/*
* Copyright (c) 1991-1994 by Xerox Corporation. All rights reserved.
* Copyright (c) 1997 by Silicon Graphics. All rights reserved.
*
* THIS MATERIAL IS PROVIDED AS IS, WITH ABSOLUTELY NO WARRANTY EXPRESSED
* OR IMPLIED. ANY USE IS AT YOUR OWN RISK.
*
* Permission is hereby granted to use or copy this program
* for any purpose, provided the above notices are retained on all copies.
* Permission to modify the code and to distribute modified code is granted,
* provided the above notices are retained, and a notice that the code was
* modified is included with the above copyright notice.
*
* Original author: Bill Janssen
* Heavily modified by Hans Boehm and others
*/
/*
* This is incredibly OS specific code for tracking down data sections in
* dynamic libraries. There appears to be no way of doing this quickly
* without groveling through undocumented data structures. We would argue
* that this is a bug in the design of the dlopen interface. THIS CODE
* MAY BREAK IN FUTURE OS RELEASES. If this matters to you, don't hesitate
* to let your vendor know ...
*
* None of this is safe with dlclose and incremental collection.
* But then not much of anything is safe in the presence of dlclose.
*/
#ifndef MACOS
# include <sys/types.h>
#endif
#include "gc_priv.h"
/* BTL: avoid circular redefinition of dlopen if SOLARIS_THREADS defined */
# if defined(SOLARIS_THREADS) && defined(dlopen)
/* To support threads in Solaris, gc.h interposes on dlopen by */
/* defining "dlopen" to be "GC_dlopen", which is implemented below. */
/* However, both GC_FirstDLOpenedLinkMap() and GC_dlopen() use the */
/* real system dlopen() in their implementation. We first remove */
/* gc.h's dlopen definition and restore it later, after GC_dlopen(). */
# undef dlopen
# define GC_must_restore_redefined_dlopen
# else
# undef GC_must_restore_redefined_dlopen
# endif
#if (defined(DYNAMIC_LOADING) || defined(MSWIN32)) && !defined(PCR)
#if !defined(SUNOS4) && !defined(SUNOS5DL) && !defined(IRIX5) && \
!defined(MSWIN32) && !(defined(ALPHA) && defined(OSF1)) && \
!defined(HP_PA) && !(defined(LINUX) && defined(__ELF__)) && \
!defined(RS6000) && !defined(SCO_ELF)
--> We only know how to find data segments of dynamic libraries for the
--> above. Additional SVR4 variants might not be too
--> hard to add.
#endif
#include <stdio.h>
#ifdef SUNOS5DL
# include <sys/elf.h>
# include <dlfcn.h>
# include <link.h>
#endif
#ifdef SUNOS4
# include <dlfcn.h>
# include <link.h>
# include <a.out.h>
/* struct link_map field overrides */
# define l_next lm_next
# define l_addr lm_addr
# define l_name lm_name
#endif
#if defined(SUNOS5DL) && !defined(USE_PROC_FOR_LIBRARIES)
#ifdef LINT
Elf32_Dyn _DYNAMIC;
#endif
static struct link_map *
GC_FirstDLOpenedLinkMap()
{
extern Elf32_Dyn _DYNAMIC;
Elf32_Dyn *dp;
struct r_debug *r;
static struct link_map * cachedResult = 0;
static Elf32_Dyn *dynStructureAddr = 0;
/* BTL: added to avoid Solaris 5.3 ld.so _DYNAMIC bug */
# ifdef SUNOS53_SHARED_LIB
/* BTL: Avoid the Solaris 5.3 bug that _DYNAMIC isn't being set */
/* up properly in dynamically linked .so's. This means we have */
/* to use its value in the set of original object files loaded */
/* at program startup. */
if( dynStructureAddr == 0 ) {
void* startupSyms = dlopen(0, RTLD_LAZY);
dynStructureAddr = (Elf32_Dyn*)dlsym(startupSyms, "_DYNAMIC");
}
# else
dynStructureAddr = &_DYNAMIC;
# endif
if( dynStructureAddr == 0) {
return(0);
}
if( cachedResult == 0 ) {
int tag;
for( dp = ((Elf32_Dyn *)(&_DYNAMIC)); (tag = dp->d_tag) != 0; dp++ ) {
if( tag == DT_DEBUG ) {
struct link_map *lm
= ((struct r_debug *)(dp->d_un.d_ptr))->r_map;
if( lm != 0 ) cachedResult = lm->l_next; /* might be NIL */
break;
}
}
}
return cachedResult;
}
#endif /* SUNOS5DL ... */
#if defined(SUNOS4) && !defined(USE_PROC_FOR_LIBRARIES)
#ifdef LINT
struct link_dynamic _DYNAMIC;
#endif
static struct link_map *
GC_FirstDLOpenedLinkMap()
{
extern struct link_dynamic _DYNAMIC;
if( &_DYNAMIC == 0) {
return(0);
}
return(_DYNAMIC.ld_un.ld_1->ld_loaded);
}
/* Return the address of the ld.so allocated common symbol */
/* with the least address, or 0 if none. */
static ptr_t GC_first_common()
{
ptr_t result = 0;
extern struct link_dynamic _DYNAMIC;
struct rtc_symb * curr_symbol;
if( &_DYNAMIC == 0) {
return(0);
}
curr_symbol = _DYNAMIC.ldd -> ldd_cp;
for (; curr_symbol != 0; curr_symbol = curr_symbol -> rtc_next) {
if (result == 0
|| (ptr_t)(curr_symbol -> rtc_sp -> n_value) < result) {
result = (ptr_t)(curr_symbol -> rtc_sp -> n_value);
}
}
return(result);
}
#endif /* SUNOS4 ... */
# if defined(SUNOS4) || defined(SUNOS5DL)
/* Add dynamic library data sections to the root set. */
# if !defined(PCR) && !defined(SOLARIS_THREADS) && defined(THREADS)
# ifndef SRC_M3
--> fix mutual exclusion with dlopen
# endif /* We assume M3 programs don't call dlopen for now */
# endif
# ifdef SOLARIS_THREADS
/* Redefine dlopen to guarantee mutual exclusion with */
/* GC_register_dynamic_libraries. */
/* assumes that dlopen doesn't need to call GC_malloc */
/* and friends. */
# include <thread.h>
# include <synch.h>
void * GC_dlopen(const char *path, int mode)
{
void * result;
# ifndef USE_PROC_FOR_LIBRARIES
mutex_lock(&GC_allocate_ml);
# endif
result = dlopen(path, mode);
# ifndef USE_PROC_FOR_LIBRARIES
mutex_unlock(&GC_allocate_ml);
# endif
return(result);
}
# endif /* SOLARIS_THREADS */
/* BTL: added to fix circular dlopen definition if SOLARIS_THREADS defined */
# if defined(GC_must_restore_redefined_dlopen)
# define dlopen GC_dlopen
# endif
# ifndef USE_PROC_FOR_LIBRARIES
void GC_register_dynamic_libraries()
{
struct link_map *lm = GC_FirstDLOpenedLinkMap();
for (lm = GC_FirstDLOpenedLinkMap();
lm != (struct link_map *) 0; lm = lm->l_next)
{
# ifdef SUNOS4
struct exec *e;
e = (struct exec *) lm->lm_addr;
GC_add_roots_inner(
((char *) (N_DATOFF(*e) + lm->lm_addr)),
((char *) (N_BSSADDR(*e) + e->a_bss + lm->lm_addr)),
TRUE);
# endif
# ifdef SUNOS5DL
Elf32_Ehdr * e;
Elf32_Phdr * p;
unsigned long offset;
char * start;
register int i;
e = (Elf32_Ehdr *) lm->l_addr;
p = ((Elf32_Phdr *)(((char *)(e)) + e->e_phoff));
offset = ((unsigned long)(lm->l_addr));
for( i = 0; i < (int)(e->e_phnum); ((i++),(p++)) ) {
switch( p->p_type ) {
case PT_LOAD:
{
if( !(p->p_flags & PF_W) ) break;
start = ((char *)(p->p_vaddr)) + offset;
GC_add_roots_inner(
start,
start + p->p_memsz,
TRUE
);
}
break;
default:
break;
}
}
# endif
}
# ifdef SUNOS4
{
static ptr_t common_start = 0;
ptr_t common_end;
extern ptr_t GC_find_limit();
if (common_start == 0) common_start = GC_first_common();
if (common_start != 0) {
common_end = GC_find_limit(common_start, TRUE);
GC_add_roots_inner((char *)common_start, (char *)common_end, TRUE);
}
}
# endif
}
# endif /* !USE_PROC ... */
# endif /* SUNOS */
#if defined(LINUX) && defined(__ELF__) || defined(SCO_ELF)
/* Dynamic loading code for Linux running ELF. Somewhat tested on
* Linux/x86, untested but hopefully should work on Linux/Alpha.
* This code was derived from the Solaris/ELF support. Thanks to
* whatever kind soul wrote that. - Patrick Bridges */
#include <elf.h>
#include <link.h>
/* Newer versions of Linux/Alpha and Linux/x86 define this macro. We
* define it for those older versions that don't. */
# ifndef ElfW
# if !defined(ELF_CLASS) || ELF_CLASS == ELFCLASS32
# define ElfW(type) Elf32_##type
# else
# define ElfW(type) Elf64_##type
# endif
# endif
static struct link_map *
GC_FirstDLOpenedLinkMap()
{
extern ElfW(Dyn) _DYNAMIC[];
ElfW(Dyn) *dp;
struct r_debug *r;
static struct link_map *cachedResult = 0;
if( _DYNAMIC == 0) {
return(0);
}
if( cachedResult == 0 ) {
int tag;
for( dp = _DYNAMIC; (tag = dp->d_tag) != 0; dp++ ) {
if( tag == DT_DEBUG ) {
struct link_map *lm
= ((struct r_debug *)(dp->d_un.d_ptr))->r_map;
if( lm != 0 ) cachedResult = lm->l_next; /* might be NIL */
break;
}
}
}
return cachedResult;
}
void GC_register_dynamic_libraries()
{
struct link_map *lm = GC_FirstDLOpenedLinkMap();
for (lm = GC_FirstDLOpenedLinkMap();
lm != (struct link_map *) 0; lm = lm->l_next)
{
ElfW(Ehdr) * e;
ElfW(Phdr) * p;
unsigned long offset;
char * start;
register int i;
e = (ElfW(Ehdr) *) lm->l_addr;
p = ((ElfW(Phdr) *)(((char *)(e)) + e->e_phoff));
offset = ((unsigned long)(lm->l_addr));
for( i = 0; i < (int)(e->e_phnum); ((i++),(p++)) ) {
switch( p->p_type ) {
case PT_LOAD:
{
if( !(p->p_flags & PF_W) ) break;
start = ((char *)(p->p_vaddr)) + offset;
GC_add_roots_inner(start, start + p->p_memsz, TRUE);
}
break;
default:
break;
}
}
}
}
#endif
#if defined(IRIX5) || defined(USE_PROC_FOR_LIBRARIES)
#include <sys/procfs.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <elf.h>
#include <errno.h>
extern void * GC_roots_present();
/* The type is a lie, since the real type doesn't make sense here, */
/* and we only test for NULL. */
extern ptr_t GC_scratch_last_end_ptr; /* End of GC_scratch_alloc arena */
/* We use /proc to track down all parts of the address space that are */
/* mapped by the process, and throw out regions we know we shouldn't */
/* worry about. This may also work under other SVR4 variants. */
void GC_register_dynamic_libraries()
{
static int fd = -1;
char buf[30];
static prmap_t * addr_map = 0;
static int current_sz = 0; /* Number of records currently in addr_map */
static int needed_sz; /* Required size of addr_map */
register int i;
register long flags;
register ptr_t start;
register ptr_t limit;
ptr_t heap_start = (ptr_t)HEAP_START;
ptr_t heap_end = heap_start;
# ifdef SUNOS5DL
# define MA_PHYS 0
# endif /* SUNOS5DL */
if (fd < 0) {
sprintf(buf, "/proc/%d", getpid());
/* The above generates a lint complaint, since pid_t varies. */
/* It's unclear how to improve this. */
fd = open(buf, O_RDONLY);
if (fd < 0) {
ABORT("/proc open failed");
}
}
if (ioctl(fd, PIOCNMAP, &needed_sz) < 0) {
GC_err_printf2("fd = %d, errno = %d\n", fd, errno);
ABORT("/proc PIOCNMAP ioctl failed");
}
if (needed_sz >= current_sz) {
current_sz = needed_sz * 2 + 1;
/* Expansion, plus room for 0 record */
addr_map = (prmap_t *)GC_scratch_alloc((word)
(current_sz * sizeof(prmap_t)));
}
if (ioctl(fd, PIOCMAP, addr_map) < 0) {
GC_err_printf4("fd = %d, errno = %d, needed_sz = %d, addr_map = 0x%X\n",
fd, errno, needed_sz, addr_map);
ABORT("/proc PIOCMAP ioctl failed");
};
if (GC_n_heap_sects > 0) {
heap_end = GC_heap_sects[GC_n_heap_sects-1].hs_start
+ GC_heap_sects[GC_n_heap_sects-1].hs_bytes;
if (heap_end < GC_scratch_last_end_ptr) heap_end = GC_scratch_last_end_ptr;
}
for (i = 0; i < needed_sz; i++) {
flags = addr_map[i].pr_mflags;
if ((flags & (MA_BREAK | MA_STACK | MA_PHYS)) != 0) goto irrelevant;
if ((flags & (MA_READ | MA_WRITE)) != (MA_READ | MA_WRITE))
goto irrelevant;
/* The latter test is empirically useless. Other than the */
/* main data and stack segments, everything appears to be */
/* mapped readable, writable, executable, and shared(!!). */
/* This makes no sense to me. - HB */
start = (ptr_t)(addr_map[i].pr_vaddr);
if (GC_roots_present(start)) goto irrelevant;
if (start < heap_end && start >= heap_start)
goto irrelevant;
# ifdef MMAP_STACKS
if (GC_is_thread_stack(start)) goto irrelevant;
# endif /* MMAP_STACKS */
limit = start + addr_map[i].pr_size;
if (addr_map[i].pr_off == 0 && strncmp(start, ELFMAG, 4) == 0) {
/* Discard text segments, i.e. 0-offset mappings against */
/* executable files which appear to have ELF headers. */
caddr_t arg;
int obj;
# define MAP_IRR_SZ 10
static ptr_t map_irr[MAP_IRR_SZ];
/* Known irrelevant map entries */
static int n_irr = 0;
struct stat buf;
register int i;
for (i = 0; i < n_irr; i++) {
if (map_irr[i] == start) goto irrelevant;
}
arg = (caddr_t)start;
obj = ioctl(fd, PIOCOPENM, &arg);
if (obj >= 0) {
fstat(obj, &buf);
close(obj);
if ((buf.st_mode & 0111) != 0) {
if (n_irr < MAP_IRR_SZ) {
map_irr[n_irr++] = start;
}
goto irrelevant;
}
}
}
GC_add_roots_inner(start, limit, TRUE);
irrelevant: ;
}
/* Dont keep cached descriptor, for now. Some kernels don't like us */
/* to keep a /proc file descriptor around during kill -9. */
if (close(fd) < 0) ABORT("Couldnt close /proc file");
fd = -1;
}
# endif /* USE_PROC || IRIX5 */
# ifdef MSWIN32
# define WIN32_LEAN_AND_MEAN
# define NOSERVICE
# include <windows.h>
# include <stdlib.h>
/* We traverse the entire address space and register all segments */
/* that could possibly have been written to. */
DWORD GC_allocation_granularity;
extern GC_bool GC_is_heap_base (ptr_t p);
# ifdef WIN32_THREADS
extern void GC_get_next_stack(char *start, char **lo, char **hi);
# endif
void GC_cond_add_roots(char *base, char * limit)
{
char dummy;
char * stack_top
= (char *) ((word)(&dummy) & ~(GC_allocation_granularity-1));
if (base == limit) return;
# ifdef WIN32_THREADS
{
char * curr_base = base;
char * next_stack_lo;
char * next_stack_hi;
for(;;) {
GC_get_next_stack(curr_base, &next_stack_lo, &next_stack_hi);
if (next_stack_lo >= limit) break;
GC_add_roots_inner(curr_base, next_stack_lo, TRUE);
curr_base = next_stack_hi;
}
if (curr_base < limit) GC_add_roots_inner(curr_base, limit, TRUE);
}
# else
if (limit > stack_top && base < GC_stackbottom) {
/* Part of the stack; ignore it. */
return;
}
GC_add_roots_inner(base, limit, TRUE);
# endif
}
extern GC_bool GC_win32s;
void GC_register_dynamic_libraries()
{
MEMORY_BASIC_INFORMATION buf;
SYSTEM_INFO sysinfo;
DWORD result;
DWORD protect;
LPVOID p;
char * base;
char * limit, * new_limit;
if (GC_win32s) return;
GetSystemInfo(&sysinfo);
base = limit = p = sysinfo.lpMinimumApplicationAddress;
GC_allocation_granularity = sysinfo.dwAllocationGranularity;
while (p < sysinfo.lpMaximumApplicationAddress) {
result = VirtualQuery(p, &buf, sizeof(buf));
if (result != sizeof(buf)) {
ABORT("Weird VirtualQuery result");
}
new_limit = (char *)p + buf.RegionSize;
protect = buf.Protect;
if (buf.State == MEM_COMMIT
&& (protect == PAGE_EXECUTE_READWRITE
|| protect == PAGE_READWRITE)
&& !GC_is_heap_base(buf.AllocationBase)) {
if ((char *)p == limit) {
limit = new_limit;
} else {
GC_cond_add_roots(base, limit);
base = p;
limit = new_limit;
}
}
if (p > (LPVOID)new_limit /* overflow */) break;
p = (LPVOID)new_limit;
}
GC_cond_add_roots(base, limit);
}
#endif /* MSWIN32 */
#if defined(ALPHA) && defined(OSF1)
#include <loader.h>
void GC_register_dynamic_libraries()
{
int status;
ldr_process_t mypid;
/* module */
ldr_module_t moduleid = LDR_NULL_MODULE;
ldr_module_info_t moduleinfo;
size_t moduleinfosize = sizeof(moduleinfo);
size_t modulereturnsize;
/* region */
ldr_region_t region;
ldr_region_info_t regioninfo;
size_t regioninfosize = sizeof(regioninfo);
size_t regionreturnsize;
/* Obtain id of this process */
mypid = ldr_my_process();
/* For each module */
while (TRUE) {
/* Get the next (first) module */
status = ldr_next_module(mypid, &moduleid);
/* Any more modules? */
if (moduleid == LDR_NULL_MODULE)
break; /* No more modules */
/* Check status AFTER checking moduleid because */
/* of a bug in the non-shared ldr_next_module stub */
if (status != 0 ) {
GC_printf1("dynamic_load: status = %ld\n", (long)status);
{
extern char *sys_errlist[];
extern int sys_nerr;
extern int errno;
if (errno <= sys_nerr) {
GC_printf1("dynamic_load: %s\n", (long)sys_errlist[errno]);
} else {
GC_printf1("dynamic_load: %d\n", (long)errno);
}
}
ABORT("ldr_next_module failed");
}
/* Get the module information */
status = ldr_inq_module(mypid, moduleid, &moduleinfo,
moduleinfosize, &modulereturnsize);
if (status != 0 )
ABORT("ldr_inq_module failed");
/* is module for the main program (i.e. nonshared portion)? */
if (moduleinfo.lmi_flags & LDR_MAIN)
continue; /* skip the main module */
# ifdef VERBOSE
GC_printf("---Module---\n");
GC_printf("Module ID = %16ld\n", moduleinfo.lmi_modid);
GC_printf("Count of regions = %16d\n", moduleinfo.lmi_nregion);
GC_printf("flags for module = %16lx\n", moduleinfo.lmi_flags);
GC_printf("pathname of module = \"%s\"\n", moduleinfo.lmi_name);
# endif
/* For each region in this module */
for (region = 0; region < moduleinfo.lmi_nregion; region++) {
/* Get the region information */
status = ldr_inq_region(mypid, moduleid, region, ®ioninfo,
regioninfosize, ®ionreturnsize);
if (status != 0 )
ABORT("ldr_inq_region failed");
/* only process writable (data) regions */
if (! (regioninfo.lri_prot & LDR_W))
continue;
# ifdef VERBOSE
GC_printf("--- Region ---\n");
GC_printf("Region number = %16ld\n",
regioninfo.lri_region_no);
GC_printf("Protection flags = %016x\n", regioninfo.lri_prot);
GC_printf("Virtual address = %16p\n", regioninfo.lri_vaddr);
GC_printf("Mapped address = %16p\n", regioninfo.lri_mapaddr);
GC_printf("Region size = %16ld\n", regioninfo.lri_size);
GC_printf("Region name = \"%s\"\n", regioninfo.lri_name);
# endif
/* register region as a garbage collection root */
GC_add_roots_inner (
(char *)regioninfo.lri_mapaddr,
(char *)regioninfo.lri_mapaddr + regioninfo.lri_size,
TRUE);
}
}
}
#endif
#if defined(HP_PA)
#include <errno.h>
#include <dl.h>
extern int errno;
extern char *sys_errlist[];
extern int sys_nerr;
void GC_register_dynamic_libraries()
{
int status;
int index = 1; /* Ordinal position in shared library search list */
struct shl_descriptor *shl_desc; /* Shared library info, see dl.h */
/* For each dynamic library loaded */
while (TRUE) {
/* Get info about next shared library */
status = shl_get(index, &shl_desc);
/* Check if this is the end of the list or if some error occured */
if (status != 0) {
if (errno == EINVAL) {
break; /* Moved past end of shared library list --> finished */
} else {
if (errno <= sys_nerr) {
GC_printf1("dynamic_load: %s\n", (long) sys_errlist[errno]);
} else {
GC_printf1("dynamic_load: %d\n", (long) errno);
}
ABORT("shl_get failed");
}
}
# ifdef VERBOSE
GC_printf0("---Shared library---\n");
GC_printf1("\tfilename = \"%s\"\n", shl_desc->filename);
GC_printf1("\tindex = %d\n", index);
GC_printf1("\thandle = %08x\n",
(unsigned long) shl_desc->handle);
GC_printf1("\ttext seg. start = %08x\n", shl_desc->tstart);
GC_printf1("\ttext seg. end = %08x\n", shl_desc->tend);
GC_printf1("\tdata seg. start = %08x\n", shl_desc->dstart);
GC_printf1("\tdata seg. end = %08x\n", shl_desc->dend);
GC_printf1("\tref. count = %lu\n", shl_desc->ref_count);
# endif
/* register shared library's data segment as a garbage collection root */
GC_add_roots_inner((char *) shl_desc->dstart,
(char *) shl_desc->dend, TRUE);
index++;
}
}
#endif /* HP_PA */
#ifdef RS6000
#pragma alloca
#include <sys/ldr.h>
#include <sys/errno.h>
void GC_register_dynamic_libraries()
{
int len;
char *ldibuf;
int ldibuflen;
struct ld_info *ldi;
ldibuf = alloca(ldibuflen = 8192);
while ( (len = loadquery(L_GETINFO,ldibuf,ldibuflen)) < 0) {
if (errno != ENOMEM) {
ABORT("loadquery failed");
}
ldibuf = alloca(ldibuflen *= 2);
}
ldi = (struct ld_info *)ldibuf;
while (ldi) {
len = ldi->ldinfo_next;
GC_add_roots_inner(
ldi->ldinfo_dataorg,
(unsigned long)ldi->ldinfo_dataorg
+ ldi->ldinfo_datasize,
TRUE);
ldi = len ? (struct ld_info *)((char *)ldi + len) : 0;
}
}
#endif /* RS6000 */
#else /* !DYNAMIC_LOADING */
#ifdef PCR
# include "il/PCR_IL.h"
# include "th/PCR_ThCtl.h"
# include "mm/PCR_MM.h"
void GC_register_dynamic_libraries()
{
/* Add new static data areas of dynamically loaded modules. */
{
PCR_IL_LoadedFile * p = PCR_IL_GetLastLoadedFile();
PCR_IL_LoadedSegment * q;
/* Skip uncommited files */
while (p != NIL && !(p -> lf_commitPoint)) {
/* The loading of this file has not yet been committed */
/* Hence its description could be inconsistent. */
/* Furthermore, it hasn't yet been run. Hence its data */
/* segments can't possibly reference heap allocated */
/* objects. */
p = p -> lf_prev;
}
for (; p != NIL; p = p -> lf_prev) {
for (q = p -> lf_ls; q != NIL; q = q -> ls_next) {
if ((q -> ls_flags & PCR_IL_SegFlags_Traced_MASK)
== PCR_IL_SegFlags_Traced_on) {
GC_add_roots_inner
((char *)(q -> ls_addr),
(char *)(q -> ls_addr) + q -> ls_bytes,
TRUE);
}
}
}
}
}
#else /* !PCR */
void GC_register_dynamic_libraries(){}
int GC_no_dynamic_loading;
#endif /* !PCR */
#endif /* !DYNAMIC_LOADING */
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