory.
Start your main program through the scheme_main_setup (or scheme_main_stack_setup) trampoline, and put all uses of Racket functions inside the function passed to scheme_main_setup. The scheme_main_setup function registers the current C stack location with the memory manager. It also creates the initial namespace Scheme_Env* by calling scheme_basic_env and passing the result to the function provided to scheme_main_setup. (The scheme_main_stack_setup trampoline registers the C stack with the memory manager without creating a namespace.)
On 32-bit Windows, when support for parallelism is enabled in the Racket build (as is the default), then before calling scheme_main_setup, your embedding application must first call scheme_register_tls_space:
scheme_register_tls_space(&tls_space, 0);
where tls_space is declared as a thread-local pointer variable in the main executable (i.e., not in a dynamically linked DLL):
static __declspec(thread) void *tls_space;
Configure the namespace by adding module declarations. The initial namespace contains declarations only for a few primitive modules, such as '#%kernel, and no bindings are imported into the top-level environment.
To embed a module like racket/base (along with all its dependencies), use raco ctool --c-mods, which generates a C file that contains modules in bytecode form as encapsulated in a static array. The generated C file defines a declare_modules function that takes a Scheme_Env*, installs the modules into the environment, and adjusts the module name resolver to access the embedded declarations.
Alternately, use scheme_set_collects_path and scheme_init_collection_paths to configure and install a path for finding modules at run time.
Access Racket through scheme_dynamic_require, scheme_load, scheme_eval, and/or other functions described in this manual.
If the embedding program configures built-in parameters in a way that should be considered part of the default configuration, then call scheme_seal_parameters afterward. The snapshot of parameter values taken by scheme_seal_parameters is used for certain privileged operations, such as installing a PLaneT package.
Compile the program and link it with the Racket libraries.
With Racket CGC, Racket values are garbage collected using a conservative garbage collector, so pointers to Racket objects can be kept in registers, stack variables, or structures allocated with scheme_malloc. In an embedding application on some platforms, static variables are also automatically registered as roots for garbage collection (but see notes below specific to Mac OS X and Windows).
For example, the following is a simple embedding program which evaluates all expressions provided on the command line and displays the results, then runs a read-eval-print loop. Run
raco ctool --c-mods base.c ++lib racket/base
to generate "base.c", which encapsulates racket/base and all of its transitive imports (so that they need not be found separately a run time).
#include "scheme.h" |
|
#include "base.c" |
|
static int run(Scheme_Env *e, int argc, char *argv[]) |
{ |
Scheme_Object *curout; |
int i; |
mz_jmp_buf * volatile save, fresh; |
|
/* Declare embedded modules in "base.c": */ |
declare_modules(e); |
|
scheme_namespace_require(scheme_intern_symbol("racket/base")); |
|
curout = scheme_get_param(scheme_current_config(), |
MZCONFIG_OUTPUT_PORT); |
|
for (i = 1; i < argc; i++) { |
save = scheme_current_thread->error_buf; |
scheme_current_thread->error_buf = &fresh; |
if (scheme_setjmp(scheme_error_buf)) { |
scheme_current_thread->error_buf = save; |
return -1; /* There was an error */ |
} else { |
Scheme_Object *v, *a[2]; |
v = scheme_eval_string(argv[i], e); |
scheme_display(v, curout); |
scheme_display(scheme_make_char('\n'), curout); |
/* read-eval-print loop, uses initial Scheme_Env: */ |
a[0] = scheme_intern_symbol("racket/base"); |
a[1] = scheme_intern_symbol("read-eval-print-loop"); |
scheme_apply(scheme_dynamic_require(2, a), 0, NULL); |
scheme_current_thread->error_buf = save; |
} |
} |
return 0; |
} |
|
int main(int argc, char *argv[]) |
{ |
return scheme_main_setup(1, run, argc, argv); |
} |
On Mac OS X, or on Windows when Racket is compiled to a DLL using Cygwin, the garbage collector cannot find static variables automatically. In that case, scheme_main_setup must be called with a non-zero first argument.
On Windows (for any other build mode), the garbage collector finds static variables in an embedding program by examining all memory pages. This strategy fails if a program contains multiple Windows threads; a page may get unmapped by a thread while the collector is examining the page, causing the collector to crash. To avoid this problem, call scheme_main_setup with a non-zero first argument.
When an embedding application calls scheme_main_setup with a non-zero first argument, it must register each of its static variables with MZ_REGISTER_STATIC if the variable can contain a GCable pointer. For example, if curout above is made static, then MZ_REGISTER_STATIC(curout) should be inserted before the call to scheme_get_param.
When building an embedded Racket CGC to use SenoraGC (SGC) instead of the default collector, scheme_main_setup must be called with a non-zero first argument. See Memory Allocation for more information.
1.5.2 3m Embedding
Racket 3m can be embedded mostly the same as Racket, as long as the embedding program cooperates with the precise garbage collector as described in Cooperating with 3m.
In either your source in the in compiler command line, #define MZ_PRECISE_GC before including "scheme.h". When using raco ctool with the --cc and --3m flags, MZ_PRECISE_GC is automatically defined.
In addition, some library details are different:
On Unix, the library is just "libracket3m.a" (or "libracket3m.so" for a dynamic-library build, with "libracket3m.la" for use with libtool). There is no separate library for 3m analogous to CGC’s "libmzgc.a".
On Windows, the stub library for use with Microsoft tools is "libracket3mx.lib" (where x represents the version number). This library identifies the bindings that are provided by "libracket3mx.dll". There is no separate library for 3m analogous to CGC’s "libmzgcx.lib".
On Mac OS X, 3m dynamic libraries are provided by the "Racket" framework, just as for CGC, but as a version suffixed with "_3m".
For Racket 3m, an embedding application must call scheme_main_setup with a non-zero first argument.
The simple embedding program from the previous section can be processed by raco ctool --xform, then compiled and linked with Racket 3m. Alternately, the source code can be extended to work with either CGC or 3m depending on whether MZ_PRECISE_GC is defined on the compiler’s command line:
#include "scheme.h" |
|
#include "base.c" |
|
static int run(Scheme_Env *e, int argc, char *argv[]) |
{ |
Scheme_Object *curout = NULL, *v = NULL, *a[2] = {NULL, NULL}; |
Scheme_Config *config = NULL; |
int i; |
mz_jmp_buf * volatile save = NULL, fresh; |
|
MZ_GC_DECL_REG(8); |
MZ_GC_VAR_IN_REG(0, e); |
MZ_GC_VAR_IN_REG(1, curout); |
MZ_GC_VAR_IN_REG(2, save); |
MZ_GC_VAR_IN_REG(3, config); |
MZ_GC_VAR_IN_REG(4, v); |
MZ_GC_ARRAY_VAR_IN_REG(5, a, 2); |
|
MZ_GC_REG(); |
|
declare_modules(e); |
|
v = scheme_intern_symbol("racket/base"); |
scheme_namespace_require(v); |
|
config = scheme_current_config(); |
curout = scheme_get_param(config, MZCONFIG_OUTPUT_PORT); |
|
for (i = 1; i < argc; i++) { |
save = scheme_current_thread->error_buf; |
scheme_current_thread->error_buf = &fresh; |
if (scheme_setjmp(scheme_error_buf)) { |
scheme_current_thread->error_buf = save; |
return -1; /* There was an error */ |
} else { |
v = scheme_eval_string(argv[i], e); |
scheme_display(v, curout); |
v = scheme_make_char('\n'); |
scheme_display(v, curout); |
/* read-eval-print loop, uses initial Scheme_Env: */ |
a[0] = scheme_intern_symbol("racket/base"); |
a[1] = scheme_intern_symbol("read-eval-print-loop"); |
v = scheme_dynamic_require(2, a); |
scheme_apply(v, 0, NULL); |
scheme_current_thread->error_buf = save; |
} |
} |
|
MZ_GC_UNREG(); |
|
return 0; |
} |
|
int main(int argc, char *argv[]) |
{ |
return scheme_main_setup(1, run, argc, argv); |
} |
Strictly speaking, the config and v variables above need not be registered with the garbage collector, since their values are not needed across function calls that allocate. The code is much easier to maintain, however, when all local variables are registered and when all temporary values are put into variables.
1.6 Racket and Places
Each Racket place corresponds to a separate OS-implemented thread. Each place has its own memory manager. Pointers to GC-managed memory cannot be communicated from one place to another, because such pointers in one place are invisible to the memory manager of another place.
When place support is enabled, static variables in an extension or an embedding generally cannot hold pointers to GC-managed memory, since the static variable may be used from multiple places. For some OSes, a static variable can be made thread-local, in which case it has a different address in each OS thread, and each different address can be registered with the GC for a given place.
The OS thread that originally calls scheme_basic_env is the OS thread of the original place. When scheme_basic_env is called a second time to reset the interpreter, it can be called in an OS thread that is different from the original call to scheme_basic_env. Thereafter, the new thread is the OS thread for the original place.
1.7 Racket and Threads
Racket implements threads for Racket programs without aid from the operating system, so that Racket threads are cooperative from the perspective of C code. On Unix, stand-alone Racket uses a single OS-implemented thread. On Windows and Mac OS X, stand-alone Racket uses a few private OS-implemented threads for background tasks, but these OS-implemented threads are never exposed by the Racket API.
In an embedding application, Racket can co-exist with additional OS-implemented threads, but the additional OS threads must not call any scheme_ function. Only the OS thread representing a particular place can call scheme_ functions. (This restriction is stronger than saying all calls for a given place must be serialized across threads. Racket relies on properties of specific threads to avoid stack overflow and garbage collection.) For the original place, only the OS thread used to call scheme_basic_env can call scheme_ functions. For any other place, only the OS thread that is created by Racket for the place can be used to call scheme_ functions.
See Threads for more information about threads, including the possible effects of Racket’s thread implementation on extension and embedding C code.
1.8 Racket, Unicode, Characters, and Strings
A character in Racket is a Unicode code point. In C, a character
value has type mzchar, which is an alias for unsigned —
Only a few Racket functions use mzchar*. Instead, most functions accept char* strings. When such byte strings are to be used as a character strings, they are interpreted as UTF-8 encodings. A plain ASCII string is always acceptable in such cases, since the UTF-8 encoding of an ASCII string is itself.
See also Strings and String Encodings.
1.9 Integers
Racket expects to be compiled in a mode where short is a 16-bit integer, int is a 32-bit integer, and intptr_t has the same number of bits as void*. The long type can match either int or intptr_t, depending on the platform. The mzlonglong type has 64 bits for compilers that support a 64-bit integer type, otherwise it is the same as intptr_t; thus, mzlonglong tends to match long long. The umzlonglong type is the unsigned version of mzlonglong.