sys/kern/kern_ksyms.c

     1.1     ragge /*
     1.1     ragge  * Copyright (c) 2001, 2003 Anders Magnusson (ragge (at) ludd.luth.se).
     1.1     ragge  * All rights reserved.
     1.1     ragge  *
     1.1     ragge  * Redistribution and use in source and binary forms, with or without
     1.1     ragge  * modification, are permitted provided that the following conditions
     1.1     ragge  * are met:
     1.1     ragge  * 1. Redistributions of source code must retain the above copyright
     1.1     ragge  *    notice, this list of conditions and the following disclaimer.
     1.1     ragge  * 2. Redistributions in binary form must reproduce the above copyright
     1.1     ragge  *    notice, this list of conditions and the following disclaimer in the
     1.1     ragge  *    documentation and/or other materials provided with the distribution.
     1.1     ragge  * 3. The name of the author may not be used to endorse or promote products
     1.1     ragge  *    derived from this software without specific prior written permission
     1.1     ragge  *
     1.1     ragge  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
     1.1     ragge  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
     1.1     ragge  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
     1.1     ragge  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
     1.1     ragge  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
     1.1     ragge  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
     1.1     ragge  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
     1.1     ragge  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
     1.1     ragge  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
     1.1     ragge  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
     1.1     ragge  */
     1.1     ragge
     1.1     ragge /*
     1.1     ragge  * Code to deal with in-kernel symbol table management + /dev/ksyms.
     1.1     ragge  *
     1.1     ragge  * For each loaded module the symbol table info is kept track of by a
     1.1     ragge  * struct, placed in a circular list. The first entry is the kernel
     1.1     ragge  * symbol table.
     1.1     ragge  */
     1.1     ragge
     1.1     ragge /*
     1.1     ragge  * TODO:
     1.1     ragge  *	Change the ugly way of adding new symbols (comes with linker)
     1.1     ragge  *	Add kernel locking stuff.
     1.1     ragge  *	(Ev) add support for poll.
     1.1     ragge  *	(Ev) fix support for mmap.
     1.1     ragge  *
     1.1     ragge  *	Export ksyms internal logic for use in post-mortem debuggers?
     1.1     ragge  *	  Need to move struct symtab to ksyms.h for that.
     1.1     ragge  */
    1.11  jdolecek
    1.11  jdolecek #include <sys/cdefs.h>
1.35.6.1       mjf __KERNEL_RCSID(0, "$NetBSD: kern_ksyms.c,v 1.35.6.1 2008/04/05 23:33:23 mjf Exp $");
     1.1     ragge
     1.1     ragge #ifdef _KERNEL
     1.1     ragge #include "opt_ddb.h"
     1.3     ragge #include "opt_ddbparam.h"	/* for SYMTAB_SPACE */
     1.1     ragge #endif
     1.1     ragge
     1.1     ragge #include <sys/param.h>
     1.1     ragge #include <sys/errno.h>
     1.1     ragge #include <sys/queue.h>
     1.1     ragge #include <sys/exec.h>
     1.1     ragge #include <sys/systm.h>
     1.1     ragge #include <sys/conf.h>
     1.1     ragge #include <sys/device.h>
     1.1     ragge #include <sys/malloc.h>
     1.1     ragge #include <sys/proc.h>
     1.1     ragge
     1.1     ragge #include <machine/elf_machdep.h> /* XXX */
     1.1     ragge #define ELFSIZE ARCH_ELFSIZE
     1.1     ragge
     1.1     ragge #include <sys/exec_elf.h>
     1.1     ragge #include <sys/ksyms.h>
     1.1     ragge
     1.1     ragge #include <lib/libkern/libkern.h>
     1.1     ragge
     1.1     ragge #ifdef DDB
     1.1     ragge #include <ddb/db_output.h>
     1.1     ragge #endif
     1.1     ragge
     1.1     ragge #include "ksyms.h"
     1.1     ragge
     1.1     ragge static int ksymsinited = 0;
     1.1     ragge
     1.1     ragge #if NKSYMS
    1.32  christos static void ksyms_hdr_init(void *hdraddr);
     1.1     ragge static void ksyms_sizes_calc(void);
     1.1     ragge static int ksyms_isopen;
     1.5     ragge static int ksyms_maxlen;
     1.1     ragge #endif
     1.1     ragge
     1.1     ragge #ifdef KSYMS_DEBUG
     1.1     ragge #define	FOLLOW_CALLS		1
     1.1     ragge #define	FOLLOW_MORE_CALLS	2
     1.1     ragge #define	FOLLOW_DEVKSYMS		4
     1.1     ragge static int ksyms_debug;
     1.1     ragge #endif
     1.1     ragge
     1.3     ragge #ifdef SYMTAB_SPACE
     1.3     ragge #define		SYMTAB_FILLER	"|This is the symbol table!"
     1.3     ragge
     1.3     ragge char		db_symtab[SYMTAB_SPACE] = SYMTAB_FILLER;
     1.3     ragge int		db_symtabsize = SYMTAB_SPACE;
     1.3     ragge #endif
     1.1     ragge
     1.1     ragge /*
     1.1     ragge  * Store the different symbol tables in a double-linked list.
     1.1     ragge  */
     1.1     ragge struct symtab {
     1.1     ragge 	CIRCLEQ_ENTRY(symtab) sd_queue;
     1.9  jdolecek 	const char *sd_name;	/* Name of this table */
     1.1     ragge 	Elf_Sym *sd_symstart;	/* Address of symbol table */
    1.35      matt 	Elf_Sym *sd_minsym;	/* symbol with minimum value */
    1.35      matt 	Elf_Sym *sd_maxsym;	/* symbol with maximum value */
    1.32  christos 	char *sd_strstart;	/* Address of corresponding string table */
    1.35      matt 	int *sd_symnmoff;	/* Used when calculating the name offset */
    1.17      cube 	int sd_usroffset;	/* Real address for userspace */
     1.1     ragge 	int sd_symsize;		/* Size in bytes of symbol table */
     1.1     ragge 	int sd_strsize;		/* Size of string table */
     1.1     ragge };
     1.1     ragge
     1.1     ragge static CIRCLEQ_HEAD(, symtab) symtab_queue =
     1.1     ragge     CIRCLEQ_HEAD_INITIALIZER(symtab_queue);
     1.1     ragge
     1.1     ragge static struct symtab kernel_symtab;
     1.1     ragge
     1.8     ragge #define	USE_PTREE
     1.8     ragge #ifdef USE_PTREE
     1.8     ragge /*
     1.8     ragge  * Patricia-tree-based lookup structure for the in-kernel global symbols.
     1.8     ragge  * Based on a design by Mikael Sundstrom, msm (at) sm.luth.se.
     1.8     ragge  */
     1.8     ragge struct ptree {
     1.8     ragge 	int16_t bitno;
     1.8     ragge 	int16_t lr[2];
     1.8     ragge } *symb;
     1.8     ragge static int16_t baseidx;
     1.8     ragge static int treex = 1;
     1.8     ragge
     1.8     ragge #define	P_BIT(key, bit) ((key[bit >> 3] >> (bit & 7)) & 1)
    1.32  christos #define	STRING(idx) (kernel_symtab.sd_symstart[idx].st_name + \
    1.32  christos 			kernel_symtab.sd_strstart)
     1.8     ragge
    1.33  christos static int
    1.33  christos ksyms_verify(void *symstart, void *strstart)
    1.33  christos {
    1.33  christos #if defined(DIAGNOSTIC) || defined(DEBUG)
    1.33  christos 	if (symstart == NULL)
    1.33  christos 		printf("ksyms: Symbol table not found\n");
    1.33  christos 	if (strstart == NULL)
    1.33  christos 		printf("ksyms: String table not found\n");
    1.33  christos 	if (symstart == NULL || strstart == NULL)
    1.33  christos 		printf("ksyms: Perhaps the kernel is stripped?\n");
    1.33  christos #endif
    1.33  christos 	if (symstart == NULL || strstart == NULL)
    1.33  christos 		return 0;
    1.33  christos 	KASSERT(symstart <= strstart);
    1.33  christos 	return 1;
    1.33  christos }
    1.33  christos
     1.8     ragge /*
     1.8     ragge  * Walk down the tree until a terminal node is found.
     1.8     ragge  */
     1.8     ragge static int
    1.24  christos symbol_traverse(const char *key)
     1.8     ragge {
     1.8     ragge 	int16_t nb, rbit = baseidx;
     1.8     ragge
     1.8     ragge 	while (rbit > 0) {
     1.8     ragge 		nb = symb[rbit].bitno;
     1.8     ragge 		rbit = symb[rbit].lr[P_BIT(key, nb)];
     1.8     ragge 	}
     1.8     ragge 	return -rbit;
     1.8     ragge }
     1.8     ragge
     1.8     ragge static int
     1.8     ragge ptree_add(char *key, int val)
     1.8     ragge {
     1.8     ragge 	int idx;
    1.15  christos 	int nix, cix, bit, rbit, sb, lastrbit, svbit = 0, ix;
     1.8     ragge 	char *m, *k;
     1.8     ragge
     1.8     ragge 	if (baseidx == 0) {
     1.8     ragge 		baseidx = -val;
     1.8     ragge 		return 0; /* First element */
     1.8     ragge 	}
     1.8     ragge
     1.8     ragge 	/* Get string to match against */
     1.8     ragge 	idx = symbol_traverse(key);
     1.8     ragge
     1.8     ragge 	/* Find first mismatching bit */
     1.8     ragge 	m = STRING(idx);
     1.8     ragge 	k = key;
     1.8     ragge 	if (strcmp(m, k) == 0)
     1.8     ragge 		return 1;
     1.8     ragge
     1.8     ragge 	for (cix = 0; *m && *k && *m == *k; m++, k++, cix += 8)
     1.8     ragge 		;
     1.8     ragge 	ix = ffs((int)*m ^ (int)*k) - 1;
     1.8     ragge 	cix += ix;
     1.8     ragge
     1.8     ragge 	/* Create new node */
     1.8     ragge 	nix = treex++;
     1.8     ragge 	bit = P_BIT(key, cix);
     1.8     ragge 	symb[nix].bitno = cix;
     1.8     ragge 	symb[nix].lr[bit] = -val;
     1.8     ragge
     1.8     ragge 	/* Find where to insert node */
     1.8     ragge 	rbit = baseidx;
     1.8     ragge 	lastrbit = 0;
     1.8     ragge 	for (;;) {
     1.8     ragge 		if (rbit < 0)
     1.8     ragge 			break;
     1.8     ragge 		sb = symb[rbit].bitno;
     1.8     ragge 		if (sb > cix)
     1.8     ragge 			break;
     1.8     ragge 		if (sb == cix)
     1.8     ragge 			printf("symb[rbit].bitno == cix!!!\n");
     1.8     ragge 		lastrbit = rbit;
     1.8     ragge 		svbit = P_BIT(key, sb);
     1.8     ragge 		rbit = symb[rbit].lr[svbit];
     1.8     ragge 	}
     1.8     ragge
     1.8     ragge 	/* Do the actual insertion */
     1.8     ragge 	if (lastrbit == 0) {
     1.8     ragge 		/* first element */
     1.8     ragge 		symb[nix].lr[!bit] = baseidx;
     1.8     ragge 		baseidx = nix;
     1.8     ragge 	} else {
     1.8     ragge 		symb[nix].lr[!bit] = rbit;
     1.8     ragge 		symb[lastrbit].lr[svbit] = nix;
     1.8     ragge 	}
     1.8     ragge 	return 0;
     1.8     ragge }
     1.8     ragge
     1.8     ragge static int
    1.24  christos ptree_find(const char *key)
     1.8     ragge {
     1.8     ragge 	int idx;
     1.8     ragge
     1.8     ragge 	if (baseidx == 0)
     1.8     ragge 		return 0;
     1.8     ragge 	idx = symbol_traverse(key);
     1.8     ragge
     1.8     ragge 	if (strcmp(key, STRING(idx)) == 0)
     1.8     ragge 		return idx;
     1.8     ragge 	return 0;
     1.8     ragge }
     1.8     ragge
     1.8     ragge static void
     1.8     ragge ptree_gen(char *off, struct symtab *tab)
     1.8     ragge {
     1.8     ragge 	Elf_Sym *sym;
    1.16     ragge 	int i, nsym;
     1.8     ragge
     1.8     ragge 	if (off != NULL)
     1.8     ragge 		symb = (struct ptree *)ALIGN(off);
     1.8     ragge 	else
     1.8     ragge 		symb = malloc((tab->sd_symsize/sizeof(Elf_Sym)) *
     1.8     ragge 		    sizeof(struct ptree), M_DEVBUF, M_WAITOK);
     1.8     ragge 	symb--; /* sym index won't be 0 */
     1.8     ragge
     1.8     ragge 	sym = tab->sd_symstart;
    1.16     ragge 	if ((nsym = tab->sd_symsize/sizeof(Elf_Sym)) > INT16_MAX) {
    1.16     ragge 		printf("Too many symbols for tree, skipping %d symbols\n",
    1.16     ragge 		    nsym-INT16_MAX);
    1.16     ragge 		nsym = INT16_MAX;
    1.16     ragge 	}
    1.16     ragge 	for (i = 1; i < nsym; i++) {
     1.8     ragge 		if (ELF_ST_BIND(sym[i].st_info) != STB_GLOBAL)
     1.8     ragge 			continue;
     1.8     ragge 		ptree_add(tab->sd_strstart+sym[i].st_name, i);
    1.35      matt 		if (tab->sd_minsym == NULL
    1.35      matt 		    || sym[i].st_value < tab->sd_minsym->st_value)
    1.35      matt 			tab->sd_minsym = &sym[i];
    1.35      matt 		if (tab->sd_maxsym == NULL
    1.35      matt 		    || sym[i].st_value > tab->sd_maxsym->st_value)
    1.35      matt 			tab->sd_maxsym = &sym[i];
     1.8     ragge 	}
     1.8     ragge }
    1.25   thorpej #endif /* USE_PTREE */
     1.8     ragge
     1.1     ragge /*
     1.1     ragge  * Finds a certain symbol name in a certain symbol table.
     1.1     ragge  */
     1.1     ragge static Elf_Sym *
    1.24  christos findsym(const char *name, struct symtab *table)
     1.1     ragge {
     1.1     ragge 	Elf_Sym *start = table->sd_symstart;
     1.1     ragge 	int i, sz = table->sd_symsize/sizeof(Elf_Sym);
     1.1     ragge 	char *np;
    1.32  christos 	char *realstart = table->sd_strstart - table->sd_usroffset;
     1.1     ragge
     1.8     ragge #ifdef USE_PTREE
     1.8     ragge 	if (table == &kernel_symtab && (i = ptree_find(name)) != 0)
     1.8     ragge 		return &start[i];
     1.8     ragge #endif
     1.8     ragge
     1.1     ragge 	for (i = 0; i < sz; i++) {
    1.17      cube 		np = realstart + start[i].st_name;
     1.1     ragge 		if (name[0] == np[0] && name[1] == np[1] &&
     1.1     ragge 		    strcmp(name, np) == 0)
     1.1     ragge 			return &start[i];
     1.1     ragge 	}
     1.1     ragge 	return NULL;
     1.1     ragge }
     1.1     ragge
     1.1     ragge void ksymsattach(int);
     1.1     ragge
     1.1     ragge /*
    1.29      jmmv  * Add a symbol table.
    1.29      jmmv  * This is intended for use when the symbol table and its corresponding
    1.29      jmmv  * string table are easily available.  If they are embedded in an ELF
    1.29      jmmv  * image, use addsymtab_elf() instead.
    1.29      jmmv  *
    1.29      jmmv  * name - Symbol's table name.
    1.29      jmmv  * symstart, symsize - Address and size of the symbol table.
    1.29      jmmv  * strstart, strsize - Address and size of the string table.
    1.29      jmmv  * tab - Symbol table to be updated with this information.
    1.29      jmmv  * newstart - Address to which the symbol table has to be copied during
    1.29      jmmv  *            shrinking.  If NULL, it is not moved.
     1.1     ragge  */
     1.1     ragge static void
    1.29      jmmv addsymtab(const char *name,
    1.32  christos     void *symstart, size_t symsize,
    1.32  christos     void *strstart, size_t strsize,
    1.29      jmmv     struct symtab *tab,
    1.32  christos     void *newstart)
     1.1     ragge {
    1.32  christos 	void *send;
     1.8     ragge 	Elf_Sym *sym, *nsym;
    1.29      jmmv 	int i, n, g;
     1.8     ragge 	char *str;
     1.1     ragge
    1.29      jmmv 	if (newstart == NULL)
    1.29      jmmv 		newstart = symstart;
    1.29      jmmv 	KASSERT(newstart <= symstart && symstart <= strstart);
    1.29      jmmv
    1.29      jmmv 	tab->sd_symstart = (Elf_Sym *)symstart;
    1.29      jmmv 	tab->sd_symsize = symsize;
    1.29      jmmv 	tab->sd_strstart = strstart;
    1.29      jmmv 	tab->sd_strsize = strsize;
     1.1     ragge 	tab->sd_name = name;
     1.8     ragge 	send = tab->sd_strstart + tab->sd_strsize;
     1.8     ragge
     1.8     ragge #ifdef KSYMS_DEBUG
    1.29      jmmv 	printf("newstart %p sym %p symsz %d str %p strsz %d send %p\n",
    1.29      jmmv 	    newstart, symstart, symsize, strstart, strsize, send);
     1.8     ragge #endif
     1.1     ragge
     1.8     ragge 	/*
     1.8     ragge 	 * Pack symbol table by removing all file name references
     1.8     ragge 	 * and overwrite the elf header.
     1.8     ragge 	 */
     1.8     ragge 	sym = tab->sd_symstart;
    1.29      jmmv 	nsym = (Elf_Sym *)newstart;
     1.8     ragge 	str = tab->sd_strstart;
     1.8     ragge 	for (g = i = n = 0; i < tab->sd_symsize/sizeof(Elf_Sym); i++) {
     1.8     ragge 		if (i == 0) {
     1.8     ragge 			nsym[n++] = sym[i];
     1.8     ragge 			continue;
     1.8     ragge 		}
     1.8     ragge 		/*
     1.8     ragge 		 * Remove useless symbols.
     1.8     ragge 		 * Should actually remove all typeless symbols.
     1.8     ragge 		 */
     1.5     ragge 		if (sym[i].st_name == 0)
     1.8     ragge 			continue; /* Skip nameless entries */
    1.34        ad 		if (sym[i].st_shndx == SHN_UNDEF)
    1.34        ad 			continue; /* Skip external references */
     1.8     ragge 		if (ELF_ST_TYPE(sym[i].st_info) == STT_FILE)
     1.8     ragge 			continue; /* Skip filenames */
     1.8     ragge 		if (ELF_ST_TYPE(sym[i].st_info) == STT_NOTYPE &&
     1.8     ragge 		    sym[i].st_value == 0 &&
     1.8     ragge 		    strcmp(str + sym[i].st_name, "*ABS*") == 0)
     1.8     ragge 			continue; /* XXX */
     1.8     ragge 		if (ELF_ST_TYPE(sym[i].st_info) == STT_NOTYPE &&
     1.8     ragge 		    strcmp(str + sym[i].st_name, "gcc2_compiled.") == 0)
     1.8     ragge 			continue; /* XXX */
     1.8     ragge
     1.8     ragge #ifndef DDB
     1.8     ragge 		/* Only need global symbols */
     1.8     ragge 		if (ELF_ST_BIND(sym[i].st_info) != STB_GLOBAL)
     1.5     ragge 			continue;
     1.8     ragge #endif
     1.8     ragge
     1.8     ragge 		/* Save symbol. Set it as an absolute offset */
     1.8     ragge 		nsym[n] = sym[i];
     1.8     ragge 		nsym[n].st_shndx = SHN_ABS;
     1.8     ragge 		if (ELF_ST_BIND(nsym[n].st_info) == STB_GLOBAL)
     1.8     ragge 			g++;
     1.6      tron #if NKSYMS
    1.29      jmmv 		{
    1.29      jmmv 			int j;
    1.29      jmmv 			j = strlen(nsym[n].st_name + tab->sd_strstart) + 1;
    1.29      jmmv 			if (j > ksyms_maxlen)
    1.29      jmmv 				ksyms_maxlen = j;
    1.29      jmmv 		}
     1.6      tron #endif
     1.8     ragge 		n++;
     1.8     ragge
     1.5     ragge 	}
     1.8     ragge 	tab->sd_symstart = nsym;
     1.8     ragge 	tab->sd_symsize = n * sizeof(Elf_Sym);
     1.8     ragge
     1.8     ragge #ifdef notyet
     1.8     ragge 	/*
     1.8     ragge 	 * Remove left-over strings.
     1.8     ragge 	 */
     1.8     ragge 	sym = tab->sd_symstart;
    1.32  christos 	str = (void *)tab->sd_symstart + tab->sd_symsize;
     1.8     ragge 	str[0] = 0;
     1.8     ragge 	n = 1;
     1.8     ragge 	for (i = 1; i < tab->sd_symsize/sizeof(Elf_Sym); i++) {
    1.10    itojun 		strcpy(str + n, tab->sd_strstart + sym[i].st_name);
     1.8     ragge 		sym[i].st_name = n;
     1.8     ragge 		n += strlen(str+n) + 1;
     1.8     ragge 	}
     1.8     ragge 	tab->sd_strstart = str;
     1.8     ragge 	tab->sd_strsize = n;
     1.8     ragge
     1.8     ragge #ifdef KSYMS_DEBUG
     1.8     ragge 	printf("str %p strsz %d send %p\n", str, n, send);
     1.8     ragge #endif
     1.8     ragge #endif
     1.1     ragge
     1.1     ragge 	CIRCLEQ_INSERT_HEAD(&symtab_queue, tab, sd_queue);
     1.8     ragge
     1.8     ragge #ifdef notyet
     1.8     ragge #ifdef USE_PTREE
     1.8     ragge 	/* Try to use the freed space, if possible */
     1.8     ragge 	if (send - str - n > g * sizeof(struct ptree))
     1.8     ragge 		ptree_gen(str + n, tab);
     1.8     ragge #endif
     1.8     ragge #endif
     1.1     ragge }
     1.1     ragge
     1.1     ragge /*
    1.29      jmmv  * Add a symbol table named name.
    1.29      jmmv  * This is intended for use when the kernel loader enters the table.
    1.29      jmmv  */
    1.29      jmmv static void
    1.29      jmmv addsymtab_elf(const char *name, Elf_Ehdr *ehdr, struct symtab *tab)
    1.29      jmmv {
    1.29      jmmv 	int i, j;
    1.32  christos 	char *start = (char *)ehdr;
    1.29      jmmv 	Elf_Shdr *shdr;
    1.32  christos 	char *symstart = NULL, *strstart = NULL;
    1.29      jmmv 	size_t symsize = 0, strsize = 0;
    1.29      jmmv
    1.29      jmmv 	/* Find the symbol table and the corresponding string table. */
    1.29      jmmv 	shdr = (Elf_Shdr *)(start + ehdr->e_shoff);
    1.29      jmmv 	for (i = 1; i < ehdr->e_shnum; i++) {
    1.29      jmmv 		if (shdr[i].sh_type != SHT_SYMTAB)
    1.29      jmmv 			continue;
    1.29      jmmv 		if (shdr[i].sh_offset == 0)
    1.29      jmmv 			continue;
    1.29      jmmv 		symstart = start + shdr[i].sh_offset;
    1.29      jmmv 		symsize = shdr[i].sh_size;
    1.29      jmmv 		j = shdr[i].sh_link;
    1.29      jmmv 		if (shdr[j].sh_offset == 0)
    1.29      jmmv 			continue; /* Can this happen? */
    1.29      jmmv 		strstart = start + shdr[j].sh_offset;
    1.29      jmmv 		strsize = shdr[j].sh_size;
    1.29      jmmv 		break;
    1.29      jmmv 	}
    1.29      jmmv
    1.33  christos 	if (!ksyms_verify(symstart, strstart))
    1.33  christos 		return;
    1.29      jmmv
    1.29      jmmv 	addsymtab(name, symstart, symsize, strstart, strsize, tab, start);
    1.29      jmmv }
    1.29      jmmv
    1.29      jmmv /*
     1.1     ragge  * Setup the kernel symbol table stuff.
     1.1     ragge  */
     1.1     ragge void
    1.30      yamt ksyms_init(int symsize, void *start, void *end)
     1.1     ragge {
     1.3     ragge 	Elf_Ehdr *ehdr;
     1.3     ragge
     1.3     ragge #ifdef SYMTAB_SPACE
     1.3     ragge 	if (symsize <= 0 &&
     1.3     ragge 	    strncmp(db_symtab, SYMTAB_FILLER, sizeof(SYMTAB_FILLER))) {
     1.3     ragge 		symsize = db_symtabsize;
     1.3     ragge 		start = db_symtab;
     1.3     ragge 		end = db_symtab + db_symtabsize;
     1.3     ragge 	}
     1.3     ragge #endif
     1.3     ragge 	if (symsize <= 0) {
     1.3     ragge 		printf("[ Kernel symbol table missing! ]\n");
     1.3     ragge 		return;
     1.3     ragge 	}
     1.3     ragge
     1.3     ragge 	/* Sanity check */
     1.3     ragge 	if (ALIGNED_POINTER(start, long) == 0) {
     1.3     ragge 		printf("[ Kernel symbol table has bad start address %p ]\n",
     1.3     ragge 		    start);
     1.3     ragge 		return;
     1.3     ragge 	}
     1.3     ragge
     1.3     ragge 	ehdr = (Elf_Ehdr *)start;
     1.1     ragge
     1.1     ragge 	/* check if this is a valid ELF header */
     1.1     ragge 	/* No reason to verify arch type, the kernel is actually running! */
     1.1     ragge 	if (memcmp(ehdr->e_ident, ELFMAG, SELFMAG) ||
     1.1     ragge 	    ehdr->e_ident[EI_CLASS] != ELFCLASS ||
     1.1     ragge 	    ehdr->e_version > 1) {
     1.3     ragge #ifdef notyet /* DDB */
     1.3     ragge 		if (ddb_init(symsize, start, end))
     1.3     ragge 			return; /* old-style symbol table */
     1.3     ragge #endif
     1.3     ragge 		printf("[ Kernel symbol table invalid! ]\n");
     1.1     ragge 		return; /* nothing to do */
     1.1     ragge 	}
     1.1     ragge
     1.8     ragge #if NKSYMS
     1.8     ragge 	/* Loaded header will be scratched in addsymtab */
     1.8     ragge 	ksyms_hdr_init(start);
     1.8     ragge #endif
     1.8     ragge
    1.29      jmmv 	addsymtab_elf("netbsd", ehdr, &kernel_symtab);
     1.8     ragge
     1.1     ragge #if NKSYMS
     1.1     ragge 	ksyms_sizes_calc();
     1.1     ragge #endif
     1.8     ragge
     1.1     ragge 	ksymsinited = 1;
     1.8     ragge
     1.1     ragge #ifdef DEBUG
     1.1     ragge 	printf("Loaded initial symtab at %p, strtab at %p, # entries %ld\n",
     1.1     ragge 	    kernel_symtab.sd_symstart, kernel_symtab.sd_strstart,
     1.2     ragge 	    (long)kernel_symtab.sd_symsize/sizeof(Elf_Sym));
     1.1     ragge #endif
     1.1     ragge }
     1.1     ragge
     1.1     ragge /*
    1.29      jmmv  * Setup the kernel symbol table stuff.
    1.29      jmmv  * Use this when the address of the symbol and string tables are known;
    1.29      jmmv  * otherwise use ksyms_init with an ELF image.
    1.31      jmmv  * We need to pass a minimal ELF header which will later be completed by
    1.31      jmmv  * ksyms_hdr_init and handed off to userland through /dev/ksyms.  We use
    1.32  christos  * a void *rather than a pointer to avoid exposing the Elf_Ehdr type.
    1.29      jmmv  */
    1.29      jmmv void
    1.32  christos ksyms_init_explicit(void *ehdr, void *symstart, size_t symsize,
    1.32  christos     void *strstart, size_t strsize)
    1.29      jmmv {
    1.29      jmmv
    1.33  christos 	if (!ksyms_verify(symstart, strstart))
    1.33  christos 		return;
    1.29      jmmv
    1.31      jmmv #if NKSYMS
    1.31      jmmv 	ksyms_hdr_init(ehdr);
    1.31      jmmv #endif
    1.31      jmmv
    1.29      jmmv 	addsymtab("netbsd", symstart, symsize, strstart, strsize,
    1.29      jmmv 	    &kernel_symtab, NULL);
    1.29      jmmv
    1.29      jmmv #if NKSYMS
    1.29      jmmv 	ksyms_sizes_calc();
    1.29      jmmv #endif
    1.29      jmmv
    1.29      jmmv 	ksymsinited = 1;
    1.29      jmmv }
    1.29      jmmv
    1.29      jmmv /*
     1.1     ragge  * Get the value associated with a symbol.
    1.23     perry  * "mod" is the module name, or null if any module.
     1.1     ragge  * "sym" is the symbol name.
     1.1     ragge  * "val" is a pointer to the corresponding value, if call succeeded.
     1.1     ragge  * Returns 0 if success or ENOENT if no such entry.
     1.1     ragge  */
     1.1     ragge int
    1.24  christos ksyms_getval(const char *mod, const char *sym, unsigned long *val, int type)
     1.1     ragge {
     1.1     ragge 	struct symtab *st;
     1.1     ragge 	Elf_Sym *es;
     1.1     ragge
     1.1     ragge 	if (ksymsinited == 0)
     1.1     ragge 		return ENOENT;
     1.1     ragge
     1.1     ragge #ifdef KSYMS_DEBUG
     1.1     ragge 	if (ksyms_debug & FOLLOW_CALLS)
     1.1     ragge 		printf("ksyms_getval: mod %s sym %s valp %p\n", mod, sym, val);
     1.1     ragge #endif
     1.1     ragge
     1.1     ragge 	CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) {
     1.1     ragge 		if (mod && strcmp(st->sd_name, mod))
     1.1     ragge 			continue;
    1.22      cube 		if ((es = findsym(sym, st)) == NULL)
     1.1     ragge 			continue;
    1.34        ad 		if (es->st_shndx == SHN_UNDEF)
    1.34        ad 			continue;
     1.1     ragge
     1.1     ragge 		/* Skip if bad binding */
     1.1     ragge 		if (type == KSYMS_EXTERN &&
     1.1     ragge 		    ELF_ST_BIND(es->st_info) != STB_GLOBAL)
     1.1     ragge 			continue;
     1.1     ragge
     1.1     ragge 		if (val)
     1.1     ragge 			*val = es->st_value;
     1.1     ragge 		return 0;
     1.1     ragge 	}
     1.1     ragge 	return ENOENT;
     1.1     ragge }
     1.1     ragge
     1.1     ragge /*
     1.1     ragge  * Get "mod" and "symbol" associated with an address.
     1.1     ragge  * Returns 0 if success or ENOENT if no such entry.
     1.1     ragge  */
     1.1     ragge int
    1.24  christos ksyms_getname(const char **mod, const char **sym, vaddr_t v, int f)
     1.1     ragge {
     1.1     ragge 	struct symtab *st;
     1.1     ragge 	Elf_Sym *les, *es = NULL;
     1.1     ragge 	vaddr_t laddr = 0;
    1.15  christos 	const char *lmod = NULL;
    1.15  christos 	char *stable = NULL;
     1.1     ragge 	int type, i, sz;
     1.1     ragge
     1.1     ragge 	if (ksymsinited == 0)
     1.1     ragge 		return ENOENT;
     1.1     ragge
     1.1     ragge 	CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) {
    1.35      matt 		if (st->sd_minsym != NULL && v < st->sd_minsym->st_value)
    1.35      matt 			continue;
    1.35      matt 		if (st->sd_maxsym != NULL && v > st->sd_maxsym->st_value)
    1.35      matt 			continue;
     1.1     ragge 		sz = st->sd_symsize/sizeof(Elf_Sym);
     1.1     ragge 		for (i = 0; i < sz; i++) {
     1.1     ragge 			les = st->sd_symstart + i;
     1.1     ragge 			type = ELF_ST_TYPE(les->st_info);
     1.1     ragge
     1.1     ragge 			if ((f & KSYMS_PROC) && (type != STT_FUNC))
     1.1     ragge 				continue;
     1.1     ragge
     1.1     ragge 			if (type == STT_NOTYPE)
     1.1     ragge 				continue;
     1.1     ragge
     1.1     ragge 			if (((f & KSYMS_ANY) == 0) &&
     1.1     ragge 			    (type != STT_FUNC) && (type != STT_OBJECT))
     1.1     ragge 				continue;
     1.1     ragge
     1.1     ragge 			if ((les->st_value <= v) && (les->st_value > laddr)) {
     1.1     ragge 				laddr = les->st_value;
     1.1     ragge 				es = les;
     1.1     ragge 				lmod = st->sd_name;
    1.17      cube 				stable = st->sd_strstart - st->sd_usroffset;
     1.1     ragge 			}
     1.1     ragge 		}
     1.1     ragge 	}
     1.1     ragge 	if (es == NULL)
     1.1     ragge 		return ENOENT;
     1.1     ragge 	if ((f & KSYMS_EXACT) && (v != es->st_value))
     1.1     ragge 		return ENOENT;
     1.1     ragge 	if (mod)
     1.1     ragge 		*mod = lmod;
     1.1     ragge 	if (sym)
     1.1     ragge 		*sym = stable + es->st_name;
     1.1     ragge 	return 0;
     1.1     ragge }
     1.1     ragge
     1.1     ragge #if NKSYMS
     1.1     ragge static int symsz, strsz;
     1.1     ragge
    1.22      cube /*
    1.22      cube  * In case we exposing the symbol table to the userland using the pseudo-
    1.22      cube  * device /dev/ksyms, it is easier to provide all the tables as one.
    1.22      cube  * However, it means we have to change all the st_name fields for the
    1.22      cube  * symbols so they match the ELF image that the userland will read
    1.22      cube  * through the device.
    1.22      cube  *
    1.22      cube  * The actual (correct) value of st_name is preserved through a global
    1.22      cube  * offset stored in the symbol table structure.
    1.22      cube  */
    1.22      cube
     1.1     ragge static void
     1.1     ragge ksyms_sizes_calc(void)
    1.23     perry {
    1.23     perry         struct symtab *st;
     1.1     ragge 	int i;
     1.1     ragge
     1.1     ragge         symsz = strsz = 0;
     1.1     ragge         CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) {
     1.1     ragge 		if (st != &kernel_symtab) {
     1.1     ragge 			for (i = 0; i < st->sd_symsize/sizeof(Elf_Sym); i++)
     1.1     ragge 				st->sd_symstart[i].st_name =
     1.1     ragge 				    strsz + st->sd_symnmoff[i];
    1.17      cube 			st->sd_usroffset = strsz;
     1.1     ragge 		}
     1.1     ragge                 symsz += st->sd_symsize;
     1.1     ragge                 strsz += st->sd_strsize;
    1.17      cube         }
     1.1     ragge }
    1.25   thorpej #endif /* NKSYMS */
     1.1     ragge
     1.1     ragge /*
    1.20      matt  * Temporary work structure for dynamic loaded symbol tables.
     1.1     ragge  * Will go away when in-kernel linker is in place.
     1.1     ragge  */
    1.20      matt
    1.20      matt struct syminfo {
    1.20      matt 	size_t cursyms;
    1.20      matt 	size_t curnamep;
    1.20      matt 	size_t maxsyms;
    1.20      matt 	size_t maxnamep;
    1.20      matt 	Elf_Sym *syms;
    1.20      matt 	int *symnmoff;
    1.20      matt 	char *symnames;
    1.20      matt };
    1.23     perry
     1.1     ragge
     1.1     ragge /*
     1.1     ragge  * Add a symbol to the temporary save area for symbols.
     1.1     ragge  * This routine will go away when the in-kernel linker is in place.
     1.1     ragge  */
     1.1     ragge static void
    1.20      matt addsym(struct syminfo *info, const Elf_Sym *sym, const char *name,
    1.20      matt        const char *mod)
     1.1     ragge {
    1.20      matt 	int len, mlen;
     1.1     ragge
     1.1     ragge #ifdef KSYMS_DEBUG
     1.1     ragge 	if (ksyms_debug & FOLLOW_MORE_CALLS)
     1.1     ragge 		printf("addsym: name %s val %lx\n", name, (long)sym->st_value);
     1.1     ragge #endif
    1.20      matt 	len = strlen(name) + 1;
    1.20      matt 	if (mod)
    1.20      matt 		mlen = 1 + strlen(mod);
    1.20      matt 	else
    1.20      matt 		mlen = 0;
    1.23     perry 	if (info->cursyms == info->maxsyms ||
    1.20      matt 	    (len + mlen + info->curnamep) > info->maxnamep) {
    1.19      matt 		printf("addsym: too many symbols, skipping '%s'\n", name);
     1.1     ragge 		return;
     1.1     ragge 	}
    1.20      matt 	strlcpy(&info->symnames[info->curnamep], name,
    1.20      matt 	    info->maxnamep - info->curnamep);
    1.20      matt 	if (mlen) {
    1.20      matt 		info->symnames[info->curnamep + len - 1] = '.';
    1.20      matt 		strlcpy(&info->symnames[info->curnamep + len], mod,
    1.20      matt 		    info->maxnamep - (info->curnamep + len));
    1.20      matt 		len += mlen;
    1.20      matt 	}
    1.20      matt 	info->syms[info->cursyms] = *sym;
    1.20      matt 	info->syms[info->cursyms].st_name = info->curnamep;
    1.20      matt 	info->symnmoff[info->cursyms] = info->curnamep;
    1.20      matt 	info->curnamep += len;
     1.7     ragge #if NKSYMS
     1.5     ragge 	if (len > ksyms_maxlen)
     1.5     ragge 		ksyms_maxlen = len;
     1.6      tron #endif
    1.20      matt 	info->cursyms++;
     1.1     ragge }
     1.1     ragge /*
     1.1     ragge  * Adds a symbol table.
     1.1     ragge  * "name" is the module name, "start" and "size" is where the symbol table
     1.1     ragge  * is located, and "type" is in which binary format the symbol table is.
     1.1     ragge  * New memory for keeping the symbol table is allocated in this function.
     1.1     ragge  * Returns 0 if success and EEXIST if the module name is in use.
     1.1     ragge  */
    1.21      matt static int
    1.21      matt specialsym(const char *symname)
    1.21      matt {
    1.21      matt 	return	!strcmp(symname, "_bss_start") ||
    1.21      matt 		!strcmp(symname, "__bss_start") ||
    1.21      matt 		!strcmp(symname, "_bss_end__") ||
    1.21      matt 		!strcmp(symname, "__bss_end__") ||
    1.21      matt 		!strcmp(symname, "_edata") ||
    1.21      matt 		!strcmp(symname, "_end") ||
    1.21      matt 		!strcmp(symname, "__end") ||
    1.21      matt 		!strcmp(symname, "__end__") ||
    1.21      matt 		!strncmp(symname, "__start_link_set_", 17) ||
    1.21      matt 		!strncmp(symname, "__stop_link_set_", 16);
    1.21      matt }
    1.21      matt
     1.1     ragge int
     1.9  jdolecek ksyms_addsymtab(const char *mod, void *symstart, vsize_t symsize,
    1.30      yamt     char *strstart, vsize_t strsize)
     1.1     ragge {
     1.1     ragge 	Elf_Sym *sym = symstart;
     1.1     ragge 	struct symtab *st;
    1.14     ragge 	unsigned long rval;
     1.1     ragge 	int i;
    1.20      matt 	char *name;
    1.20      matt 	struct syminfo info;
     1.1     ragge
     1.1     ragge #ifdef KSYMS_DEBUG
     1.1     ragge 	if (ksyms_debug & FOLLOW_CALLS)
     1.1     ragge 		printf("ksyms_addsymtab: mod %s symsize %lx strsize %lx\n",
     1.1     ragge 		    mod, symsize, strsize);
     1.1     ragge #endif
     1.1     ragge
     1.1     ragge #if NKSYMS
     1.1     ragge 	/*
     1.1     ragge 	 * Do not try to add a symbol table while someone is reading
     1.1     ragge 	 * from /dev/ksyms.
     1.1     ragge 	 */
     1.1     ragge 	while (ksyms_isopen != 0)
     1.1     ragge 		tsleep(&ksyms_isopen, PWAIT, "ksyms", 0);
     1.1     ragge #endif
     1.1     ragge
     1.1     ragge 	/* Check if this symtab already loaded */
     1.1     ragge 	CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) {
     1.1     ragge 		if (strcmp(mod, st->sd_name) == 0)
     1.1     ragge 			return EEXIST;
     1.1     ragge 	}
     1.1     ragge
     1.1     ragge 	/*
     1.1     ragge 	 * XXX - Only add a symbol if it do not exist already.
     1.1     ragge 	 * This is because of a flaw in the current LKM implementation,
    1.20      matt 	 * these loops will be removed once the in-kernel linker is in place.
     1.1     ragge 	 */
    1.20      matt 	memset(&info, 0, sizeof(info));
     1.1     ragge 	for (i = 0; i < symsize/sizeof(Elf_Sym); i++) {
    1.20      matt 		char * const symname = strstart + sym[i].st_name;
     1.1     ragge 		if (sym[i].st_name == 0)
     1.1     ragge 			continue; /* Just ignore */
     1.1     ragge
     1.1     ragge 		/* check validity of the symbol */
     1.1     ragge 		/* XXX - save local symbols if DDB */
     1.1     ragge 		if (ELF_ST_BIND(sym[i].st_info) != STB_GLOBAL)
     1.1     ragge 			continue;
    1.23     perry
     1.1     ragge 		/* Check if the symbol exists */
    1.22      cube 		if (ksyms_getval(NULL, symname, &rval, KSYMS_EXTERN) == 0) {
     1.1     ragge 			/* Check (and complain) about differing values */
    1.34        ad 			if (sym[i].st_value != rval &&
    1.34        ad 			    sym[i].st_shndx != SHN_UNDEF) {
    1.21      matt 				if (specialsym(symname)) {
    1.20      matt 					info.maxsyms++;
    1.20      matt 					info.maxnamep += strlen(symname) + 1 +
    1.20      matt 					    strlen(mod) + 1;
    1.20      matt 				} else {
    1.20      matt 					printf("%s: symbol '%s' redeclared with"
    1.20      matt 					    " different value (%lx != %lx)\n",
    1.20      matt 					    mod, symname,
    1.20      matt 					    rval, (long)sym[i].st_value);
    1.20      matt 				}
    1.20      matt 			}
    1.20      matt 		} else {
    1.20      matt 			/*
    1.20      matt 			 * Count this symbol
    1.20      matt 			 */
    1.20      matt 			info.maxsyms++;
    1.20      matt 			info.maxnamep += strlen(symname) + 1;
    1.20      matt 		}
    1.20      matt 	}
    1.20      matt
    1.20      matt 	/*
    1.20      matt 	 * Now that we know the sizes, malloc the structures.
    1.20      matt 	 */
    1.20      matt 	info.syms = malloc(sizeof(Elf_Sym)*info.maxsyms, M_DEVBUF, M_WAITOK);
    1.20      matt 	info.symnames = malloc(info.maxnamep, M_DEVBUF, M_WAITOK);
    1.20      matt 	info.symnmoff = malloc(sizeof(int)*info.maxsyms, M_DEVBUF, M_WAITOK);
    1.20      matt
    1.20      matt 	/*
    1.20      matt 	 * Now that we have the symbols, actually fill in the structures.
    1.20      matt 	 */
    1.20      matt 	for (i = 0; i < symsize/sizeof(Elf_Sym); i++) {
    1.20      matt 		char * const symname = strstart + sym[i].st_name;
    1.20      matt 		if (sym[i].st_name == 0)
    1.20      matt 			continue; /* Just ignore */
    1.20      matt
    1.20      matt 		/* check validity of the symbol */
    1.20      matt 		/* XXX - save local symbols if DDB */
    1.20      matt 		if (ELF_ST_BIND(sym[i].st_info) != STB_GLOBAL)
    1.20      matt 			continue;
    1.23     perry
    1.20      matt 		/* Check if the symbol exists */
    1.22      cube 		if (ksyms_getval(NULL, symname, &rval, KSYMS_EXTERN) == 0) {
    1.21      matt 			if ((sym[i].st_value != rval) && specialsym(symname)) {
    1.20      matt 				addsym(&info, &sym[i], symname, mod);
     1.1     ragge 			}
     1.1     ragge 		} else
     1.1     ragge 			/* Ok, save this symbol */
    1.20      matt 			addsym(&info, &sym[i], symname, NULL);
     1.1     ragge 	}
     1.5     ragge
     1.1     ragge 	st = malloc(sizeof(struct symtab), M_DEVBUF, M_WAITOK);
    1.10    itojun 	i = strlen(mod) + 1;
    1.10    itojun 	name = malloc(i, M_DEVBUF, M_WAITOK);
    1.10    itojun 	strlcpy(name, mod, i);
     1.9  jdolecek 	st->sd_name = name;
    1.20      matt 	st->sd_symnmoff = info.symnmoff;
    1.20      matt 	st->sd_symstart = info.syms;
    1.20      matt 	st->sd_symsize = sizeof(Elf_Sym)*info.maxsyms;
    1.20      matt 	st->sd_strstart = info.symnames;
    1.20      matt 	st->sd_strsize = info.maxnamep;
     1.1     ragge
     1.1     ragge 	/* Make them absolute references */
     1.1     ragge 	sym = st->sd_symstart;
     1.1     ragge 	for (i = 0; i < st->sd_symsize/sizeof(Elf_Sym); i++)
     1.1     ragge 		sym[i].st_shndx = SHN_ABS;
     1.1     ragge
     1.1     ragge 	CIRCLEQ_INSERT_TAIL(&symtab_queue, st, sd_queue);
     1.1     ragge #if NKSYMS
     1.1     ragge 	ksyms_sizes_calc();
     1.1     ragge #endif
     1.1     ragge 	return 0;
     1.1     ragge }
     1.1     ragge
     1.1     ragge /*
     1.1     ragge  * Remove a symbol table specified by name.
     1.1     ragge  * Returns 0 if success, EBUSY if device open and ENOENT if no such name.
     1.1     ragge  */
     1.1     ragge int
     1.9  jdolecek ksyms_delsymtab(const char *mod)
     1.1     ragge {
     1.1     ragge 	struct symtab *st;
     1.1     ragge 	int found = 0;
     1.1     ragge
     1.1     ragge #if NKSYMS
     1.1     ragge 	/*
     1.1     ragge 	 * Do not try to delete a symbol table while someone is reading
     1.1     ragge 	 * from /dev/ksyms.
     1.1     ragge 	 */
     1.1     ragge 	while (ksyms_isopen != 0)
     1.1     ragge 		tsleep(&ksyms_isopen, PWAIT, "ksyms", 0);
     1.1     ragge #endif
     1.1     ragge
     1.1     ragge 	CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) {
     1.1     ragge 		if (strcmp(mod, st->sd_name) == 0) {
     1.1     ragge 			found = 1;
     1.1     ragge 			break;
     1.1     ragge 		}
     1.1     ragge 	}
     1.1     ragge 	if (found == 0)
     1.1     ragge 		return ENOENT;
     1.1     ragge 	CIRCLEQ_REMOVE(&symtab_queue, st, sd_queue);
     1.1     ragge 	free(st->sd_symstart, M_DEVBUF);
     1.1     ragge 	free(st->sd_strstart, M_DEVBUF);
     1.1     ragge 	free(st->sd_symnmoff, M_DEVBUF);
    1.24  christos 	/* XXXUNCONST LINTED - const castaway */
    1.24  christos 	free(__UNCONST(st->sd_name), M_DEVBUF);
     1.1     ragge 	free(st, M_DEVBUF);
     1.1     ragge #if NKSYMS
     1.1     ragge 	ksyms_sizes_calc();
     1.1     ragge #endif
     1.1     ragge 	return 0;
     1.1     ragge }
     1.1     ragge
    1.17      cube int
    1.17      cube ksyms_rensymtab(const char *old, const char *new)
    1.17      cube {
    1.17      cube 	struct symtab *st, *oldst = NULL;
    1.17      cube 	char *newstr;
    1.17      cube
    1.17      cube 	CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) {
    1.17      cube 		if (strcmp(old, st->sd_name) == 0)
    1.17      cube 			oldst = st;
    1.17      cube 		if (strcmp(new, st->sd_name) == 0)
    1.17      cube 			return (EEXIST);
    1.17      cube 	}
    1.17      cube 	if (oldst == NULL)
    1.17      cube 		return (ENOENT);
    1.17      cube
    1.17      cube 	newstr = malloc(strlen(new)+1, M_DEVBUF, M_WAITOK);
    1.17      cube 	if (!newstr)
    1.17      cube 		return (ENOMEM);
    1.17      cube 	strcpy(newstr, new);
    1.24  christos 	/*XXXUNCONST*/
    1.24  christos 	free(__UNCONST(oldst->sd_name), M_DEVBUF);
    1.17      cube 	oldst->sd_name = newstr;
    1.17      cube
    1.17      cube 	return (0);
    1.17      cube }
    1.17      cube
     1.1     ragge #ifdef DDB
     1.1     ragge /*
     1.1     ragge  * Keep sifting stuff here, to avoid export of ksyms internals.
     1.1     ragge  */
     1.1     ragge int
     1.1     ragge ksyms_sift(char *mod, char *sym, int mode)
     1.1     ragge {
     1.1     ragge 	struct symtab *st;
     1.1     ragge 	char *sb;
     1.1     ragge 	int i, sz;
     1.1     ragge
     1.1     ragge 	if (ksymsinited == 0)
     1.1     ragge 		return ENOENT;
     1.1     ragge
     1.1     ragge 	CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) {
     1.1     ragge 		if (mod && strcmp(mod, st->sd_name))
     1.1     ragge 			continue;
     1.1     ragge 		sb = st->sd_strstart;
     1.1     ragge
     1.1     ragge 		sz = st->sd_symsize/sizeof(Elf_Sym);
     1.1     ragge 		for (i = 0; i < sz; i++) {
     1.1     ragge 			Elf_Sym *les = st->sd_symstart + i;
     1.1     ragge 			char c;
     1.1     ragge
    1.17      cube 			if (strstr(sb + les->st_name - st->sd_usroffset, sym)
    1.17      cube 			    == NULL)
     1.1     ragge 				continue;
     1.1     ragge
     1.1     ragge 			if (mode == 'F') {
     1.1     ragge 				switch (ELF_ST_TYPE(les->st_info)) {
     1.1     ragge 				case STT_OBJECT:
     1.1     ragge 					c = '+';
     1.1     ragge 					break;
     1.1     ragge 				case STT_FUNC:
     1.1     ragge 					c = '*';
     1.1     ragge 					break;
     1.1     ragge 				case STT_SECTION:
     1.1     ragge 					c = '&';
     1.1     ragge 					break;
     1.1     ragge 				case STT_FILE:
     1.1     ragge 					c = '/';
     1.1     ragge 					break;
     1.1     ragge 				default:
     1.1     ragge 					c = ' ';
     1.1     ragge 					break;
     1.1     ragge 				}
    1.17      cube 				db_printf("%s%c ", sb + les->st_name -
    1.17      cube 				    st->sd_usroffset, c);
     1.1     ragge 			} else
    1.17      cube 				db_printf("%s ", sb + les->st_name -
    1.17      cube 				    st->sd_usroffset);
     1.1     ragge 		}
     1.1     ragge 	}
     1.1     ragge 	return ENOENT;
     1.1     ragge }
    1.25   thorpej #endif /* DDB */
     1.1     ragge
     1.1     ragge #if NKSYMS
     1.1     ragge /*
     1.1     ragge  * Static allocated ELF header.
     1.1     ragge  * Basic info is filled in at attach, sizes at open.
     1.1     ragge  */
     1.1     ragge #define	SYMTAB		1
     1.1     ragge #define	STRTAB		2
     1.1     ragge #define	SHSTRTAB	3
     1.1     ragge #define NSECHDR		4
     1.1     ragge
     1.1     ragge #define	NPRGHDR		2
     1.1     ragge #define	SHSTRSIZ	28
     1.1     ragge
     1.1     ragge static struct ksyms_hdr {
     1.1     ragge 	Elf_Ehdr	kh_ehdr;
     1.1     ragge 	Elf_Phdr	kh_phdr[NPRGHDR];
     1.1     ragge 	Elf_Shdr	kh_shdr[NSECHDR];
     1.1     ragge 	char 		kh_strtab[SHSTRSIZ];
     1.1     ragge } ksyms_hdr;
     1.1     ragge
     1.1     ragge
    1.25   thorpej static void
    1.32  christos ksyms_hdr_init(void *hdraddr)
     1.1     ragge {
     1.1     ragge
     1.1     ragge 	/* Copy the loaded elf exec header */
     1.1     ragge 	memcpy(&ksyms_hdr.kh_ehdr, hdraddr, sizeof(Elf_Ehdr));
     1.1     ragge
     1.1     ragge 	/* Set correct program/section header sizes, offsets and numbers */
     1.1     ragge 	ksyms_hdr.kh_ehdr.e_phoff = offsetof(struct ksyms_hdr, kh_phdr[0]);
     1.1     ragge 	ksyms_hdr.kh_ehdr.e_phentsize = sizeof(Elf_Phdr);
     1.1     ragge 	ksyms_hdr.kh_ehdr.e_phnum = NPRGHDR;
     1.1     ragge 	ksyms_hdr.kh_ehdr.e_shoff = offsetof(struct ksyms_hdr, kh_shdr[0]);
     1.1     ragge 	ksyms_hdr.kh_ehdr.e_shentsize = sizeof(Elf_Shdr);
     1.1     ragge 	ksyms_hdr.kh_ehdr.e_shnum = NSECHDR;
     1.1     ragge 	ksyms_hdr.kh_ehdr.e_shstrndx = NSECHDR - 1; /* Last section */
     1.1     ragge
     1.1     ragge 	/*
     1.1     ragge 	 * Keep program headers zeroed (unused).
     1.1     ragge 	 * The section headers are hand-crafted.
     1.1     ragge 	 * First section is section zero.
     1.1     ragge 	 */
     1.1     ragge
     1.1     ragge 	/* Second section header; ".symtab" */
     1.1     ragge 	ksyms_hdr.kh_shdr[SYMTAB].sh_name = 1; /* Section 3 offset */
     1.1     ragge 	ksyms_hdr.kh_shdr[SYMTAB].sh_type = SHT_SYMTAB;
     1.1     ragge 	ksyms_hdr.kh_shdr[SYMTAB].sh_offset = sizeof(struct ksyms_hdr);
     1.1     ragge /*	ksyms_hdr.kh_shdr[SYMTAB].sh_size = filled in at open */
     1.1     ragge 	ksyms_hdr.kh_shdr[SYMTAB].sh_link = 2; /* Corresponding strtab */
     1.1     ragge 	ksyms_hdr.kh_shdr[SYMTAB].sh_info = 0; /* XXX */
     1.1     ragge 	ksyms_hdr.kh_shdr[SYMTAB].sh_addralign = sizeof(long);
     1.1     ragge 	ksyms_hdr.kh_shdr[SYMTAB].sh_entsize = sizeof(Elf_Sym);
     1.1     ragge
     1.1     ragge 	/* Third section header; ".strtab" */
     1.1     ragge 	ksyms_hdr.kh_shdr[STRTAB].sh_name = 9; /* Section 3 offset */
     1.1     ragge 	ksyms_hdr.kh_shdr[STRTAB].sh_type = SHT_STRTAB;
     1.1     ragge /*	ksyms_hdr.kh_shdr[STRTAB].sh_offset = filled in at open */
     1.1     ragge /*	ksyms_hdr.kh_shdr[STRTAB].sh_size = filled in at open */
     1.1     ragge /*	ksyms_hdr.kh_shdr[STRTAB].sh_link = kept zero */
     1.1     ragge 	ksyms_hdr.kh_shdr[STRTAB].sh_info = 0;
     1.1     ragge 	ksyms_hdr.kh_shdr[STRTAB].sh_addralign = sizeof(char);
     1.1     ragge 	ksyms_hdr.kh_shdr[STRTAB].sh_entsize = 0;
     1.1     ragge
     1.1     ragge 	/* Fourth section, ".shstrtab" */
     1.1     ragge 	ksyms_hdr.kh_shdr[SHSTRTAB].sh_name = 17; /* This section name offset */
     1.1     ragge 	ksyms_hdr.kh_shdr[SHSTRTAB].sh_type = SHT_STRTAB;
     1.1     ragge 	ksyms_hdr.kh_shdr[SHSTRTAB].sh_offset =
     1.1     ragge 	    offsetof(struct ksyms_hdr, kh_strtab);
     1.1     ragge 	ksyms_hdr.kh_shdr[SHSTRTAB].sh_size = SHSTRSIZ;
     1.1     ragge 	ksyms_hdr.kh_shdr[SHSTRTAB].sh_addralign = sizeof(char);
     1.1     ragge
     1.1     ragge 	/* Set section names */
    1.10    itojun 	strlcpy(&ksyms_hdr.kh_strtab[1], ".symtab",
    1.10    itojun 	    sizeof(ksyms_hdr.kh_strtab) - 1);
    1.10    itojun 	strlcpy(&ksyms_hdr.kh_strtab[9], ".strtab",
    1.10    itojun 	    sizeof(ksyms_hdr.kh_strtab) - 9);
    1.10    itojun 	strlcpy(&ksyms_hdr.kh_strtab[17], ".shstrtab",
    1.10    itojun 	    sizeof(ksyms_hdr.kh_strtab) - 17);
     1.1     ragge };
     1.1     ragge
    1.25   thorpej static int
    1.30      yamt ksymsopen(dev_t dev, int oflags, int devtype, struct lwp *l)
     1.1     ragge {
     1.1     ragge
     1.1     ragge 	if (minor(dev))
     1.1     ragge 		return ENXIO;
    1.18      cube 	if (ksymsinited == 0)
    1.18      cube 		return ENXIO;
     1.1     ragge
     1.1     ragge 	ksyms_hdr.kh_shdr[SYMTAB].sh_size = symsz;
     1.1     ragge 	ksyms_hdr.kh_shdr[STRTAB].sh_offset = symsz +
     1.1     ragge 	    ksyms_hdr.kh_shdr[SYMTAB].sh_offset;
     1.1     ragge 	ksyms_hdr.kh_shdr[STRTAB].sh_size = strsz;
     1.1     ragge 	ksyms_isopen = 1;
     1.1     ragge
     1.1     ragge #ifdef KSYMS_DEBUG
     1.1     ragge 	if (ksyms_debug & FOLLOW_DEVKSYMS)
     1.1     ragge 		printf("ksymsopen: symsz 0x%x strsz 0x%x\n", symsz, strsz);
     1.1     ragge #endif
     1.1     ragge
     1.1     ragge 	return 0;
     1.1     ragge }
     1.1     ragge
    1.25   thorpej static int
    1.30      yamt ksymsclose(dev_t dev, int oflags, int devtype, struct lwp *l)
     1.1     ragge {
     1.1     ragge
     1.1     ragge #ifdef KSYMS_DEBUG
     1.1     ragge 	if (ksyms_debug & FOLLOW_DEVKSYMS)
     1.1     ragge 		printf("ksymsclose\n");
     1.1     ragge #endif
     1.1     ragge
     1.1     ragge 	ksyms_isopen = 0;
     1.1     ragge 	wakeup(&ksyms_isopen);
     1.1     ragge 	return 0;
     1.1     ragge }
     1.1     ragge
     1.1     ragge #define	HDRSIZ	sizeof(struct ksyms_hdr)
     1.1     ragge
    1.25   thorpej static int
    1.30      yamt ksymsread(dev_t dev, struct uio *uio, int ioflag)
     1.1     ragge {
     1.1     ragge 	struct symtab *st;
     1.1     ragge 	size_t filepos, inpos, off;
     1.1     ragge
     1.1     ragge #ifdef KSYMS_DEBUG
     1.1     ragge 	if (ksyms_debug & FOLLOW_DEVKSYMS)
    1.26       riz 		printf("ksymsread: offset 0x%llx resid 0x%zx\n",
     1.1     ragge 		    (long long)uio->uio_offset, uio->uio_resid);
     1.1     ragge #endif
     1.1     ragge
     1.1     ragge 	off = uio->uio_offset;
     1.1     ragge 	if (off >= (strsz + symsz + HDRSIZ))
     1.1     ragge 		return 0; /* End of symtab */
     1.1     ragge 	/*
     1.1     ragge 	 * First: Copy out the ELF header.
     1.1     ragge 	 */
     1.1     ragge 	if (off < HDRSIZ)
     1.1     ragge 		uiomove((char *)&ksyms_hdr + off, HDRSIZ - off, uio);
     1.1     ragge
     1.1     ragge 	/*
     1.1     ragge 	 * Copy out the symbol table.
     1.1     ragge 	 */
     1.1     ragge 	filepos = HDRSIZ;
     1.1     ragge 	CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) {
     1.1     ragge 		if (uio->uio_resid == 0)
     1.1     ragge 			return 0;
     1.1     ragge 		if (uio->uio_offset <= st->sd_symsize + filepos) {
     1.1     ragge 			inpos = uio->uio_offset - filepos;
     1.1     ragge 			uiomove((char *)st->sd_symstart + inpos,
     1.1     ragge 			   st->sd_symsize - inpos, uio);
     1.1     ragge 		}
     1.1     ragge 		filepos += st->sd_symsize;
     1.1     ragge 	}
     1.1     ragge
     1.1     ragge 	if (filepos != HDRSIZ + symsz)
     1.1     ragge 		panic("ksymsread: unsunc");
     1.1     ragge
     1.1     ragge 	/*
     1.1     ragge 	 * Copy out the string table
     1.1     ragge 	 */
     1.1     ragge 	CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) {
     1.1     ragge 		if (uio->uio_resid == 0)
     1.1     ragge 			return 0;
     1.1     ragge 		if (uio->uio_offset <= st->sd_strsize + filepos) {
     1.1     ragge 			inpos = uio->uio_offset - filepos;
     1.1     ragge 			uiomove((char *)st->sd_strstart + inpos,
     1.1     ragge 			   st->sd_strsize - inpos, uio);
     1.1     ragge 		}
     1.1     ragge 		filepos += st->sd_strsize;
     1.1     ragge 	}
     1.1     ragge 	return 0;
     1.1     ragge }
     1.1     ragge
    1.25   thorpej static int
    1.30      yamt ksymswrite(dev_t dev, struct uio *uio, int ioflag)
     1.1     ragge {
    1.30      yamt
     1.1     ragge 	return EROFS;
     1.1     ragge }
     1.1     ragge
    1.25   thorpej static int
    1.32  christos ksymsioctl(dev_t dev, u_long cmd, void *data, int fflag, struct lwp *l)
     1.1     ragge {
     1.1     ragge 	struct ksyms_gsymbol *kg = (struct ksyms_gsymbol *)data;
     1.1     ragge 	struct symtab *st;
    1.15  christos 	Elf_Sym *sym = NULL;
     1.1     ragge 	unsigned long val;
     1.1     ragge 	int error = 0;
    1.15  christos 	char *str = NULL;
     1.5     ragge
     1.5     ragge 	if (cmd == KIOCGVALUE || cmd == KIOCGSYMBOL)
     1.5     ragge 		str = malloc(ksyms_maxlen, M_DEVBUF, M_WAITOK);
     1.1     ragge
     1.1     ragge 	switch (cmd) {
     1.1     ragge 	case KIOCGVALUE:
     1.1     ragge 		/*
     1.1     ragge 		 * Use the in-kernel symbol lookup code for fast
     1.1     ragge 		 * retreival of a value.
     1.1     ragge 		 */
     1.5     ragge 		if ((error = copyinstr(kg->kg_name, str, ksyms_maxlen, NULL)))
     1.1     ragge 			break;
    1.22      cube 		if ((error = ksyms_getval(NULL, str, &val, KSYMS_EXTERN)))
     1.1     ragge 			break;
     1.1     ragge 		error = copyout(&val, kg->kg_value, sizeof(long));
     1.1     ragge 		break;
     1.1     ragge
     1.1     ragge 	case KIOCGSYMBOL:
     1.1     ragge 		/*
     1.1     ragge 		 * Use the in-kernel symbol lookup code for fast
     1.1     ragge 		 * retreival of a symbol.
     1.1     ragge 		 */
     1.5     ragge 		if ((error = copyinstr(kg->kg_name, str, ksyms_maxlen, NULL)))
     1.1     ragge 			break;
     1.1     ragge 		CIRCLEQ_FOREACH(st, &symtab_queue, sd_queue) {
    1.22      cube 			if ((sym = findsym(str, st)) == NULL) /* from userland */
     1.1     ragge 				continue;
     1.1     ragge
     1.1     ragge 			/* Skip if bad binding */
     1.1     ragge 			if (ELF_ST_BIND(sym->st_info) != STB_GLOBAL) {
     1.1     ragge 				sym = NULL;
     1.1     ragge 				continue;
     1.1     ragge 			}
     1.1     ragge 			break;
     1.1     ragge 		}
    1.22      cube 		/*
    1.22      cube 		 * XXX which value of sym->st_name should be returned?  The real
    1.22      cube 		 * one, or the one that matches what reading /dev/ksyms get?
    1.22      cube 		 *
    1.22      cube 		 * Currently, we're returning the /dev/ksyms one.
    1.22      cube 		 */
     1.1     ragge 		if (sym != NULL)
     1.1     ragge 			error = copyout(sym, kg->kg_sym, sizeof(Elf_Sym));
     1.1     ragge 		else
     1.1     ragge 			error = ENOENT;
     1.1     ragge 		break;
     1.1     ragge
     1.1     ragge 	case KIOCGSIZE:
     1.1     ragge 		/*
     1.1     ragge 		 * Get total size of symbol table.
     1.1     ragge 		 */
     1.1     ragge 		*(int *)data = strsz + symsz + HDRSIZ;
     1.1     ragge 		break;
     1.1     ragge
     1.1     ragge 	default:
     1.1     ragge 		error = ENOTTY;
     1.1     ragge 		break;
     1.1     ragge 	}
     1.5     ragge
     1.5     ragge 	if (cmd == KIOCGVALUE || cmd == KIOCGSYMBOL)
     1.5     ragge 		free(str, M_DEVBUF);
     1.5     ragge
     1.5     ragge 	return error;
     1.1     ragge }
    1.25   thorpej
    1.25   thorpej const struct cdevsw ksyms_cdevsw = {
    1.25   thorpej 	ksymsopen, ksymsclose, ksymsread, ksymswrite, ksymsioctl,
    1.25   thorpej 	    nullstop, notty, nopoll, nommap, nullkqfilter, DV_DULL
    1.25   thorpej };
1.35.6.1       mjf
1.35.6.1       mjf /*
1.35.6.1       mjf  * The "attach" is in reality done in ksyms_init().
1.35.6.1       mjf  */
1.35.6.1       mjf void
1.35.6.1       mjf ksymsattach(int arg)
1.35.6.1       mjf {
1.35.6.1       mjf 	int maj = cdevsw_lookup_major(&ksyms_cdevsw);
1.35.6.1       mjf
1.35.6.1       mjf 	device_register_name(makedev(maj, 0), NULL, true, DEV_OTHER, "ksyms");
1.35.6.1       mjf
1.35.6.1       mjf #ifdef USE_PTREE
1.35.6.1       mjf 	if (baseidx == 0)
1.35.6.1       mjf 		ptree_gen(0, &kernel_symtab);
1.35.6.1       mjf #endif
1.35.6.1       mjf
1.35.6.1       mjf }
    1.25   thorpej #endif /* NKSYMS */