void dcArgStructUnroll(DCCallVM* vm, DCstruct* s, DCpointer value)
{
DCsize i;
/*printf("UNROLLING STRUCT !\n");@@@*/
assert(s && value);
for (i = 0; i < s->fieldCount; i++) {
DCfield *f = s->pFields + i;
DCpointer p = (char*)value + f->offset;
switch(f->type) {
case DC_SIGCHAR_STRUCT:
dcArgStruct(vm, f->pSubStruct, p);
break;
case DC_SIGCHAR_BOOL:
dcArgBool (vm, *(DCbool*)p);
break;
case DC_SIGCHAR_CHAR:
case DC_SIGCHAR_UCHAR:
dcArgChar (vm, *(DCchar*)p);
break;
case DC_SIGCHAR_SHORT:
case DC_SIGCHAR_USHORT:
dcArgShort (vm, *(DCshort*)p);
break;
case DC_SIGCHAR_INT:
case DC_SIGCHAR_UINT:
dcArgInt (vm, *(DCint*)p);
break;
case DC_SIGCHAR_LONG:
case DC_SIGCHAR_ULONG:
dcArgLong (vm, *(DCulong*)p);
break;
case DC_SIGCHAR_LONGLONG:
case DC_SIGCHAR_ULONGLONG:
dcArgLongLong (vm, *(DCulonglong*)p);
break;
case DC_SIGCHAR_FLOAT:
dcArgFloat (vm, *(DCfloat*)p);
break;
case DC_SIGCHAR_DOUBLE:
dcArgDouble (vm, *(DCdouble*)p);
break;
case DC_SIGCHAR_POINTER:
case DC_SIGCHAR_STRING:
dcArgPointer (vm, *(DCpointer**)p);
break;
default:
assert(0);
}
}
}
// Shareable implementation for argument binding used in ArgF and CallF below.
static void dcArgF_impl(DCCallVM* vm, const DCsigchar** sigptr, va_list args)
{
DCsigchar ch;
dcReset(vm);
while((ch=*(*sigptr)++) != '\0' && ch != DC_SIGCHAR_ENDARG) {
switch(ch) {
case DC_SIGCHAR_BOOL: dcArgBool (vm, (DCbool) va_arg(args, DCint )); break;
case DC_SIGCHAR_CHAR: dcArgChar (vm, (DCchar) va_arg(args, DCint )); break;
case DC_SIGCHAR_UCHAR: dcArgChar (vm, (DCchar)(DCuchar) va_arg(args, DCint )); break;
case DC_SIGCHAR_SHORT: dcArgShort (vm, (DCshort) va_arg(args, DCint )); break;
case DC_SIGCHAR_USHORT: dcArgShort (vm, (DCshort)(DCushort)va_arg(args, DCint )); break;
case DC_SIGCHAR_INT: dcArgInt (vm, (DCint) va_arg(args, DCint )); break;
case DC_SIGCHAR_UINT: dcArgInt (vm, (DCint)(DCuint) va_arg(args, DCint )); break;
case DC_SIGCHAR_LONG: dcArgLong (vm, (DClong) va_arg(args, DClong )); break;
case DC_SIGCHAR_ULONG: dcArgLong (vm, (DCulong) va_arg(args, DClong )); break;
case DC_SIGCHAR_LONGLONG: dcArgLongLong(vm, (DClonglong) va_arg(args, DClonglong)); break;
case DC_SIGCHAR_ULONGLONG: dcArgLongLong(vm, (DCulonglong) va_arg(args, DClonglong)); break;
case DC_SIGCHAR_FLOAT: dcArgFloat (vm, (DCfloat) va_arg(args, DCdouble )); break;
case DC_SIGCHAR_DOUBLE: dcArgDouble (vm, (DCdouble) va_arg(args, DCdouble )); break;
case DC_SIGCHAR_POINTER: dcArgPointer (vm, (DCpointer) va_arg(args, DCpointer )); break;
case DC_SIGCHAR_STRING: dcArgPointer (vm, (DCpointer) va_arg(args, DCpointer )); break;
}
}
}
int invoke(char const* signature, void* t)
{
DCCallVM * p = (DCCallVM*) G_callvm;
char const * sig = signature;
char rtype;
char atype;
int pos = 0;
int s = 0;
clear_V();
rtype = *sig++;
dcReset(p);
while ( (atype = *sig++) != '\0') {
pos++;
switch(atype) {
case 'c': dcArgChar (p,K_c[pos]); break;
case 's': dcArgShort (p,K_s[pos]); break;
case 'i': dcArgInt (p,K_i[pos]); break;
case 'j': dcArgLong (p,K_j[pos]); break;
case 'l': dcArgLongLong(p,K_l[pos]); break;
case 'p': dcArgPointer (p,K_p[pos]); break;
case 'f': dcArgFloat (p,K_f[pos]); break;
case 'd': dcArgDouble (p,K_d[pos]); break;
default: printf("unknown atype '%c' (1) ;", atype); return 0;
}
}
switch(rtype)
{
case 'v': dcCallVoid(p,t); s=1; /*TODO:check that no return-arg was touched.*/ break;
case 'c': s = (dcCallChar (p,t) == K_c[pos]) ; break;
case 's': s = (dcCallShort (p,t) == K_s[pos]) ; break;
case 'i': s = (dcCallInt (p,t) == K_i[pos]) ; break;
case 'j': s = (dcCallLong (p,t) == K_j[pos]) ; break;
case 'l': s = (dcCallLongLong(p,t) == K_l[pos]) ; break;
case 'p': s = (dcCallPointer (p,t) == K_p[pos]) ; break;
case 'f': s = (dcCallFloat (p,t) == K_f[pos]) ; break;
case 'd': s = (dcCallDouble (p,t) == K_d[pos]) ; break;
default: printf("unknown rtype '%c'", rtype); return 0;
}
if (!s) { printf("rval wrong;"); return 0; }
/* test: */
sig = signature+1;
pos = 1;
while ( (atype = *sig++) != '\0') {
switch(atype) {
#if 0
#define X(CH,T,QCH) case QCH: s = (V_##CH[pos] == K_##CH[pos]); break;
DEF_TYPES
#undef X
#endif
case 'c': s = ( V_c[pos] == K_c[pos] ); if (!s) printf("'c':%d: %d != %d ; ", pos, V_c[pos], K_c[pos]); break;
case 's': s = ( V_s[pos] == K_s[pos] ); if (!s) printf("'s':%d: %d != %d ; ", pos, V_s[pos], K_s[pos]); break;
case 'i': s = ( V_i[pos] == K_i[pos] ); if (!s) printf("'i':%d: %d != %d ; ", pos, V_i[pos], K_i[pos]); break;
case 'j': s = ( V_j[pos] == K_j[pos] ); if (!s) printf("'j':%d: %ld != %ld ; ", pos, V_j[pos], K_j[pos]); break;
case 'l': s = ( V_l[pos] == K_l[pos] ); if (!s) printf("'l':%d: %lld != %lld ; ", pos, V_l[pos], K_l[pos]); break;
case 'p': s = ( V_p[pos] == K_p[pos] ); if (!s) printf("'p':%d: %lld != %lld ; ", pos, (long long) V_p[pos], (long long) K_p[pos]); break;
case 'f': s = ( V_f[pos] == K_f[pos] ); if (!s) printf("'f':%d: %f != %f ; ", pos, V_f[pos], K_f[pos]); break;
case 'd': s = ( V_d[pos] == K_d[pos] ); if (!s) printf("'d':%d: %f != %f ; ", pos, V_d[pos], K_d[pos]); break;
default: printf("unknown atype '%c' ; ", atype); return 0;
}
if (!s) {
printf("arg mismatch at %d ; ", pos);
return 0;
}
pos++;
}
return 1;
}
/* libcall(const libname[], const funcname[], const typestring[], ...)
*
* Loads the DLL or shared library if not yet loaded (the name comparison is
* case sensitive).
*
* typestring format:
* Whitespace is permitted between the types, but not inside the type
* specification. The string "ii[4]&u16s" is equivalent to "i i[4] &u16 s",
* but the latter is easier on the eye.
*
* types:
* i = signed integer, 16-bit in Windows 3.x, else 32-bit in Win32 and Linux
* u = unsigned integer, 16-bit in Windows 3.x, else 32-bit in Win32 and Linux
* f = IEEE floating point, 32-bit
* p = packed string
* s = unpacked string
* The difference between packed and unpacked strings is only relevant when
* the parameter is passed by reference (see below).
*
* pass-by-value and pass-by-reference:
* By default, parameters are passed by value. To pass a parameter by
* reference, prefix the type letter with an "&":
* &i = signed integer passed by reference
* i = signed integer passed by value
* Same for '&u' versus 'u' and '&f' versus 'f'.
*
* Arrays are passed by "copy & copy-back". That is, libcall() allocates a
* block of dynamic memory to copy the array into. On return from the foreign
* function, libcall() copies the array back to the abstract machine. The
* net effect is similar to pass by reference, but the foreign function does
* not work in the AMX stack directly. During the copy and the copy-back
* operations, libcall() may also transform the array elements, for example
* between 16-bit and 32-bit elements. This is done because Pawn only
* supports a single cell size, which may not fit the required integer size
* of the foreign function.
*
* See "element ranges" for the syntax of passing an array.
*
* Strings may either be passed by copy, or by "copy & copy-back". When the
* string is an output parameter (for the foreign function), the size of the
* array that will hold the return string must be indicated between square
* brackets behind the type letter (see "element ranges"). When the string
* is "input only", this is not needed --libcall() will determine the length
* of the input string itself.
*
* The tokens 'p' and 's' are equivalent, but 'p[10]' and 's[10]' are not
* equivalent: the latter syntaxes determine whether the output from the
* foreign function will be stored as a packed or an unpacked string.
*
* element sizes:
* Add an integer behind the type letter; for example, 'i16' refers to a
* 16-bit signed integer. Note that the value behind the type letter must
* be either 8, 16 or 32.
*
* You should only use element size specifiers on the 'i' and 'u' types. That
* is, do not use these specifiers on 'f', 's' and 'p'.
*
* element ranges:
* For passing arrays, the size of the array may be given behind the type
* letter and optional element size. The token 'u[4]' indicates an array of
* four unsigned integers, which are typically 32-bit. The token 'i16[8]'
* is an array of 8 signed 16-bit integers. Arrays are always passed by
* "copy & copy-back"
*
* When compiled as Unicode, this library converts all strings to Unicode
* strings.
*
* The calling convention for the foreign functions is assumed:
* - "__stdcall" for Win32,
* - "far pascal" for Win16
* - and the GCC default for Unix/Linux (_cdecl)
*
* C++ name mangling of the called function is not handled (there is no standard
* convention for name mangling, so there is no portable way to convert C++
* function names to mangled names). Win32 name mangling (used by default by
* Microsoft compilers on functions declared as __stdcall) is also not handled.
*
* Returns the value of the called function.
*/
static cell AMX_NATIVE_CALL n_libcall(AMX *amx, const cell *params)
{
const TCHAR *libname, *funcname, *typestring;
MODLIST *item;
int paramidx, typeidx, idx;
PARAM ps[MAXPARAMS];
cell *cptr,result;
LIBFUNC LibFunc;
amx_StrParam(amx, params[1], libname);
item = findlib(&ModRoot, amx, libname);
if (item == NULL)
item = addlib(&ModRoot, amx, libname);
if (item == NULL) {
amx_RaiseError(amx, AMX_ERR_NATIVE);
return 0;
} /* if */
/* library is loaded, get the function */
amx_StrParam(amx, params[2], funcname);
LibFunc=(LIBFUNC)SearchProcAddress(item->inst, funcname);
if (LibFunc==NULL) {
amx_RaiseError(amx, AMX_ERR_NATIVE);
return 0;
} /* if */
#if defined HAVE_DYNCALL_H
/* (re-)initialize the dyncall library */
if (dcVM==NULL) {
dcVM=dcNewCallVM(4096);
dcMode(dcVM,DC_CALL_C_X86_WIN32_STD);
} /* if */
dcReset(dcVM);
#endif
/* decode the parameters */
paramidx=typeidx=0;
amx_StrParam(amx, params[3], typestring);
while (paramidx < MAXPARAMS && typestring[typeidx]!=__T('\0')) {
/* skip white space */
while (typestring[typeidx]!=__T('\0') && typestring[typeidx]<=__T(' '))
typeidx++;
if (typestring[typeidx]==__T('\0'))
break;
/* save "pass-by-reference" token */
ps[paramidx].type=0;
if (typestring[typeidx]==__T('&')) {
ps[paramidx].type=BYREF;
typeidx++;
} /* if */
/* store type character */
ps[paramidx].type |= (unsigned char)typestring[typeidx];
typeidx++;
/* set default size, then check for an explicit size */
#if defined __WIN32__ || defined _WIN32 || defined WIN32
ps[paramidx].size=32;
#elif defined _Windows
ps[paramidx].size=16;
#endif
if (_istdigit(typestring[typeidx])) {
ps[paramidx].size=(unsigned char)_tcstol(&typestring[typeidx],NULL,10);
while (_istdigit(typestring[typeidx]))
typeidx++;
} /* if */
/* set default range, then check for an explicit range */
ps[paramidx].range=1;
if (typestring[typeidx]=='[') {
ps[paramidx].range=_tcstol(&typestring[typeidx+1],NULL,10);
while (typestring[typeidx]!=']' && typestring[typeidx]!='\0')
typeidx++;
ps[paramidx].type |= BYREF; /* arrays are always passed by reference */
typeidx++; /* skip closing ']' too */
} /* if */
/* get pointer to parameter */
cptr=amx_Address(amx,params[paramidx+4]);
switch (ps[paramidx].type) {
case 'i': /* signed integer */
case 'u': /* unsigned integer */
case 'f': /* floating point */
assert(ps[paramidx].range==1);
ps[paramidx].v.val=(int)*cptr;
break;
case 'i' | BYREF:
case 'u' | BYREF:
case 'f' | BYREF:
ps[paramidx].v.ptr=cptr;
if (ps[paramidx].range>1) {
/* convert array and pass by address */
ps[paramidx].v.ptr = fillarray(amx, &ps[paramidx], cptr);
} /* if */
break;
case 'p':
case 's':
case 'p' | BYREF:
case 's' | BYREF:
if (ps[paramidx].type=='s' || ps[paramidx].type=='p') {
int len;
/* get length of input string */
amx_StrLen(cptr,&len);
len++; /* include '\0' */
/* check max. size */
if (len<ps[paramidx].range)
len=ps[paramidx].range;
ps[paramidx].range=len;
} /* if */
ps[paramidx].v.ptr=malloc(ps[paramidx].range*sizeof(TCHAR));
if (ps[paramidx].v.ptr==NULL)
return amx_RaiseError(amx, AMX_ERR_NATIVE);
amx_GetString((char *)ps[paramidx].v.ptr,cptr,sizeof(TCHAR)>1,UNLIMITED);
break;
default:
/* invalid parameter type */
return amx_RaiseError(amx, AMX_ERR_NATIVE);
} /* switch */
paramidx++;
} /* while */
if ((params[0]/sizeof(cell)) - 3 != (size_t)paramidx)
return amx_RaiseError(amx, AMX_ERR_NATIVE); /* format string does not match number of parameters */
#if defined HAVE_DYNCALL_H
for (idx = 0; idx < paramidx; idx++) {
if ((ps[idx].type=='i' || ps[idx].type=='u' || ps[idx].type=='f') && ps[idx].range==1) {
switch (ps[idx].size) {
case 8:
dcArgChar(dcVM,(unsigned char)(ps[idx].v.val & 0xff));
break;
case 16:
dcArgShort(dcVM,(unsigned short)(ps[idx].v.val & 0xffff));
break;
default:
dcArgLong(dcVM,ps[idx].v.val);
} /* switch */
} else {
dcArgPointer(dcVM,ps[idx].v.ptr);
} /* if */
} /* for */
result=(cell)dcCallPointer(dcVM,(void*)LibFunc);
#else /* HAVE_DYNCALL_H */
/* push the parameters to the stack (left-to-right in 16-bit; right-to-left
* in 32-bit)
*/
#if defined __WIN32__ || defined _WIN32 || defined WIN32
for (idx=paramidx-1; idx>=0; idx--) {
#else
for (idx=0; idx<paramidx; idx++) {
#endif
if ((ps[idx].type=='i' || ps[idx].type=='u' || ps[idx].type=='f') && ps[idx].range==1) {
switch (ps[idx].size) {
case 8:
push((unsigned char)(ps[idx].v.val & 0xff));
break;
case 16:
push((unsigned short)(ps[idx].v.val & 0xffff));
break;
default:
push(ps[idx].v.val);
} /* switch */
} else {
push(ps[idx].v.ptr);
} /* if */
} /* for */
/* call the function; all parameters are already pushed to the stack (the
* function should remove the parameters from the stack)
*/
result=LibFunc();
#endif /* HAVE_DYNCALL_H */
/* store return values and free allocated memory */
for (idx=0; idx<paramidx; idx++) {
switch (ps[idx].type) {
case 'p':
case 's':
free(ps[idx].v.ptr);
break;
case 'p' | BYREF:
case 's' | BYREF:
cptr=amx_Address(amx,params[idx+4]);
amx_SetString(cptr,(char *)ps[idx].v.ptr,ps[idx].type==('p'|BYREF),sizeof(TCHAR)>1,UNLIMITED);
free(ps[idx].v.ptr);
break;
case 'i':
case 'u':
case 'f':
assert(ps[idx].range==1);
break;
case 'i' | BYREF:
case 'u' | BYREF:
case 'f' | BYREF:
cptr=amx_Address(amx,params[idx+4]);
if (ps[idx].range==1) {
/* modify directly in the AMX (no memory block was allocated */
switch (ps[idx].size) {
case 8:
*cptr= (ps[idx].type==('i' | BYREF)) ? (long)((signed char)*cptr) : (*cptr & 0xff);
break;
case 16:
*cptr= (ps[idx].type==('i' | BYREF)) ? (long)((short)*cptr) : (*cptr & 0xffff);
break;
} /* switch */
} else {
int i;
for (i=0; i<ps[idx].range; i++) {
switch (ps[idx].size) {
case 8:
*cptr= (ps[idx].type==('i' | BYREF)) ? ((signed char*)ps[idx].v.ptr)[i] : ((unsigned char*)ps[idx].v.ptr)[i];
break;
case 16:
*cptr= (ps[idx].type==('i' | BYREF)) ? ((short*)ps[idx].v.ptr)[i] : ((unsigned short*)ps[idx].v.ptr)[i];
break;
default:
*cptr= (ps[idx].type==('i' | BYREF)) ? ((long*)ps[idx].v.ptr)[i] : ((unsigned long*)ps[idx].v.ptr)[i];
} /* switch */
} /* for */
free((char *)ps[idx].v.ptr);
} /* if */
break;
default:
assert(0);
} /* switch */
} /* for */
return result;
}
/* bool: libfree(const libname[]="")
* When the name is an empty string, this function frees all libraries (for this
* abstract machine). The name comparison is case sensitive.
* Returns true if one or more libraries were freed.
*/
static cell AMX_NATIVE_CALL n_libfree(AMX *amx, const cell *params)
{
const TCHAR *libname;
amx_StrParam(amx,params[1],libname);
return freelib(&ModRoot,amx,libname) > 0;
}
#else /* HAVE_DYNCALL_H || WIN32_FFI */
static cell AMX_NATIVE_CALL n_libcall(AMX *amx, const cell *params)
{
(void)amx;
(void)params;
return 0;
}
template<> void _push_fn_arg<long>(long value) { dcArgLong(vm, value); }
