/*
* R : A Computer Language for Statistical Data Analysis
* Copyright (C) 1995-1996 Robert Gentleman and Ross Ihaka
* Copyright (C) 1997-2006 The R Development Core Team
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street Fifth Floor, Boston, MA 02110-1301 USA
*/
/* <UTF8> char here is handled as a whole string */
/*
This is an effort to merge the 3 different dynload.c files in the
distribution from the unix/, macintosh/dll/ and gnuwin32/ directories.
The aim is to consolidate these different implementations into
i) a generic or platform-independent common core
ii) platform-dependent routines that are registered
as function pointers.
The reason for using function pointers rather than explicit
linking of symbols is
a) to avoid confusion in the linking
b) to allow for easily overriding these in embedded applications
in which a host application needs to control how R finds
symbols. This may be necessary for security reasons.
*/
/* Dynamic Loading Support
*
* This module provides support for run-time loading of shared libraries
* access to symbols within such libraries via .C and .Fortran. This is
* done under Unix with dlopen, dlclose and dlsym (the exception is
* hpux, where we use compatibility code provided by Luke Tierney.
* There are two cases:
*
*
* 1. The dlopen interface is available.
*
* In this case all symbol location in packages is done using the dlopen routines.
* We maintain a list of currently loaded shared libraries in an array
* called "LoadedDLL" with the number of currenly loaded libraries
* being "CountDLL". To locate a symbol, we probe the loaded libraries
* in order until the symbol is located. If we do not find a symbol
* in the loaded libraries, we search the executable itself. This
* search is not very efficient, but this probably pales into
* insignificance when compared with the inefficiencies in the R
* interpreter.
*
* Loading and unloading of shared libraries is done via the routines
* AddDLL and DeleteDLL. These routines maintain the list of currently
* loaded libraries. When a library is added, any existing reference
* to that library are deleted and then the library is inserted at the
* start of the search list. This way, symbols in more recently loaded
* libraries are found first.
*
*
* Accessing native routines in base (the R executable).
*
* In this case, we use the registration mechanism and the DllInfo array
* in ../main/Rdynload.c to locate functions in the executable. We do this
* by straight linear search through the table.
* Note that the base routines registered are listed in
* ../main/registration.c
* and are registered during the initialization of the R engine.
* (This replaces the previous mechanism that built a table
* from ../appl/ROUTINES using Perl/sed).
*
*
* If speed is ever an issue in the lookup of registered symbols, we can
* store the registered routines in a hashtable or binary tree as they
* are being registered.
*/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include <Defn.h>
#include <string.h>
#include <stdlib.h>
#ifdef HAVE_UNISTD_H
#include <unistd.h>
#endif
#include <Rmath.h>
#include <Rdynpriv.h>
#ifdef Unix
/* HP-UX 11.0 has dlfcn.h, but according to libtool as of Dec 2001
this support is broken. So we force use of shlib even when dlfcn.h
is available */
# ifdef __hpux
# ifdef HAVE_DL_H
# define HAVE_DYNAMIC_LOADING
# endif
# else
# ifdef HAVE_DLFCN_H
# define HAVE_DYNAMIC_LOADING
# endif
# endif /* __hpux */
# ifndef HAVE_NO_SYMBOL_UNDERSCORE
# ifdef HAVE_ELF_H
# define HAVE_NO_SYMBOL_UNDERSCORE
# endif /* HAVE_ELF_H */
# endif /* HAVE_NO_SYMBOL_UNDERSCORE */
#endif
#ifdef Win32
# define HAVE_DYNAMIC_LOADING
#endif
#ifdef __APPLE_CC__
# define HAVE_DYNAMIC_LOADING
#endif
/* The following code loads in a compatibility module written by Luke
Tierney to support S version 4 on Hewlett-Packard machines. The
relevant defines are set up by autoconf. */
#ifdef HAVE_DYNAMIC_LOADING
#ifdef CACHE_DLL_SYM
/* keep a record of symbols that have been found */
R_CPFun CPFun[100];
int nCPFun = 0;
#endif
#define MAX_NUM_DLLS 100
static int CountDLL = 0;
#include <R_ext/Rdynload.h>
static DllInfo LoadedDLL[MAX_NUM_DLLS];
static int addDLL(char *dpath, char *name, HINSTANCE handle);
static SEXP Rf_MakeDLLInfo(DllInfo *info);
static SEXP createRSymbolObject(SEXP sname, DL_FUNC f,
R_RegisteredNativeSymbol *symbol,
Rboolean withRegistrationInfo);
static DllInfo *R_RegisterDLL(HINSTANCE handle, const char *path);
attribute_hidden OSDynSymbol Rf_osDynSymbol;
attribute_hidden OSDynSymbol *R_osDynSymbol = &Rf_osDynSymbol;
void R_init_base(DllInfo *); /* In Registration.c */
DL_FUNC R_dlsym(DllInfo *dll, char const *name,
R_RegisteredNativeSymbol *symbol);
void attribute_hidden
InitDynload()
{
DllInfo *dll;
int which = addDLL(strdup("base"), "base", NULL);
dll = &LoadedDLL[which];
R_init_base(dll);
InitFunctionHashing();
}
#ifdef UNUSED
DllInfo *
getBaseDllInfo()
{
return(&LoadedDLL[0]);
}
#endif
Rboolean R_useDynamicSymbols(DllInfo *info, Rboolean value)
{
Rboolean old;
old = info->useDynamicLookup;
info->useDynamicLookup = value;
return(old);
}
static void
R_addCRoutine(DllInfo *info, const R_CMethodDef * const croutine,
Rf_DotCSymbol *sym);
static void
R_addCallRoutine(DllInfo *info,
const R_CallMethodDef * const croutine,
Rf_DotCallSymbol *sym);
static void
R_addFortranRoutine(DllInfo *info,
const R_FortranMethodDef * const croutine,
Rf_DotFortranSymbol *sym);
static void
R_addExternalRoutine(DllInfo *info,
const R_ExternalMethodDef * const croutine,
Rf_DotExternalSymbol *sym);
/*
Returns a reference to the DllInfo object associated with the dynamic library
with the path name `path'. This ensures uniqueness rather than having the
undesirable situation of two libraries with the same name but in different
directories.
This is available so that it can be called from arbitrary C routines
that need to call R_registerRoutines(). The initialization routine
R_init_<library name> is passed the DllInfo reference as an argument.
Other routines must explicitly request it using this routine.
*/
DllInfo *
R_getDllInfo(const char *path)
{
int i;
for(i = 0; i < CountDLL; i++) {
if(strcmp(LoadedDLL[i].path, path) == 0)
return(&LoadedDLL[i]);
}
return((DllInfo*) NULL);
}
/*
Explicitly register the native routines for use in .Call(), .C() and .Fortran()
functions. These registered values are used to resolve symbols in a library
that makes a call to this routine, rather than the usual dynamic resolution
done by dlsym() or the equivalent on the different platforms.
*/
int
R_registerRoutines(DllInfo *info, const R_CMethodDef * const croutines,
const R_CallMethodDef * const callRoutines,
const R_FortranMethodDef * const fortranRoutines,
const R_ExternalMethodDef * const externalRoutines)
{
int i, num;
if(info == NULL)
error(_("R_RegisterRoutines called with invalid DllInfo object."));
info->useDynamicLookup = TRUE; /* Default is to look in registered and then dynamic.
Potentially change in the future to be only registered
if there are any registered values.
*/
if(croutines) {
for(num=0; croutines[num].name != NULL; num++) {;}
info->CSymbols = (Rf_DotCSymbol*)calloc(num, sizeof(Rf_DotCSymbol));
info->numCSymbols = num;
for(i = 0; i < num; i++) {
R_addCRoutine(info, croutines+i, info->CSymbols + i);
}
}
if(fortranRoutines) {
for(num=0; fortranRoutines[num].name != NULL; num++) {;}
info->FortranSymbols =
(Rf_DotFortranSymbol*)calloc(num, sizeof(Rf_DotFortranSymbol));
info->numFortranSymbols = num;
for(i = 0; i < num; i++) {
R_addFortranRoutine(info, fortranRoutines+i,
info->FortranSymbols + i);
}
}
if(callRoutines) {
for(num=0; callRoutines[num].name != NULL; num++) {;}
info->CallSymbols =
(Rf_DotCallSymbol*)calloc(num, sizeof(Rf_DotCallSymbol));
info->numCallSymbols = num;
for(i = 0; i < num; i++) {
R_addCallRoutine(info, callRoutines+i, info->CallSymbols + i);
}
}
if(externalRoutines) {
for(num=0; externalRoutines[num].name != NULL; num++) {;}
info->ExternalSymbols =
(Rf_DotExternalSymbol*)calloc(num, sizeof(Rf_DotExternalSymbol));
info->numExternalSymbols = num;
for(i = 0; i < num; i++) {
R_addExternalRoutine(info, externalRoutines+i,
info->ExternalSymbols + i);
}
}
return(1);
}
static void
R_setPrimitiveArgTypes(const R_FortranMethodDef * const croutine,
Rf_DotFortranSymbol *sym)
{
sym->types = (R_NativePrimitiveArgType *)
malloc(sizeof(R_NativePrimitiveArgType) * croutine->numArgs);
if(sym->types)
memcpy(sym->types, croutine->types,
sizeof(R_NativePrimitiveArgType) * croutine->numArgs);
}
static void
R_setArgStyles(const R_FortranMethodDef * const croutine,
Rf_DotFortranSymbol *sym)
{
sym->styles = (R_NativeArgStyle *)
malloc(sizeof(R_NativeArgStyle) * croutine->numArgs);
if(sym->styles)
memcpy(sym->styles, croutine->styles,
sizeof(R_NativeArgStyle) * croutine->numArgs);
}
static void
R_addFortranRoutine(DllInfo *info,
const R_FortranMethodDef * const croutine,
Rf_DotFortranSymbol *sym)
{
sym->name = strdup(croutine->name);
sym->fun = croutine->fun;
sym->numArgs = croutine->numArgs > -1 ? croutine->numArgs : -1;
if(croutine->types)
R_setPrimitiveArgTypes(croutine, sym);
if(croutine->styles)
R_setArgStyles(croutine, sym);
}
static void
R_addExternalRoutine(DllInfo *info,
const R_ExternalMethodDef * const croutine,
Rf_DotExternalSymbol *sym)
{
sym->name = strdup(croutine->name);
sym->fun = croutine->fun;
sym->numArgs = croutine->numArgs > -1 ? croutine->numArgs : -1;
}
static void
R_addCRoutine(DllInfo *info, const R_CMethodDef * const croutine,
Rf_DotCSymbol *sym)
{
sym->name = strdup(croutine->name);
sym->fun = croutine->fun;
sym->numArgs = croutine->numArgs > -1 ? croutine->numArgs : -1;
if(croutine->types)
R_setPrimitiveArgTypes(croutine, sym);
if(croutine->styles)
R_setArgStyles(croutine, sym);
}
static void
R_addCallRoutine(DllInfo *info, const R_CallMethodDef * const croutine,
Rf_DotCallSymbol *sym)
{
sym->name = strdup(croutine->name);
sym->fun = croutine->fun;
sym->numArgs = croutine->numArgs > -1 ? croutine->numArgs : -1;
}
static void
Rf_freeCSymbol(Rf_DotCSymbol *sym)
{
free(sym->name);
}
static void
Rf_freeCallSymbol(Rf_DotCallSymbol *sym)
{
free(sym->name);
}
static void
Rf_freeExternalSymbol(Rf_DotCallSymbol *sym)
{
free(sym->name);
}
static void
Rf_freeFortranSymbol(Rf_DotFortranSymbol *sym)
{
free(sym->name);
}
static void
Rf_freeDllInfo(DllInfo *info)
{
int i;
free(info->name);
free(info->path);
if(info->CSymbols) {
for(i = 0; i < info->numCSymbols; i++)
Rf_freeCSymbol(info->CSymbols+i);
free(info->CSymbols);
}
if(info->CallSymbols) {
for(i = 0; i < info->numCallSymbols; i++)
Rf_freeCallSymbol(info->CallSymbols+i);
free(info->CallSymbols);
}
if(info->ExternalSymbols) {
for(i = 0; i < info->numExternalSymbols; i++)
Rf_freeExternalSymbol(info->ExternalSymbols+i);
free(info->ExternalSymbols);
}
if(info->FortranSymbols) {
for(i = 0; i < info->numFortranSymbols; i++)
Rf_freeFortranSymbol(info->FortranSymbols+i);
free(info->FortranSymbols);
}
}
static Rboolean
R_callDLLUnload(DllInfo *dllInfo)
{
char buf[1024];
DL_FUNC f;
R_RegisteredNativeSymbol symbol;
symbol.type = R_ANY_SYM;
snprintf(buf, 1024, "R_unload_%s", dllInfo->name);
f = R_dlsym(dllInfo, buf, &symbol);
if(f)
f(dllInfo);
return(TRUE);
}
/* Remove the specified DLL from the current DLL list */
/* Returns 1 if the DLL was found and removed from */
/* the list and returns 0 otherwise. */
static int DeleteDLL(char *path)
{
int i, loc;
for (i = 0; i < CountDLL; i++) {
if (!strcmp(path, LoadedDLL[i].path)) {
loc = i;
goto found;
}
}
return 0;
found:
#ifdef CACHE_DLL_SYM
if(R_osDynSymbol->deleteCachedSymbols)
R_osDynSymbol->deleteCachedSymbols(&LoadedDLL[loc]);
#endif
R_callDLLUnload(&LoadedDLL[loc]);
R_osDynSymbol->closeLibrary(LoadedDLL[loc].handle);
Rf_freeDllInfo(LoadedDLL+loc);
for(i = loc + 1 ; i < CountDLL ; i++) {
LoadedDLL[i - 1].path = LoadedDLL[i].path;
LoadedDLL[i - 1].name = LoadedDLL[i].name;
LoadedDLL[i - 1].handle = LoadedDLL[i].handle;
LoadedDLL[i - 1].useDynamicLookup = LoadedDLL[i].useDynamicLookup;
LoadedDLL[i - 1].numCSymbols = LoadedDLL[i].numCSymbols;
LoadedDLL[i - 1].numCallSymbols = LoadedDLL[i].numCallSymbols;
LoadedDLL[i - 1].numFortranSymbols = LoadedDLL[i].numFortranSymbols;
LoadedDLL[i - 1].numExternalSymbols = LoadedDLL[i].numExternalSymbols;
LoadedDLL[i - 1].CSymbols = LoadedDLL[i].CSymbols;
LoadedDLL[i - 1].CallSymbols = LoadedDLL[i].CallSymbols;
LoadedDLL[i - 1].FortranSymbols = LoadedDLL[i].FortranSymbols;
LoadedDLL[i - 1].ExternalSymbols = LoadedDLL[i].ExternalSymbols;
}
CountDLL--;
return 1;
}
attribute_hidden
DL_FUNC Rf_lookupCachedSymbol(const char *name, const char *pkg, int all)
{
#ifdef CACHE_DLL_SYM
int i;
for (i = 0; i < nCPFun; i++)
if (!strcmp(name, CPFun[i].name) &&
(all || !strcmp(pkg, CPFun[i].pkg)))
return CPFun[i].func;
#endif
return((DL_FUNC) NULL);
}
#ifdef Win32
#define DLLerrBUFSIZE 4000
#else /* Not Windows */
#define DLLerrBUFSIZE 1000
#endif
static char DLLerror[DLLerrBUFSIZE] = "";
/* the error message; length taken from ERRBUFSIZE in ./hpdlfcn.c */
/* Inserts the specified DLL at the head of the DLL list */
/* Returns 1 if the library was successfully added */
/* and returns 0 if the library table is full or */
/* or if dlopen fails for some reason. */
static DllInfo* AddDLL(char *path, int asLocal, int now)
{
HINSTANCE handle;
DllInfo *info = NULL;
DeleteDLL(path);
if(CountDLL == MAX_NUM_DLLS) {
strcpy(DLLerror, _("Maximal number of DLLs reached..."));
return NULL;
}
handle = R_osDynSymbol->loadLibrary(path, asLocal, now);
if(handle == NULL) {
R_osDynSymbol->getError(DLLerror, DLLerrBUFSIZE);
return NULL;
}
info = R_RegisterDLL(handle, path);
/* Now look for an initializing routine named R_init_<library name>.
If it is present, we invoke it. It should take a reference to the
DllInfo object currently being initialized.
*/
if(info) {
char *tmp;
DL_FUNC f;
#ifdef HAVE_NO_SYMBOL_UNDERSCORE
tmp = (char*) malloc(sizeof(char)*(strlen("R_init_") +
strlen(info->name)+ 1));
sprintf(tmp, "%s%s","R_init_", info->name);
#else
tmp = (char*) malloc(sizeof(char)*(strlen("R_init_") +
strlen(info->name)+ 2));
sprintf(tmp, "_%s%s","R_init_", info->name);
#endif
f = (DL_FUNC) R_osDynSymbol->dlsym(info, tmp);
free(tmp);
if(f)
f(info);
}
return info;
}
static DllInfo *R_RegisterDLL(HINSTANCE handle, const char *path)
{
char *dpath, DLLname[PATH_MAX], *p;
DllInfo *info;
info = &LoadedDLL[CountDLL];
/* default is to use old-style dynamic lookup. Library's
initialization routine can limit access by setting this to FALSE.
*/
info->useDynamicLookup = TRUE;
dpath = malloc(strlen(path)+1);
if(dpath == NULL) {
strcpy(DLLerror, _("could not allocate space for 'path'"));
R_osDynSymbol->closeLibrary(handle);
return 0;
}
strcpy(dpath, path);
if(R_osDynSymbol->fixPath)
R_osDynSymbol->fixPath(dpath);
/* keep only basename from path */
p = Rf_strrchr(dpath, FILESEP[0]);
if(!p) p = dpath; else p++;
if(strlen(p) < PATH_MAX) strcpy(DLLname, p);
else error(_("DLLname '%s' is too long"), p);
/* remove SHLIB_EXT if present */
p = DLLname + strlen(DLLname) - strlen(SHLIB_EXT);
#ifdef Win32 /* case-insensitive file system */
if(p > DLLname && stricmp(p, SHLIB_EXT) == 0) *p = '\0';
#else
if(p > DLLname && strcmp(p, SHLIB_EXT) == 0) *p = '\0';
#endif
addDLL(dpath, DLLname, handle);
return(info);
}
static int
addDLL(char *dpath, char *DLLname, HINSTANCE handle)
{
int ans = CountDLL;
char *name = malloc(strlen(DLLname)+1);
if(name == NULL) {
strcpy(DLLerror, _("could not allocate space for 'name'"));
if(handle)
R_osDynSymbol->closeLibrary(handle);
free(dpath);
return 0;
}
strcpy(name, DLLname);
LoadedDLL[CountDLL].path = dpath;
LoadedDLL[CountDLL].name = name;
LoadedDLL[CountDLL].handle = handle;
LoadedDLL[CountDLL].numCSymbols = 0;
LoadedDLL[CountDLL].numCallSymbols = 0;
LoadedDLL[CountDLL].numFortranSymbols = 0;
LoadedDLL[CountDLL].CSymbols = NULL;
LoadedDLL[CountDLL].CallSymbols = NULL;
LoadedDLL[CountDLL].FortranSymbols = NULL;
CountDLL++;
return(ans);
}
static Rf_DotCSymbol *
Rf_lookupRegisteredCSymbol(DllInfo *info, const char *name)
{
int i;
for(i = 0; i < info->numCSymbols; i++) {
if(strcmp(name, info->CSymbols[i].name) == 0)
return(&(info->CSymbols[i]));
}
return(NULL);
}
static Rf_DotFortranSymbol *
Rf_lookupRegisteredFortranSymbol(DllInfo *info, const char *name)
{
int i;
for(i = 0; i < info->numFortranSymbols; i++) {
if(strcmp(name, info->FortranSymbols[i].name) == 0)
return(&(info->FortranSymbols[i]));
}
return((Rf_DotFortranSymbol*)NULL);
}
static Rf_DotCallSymbol *
Rf_lookupRegisteredCallSymbol(DllInfo *info, const char *name)
{
int i;
for(i = 0; i < info->numCallSymbols; i++) {
if(strcmp(name, info->CallSymbols[i].name) == 0)
return(&(info->CallSymbols[i]));
}
return((Rf_DotCallSymbol*)NULL);
}
static Rf_DotExternalSymbol *
Rf_lookupRegisteredExternalSymbol(DllInfo *info, const char *name)
{
int i;
for(i = 0; i < info->numExternalSymbols; i++) {
if(strcmp(name, info->ExternalSymbols[i].name) == 0)
return(&(info->ExternalSymbols[i]));
}
return((Rf_DotExternalSymbol*)NULL);
}
static DL_FUNC R_getDLLRegisteredSymbol(DllInfo *info, const char *name,
R_RegisteredNativeSymbol *symbol)
{
int fail = 0;
NativeSymbolType purpose = R_ANY_SYM;
if(symbol)
purpose = symbol->type;
if((purpose == R_ANY_SYM || purpose == R_C_SYM) &&
info->numCSymbols > 0) {
Rf_DotCSymbol *sym;
sym = Rf_lookupRegisteredCSymbol(info, name);
if(sym) {
if(symbol) {
symbol->type = R_C_SYM;
symbol->symbol.c = sym;
symbol->dll = info;
}
return((DL_FUNC) sym->fun);
}
fail = 1;
}
if((purpose == R_ANY_SYM || purpose == R_CALL_SYM) &&
info->numCallSymbols > 0) {
Rf_DotCallSymbol *sym;
sym = Rf_lookupRegisteredCallSymbol(info, name);
if(sym) {
if(symbol) {
symbol->type = R_CALL_SYM;
symbol->symbol.call = sym;
symbol->dll = info;
}
return((DL_FUNC) sym->fun);
}
fail = 1;
}
if((purpose == R_ANY_SYM || purpose == R_FORTRAN_SYM) &&
info->numFortranSymbols > 0) {
Rf_DotFortranSymbol *sym;
sym = Rf_lookupRegisteredFortranSymbol(info, name);
if(sym) {
if(symbol) {
symbol->type = R_FORTRAN_SYM;
symbol->symbol.fortran = sym;
symbol->dll = info;
}
return((DL_FUNC) sym->fun);
}
fail = 1;
}
if((purpose == R_ANY_SYM || purpose == R_EXTERNAL_SYM) &&
info->numExternalSymbols > 0) {
Rf_DotExternalSymbol *sym;
sym = Rf_lookupRegisteredExternalSymbol(info, name);
if(sym) {
if(symbol) {
symbol->type = R_EXTERNAL_SYM;
symbol->symbol.external = sym;
symbol->dll = info;
}
return((DL_FUNC) sym->fun);
}
fail = 1;
}
return((DL_FUNC) NULL);
}
DL_FUNC attribute_hidden
R_dlsym(DllInfo *info, char const *name,
R_RegisteredNativeSymbol *symbol)
{
char buf[MAXIDSIZE+1];
DL_FUNC f;
f = R_getDLLRegisteredSymbol(info, name, symbol);
if(f)
return(f);
if(info->useDynamicLookup == FALSE)
return(NULL);
#ifdef HAVE_NO_SYMBOL_UNDERSCORE
snprintf(buf, MAXIDSIZE+1, "%s", name);
#else
snprintf(buf, MAXIDSIZE+1,"_%s", name);
#endif
#ifdef HAVE_F77_UNDERSCORE
if(symbol && symbol->type == R_FORTRAN_SYM) {
buf[strlen(buf)+1] = '\0';
buf[strlen(buf)] = '_';
}
#endif
#ifdef HAVE_F77_EXTRA_UNDERSCORE
if(strchr(name, '_') && symbol && symbol->type == R_FORTRAN_SYM) {
buf[strlen(buf)+1] = '\0';
buf[strlen(buf)] = '_';
}
#endif
return (DL_FUNC) R_osDynSymbol->dlsym(info, buf);
}
/* R_FindSymbol checks whether one of the libraries */
/* that have been loaded contains the symbol name and */
/* returns a pointer to that symbol upon success. */
/*
In the future, this will receive an additional argument
which will specify the nature of the symbol expected by the
caller, specifically whether it is for a .C(), .Call(),
.Fortran(), .External(), generic, etc. invocation. This will
reduce the pool of possible symbols in the case of a library
that registers its routines.
This is currently done via the value in symbol.
*/
DL_FUNC R_FindSymbol(char const *name, char const *pkg,
R_RegisteredNativeSymbol *symbol)
{
DL_FUNC fcnptr = (DL_FUNC) NULL;
int i, all = (strlen(pkg) == 0), doit;
if(R_osDynSymbol->lookupCachedSymbol)
fcnptr = R_osDynSymbol->lookupCachedSymbol(name, pkg, all);
if(fcnptr)
return(fcnptr);
/* The following is not legal ANSI C. */
/* It is only meant to be used in systems supporting */
/* the dlopen() interface, in which systems data and */
/* function pointers _are_ the same size and _can_ */
/* be cast without loss of information. */
for (i = CountDLL - 1; i >= 0; i--) {
doit = all;
if(!doit && !strcmp(pkg, LoadedDLL[i].name)) doit = 2;
if(doit) {
fcnptr = R_dlsym(&LoadedDLL[i], name, symbol); /* R_osDynSymbol->dlsym */
if (fcnptr != (DL_FUNC) NULL) {
if(symbol)
symbol->dll = LoadedDLL+i;
#ifdef CACHE_DLL_SYM
if(strlen(pkg) <= 20 && strlen(name) <= 40 && nCPFun < 100
&& (!symbol || !symbol->symbol.c)) {
strcpy(CPFun[nCPFun].pkg, LoadedDLL[i].name);
strcpy(CPFun[nCPFun].name, name);
CPFun[nCPFun++].func = fcnptr;
}
#endif
return fcnptr;
}
}
if(doit > 1) return (DL_FUNC) NULL; /* Only look in the first-matching DLL */
}
return (DL_FUNC) NULL;
}
static void GetFullDLLPath(SEXP call, char *buf, char *path)
{
R_osDynSymbol->getFullDLLPath(call, buf, path);
}
/* do_dynload implements the R-Interface for the */
/* loading of shared libraries */
/*
Extended to support 2 additional arguments (3 in total).
First argument is the name of the library.
Second argument is a logical indicating whether we
want the symbols to be kept in their own local symbol table
or added to the global symbol table of the application.
Third argument is a logical indicating whether the
dynamic loading should relocate all routine symbols
now and signal any errors immediately or lazily relocate
the symbols as they are invoked. This is useful for
developers so that they can ensure that all the symbols
are available before they release, and allows users to
call routines from "incomplete" libraries.
*/
SEXP attribute_hidden do_dynload(SEXP call, SEXP op, SEXP args, SEXP env)
{
char buf[2 * PATH_MAX];
DllInfo *info;
checkArity(op,args);
if (!isString(CAR(args)) || length(CAR(args)) < 1)
errorcall(call, _("character argument expected"));
GetFullDLLPath(call, buf, CHAR(STRING_ELT(CAR(args), 0)));
/* AddDLL does this DeleteDLL(buf); */
info = AddDLL(buf, LOGICAL(CADR(args))[0], LOGICAL(CADDR(args))[0]);
if(!info)
errorcall(call, _("unable to load shared library '%s':\n %s"),
buf, DLLerror);
return(Rf_MakeDLLInfo(info));
}
SEXP attribute_hidden do_dynunload(SEXP call, SEXP op, SEXP args, SEXP env)
{
char buf[2 * PATH_MAX];
checkArity(op,args);
if (!isString(CAR(args)) || length(CAR(args)) < 1)
errorcall(call, _("character argument expected"));
GetFullDLLPath(call, buf, CHAR(STRING_ELT(CAR(args), 0)));
if(!DeleteDLL(buf))
errorcall(call, _("dynamic/shared library '%s\' was not loaded"),
buf);
return R_NilValue;
}
int R_moduleCdynload(char *module, int local, int now)
{
char dllpath[PATH_MAX], *p = getenv("R_HOME");
DllInfo *res;
if(!p) return 0;
#ifdef R_ARCH
snprintf(dllpath, PATH_MAX, "%s%smodules%s%s%s%s%s", p, FILESEP, FILESEP,
R_ARCH, FILESEP, module, SHLIB_EXT);
#else
snprintf(dllpath, PATH_MAX, "%s%smodules%s%s%s", p, FILESEP, FILESEP,
module, SHLIB_EXT);
#endif
res = AddDLL(dllpath, local, now);
if(!res)
warning(_("unable to load shared library '%s':\n %s"),
dllpath, DLLerror);
return res != NULL ? 1 : 0;
}
/**
Creates an R object representing the value of the
function pointer given by `f'. This object has class
NativeSymbol and can be used to relay symbols from
one library to another.
*/
static SEXP
Rf_MakeNativeSymbolRef(DL_FUNC f)
{
SEXP ref, klass;
/* The (void *) here is illegal C */
PROTECT(ref = R_MakeExternalPtr((void *) f, Rf_install("native symbol"),
R_NilValue));
PROTECT(klass = allocVector(STRSXP, 1));
SET_STRING_ELT(klass, 0, mkChar("NativeSymbol"));
setAttrib(ref, R_ClassSymbol, klass);
UNPROTECT(2);
return(ref);
}
static void
freeRegisteredNativeSymbolCopy(SEXP ref)
{
void *ptr;
ptr = R_ExternalPtrAddr(ref);
if (ptr)
free(ptr);
}
static SEXP
Rf_MakeRegisteredNativeSymbol(R_RegisteredNativeSymbol *symbol)
{
SEXP ref, klass;
R_RegisteredNativeSymbol *copy;
copy = (R_RegisteredNativeSymbol *) malloc(1 * sizeof(R_RegisteredNativeSymbol));
if(!copy) {
error(_("cannot allocate memory for registered native symbol (%d bytes)"),
(int) sizeof(R_RegisteredNativeSymbol));
}
*copy = *symbol;
PROTECT(ref = R_MakeExternalPtr((void *) copy,
Rf_install("registered native symbol"),
R_NilValue));
R_RegisterCFinalizer(ref, freeRegisteredNativeSymbolCopy);
PROTECT(klass = allocVector(STRSXP, 1));
SET_STRING_ELT(klass, 0, mkChar("RegisteredNativeSymbol"));
setAttrib(ref, R_ClassSymbol, klass);
UNPROTECT(2);
return(ref);
}
static SEXP
Rf_makeDllObject(HINSTANCE inst)
{
SEXP ans;
PROTECT(ans = R_MakeExternalPtr(inst, Rf_install("DLLHandle"),
R_NilValue));
setAttrib(ans, R_ClassSymbol, mkString("DLLHandle"));
UNPROTECT(1);
return(ans);
}
static SEXP
Rf_makeDllInfoReference(HINSTANCE inst)
{
SEXP ans;
PROTECT(ans = R_MakeExternalPtr(inst, Rf_install("DLLInfo"),
Rf_install("DLLInfo")));
setAttrib(ans, R_ClassSymbol, mkString("DLLInfoReference"));
UNPROTECT(1);
return(ans);
}
/**
Creates an R object representing the public DLL information stored in
info. Currently this is only the short and the long, fully qualified
name of the DLL and whether we only look for symbols that have been
registered in this DLL or do we also use dynamic lookup.
*/
static SEXP
Rf_MakeDLLInfo(DllInfo *info)
{
SEXP ref, elNames, tmp;
int i, n;
const char *const names[] = {"name", "path", "dynamicLookup",
"handle", "info"};
n = sizeof(names)/sizeof(names[0]);
PROTECT(ref = allocVector(VECSXP, n));
SET_VECTOR_ELT(ref, 0, tmp = allocVector(STRSXP, 1));
if(info->name)
SET_STRING_ELT(tmp, 0, mkChar(info->name));
SET_VECTOR_ELT(ref, 1, tmp = allocVector(STRSXP, 1));
if(info->path)
SET_STRING_ELT(tmp, 0, mkChar(info->path));
SET_VECTOR_ELT(ref, 2, ScalarLogical(info->useDynamicLookup));
SET_VECTOR_ELT(ref, 3, Rf_makeDllObject(info->handle));
SET_VECTOR_ELT(ref, 4, Rf_makeDllInfoReference((HINSTANCE) info));
PROTECT(elNames = allocVector(STRSXP, n));
for(i = 0; i < n; i++)
SET_STRING_ELT(elNames, i, mkChar(names[i]));
setAttrib(ref, R_NamesSymbol, elNames);
setAttrib(ref, R_ClassSymbol, mkString("DLLInfo"));
UNPROTECT(2);
return(ref);
}
/**
This is the routine associated with the getNativeSymbolInfo()
function and it takes the name of a symbol and optionally a
library identifier (package usually) in which to restrict the search
for this symbol. It resolves the symbol and returns it to the caller
giving the symbol address, the package information (i.e. name and
fully qualified shared library name). If the symbol was explicitly
registered (rather than dynamically resolved by R), then we pass
back that information also, giving the number of arguments it
expects and the interface by which it should be called.
The returned object has class NativeSymbol. If the symbol was
registered, we add a class identifying the interface type
for which it is intended (i.e. .C(), .Call(), etc.)
*/
SEXP attribute_hidden
R_getSymbolInfo(SEXP sname, SEXP spackage, SEXP withRegistrationInfo)
{
char *package, *name;
R_RegisteredNativeSymbol symbol = {R_ANY_SYM, {NULL}, NULL};
SEXP sym = R_NilValue;
DL_FUNC f = NULL;
package = "";
name = CHAR(STRING_ELT(sname, 0));
if(length(spackage)) {
if(TYPEOF(spackage) == STRSXP) {
package = CHAR(STRING_ELT(spackage, 0));
}
else if(TYPEOF(spackage) == EXTPTRSXP &&
R_ExternalPtrTag(spackage) == Rf_install("DLLInfo")) {
f = R_dlsym((DllInfo *)R_ExternalPtrAddr(spackage), name, &symbol);
package = NULL;
} else {
error(_("must pass package name or DllInfo reference"));
}
}
if(package)
f = R_FindSymbol(name, package, &symbol);
if(f)
sym = createRSymbolObject(sname, f, &symbol, LOGICAL(withRegistrationInfo)[0]);
return(sym);
}
SEXP attribute_hidden
R_getDllTable()
{
int i;
SEXP ans;
PROTECT(ans = allocVector(VECSXP, CountDLL));
for(i = 0; i < CountDLL; i++) {
SET_VECTOR_ELT(ans, i, Rf_MakeDLLInfo(&(LoadedDLL[i])));
}
setAttrib(ans, R_ClassSymbol, mkString("DLLInfoList"));
UNPROTECT(1);
return(ans);
}
static SEXP
createRSymbolObject(SEXP sname, DL_FUNC f, R_RegisteredNativeSymbol *symbol,
Rboolean withRegistrationInfo)
{
SEXP tmp, klass, sym, names;
int n = (symbol->type != R_ANY_SYM) ? 4 : 3;
int numProtects = 0;
PROTECT(sym = allocVector(VECSXP, n)); numProtects++;
PROTECT(names = allocVector(STRSXP, n)); numProtects++;
if(!sname || sname == R_NilValue) {
PROTECT(sname = mkString(symbol->symbol.call->name));
numProtects++;
}
SET_VECTOR_ELT(sym, 0, sname);
SET_STRING_ELT(names, 0, mkChar("name"));
SET_VECTOR_ELT(sym, 1,
withRegistrationInfo && symbol && symbol->symbol.c && symbol->dll
? Rf_MakeRegisteredNativeSymbol(symbol)
: Rf_MakeNativeSymbolRef(f));
SET_STRING_ELT(names, 1, mkChar("address"));
if(symbol->dll)
SET_VECTOR_ELT(sym, 2, Rf_MakeDLLInfo(symbol->dll));
SET_STRING_ELT(names, 2, mkChar("dll"));
PROTECT(klass = allocVector(STRSXP, (symbol->type != R_ANY_SYM ? 2 : 1)));
numProtects++;
SET_STRING_ELT(klass, length(klass)-1, mkChar("NativeSymbolInfo"));
if(n > 3) {
/* Add the registration information:
the number of arguments and the classname.
*/
int nargs = -1;
char *className = "";
switch(symbol->type) {
case R_C_SYM:
nargs = symbol->symbol.c->numArgs;
className = "CRoutine";
break;
case R_CALL_SYM:
nargs = symbol->symbol.call->numArgs;
className = "CallRoutine";
break;
case R_FORTRAN_SYM:
nargs = symbol->symbol.fortran->numArgs;
className = "FortranRoutine";
break;
case R_EXTERNAL_SYM:
nargs = symbol->symbol.external->numArgs;
className = "ExternalRoutine";
break;
default:
/* Something unintended has happened if we get here. */
error(_("Unimplemented type %d in createRSymbolObject"),
symbol->type);
break;
}
SET_VECTOR_ELT(sym, 3, tmp = ScalarInteger(nargs));
SET_STRING_ELT(klass, 0, mkChar(className));
SET_STRING_ELT(names, 3, mkChar("numParameters"));
}
setAttrib(sym, R_ClassSymbol, klass);
setAttrib(sym, R_NamesSymbol, names);
UNPROTECT(numProtects);
return(sym);
}
static SEXP
R_getRoutineSymbols(NativeSymbolType type, DllInfo *info)
{
SEXP ans;
int i, num;
R_RegisteredNativeSymbol sym;
DL_FUNC address = NULL;
sym.dll = info;
sym.type =type;
switch(type) {
case R_CALL_SYM: num = info->numCallSymbols;
break;
case R_C_SYM: num = info->numCSymbols;
break;
case R_FORTRAN_SYM: num = info->numFortranSymbols;
break;
case R_EXTERNAL_SYM: num = info->numExternalSymbols;
break;
default:
num = 0;
}
PROTECT(ans = allocVector(VECSXP, num));
for(i = 0; i < num ; i++) {
switch(type) {
case R_CALL_SYM:
sym.symbol.call = &info->CallSymbols[i];
address = sym.symbol.call->fun;
break;
case R_C_SYM:
sym.symbol.c = &info->CSymbols[i];
address = sym.symbol.c->fun;
break;
case R_FORTRAN_SYM:
sym.symbol.fortran = &info->FortranSymbols[i];
address = sym.symbol.fortran->fun;
break;
case R_EXTERNAL_SYM:
sym.symbol.external = &info->ExternalSymbols[i];
address = sym.symbol.external->fun;
break;
default:
continue;
}
SET_VECTOR_ELT(ans, i, createRSymbolObject(NULL, address, &sym, TRUE));/* XXX */
}
setAttrib(ans, R_ClassSymbol, mkString("NativeRoutineList"));
UNPROTECT(1);
return(ans);
}
SEXP attribute_hidden
R_getRegisteredRoutines(SEXP dll)
{
DllInfo *info;
SEXP ans, snames;
int i;
const char * const names[] = {".C", ".Call", ".Fortran", ".External"};
if(TYPEOF(dll) != EXTPTRSXP &&
R_ExternalPtrTag(dll) != Rf_install("DLLInfo")) {
error(_("R_getRegisteredRoutines() expects a DllInfo reference"));
}
info = (DllInfo *) R_ExternalPtrAddr(dll);
if(!info) {
error(_("NULL value passed for DllInfo"));
}
PROTECT(ans = allocVector(VECSXP, 4));
SET_VECTOR_ELT(ans, 0, R_getRoutineSymbols(R_C_SYM, info));
SET_VECTOR_ELT(ans, 1, R_getRoutineSymbols(R_CALL_SYM, info));
SET_VECTOR_ELT(ans, 2, R_getRoutineSymbols(R_FORTRAN_SYM, info));
SET_VECTOR_ELT(ans, 3, R_getRoutineSymbols(R_EXTERNAL_SYM, info));
PROTECT(snames = allocVector(STRSXP, 4));
for(i = 0; i < 4; i++) {
SET_STRING_ELT(snames, i, mkChar(names[i]));
}
setAttrib(ans, R_NamesSymbol, snames);
UNPROTECT(2);
return(ans);
}
#else /* no dyn.load support */
void InitFunctionHashing()
{
}
attribute_hidden
DL_FUNC R_FindSymbol(char const *name, char const *pkg,
R_RegisteredNativeSymbol *symbol)
{
int i;
for(i=0 ; CFunTab[i].name ; i++)
if(!strcmp(name, CFunTab[i].name))
return CFunTab[i].func;
return (DL_FUNC)0;
}
SEXP attribute_hidden do_dynload(SEXP call, SEXP op, SEXP args, SEXP env)
{
error(_("no dyn.load support in this R version"));
return(R_NilValue);
}
SEXP attribute_hidden do_dynunload(SEXP call, SEXP op, SEXP args, SEXP env)
{
error(_("no dyn.load support in this R version"));
return(R_NilValue);
}
SEXP attribute_hidden
R_getSymbolInfo(SEXP sname, SEXP spackage)
{
error(_("no dyn.load support in this R version"));
}
SEXP attribute_hidden
R_getDllTable()
{
error(_("no dyn.load support in this R version"));
}
SEXP attribute_hidden
R_getRegisteredRoutines(SEXP dll)
{
error(_("no dyn.load support in this R version"));
}
#endif
/* Experimental interface for exporting and importing functions and
data from one package for use from C code in a package. The
registration part probably ought to be integrated with the other
registrations. The naming of these routines may be less than
ideal. */
static SEXP CEntryTable = NULL;
static SEXP get_package_CEntry_table(char *package)
{
SEXP penv, pname;
if (CEntryTable == NULL) {
CEntryTable = R_NewHashedEnv(R_NilValue);
R_PreserveObject(CEntryTable);
}
pname = install(package);
penv = findVarInFrame(CEntryTable, pname);
if (penv == R_UnboundValue) {
penv = R_NewHashedEnv(R_NilValue);
defineVar(pname, penv, CEntryTable);
}
return penv;
}
void R_RegisterCCallable(char *package, char *name, DL_FUNC fptr)
{
SEXP penv = get_package_CEntry_table(package);
SEXP eptr = R_MakeExternalPtr((void *) fptr, R_NilValue, R_NilValue);
PROTECT(eptr);
defineVar(install(name), eptr, penv);
UNPROTECT(1);
}
DL_FUNC R_GetCCallable(char *package, char *name)
{
SEXP penv = get_package_CEntry_table(package);
SEXP eptr = findVarInFrame(penv, install(name));
if (eptr == R_UnboundValue)
error(_("function '%s' not provided by package '%s'"), name, package);
else if (TYPEOF(eptr) != EXTPTRSXP)
error(_("table entry must be an external pointer"));
return (DL_FUNC) R_ExternalPtrAddr(eptr);
}
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