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ruby--ruby/ext/fiddle/function.c

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#include <fiddle.h>
#include <ruby/thread.h>
#include <stdbool.h>
#ifdef PRIsVALUE
# define RB_OBJ_CLASSNAME(obj) rb_obj_class(obj)
# define RB_OBJ_STRING(obj) (obj)
#else
# define PRIsVALUE "s"
# define RB_OBJ_CLASSNAME(obj) rb_obj_classname(obj)
# define RB_OBJ_STRING(obj) StringValueCStr(obj)
#endif
VALUE cFiddleFunction;
#define MAX_ARGS (SIZE_MAX / (sizeof(void *) + sizeof(fiddle_generic)) - 1)
#define Check_Max_Args(name, len) \
Check_Max_Args_(name, len, "")
#define Check_Max_Args_Long(name, len) \
Check_Max_Args_(name, len, "l")
#define Check_Max_Args_(name, len, fmt) \
do { \
if ((size_t)(len) >= MAX_ARGS) { \
rb_raise(rb_eTypeError, \
"%s is so large " \
"that it can cause integer overflow (%"fmt"d)", \
(name), (len)); \
} \
} while (0)
static void
deallocate(void *p)
{
ffi_cif *cif = p;
if (cif->arg_types) xfree(cif->arg_types);
xfree(cif);
}
static size_t
function_memsize(const void *p)
{
/* const */ffi_cif *ptr = (ffi_cif *)p;
size_t size = 0;
size += sizeof(*ptr);
#if !defined(FFI_NO_RAW_API) || !FFI_NO_RAW_API
size += ffi_raw_size(ptr);
#endif
return size;
}
const rb_data_type_t function_data_type = {
"fiddle/function",
{0, deallocate, function_memsize,},
};
static VALUE
allocate(VALUE klass)
{
ffi_cif * cif;
return TypedData_Make_Struct(klass, ffi_cif, &function_data_type, cif);
}
VALUE
rb_fiddle_new_function(VALUE address, VALUE arg_types, VALUE ret_type)
{
VALUE argv[3];
argv[0] = address;
argv[1] = arg_types;
argv[2] = ret_type;
return rb_class_new_instance(3, argv, cFiddleFunction);
}
static VALUE
normalize_argument_types(const char *name,
VALUE arg_types,
bool *is_variadic)
{
VALUE normalized_arg_types;
int i;
int n_arg_types;
*is_variadic = false;
Check_Type(arg_types, T_ARRAY);
n_arg_types = RARRAY_LENINT(arg_types);
Check_Max_Args(name, n_arg_types);
normalized_arg_types = rb_ary_new_capa(n_arg_types);
for (i = 0; i < n_arg_types; i++) {
VALUE arg_type = RARRAY_AREF(arg_types, i);
int c_arg_type;
arg_type = rb_fiddle_type_ensure(arg_type);
c_arg_type = NUM2INT(arg_type);
if (c_arg_type == TYPE_VARIADIC) {
if (i != n_arg_types - 1) {
rb_raise(rb_eArgError,
"Fiddle::TYPE_VARIADIC must be the last argument type: "
"%"PRIsVALUE,
arg_types);
}
*is_variadic = true;
break;
}
else {
(void)INT2FFI_TYPE(c_arg_type); /* raise */
}
rb_ary_push(normalized_arg_types, INT2FIX(c_arg_type));
}
/* freeze to prevent inconsistency at calling #to_int later */
OBJ_FREEZE(normalized_arg_types);
return normalized_arg_types;
}
static VALUE
initialize(int argc, VALUE argv[], VALUE self)
{
ffi_cif * cif;
VALUE ptr, arg_types, ret_type, abi, kwargs;
VALUE name = Qnil;
VALUE need_gvl = Qfalse;
int c_ret_type;
bool is_variadic = false;
ffi_abi c_ffi_abi;
void *cfunc;
rb_scan_args(argc, argv, "31:", &ptr, &arg_types, &ret_type, &abi, &kwargs);
rb_iv_set(self, "@closure", ptr);
if (!NIL_P(kwargs)) {
enum {
kw_name,
kw_need_gvl,
kw_max_,
};
static ID kw[kw_max_];
VALUE args[kw_max_];
if (!kw[0]) {
kw[kw_name] = rb_intern_const("name");
kw[kw_need_gvl] = rb_intern_const("need_gvl");
}
rb_get_kwargs(kwargs, kw, 0, kw_max_, args);
if (args[kw_name] != Qundef) {
name = args[kw_name];
}
if (args[kw_need_gvl] != Qundef) {
need_gvl = args[kw_need_gvl];
}
}
rb_iv_set(self, "@name", name);
rb_iv_set(self, "@need_gvl", need_gvl);
ptr = rb_Integer(ptr);
cfunc = NUM2PTR(ptr);
PTR2NUM(cfunc);
c_ffi_abi = NIL_P(abi) ? FFI_DEFAULT_ABI : NUM2INT(abi);
abi = INT2FIX(c_ffi_abi);
ret_type = rb_fiddle_type_ensure(ret_type);
c_ret_type = NUM2INT(ret_type);
(void)INT2FFI_TYPE(c_ret_type); /* raise */
ret_type = INT2FIX(c_ret_type);
arg_types = normalize_argument_types("argument types",
arg_types,
&is_variadic);
#ifndef HAVE_FFI_PREP_CIF_VAR
if (is_variadic) {
rb_raise(rb_eNotImpError,
"ffi_prep_cif_var() is required in libffi "
"for variadic arguments");
}
#endif
rb_iv_set(self, "@ptr", ptr);
rb_iv_set(self, "@argument_types", arg_types);
rb_iv_set(self, "@return_type", ret_type);
rb_iv_set(self, "@abi", abi);
rb_iv_set(self, "@is_variadic", is_variadic ? Qtrue : Qfalse);
TypedData_Get_Struct(self, ffi_cif, &function_data_type, cif);
cif->arg_types = NULL;
return self;
}
struct nogvl_ffi_call_args {
ffi_cif *cif;
void (*fn)(void);
void **values;
fiddle_generic retval;
};
static void *
nogvl_ffi_call(void *ptr)
{
struct nogvl_ffi_call_args *args = ptr;
ffi_call(args->cif, args->fn, &args->retval, args->values);
return NULL;
}
static VALUE
function_call(int argc, VALUE argv[], VALUE self)
{
struct nogvl_ffi_call_args args = { 0 };
fiddle_generic *generic_args;
VALUE cfunc;
VALUE abi;
VALUE arg_types;
VALUE cPointer;
VALUE is_variadic;
VALUE need_gvl;
int n_arg_types;
int n_fixed_args = 0;
int n_call_args = 0;
int i;
int i_call;
VALUE converted_args = Qnil;
VALUE alloc_buffer = 0;
cfunc = rb_iv_get(self, "@ptr");
abi = rb_iv_get(self, "@abi");
arg_types = rb_iv_get(self, "@argument_types");
cPointer = rb_const_get(mFiddle, rb_intern("Pointer"));
is_variadic = rb_iv_get(self, "@is_variadic");
need_gvl = rb_iv_get(self, "@need_gvl");
n_arg_types = RARRAY_LENINT(arg_types);
n_fixed_args = n_arg_types;
if (RTEST(is_variadic)) {
if (argc < n_arg_types) {
rb_error_arity(argc, n_arg_types, UNLIMITED_ARGUMENTS);
}
if (((argc - n_arg_types) % 2) != 0) {
rb_raise(rb_eArgError,
"variadic arguments must be type and value pairs: "
"%"PRIsVALUE,
rb_ary_new_from_values(argc, argv));
}
n_call_args = n_arg_types + ((argc - n_arg_types) / 2);
}
else {
if (argc != n_arg_types) {
rb_error_arity(argc, n_arg_types, n_arg_types);
}
n_call_args = n_arg_types;
}
Check_Max_Args("the number of arguments", n_call_args);
TypedData_Get_Struct(self, ffi_cif, &function_data_type, args.cif);
if (is_variadic && args.cif->arg_types) {
xfree(args.cif->arg_types);
args.cif->arg_types = NULL;
}
if (!args.cif->arg_types) {
VALUE fixed_arg_types = arg_types;
VALUE return_type;
int c_return_type;
ffi_type *ffi_return_type;
ffi_type **ffi_arg_types;
ffi_status result;
arg_types = rb_ary_dup(fixed_arg_types);
for (i = n_fixed_args; i < argc; i += 2) {
VALUE arg_type = argv[i];
int c_arg_type;
arg_type = rb_fiddle_type_ensure(arg_type);
c_arg_type = NUM2INT(arg_type);
(void)INT2FFI_TYPE(c_arg_type); /* raise */
rb_ary_push(arg_types, INT2FIX(c_arg_type));
}
return_type = rb_iv_get(self, "@return_type");
c_return_type = FIX2INT(return_type);
ffi_return_type = INT2FFI_TYPE(c_return_type);
ffi_arg_types = xcalloc(n_call_args + 1, sizeof(ffi_type *));
for (i_call = 0; i_call < n_call_args; i_call++) {
VALUE arg_type;
int c_arg_type;
arg_type = RARRAY_AREF(arg_types, i_call);
c_arg_type = FIX2INT(arg_type);
ffi_arg_types[i_call] = INT2FFI_TYPE(c_arg_type);
}
ffi_arg_types[i_call] = NULL;
if (is_variadic) {
#ifdef HAVE_FFI_PREP_CIF_VAR
result = ffi_prep_cif_var(args.cif,
FIX2INT(abi),
n_fixed_args,
n_call_args,
ffi_return_type,
ffi_arg_types);
#else
/* This code is never used because ffi_prep_cif_var()
* availability check is done in #initialize. */
result = FFI_BAD_TYPEDEF;
#endif
}
else {
result = ffi_prep_cif(args.cif,
FIX2INT(abi),
n_call_args,
ffi_return_type,
ffi_arg_types);
}
if (result != FFI_OK) {
xfree(ffi_arg_types);
args.cif->arg_types = NULL;
rb_raise(rb_eRuntimeError, "error creating CIF %d", result);
}
}
generic_args = ALLOCV(alloc_buffer,
sizeof(fiddle_generic) * n_call_args +
sizeof(void *) * (n_call_args + 1));
args.values = (void **)((char *)generic_args +
sizeof(fiddle_generic) * n_call_args);
for (i = 0, i_call = 0;
i < argc && i_call < n_call_args;
i++, i_call++) {
VALUE arg_type;
int c_arg_type;
VALUE original_src;
VALUE src;
arg_type = RARRAY_AREF(arg_types, i_call);
c_arg_type = FIX2INT(arg_type);
if (i >= n_fixed_args) {
i++;
}
src = argv[i];
if (c_arg_type == TYPE_VOIDP) {
if (NIL_P(src)) {
src = INT2FIX(0);
}
else if (cPointer != CLASS_OF(src)) {
src = rb_funcall(cPointer, rb_intern("[]"), 1, src);
if (NIL_P(converted_args)) {
converted_args = rb_ary_new();
}
rb_ary_push(converted_args, src);
}
src = rb_Integer(src);
}
original_src = src;
VALUE2GENERIC(c_arg_type, src, &generic_args[i_call]);
if (src != original_src) {
if (NIL_P(converted_args)) {
converted_args = rb_ary_new();
}
rb_ary_push(converted_args, src);
}
args.values[i_call] = (void *)&generic_args[i_call];
}
args.values[i_call] = NULL;
args.fn = (void(*)(void))NUM2PTR(cfunc);
if (RTEST(need_gvl)) {
ffi_call(args.cif, args.fn, &(args.retval), args.values);
}
else {
(void)rb_thread_call_without_gvl(nogvl_ffi_call, &args, 0, 0);
}
{
int errno_keep = errno;
#if defined(_WIN32)
DWORD error = WSAGetLastError();
int socket_error = WSAGetLastError();
rb_funcall(mFiddle, rb_intern("win32_last_error="), 1,
ULONG2NUM(error));
rb_funcall(mFiddle, rb_intern("win32_last_socket_error="), 1,
INT2NUM(socket_error));
#endif
rb_funcall(mFiddle, rb_intern("last_error="), 1, INT2NUM(errno_keep));
}
ALLOCV_END(alloc_buffer);
return GENERIC2VALUE(rb_iv_get(self, "@return_type"), args.retval);
}
void
Init_fiddle_function(void)
{
/*
* Document-class: Fiddle::Function
*
* == Description
*
* A representation of a C function
*
* == Examples
*
* === 'strcpy'
*
* @libc = Fiddle.dlopen "/lib/libc.so.6"
* #=> #<Fiddle::Handle:0x00000001d7a8d8>
* f = Fiddle::Function.new(
* @libc['strcpy'],
* [Fiddle::TYPE_VOIDP, Fiddle::TYPE_VOIDP],
* Fiddle::TYPE_VOIDP)
* #=> #<Fiddle::Function:0x00000001d8ee00>
* buff = "000"
* #=> "000"
* str = f.call(buff, "123")
* #=> #<Fiddle::Pointer:0x00000001d0c380 ptr=0x000000018a21b8 size=0 free=0x00000000000000>
* str.to_s
* => "123"
*
* === ABI check
*
* @libc = Fiddle.dlopen "/lib/libc.so.6"
* #=> #<Fiddle::Handle:0x00000001d7a8d8>
* f = Fiddle::Function.new(@libc['strcpy'], [TYPE_VOIDP, TYPE_VOIDP], TYPE_VOIDP)
* #=> #<Fiddle::Function:0x00000001d8ee00>
* f.abi == Fiddle::Function::DEFAULT
* #=> true
*/
cFiddleFunction = rb_define_class_under(mFiddle, "Function", rb_cObject);
/*
* Document-const: DEFAULT
*
* Default ABI
*
*/
rb_define_const(cFiddleFunction, "DEFAULT", INT2NUM(FFI_DEFAULT_ABI));
#ifdef HAVE_CONST_FFI_STDCALL
/*
* Document-const: STDCALL
*
* FFI implementation of WIN32 stdcall convention
*
*/
rb_define_const(cFiddleFunction, "STDCALL", INT2NUM(FFI_STDCALL));
#endif
rb_define_alloc_func(cFiddleFunction, allocate);
/*
* Document-method: call
*
* Calls the constructed Function, with +args+.
* Caller must ensure the underlying function is called in a
* thread-safe manner if running in a multi-threaded process.
*
2020-12-22 00:56:47 -05:00
* Note that it is not thread-safe to use this method to
* directly or indirectly call many Ruby C-extension APIs unless
* you don't pass +need_gvl: true+ to Fiddle::Function#new.
*
* For an example see Fiddle::Function
*
*/
rb_define_method(cFiddleFunction, "call", function_call, -1);
/*
* Document-method: new
* call-seq: new(ptr,
* args,
* ret_type,
* abi = DEFAULT,
* name: nil,
* need_gvl: false)
*
* Constructs a Function object.
* * +ptr+ is a referenced function, of a Fiddle::Handle
* * +args+ is an Array of arguments, passed to the +ptr+ function
* * +ret_type+ is the return type of the function
* * +abi+ is the ABI of the function
* * +name+ is the name of the function
* * +need_gvl+ is whether GVL is needed to call the function
*
*/
rb_define_method(cFiddleFunction, "initialize", initialize, -1);
}
/* vim: set noet sws=4 sw=4: */