lib/librumpuser/rumpuser_dl.c

1.31  msaitoh /*      $NetBSD: rumpuser_dl.c,v 1.31 2019/12/26 04:53:11 msaitoh Exp $	*/
 1.1    pooka
 1.1    pooka /*
 1.1    pooka  * Copyright (c) 2009 Antti Kantee.  All Rights Reserved.
 1.1    pooka  *
 1.1    pooka  * Redistribution and use in source and binary forms, with or without
 1.1    pooka  * modification, are permitted provided that the following conditions
 1.1    pooka  * are met:
 1.1    pooka  * 1. Redistributions of source code must retain the above copyright
 1.1    pooka  *    notice, this list of conditions and the following disclaimer.
 1.1    pooka  * 2. Redistributions in binary form must reproduce the above copyright
 1.1    pooka  *    notice, this list of conditions and the following disclaimer in the
 1.1    pooka  *    documentation and/or other materials provided with the distribution.
 1.1    pooka  *
 1.1    pooka  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS
 1.1    pooka  * OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
 1.1    pooka  * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
 1.1    pooka  * DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE
 1.1    pooka  * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 1.1    pooka  * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
 1.1    pooka  * SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
 1.1    pooka  * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
 1.1    pooka  * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
 1.1    pooka  * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
 1.1    pooka  * SUCH DAMAGE.
 1.1    pooka  */
 1.1    pooka
 1.1    pooka /*
 1.1    pooka  * Load all module link sets and feed symbol table to the kernel.
 1.1    pooka  * Called during rump bootstrap.
 1.1    pooka  */
 1.1    pooka
1.16    pooka /*
1.16    pooka  * Solaris libelf.h doesn't support _FILE_OFFSET_BITS=64.  Luckily,
1.16    pooka  * for this module it doesn't matter.
1.16    pooka  */
1.17    pooka #if defined(__sun__)
1.17    pooka #define RUMPUSER_NO_FILE_OFFSET_BITS
1.16    pooka #endif
 1.8    pooka #include "rumpuser_port.h"
 1.8    pooka
 1.8    pooka #if !defined(lint)
1.31  msaitoh __RCSID("$NetBSD: rumpuser_dl.c,v 1.31 2019/12/26 04:53:11 msaitoh Exp $");
 1.8    pooka #endif /* !lint */
 1.1    pooka
 1.1    pooka #include <sys/types.h>
 1.1    pooka #include <sys/time.h>
 1.8    pooka #include <assert.h>
 1.1    pooka
 1.1    pooka #include <dlfcn.h>
 1.1    pooka #include <errno.h>
 1.1    pooka #include <fcntl.h>
1.25    pooka #include <stdint.h>
 1.1    pooka #include <stdio.h>
 1.1    pooka #include <stdlib.h>
 1.1    pooka #include <string.h>
 1.1    pooka #include <unistd.h>
 1.1    pooka
 1.1    pooka #include <rump/rumpuser.h>
 1.1    pooka
1.30    pooka #if defined(__ELF__) && defined(HAVE_DLINFO)
1.22    rmind #include <elf.h>
1.12    pooka #include <link.h>
1.12    pooka
 1.1    pooka static size_t symtabsize = 0, strtabsize = 0;
 1.1    pooka static size_t symtaboff = 0, strtaboff = 0;
 1.1    pooka static uint8_t *symtab = NULL;
 1.1    pooka static char *strtab = NULL;
 1.1    pooka static unsigned char eident;
 1.1    pooka
 1.7    pooka /* nb5 compat */
 1.7    pooka #ifndef Elf_Symindx
 1.7    pooka #define Elf_Symindx uint32_t
 1.7    pooka #endif
 1.7    pooka
 1.1    pooka static void *
 1.1    pooka reservespace(void *store, size_t *storesize,
 1.1    pooka 	size_t storeoff, size_t required)
 1.1    pooka {
 1.1    pooka 	size_t chunk, newsize;
 1.1    pooka
 1.1    pooka 	assert(storeoff <= *storesize);
 1.1    pooka 	chunk = *storesize - storeoff;
 1.1    pooka
 1.1    pooka 	if (chunk >= required)
 1.1    pooka 		return store;
 1.1    pooka
 1.1    pooka 	newsize = *storesize + ((size_t)required - chunk);
 1.1    pooka 	store = realloc(store, newsize);
 1.1    pooka 	if (store == NULL) {
 1.1    pooka 		return NULL;
 1.1    pooka 	}
 1.1    pooka 	*((uint8_t *)store + storeoff) = '\0';
 1.1    pooka 	*storesize = newsize;
 1.1    pooka
 1.1    pooka 	return store;
 1.1    pooka }
 1.1    pooka
 1.1    pooka /*
 1.1    pooka  * Macros to make handling elf32/64 in the code a little saner.
 1.1    pooka  */
 1.1    pooka
 1.1    pooka #define DYNn_GETMEMBER(base, n, thevar, result)				\
 1.1    pooka do {									\
 1.1    pooka 	if (eident == ELFCLASS32) {					\
 1.9    pooka 		const Elf32_Dyn *dyn = base;				\
 1.1    pooka 		/*LINTED*/						\
 1.1    pooka 		result = dyn[n].thevar;					\
 1.1    pooka 	} else {							\
 1.9    pooka 		const Elf64_Dyn *dyn = base;				\
 1.1    pooka 		/*LINTED*/						\
 1.1    pooka 		result = dyn[n].thevar;					\
 1.1    pooka 	}								\
 1.1    pooka } while (/*CONSTCOND*/0)
 1.1    pooka
 1.1    pooka #define SYMn_GETMEMBER(base, n, thevar, result)				\
 1.1    pooka do {									\
 1.1    pooka 	if (eident == ELFCLASS32) {					\
 1.4    pooka 		const Elf32_Sym *sym = base;				\
 1.1    pooka 		/*LINTED*/						\
 1.1    pooka 		result = sym[n].thevar;					\
 1.1    pooka 	} else {							\
 1.4    pooka 		const Elf64_Sym *sym = base;				\
 1.1    pooka 		/*LINTED*/						\
 1.1    pooka 		result = sym[n].thevar;					\
 1.1    pooka 	}								\
 1.1    pooka } while (/*CONSTCOND*/0)
 1.1    pooka
 1.1    pooka #define SYMn_SETMEMBER(base, n, thevar, value)				\
 1.1    pooka do {									\
 1.1    pooka 	if (eident == ELFCLASS32) {					\
 1.1    pooka 		Elf32_Sym *sym = base;					\
 1.1    pooka 		/*LINTED*/						\
 1.1    pooka 		sym[n].thevar = value;					\
 1.1    pooka 	} else {							\
 1.1    pooka 		Elf64_Sym *sym = base;					\
 1.1    pooka 		/*LINTED*/						\
 1.1    pooka 		sym[n].thevar = value;					\
 1.1    pooka 	}								\
 1.1    pooka } while (/*CONSTCOND*/0)
 1.1    pooka
 1.1    pooka #define SYM_GETSIZE() ((eident==ELFCLASS32)?sizeof(Elf32_Sym):sizeof(Elf64_Sym))
 1.1    pooka
 1.8    pooka /*
 1.8    pooka  * On NetBSD, the dynamic section pointer values seem to be relative to
1.20    pooka  * the address the dso is mapped at.  On glibc, they seem to contain
 1.8    pooka  * the absolute address.  I couldn't find anything definite from a quick
 1.8    pooka  * read of the standard and therefore I will not go and figure beyond ifdef.
1.20    pooka  * On Solaris and DragonFly / FreeBSD, the main object works differently
1.20    pooka  * ... uuuuh.
 1.8    pooka  */
1.23    pooka #if defined(__GLIBC__) && !defined(__mips__)
 1.8    pooka #define adjptr(_map_, _ptr_) ((void *)(_ptr_))
1.19    pooka #elif defined(__sun__) || defined(__DragonFly__) || defined(__FreeBSD__)
1.13    pooka #define adjptr(_map_, _ptr_) \
1.14    pooka     (ismainobj ? (void *)(_ptr_) : (void *)(_map_->l_addr + (_ptr_)))
 1.8    pooka #else
1.21    pooka /* NetBSD and some others, e.g. Linux + musl */
 1.8    pooka #define adjptr(_map_, _ptr_) ((void *)(_map_->l_addr + (_ptr_)))
 1.8    pooka #endif
 1.8    pooka
 1.1    pooka static int
1.14    pooka getsymbols(struct link_map *map, int ismainobj)
 1.1    pooka {
 1.1    pooka 	char *str_base;
 1.1    pooka 	void *syms_base = NULL; /* XXXgcc */
 1.4    pooka 	size_t curstrsize;
 1.9    pooka 	const void *ed_base;
 1.1    pooka 	uint64_t ed_tag;
 1.4    pooka 	size_t cursymcount;
 1.4    pooka 	unsigned i;
 1.1    pooka
 1.4    pooka 	if (map->l_addr) {
 1.8    pooka 		if (memcmp((void *)map->l_addr, ELFMAG, SELFMAG) != 0)
 1.4    pooka 			return ENOEXEC;
 1.4    pooka 		eident = *(unsigned char *)(map->l_addr + EI_CLASS);
 1.4    pooka 		if (eident != ELFCLASS32 && eident != ELFCLASS64)
 1.4    pooka 			return ENOEXEC;
 1.4    pooka 	}
 1.1    pooka
 1.4    pooka 	/*
 1.4    pooka 	 * ok, we probably have only the main object.  instead of going
 1.4    pooka 	 * to disk and reading the ehdr, just try to guess the size.
 1.4    pooka 	 */
 1.4    pooka 	if (eident == 0) {
 1.4    pooka 		if (/*CONSTCOND*/sizeof(void *) == 4)
 1.4    pooka 			eident = ELFCLASS32;
 1.4    pooka 		else
 1.4    pooka 			eident = ELFCLASS64;
 1.1    pooka 	}
 1.1    pooka
 1.4    pooka 	/*
 1.4    pooka 	 * Find symtab and strtab and their sizes.
 1.4    pooka 	 */
 1.1    pooka 	str_base = NULL;
 1.4    pooka 	curstrsize = 0;
 1.4    pooka 	cursymcount = 0;
 1.1    pooka 	ed_base = map->l_ld;
 1.4    pooka 	DYNn_GETMEMBER(ed_base, 0, d_tag, ed_tag);
 1.4    pooka 	for (i = 0; ed_tag != DT_NULL;) {
 1.1    pooka 		uintptr_t edptr;
 1.1    pooka 		size_t edval;
 1.6    njoly 		Elf_Symindx *hashtab;
 1.1    pooka
 1.1    pooka 		switch (ed_tag) {
 1.1    pooka 		case DT_SYMTAB:
 1.1    pooka 			DYNn_GETMEMBER(ed_base, i, d_un.d_ptr, edptr);
 1.8    pooka 			syms_base = adjptr(map, edptr);
 1.1    pooka 			break;
 1.1    pooka 		case DT_STRTAB:
 1.1    pooka 			DYNn_GETMEMBER(ed_base, i, d_un.d_ptr, edptr);
 1.8    pooka 			str_base = adjptr(map, edptr);
 1.1    pooka 			break;
 1.1    pooka 		case DT_STRSZ:
 1.1    pooka 			DYNn_GETMEMBER(ed_base, i, d_un.d_val, edval);
 1.1    pooka 			curstrsize = edval;
 1.1    pooka 			break;
 1.4    pooka 		case DT_HASH:
 1.4    pooka 			DYNn_GETMEMBER(ed_base, i, d_un.d_ptr, edptr);
 1.8    pooka 			hashtab = (Elf_Symindx *)adjptr(map, edptr);
 1.6    njoly 			cursymcount = hashtab[1];
 1.4    pooka 			break;
1.11    pooka #ifdef DT_GNU_HASH
1.11    pooka 		/*
1.11    pooka 		 * DT_GNU_HASH is a bit more complicated than DT_HASH
1.11    pooka 		 * in this regard since apparently there is no field
1.11    pooka 		 * telling us the total symbol count.  Instead, we look
1.31  msaitoh 		 * for the last valid hash bucket and add its chain length
1.11    pooka 		 * to the bucket's base index.
1.11    pooka 		 */
1.11    pooka 		case DT_GNU_HASH: {
1.11    pooka 			Elf32_Word nbuck, symndx, maskwords, maxchain = 0;
1.11    pooka 			Elf32_Word *gnuhash, *buckets, *ptr;
1.11    pooka 			int bi;
1.11    pooka
1.11    pooka 			DYNn_GETMEMBER(ed_base, i, d_un.d_ptr, edptr);
1.11    pooka 			gnuhash = (Elf32_Word *)adjptr(map, edptr);
1.11    pooka
1.11    pooka 			nbuck = gnuhash[0];
1.11    pooka 			symndx = gnuhash[1];
1.11    pooka 			maskwords = gnuhash[2];
1.11    pooka
1.11    pooka 			/*
1.11    pooka 			 * First, find the last valid bucket and grab its index
1.11    pooka 			 */
1.11    pooka 			if (eident == ELFCLASS64)
1.11    pooka 				maskwords *= 2; /* sizeof(*buckets) == 4 */
1.11    pooka 			buckets = gnuhash + 4 + maskwords;
1.11    pooka 			for (bi = nbuck-1; bi >= 0; bi--) {
1.11    pooka 				if (buckets[bi] != 0) {
1.11    pooka 					maxchain = buckets[bi];
1.11    pooka 					break;
1.11    pooka 				}
1.11    pooka 			}
1.11    pooka 			if (maxchain == 0 || maxchain < symndx)
1.11    pooka 				break;
1.11    pooka
1.11    pooka 			/*
1.11    pooka 			 * Then, traverse the last chain and count symbols.
1.11    pooka 			 */
1.11    pooka
1.11    pooka 			cursymcount = maxchain;
1.11    pooka 			ptr = buckets + nbuck + (maxchain - symndx);
1.11    pooka 			do {
1.11    pooka 				cursymcount++;
1.11    pooka 			} while ((*ptr++ & 1) == 0);
1.11    pooka 		}
1.11    pooka 			break;
1.11    pooka #endif
 1.4    pooka 		case DT_SYMENT:
 1.4    pooka 			DYNn_GETMEMBER(ed_base, i, d_un.d_val, edval);
 1.4    pooka 			assert(edval == SYM_GETSIZE());
 1.4    pooka 			break;
 1.1    pooka 		default:
 1.1    pooka 			break;
 1.1    pooka 		}
 1.1    pooka 		i++;
 1.1    pooka 		DYNn_GETMEMBER(ed_base, i, d_tag, ed_tag);
 1.4    pooka 	}
 1.1    pooka
 1.4    pooka 	if (str_base == NULL || syms_base == NULL ||
 1.4    pooka 	    curstrsize == 0 || cursymcount == 0) {
 1.4    pooka 		fprintf(stderr, "could not find strtab, symtab or their sizes "
 1.1    pooka 		    "in %s\n", map->l_name);
 1.1    pooka 		return ENOEXEC;
 1.1    pooka 	}
 1.1    pooka
 1.1    pooka 	/*
 1.1    pooka 	 * Make sure we have enough space for the contents of the symbol
 1.1    pooka 	 * and string tables we are currently processing.  The total used
 1.1    pooka 	 * space will be smaller due to undefined symbols we are not
 1.1    pooka 	 * interested in.
 1.1    pooka 	 */
 1.4    pooka 	symtab = reservespace(symtab, &symtabsize,
 1.4    pooka 	    symtaboff, cursymcount * SYM_GETSIZE());
 1.1    pooka 	strtab = reservespace(strtab, &strtabsize, strtaboff, curstrsize);
 1.1    pooka 	if (symtab == NULL || strtab == NULL) {
 1.1    pooka 		fprintf(stderr, "failed to reserve memory");
 1.1    pooka 		return ENOMEM;
 1.1    pooka 	}
 1.1    pooka
 1.1    pooka 	/* iterate over all symbols in current symtab */
 1.4    pooka 	for (i = 0; i < cursymcount; i++) {
 1.4    pooka 		const char *cursymname;
 1.1    pooka 		int shndx, name;
 1.1    pooka 		uintptr_t value;
 1.1    pooka 		void *csym;
 1.1    pooka
 1.1    pooka 		SYMn_GETMEMBER(syms_base, i, st_shndx, shndx);
 1.1    pooka 		SYMn_GETMEMBER(syms_base, i, st_value, value);
 1.1    pooka 		if (shndx == SHN_UNDEF || value == 0)
 1.1    pooka 			continue;
 1.1    pooka
 1.1    pooka 		/* get symbol name */
 1.1    pooka 		SYMn_GETMEMBER(syms_base, i, st_name, name);
 1.1    pooka 		cursymname = name + str_base;
 1.4    pooka
 1.4    pooka 		/*
 1.4    pooka 		 * Only accept symbols which are decidedly in
 1.4    pooka 		 * the rump kernel namespace.
 1.4    pooka 		 * XXX: quirks, but they wouldn't matter here
 1.4    pooka 		 */
 1.4    pooka 		if (strncmp(cursymname, "rump", 4) != 0 &&
 1.4    pooka 		    strncmp(cursymname, "RUMP", 4) != 0 &&
 1.4    pooka 		    strncmp(cursymname, "__", 2) != 0) {
 1.4    pooka 			continue;
 1.4    pooka 		}
 1.4    pooka
 1.1    pooka 		memcpy(symtab + symtaboff,
 1.4    pooka 		    (const uint8_t *)syms_base + i*SYM_GETSIZE(),SYM_GETSIZE());
 1.1    pooka
 1.1    pooka 		/*
 1.1    pooka 		 * set name to point at new strtab, offset symbol value
 1.1    pooka 		 * with lib base address.
 1.1    pooka 		 */
 1.1    pooka 		csym = symtab + symtaboff;
 1.1    pooka 		SYMn_SETMEMBER(csym, 0, st_name, strtaboff);
 1.1    pooka 		SYMn_GETMEMBER(csym, 0, st_value, value);
 1.1    pooka 		SYMn_SETMEMBER(csym, 0, st_value,(intptr_t)(value+map->l_addr));
 1.1    pooka 		symtaboff += SYM_GETSIZE();
 1.1    pooka
 1.1    pooka 		strcpy(strtab + strtaboff, cursymname);
 1.1    pooka 		strtaboff += strlen(cursymname)+1;
 1.1    pooka 	}
 1.1    pooka
 1.1    pooka 	return 0;
 1.1    pooka }
 1.1    pooka
 1.3    pooka static void
1.13    pooka process_object(void *handle,
1.13    pooka 	rump_modinit_fn domodinit, rump_compload_fn docompload)
 1.1    pooka {
 1.3    pooka 	const struct modinfo *const *mi_start, *const *mi_end;
1.13    pooka 	struct rump_component *const *rc, *const *rc_end;
 1.1    pooka
 1.3    pooka 	mi_start = dlsym(handle, "__start_link_set_modules");
 1.1    pooka 	mi_end = dlsym(handle, "__stop_link_set_modules");
1.13    pooka 	if (mi_start && mi_end)
1.13    pooka 		domodinit(mi_start, (size_t)(mi_end-mi_start));
 1.1    pooka
1.13    pooka 	rc = dlsym(handle, "__start_link_set_rump_components");
1.13    pooka 	rc_end = dlsym(handle, "__stop_link_set_rump_components");
1.13    pooka 	if (rc && rc_end) {
1.13    pooka 		for (; rc < rc_end; rc++)
1.13    pooka 			docompload(*rc);
1.13    pooka 		assert(rc == rc_end);
1.13    pooka 	}
 1.1    pooka }
 1.1    pooka
 1.1    pooka /*
 1.1    pooka  * Get the linkmap from the dynlinker.  Try to load kernel modules
 1.1    pooka  * from all objects in the linkmap.
 1.1    pooka  */
 1.1    pooka void
 1.1    pooka rumpuser_dl_bootstrap(rump_modinit_fn domodinit,
1.13    pooka 	rump_symload_fn symload, rump_compload_fn compload)
 1.1    pooka {
1.13    pooka 	struct link_map *map, *origmap, *mainmap;
1.13    pooka 	void *mainhandle;
 1.1    pooka 	int error;
 1.1    pooka
 1.8    pooka 	mainhandle = dlopen(NULL, RTLD_NOW);
1.27   justin 	/* Will be null if statically linked so just return */
1.27   justin 	if (mainhandle == NULL)
1.27   justin 		return;
1.13    pooka 	if (dlinfo(mainhandle, RTLD_DI_LINKMAP, &mainmap) == -1) {
 1.1    pooka 		fprintf(stderr, "warning: rumpuser module bootstrap "
 1.1    pooka 		    "failed: %s\n", dlerror());
 1.1    pooka 		return;
 1.1    pooka 	}
1.13    pooka 	origmap = mainmap;
1.13    pooka
 1.1    pooka 	/*
1.26    pooka 	 * Use a heuristic to determine if we are static linked.
1.26    pooka 	 * A dynamically linked binary should always have at least
1.26    pooka 	 * two objects: itself and ld.so.
1.26    pooka 	 *
1.26    pooka 	 * In a statically linked binary with glibc the linkmap
1.26    pooka 	 * contains some "info" that leads to a segfault.  Since we
1.26    pooka 	 * can't really do anything useful in here without ld.so, just
1.26    pooka 	 * simply bail and let the symbol references in librump do the
1.26    pooka 	 * right things.
1.26    pooka 	 */
1.26    pooka 	if (origmap->l_next == NULL && origmap->l_prev == NULL) {
1.26    pooka 		dlclose(mainhandle);
1.26    pooka 		return;
1.26    pooka 	}
1.26    pooka
1.26    pooka 	/*
 1.1    pooka 	 * Process last->first because that's the most probable
 1.1    pooka 	 * order for dependencies
 1.1    pooka 	 */
 1.1    pooka 	for (; origmap->l_next; origmap = origmap->l_next)
 1.1    pooka 		continue;
 1.1    pooka
 1.1    pooka 	/*
 1.1    pooka 	 * Build symbol table to hand to the rump kernel.  Do this by
 1.1    pooka 	 * iterating over all rump libraries and collecting symbol
 1.1    pooka 	 * addresses and relocation info.
 1.1    pooka 	 */
 1.1    pooka 	error = 0;
 1.1    pooka 	for (map = origmap; map && !error; map = map->l_prev) {
1.13    pooka 		if (strstr(map->l_name, "librump") != NULL || map == mainmap)
1.14    pooka 			error = getsymbols(map, map == mainmap);
 1.1    pooka 	}
 1.1    pooka
 1.1    pooka 	if (error == 0) {
 1.1    pooka 		void *trimmedsym, *trimmedstr;
 1.1    pooka
 1.1    pooka 		/*
 1.1    pooka 		 * Allocate optimum-sized memory for storing tables
 1.1    pooka 		 * and feed to kernel.  If memory allocation fails,
 1.1    pooka 		 * just give the ones with extra context (although
 1.1    pooka 		 * I'm pretty sure we'll die moments later due to
 1.1    pooka 		 * memory running out).
 1.1    pooka 		 */
 1.1    pooka 		if ((trimmedsym = malloc(symtaboff)) != NULL) {
 1.1    pooka 			memcpy(trimmedsym, symtab, symtaboff);
 1.1    pooka 		} else {
 1.1    pooka 			trimmedsym = symtab;
 1.1    pooka 			symtab = NULL;
 1.1    pooka 		}
 1.1    pooka 		if ((trimmedstr = malloc(strtaboff)) != NULL) {
 1.1    pooka 			memcpy(trimmedstr, strtab, strtaboff);
 1.1    pooka 		} else {
 1.1    pooka 			trimmedstr = strtab;
 1.1    pooka 			strtab = NULL;
 1.1    pooka 		}
 1.1    pooka 		symload(trimmedsym, symtaboff, trimmedstr, strtaboff);
 1.1    pooka 	}
 1.1    pooka 	free(symtab);
 1.1    pooka 	free(strtab);
 1.1    pooka
 1.1    pooka 	/*
1.13    pooka 	 * Next, load modules and components.
1.13    pooka 	 *
1.13    pooka 	 * Simply loop through all objects, ones unrelated to rump kernels
1.13    pooka 	 * will not contain link_set_rump_components (well, not including
1.13    pooka 	 * "sabotage", but that needs to be solved at another level anyway).
 1.1    pooka 	 */
1.13    pooka 	for (map = origmap; map; map = map->l_prev) {
1.13    pooka 		void *handle;
 1.2    pooka
1.13    pooka 		if (map == mainmap) {
1.13    pooka 			handle = mainhandle;
1.13    pooka 		} else {
 1.2    pooka 			handle = dlopen(map->l_name, RTLD_LAZY);
 1.2    pooka 			if (handle == NULL)
 1.2    pooka 				continue;
1.13    pooka 		}
1.13    pooka 		process_object(handle, domodinit, compload);
1.13    pooka 		if (map != mainmap)
 1.2    pooka 			dlclose(handle);
 1.2    pooka 	}
 1.2    pooka }
 1.1    pooka #else
1.12    pooka /*
1.18    pooka  * no dynamic linking supported
1.12    pooka  */
 1.2    pooka void
1.13    pooka rumpuser_dl_bootstrap(rump_modinit_fn domodinit,
1.13    pooka 	rump_symload_fn symload, rump_compload_fn compload)
 1.2    pooka {
1.12    pooka
1.18    pooka 	return;
 1.2    pooka }
 1.1    pooka #endif