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|
/* $OpenBSD: kvm_proc.c,v 1.29 2006/06/21 16:20:05 mickey Exp $ */
/* $NetBSD: kvm_proc.c,v 1.30 1999/03/24 05:50:50 mrg Exp $ */
/*-
* Copyright (c) 1998 The NetBSD Foundation, Inc.
* All rights reserved.
*
* This code is derived from software contributed to The NetBSD Foundation
* by Charles M. Hannum.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. All advertising materials mentioning features or use of this software
* must display the following acknowledgement:
* This product includes software developed by the NetBSD
* Foundation, Inc. and its contributors.
* 4. Neither the name of The NetBSD Foundation nor the names of its
* contributors may be used to endorse or promote products derived
* from this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS
* ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS
* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
* INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
* CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
* ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
* POSSIBILITY OF SUCH DAMAGE.
*/
/*-
* Copyright (c) 1994, 1995 Charles M. Hannum. All rights reserved.
* Copyright (c) 1989, 1992, 1993
* The Regents of the University of California. All rights reserved.
*
* This code is derived from software developed by the Computer Systems
* Engineering group at Lawrence Berkeley Laboratory under DARPA contract
* BG 91-66 and contributed to Berkeley.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
* 3. Neither the name of the University nor the names of its contributors
* may be used to endorse or promote products derived from this software
* without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
* ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
* OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
* HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
* LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
* OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
* SUCH DAMAGE.
*/
#if defined(LIBC_SCCS) && !defined(lint)
#if 0
static char sccsid[] = "@(#)kvm_proc.c 8.3 (Berkeley) 9/23/93";
#else
static char *rcsid = "$OpenBSD: kvm_proc.c,v 1.29 2006/06/21 16:20:05 mickey Exp $";
#endif
#endif /* LIBC_SCCS and not lint */
/*
* Proc traversal interface for kvm. ps and w are (probably) the exclusive
* users of this code, so we've factored it out into a separate module.
* Thus, we keep this grunge out of the other kvm applications (i.e.,
* most other applications are interested only in open/close/read/nlist).
*/
#include <sys/param.h>
#include <sys/user.h>
#include <sys/proc.h>
#include <sys/exec.h>
#include <sys/stat.h>
#include <sys/ioctl.h>
#include <sys/tty.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <nlist.h>
#include <kvm.h>
#include <uvm/uvm_extern.h>
#include <uvm/uvm_amap.h>
#include <machine/vmparam.h>
#include <machine/pmap.h>
#include <sys/sysctl.h>
#include <limits.h>
#include <db.h>
#include <paths.h>
#include "kvm_private.h"
/*
* Common info from kinfo_proc and kinfo_proc2 used by helper routines.
*/
struct miniproc {
struct vmspace *p_vmspace;
char p_stat;
struct proc *p_paddr;
pid_t p_pid;
};
/*
* Convert from struct proc and kinfo_proc{,2} to miniproc.
*/
#define PTOMINI(kp, p) \
do { \
(p)->p_stat = (kp)->p_stat; \
(p)->p_pid = (kp)->p_pid; \
(p)->p_paddr = NULL; \
(p)->p_vmspace = (kp)->p_vmspace; \
} while (/*CONSTCOND*/0);
#define KPTOMINI(kp, p) \
do { \
(p)->p_stat = (kp)->kp_proc.p_stat; \
(p)->p_pid = (kp)->kp_proc.p_pid; \
(p)->p_paddr = (kp)->kp_eproc.e_paddr; \
(p)->p_vmspace = (kp)->kp_proc.p_vmspace; \
} while (/*CONSTCOND*/0);
#define KP2TOMINI(kp, p) \
do { \
(p)->p_stat = (kp)->p_stat; \
(p)->p_pid = (kp)->p_pid; \
(p)->p_paddr = (void *)(long)(kp)->p_paddr; \
(p)->p_vmspace = (void *)(long)(kp)->p_vmspace; \
} while (/*CONSTCOND*/0);
#define PTRTOINT64(foo) ((u_int64_t)(u_long)(foo))
#define KREAD(kd, addr, obj) \
(kvm_read(kd, addr, (void *)(obj), sizeof(*obj)) != sizeof(*obj))
ssize_t kvm_uread(kvm_t *, const struct proc *, u_long, char *, size_t);
static char *_kvm_ureadm(kvm_t *, const struct miniproc *, u_long, u_long *);
static ssize_t kvm_ureadm(kvm_t *, const struct miniproc *, u_long, char *, size_t);
static char **kvm_argv(kvm_t *, const struct miniproc *, u_long, int, int);
static int kvm_deadprocs(kvm_t *, int, int, u_long, u_long, int);
static char **kvm_doargv(kvm_t *, const struct miniproc *, int,
void (*)(struct ps_strings *, u_long *, int *));
static int kvm_proclist(kvm_t *, int, int, struct proc *,
struct kinfo_proc *, int);
static int proc_verify(kvm_t *, const struct miniproc *);
static void ps_str_a(struct ps_strings *, u_long *, int *);
static void ps_str_e(struct ps_strings *, u_long *, int *);
static char *
_kvm_ureadm(kvm_t *kd, const struct miniproc *p, u_long va, u_long *cnt)
{
u_long addr, head, offset, slot;
struct vm_anon *anonp, anon;
struct vm_map_entry vme;
struct vm_amap amap;
struct vm_page pg;
if (kd->swapspc == 0) {
kd->swapspc = _kvm_malloc(kd, kd->nbpg);
if (kd->swapspc == 0)
return (0);
}
/*
* Look through the address map for the memory object
* that corresponds to the given virtual address.
* The header just has the entire valid range.
*/
head = (u_long)&p->p_vmspace->vm_map.header;
addr = head;
while (1) {
if (KREAD(kd, addr, &vme))
return (0);
if (va >= vme.start && va < vme.end &&
vme.aref.ar_amap != NULL)
break;
addr = (u_long)vme.next;
if (addr == head)
return (0);
}
/*
* we found the map entry, now to find the object...
*/
if (vme.aref.ar_amap == NULL)
return (NULL);
addr = (u_long)vme.aref.ar_amap;
if (KREAD(kd, addr, &amap))
return (NULL);
offset = va - vme.start;
slot = offset / kd->nbpg + vme.aref.ar_pageoff;
/* sanity-check slot number */
if (slot > amap.am_nslot)
return (NULL);
addr = (u_long)amap.am_anon + (offset / kd->nbpg) * sizeof(anonp);
if (KREAD(kd, addr, &anonp))
return (NULL);
addr = (u_long)anonp;
if (KREAD(kd, addr, &anon))
return (NULL);
addr = (u_long)anon.an_page;
if (addr) {
if (KREAD(kd, addr, &pg))
return (NULL);
if (_kvm_pread(kd, kd->pmfd, (void *)kd->swapspc,
(size_t)kd->nbpg, (off_t)pg.phys_addr) != kd->nbpg)
return (NULL);
} else {
if (_kvm_pread(kd, kd->swfd, (void *)kd->swapspc,
(size_t)kd->nbpg,
(off_t)(anon.an_swslot * kd->nbpg)) != kd->nbpg)
return (NULL);
}
/* Found the page. */
offset %= kd->nbpg;
*cnt = kd->nbpg - offset;
return (&kd->swapspc[offset]);
}
char *
_kvm_uread(kvm_t *kd, const struct proc *p, u_long va, u_long *cnt)
{
struct miniproc mp;
PTOMINI(p, &mp);
return (_kvm_ureadm(kd, &mp, va, cnt));
}
/*
* Read proc's from memory file into buffer bp, which has space to hold
* at most maxcnt procs.
*/
static int
kvm_proclist(kvm_t *kd, int what, int arg, struct proc *p,
struct kinfo_proc *bp, int maxcnt)
{
struct session sess;
struct eproc eproc;
struct proc proc;
struct pgrp pgrp;
struct tty tty;
int cnt = 0;
for (; cnt < maxcnt && p != NULL; p = LIST_NEXT(&proc, p_list)) {
if (KREAD(kd, (u_long)p, &proc)) {
_kvm_err(kd, kd->program, "can't read proc at %x", p);
return (-1);
}
if (KREAD(kd, (u_long)proc.p_cred, &eproc.e_pcred) == 0)
KREAD(kd, (u_long)eproc.e_pcred.pc_ucred,
&eproc.e_ucred);
switch (what) {
case KERN_PROC_PID:
if (proc.p_pid != (pid_t)arg)
continue;
break;
case KERN_PROC_UID:
if (eproc.e_ucred.cr_uid != (uid_t)arg)
continue;
break;
case KERN_PROC_RUID:
if (eproc.e_pcred.p_ruid != (uid_t)arg)
continue;
break;
case KERN_PROC_ALL:
if (proc.p_flag & P_SYSTEM)
continue;
break;
}
/*
* We're going to add another proc to the set. If this
* will overflow the buffer, assume the reason is because
* nprocs (or the proc list) is corrupt and declare an error.
*/
if (cnt >= maxcnt) {
_kvm_err(kd, kd->program, "nprocs corrupt");
return (-1);
}
/*
* gather eproc
*/
eproc.e_paddr = p;
if (KREAD(kd, (u_long)proc.p_pgrp, &pgrp)) {
_kvm_err(kd, kd->program, "can't read pgrp at %x",
proc.p_pgrp);
return (-1);
}
eproc.e_sess = pgrp.pg_session;
eproc.e_pgid = pgrp.pg_id;
eproc.e_jobc = pgrp.pg_jobc;
if (KREAD(kd, (u_long)pgrp.pg_session, &sess)) {
_kvm_err(kd, kd->program, "can't read session at %x",
pgrp.pg_session);
return (-1);
}
if ((proc.p_flag & P_CONTROLT) && sess.s_ttyp != NULL) {
if (KREAD(kd, (u_long)sess.s_ttyp, &tty)) {
_kvm_err(kd, kd->program,
"can't read tty at %x", sess.s_ttyp);
return (-1);
}
eproc.e_tdev = tty.t_dev;
eproc.e_tsess = tty.t_session;
if (tty.t_pgrp != NULL) {
if (KREAD(kd, (u_long)tty.t_pgrp, &pgrp)) {
_kvm_err(kd, kd->program,
"can't read tpgrp at &x",
tty.t_pgrp);
return (-1);
}
eproc.e_tpgid = pgrp.pg_id;
} else
eproc.e_tpgid = -1;
} else
eproc.e_tdev = NODEV;
eproc.e_flag = sess.s_ttyvp ? EPROC_CTTY : 0;
if (sess.s_leader == p)
eproc.e_flag |= EPROC_SLEADER;
if (proc.p_wmesg)
(void)kvm_read(kd, (u_long)proc.p_wmesg,
eproc.e_wmesg, WMESGLEN);
(void)kvm_read(kd, (u_long)proc.p_vmspace,
&eproc.e_vm, sizeof(eproc.e_vm));
eproc.e_xsize = eproc.e_xrssize = 0;
eproc.e_xccount = eproc.e_xswrss = 0;
switch (what) {
case KERN_PROC_PGRP:
if (eproc.e_pgid != (pid_t)arg)
continue;
break;
case KERN_PROC_TTY:
if ((proc.p_flag & P_CONTROLT) == 0 ||
eproc.e_tdev != (dev_t)arg)
continue;
break;
}
bcopy(&proc, &bp->kp_proc, sizeof(proc));
bcopy(&eproc, &bp->kp_eproc, sizeof(eproc));
++bp;
++cnt;
}
return (cnt);
}
/*
* Build proc info array by reading in proc list from a crash dump.
* Return number of procs read. maxcnt is the max we will read.
*/
static int
kvm_deadprocs(kvm_t *kd, int what, int arg, u_long a_allproc,
u_long a_zombproc, int maxcnt)
{
struct kinfo_proc *bp = kd->procbase;
struct proc *p;
int acnt, zcnt;
if (KREAD(kd, a_allproc, &p)) {
_kvm_err(kd, kd->program, "cannot read allproc");
return (-1);
}
acnt = kvm_proclist(kd, what, arg, p, bp, maxcnt);
if (acnt < 0)
return (acnt);
if (KREAD(kd, a_zombproc, &p)) {
_kvm_err(kd, kd->program, "cannot read zombproc");
return (-1);
}
zcnt = kvm_proclist(kd, what, arg, p, bp + acnt, maxcnt - acnt);
if (zcnt < 0)
zcnt = 0;
return (acnt + zcnt);
}
struct kinfo_proc2 *
kvm_getproc2(kvm_t *kd, int op, int arg, size_t esize, int *cnt)
{
int mib[6], st, nprocs;
struct user user;
size_t size;
if ((ssize_t)esize < 0)
return (NULL);
if (kd->procbase2 != NULL) {
free(kd->procbase2);
/*
* Clear this pointer in case this call fails. Otherwise,
* kvm_close() will free it again.
*/
kd->procbase2 = 0;
}
if (ISALIVE(kd)) {
size = 0;
mib[0] = CTL_KERN;
mib[1] = KERN_PROC2;
mib[2] = op;
mib[3] = arg;
mib[4] = esize;
mib[5] = 0;
st = sysctl(mib, 6, NULL, &size, NULL, 0);
if (st == -1) {
_kvm_syserr(kd, kd->program, "kvm_getproc2");
return (NULL);
}
mib[5] = size / esize;
kd->procbase2 = _kvm_malloc(kd, size);
if (kd->procbase2 == 0)
return (NULL);
st = sysctl(mib, 6, kd->procbase2, &size, NULL, 0);
if (st == -1) {
_kvm_syserr(kd, kd->program, "kvm_getproc2");
return (NULL);
}
nprocs = size / esize;
} else {
struct kinfo_proc2 kp2, *kp2p;
struct kinfo_proc *kp;
char *kp2c;
int i;
kp = kvm_getprocs(kd, op, arg, &nprocs);
if (kp == NULL)
return (NULL);
kd->procbase2 = _kvm_malloc(kd, nprocs * esize);
kp2c = (char *)kd->procbase2;
kp2p = &kp2;
for (i = 0; i < nprocs; i++, kp++) {
memset(kp2p, 0, sizeof(kp2));
kp2p->p_forw = PTRTOINT64(kp->kp_proc.p_forw);
kp2p->p_back = PTRTOINT64(kp->kp_proc.p_back);
kp2p->p_paddr = PTRTOINT64(kp->kp_eproc.e_paddr);
kp2p->p_addr = PTRTOINT64(kp->kp_proc.p_addr);
kp2p->p_fd = PTRTOINT64(kp->kp_proc.p_fd);
kp2p->p_stats = PTRTOINT64(kp->kp_proc.p_stats);
kp2p->p_limit = PTRTOINT64(kp->kp_proc.p_limit);
kp2p->p_vmspace = PTRTOINT64(kp->kp_proc.p_vmspace);
kp2p->p_sigacts = PTRTOINT64(kp->kp_proc.p_sigacts);
kp2p->p_sess = PTRTOINT64(kp->kp_eproc.e_sess);
kp2p->p_tsess = 0;
kp2p->p_ru = PTRTOINT64(kp->kp_proc.p_ru);
kp2p->p_eflag = 0;
kp2p->p_exitsig = kp->kp_proc.p_exitsig;
kp2p->p_flag = kp->kp_proc.p_flag;
kp2p->p_pid = kp->kp_proc.p_pid;
kp2p->p_ppid = kp->kp_eproc.e_ppid;
#if 0
kp2p->p_sid = kp->kp_eproc.e_sid;
#else
kp2p->p_sid = -1; /* XXX */
#endif
kp2p->p__pgid = kp->kp_eproc.e_pgid;
kp2p->p_tpgid = -1;
kp2p->p_uid = kp->kp_eproc.e_ucred.cr_uid;
kp2p->p_ruid = kp->kp_eproc.e_pcred.p_ruid;
kp2p->p_gid = kp->kp_eproc.e_ucred.cr_gid;
kp2p->p_rgid = kp->kp_eproc.e_pcred.p_rgid;
memcpy(kp2p->p_groups, kp->kp_eproc.e_ucred.cr_groups,
MIN(sizeof(kp2p->p_groups),
sizeof(kp->kp_eproc.e_ucred.cr_groups)));
kp2p->p_ngroups = kp->kp_eproc.e_ucred.cr_ngroups;
kp2p->p_jobc = kp->kp_eproc.e_jobc;
kp2p->p_tdev = kp->kp_eproc.e_tdev;
kp2p->p_tpgid = kp->kp_eproc.e_tpgid;
kp2p->p_tsess = PTRTOINT64(kp->kp_eproc.e_tsess);
kp2p->p_estcpu = kp->kp_proc.p_estcpu;
kp2p->p_rtime_sec = kp->kp_proc.p_estcpu;
kp2p->p_rtime_usec = kp->kp_proc.p_estcpu;
kp2p->p_cpticks = kp->kp_proc.p_cpticks;
kp2p->p_pctcpu = kp->kp_proc.p_pctcpu;
kp2p->p_swtime = kp->kp_proc.p_swtime;
kp2p->p_slptime = kp->kp_proc.p_slptime;
kp2p->p_schedflags = 0;
kp2p->p_uticks = kp->kp_proc.p_uticks;
kp2p->p_sticks = kp->kp_proc.p_sticks;
kp2p->p_iticks = kp->kp_proc.p_iticks;
kp2p->p_tracep = PTRTOINT64(kp->kp_proc.p_tracep);
kp2p->p_traceflag = kp->kp_proc.p_traceflag;
kp2p->p_holdcnt = kp->kp_proc.p_holdcnt;
kp2p->p_siglist = kp->kp_proc.p_siglist;
kp2p->p_sigmask = kp->kp_proc.p_sigmask;
kp2p->p_sigignore = kp->kp_proc.p_sigignore;
kp2p->p_sigcatch = kp->kp_proc.p_sigcatch;
kp2p->p_stat = kp->kp_proc.p_stat;
kp2p->p_priority = kp->kp_proc.p_priority;
kp2p->p_usrpri = kp->kp_proc.p_usrpri;
kp2p->p_nice = kp->kp_proc.p_nice;
kp2p->p_xstat = kp->kp_proc.p_xstat;
kp2p->p_acflag = kp->kp_proc.p_acflag;
strncpy(kp2p->p_comm, kp->kp_proc.p_comm,
MIN(sizeof(kp2p->p_comm), sizeof(kp->kp_proc.p_comm)));
strncpy(kp2p->p_wmesg, kp->kp_eproc.e_wmesg,
sizeof(kp2p->p_wmesg));
kp2p->p_wchan = PTRTOINT64(kp->kp_proc.p_wchan);
strncpy(kp2p->p_login, kp->kp_eproc.e_login,
sizeof(kp2p->p_login));
kp2p->p_vm_rssize = kp->kp_eproc.e_xrssize;
kp2p->p_vm_tsize = kp->kp_eproc.e_vm.vm_tsize;
kp2p->p_vm_dsize = kp->kp_eproc.e_vm.vm_dsize;
kp2p->p_vm_ssize = kp->kp_eproc.e_vm.vm_ssize;
kp2p->p_eflag = kp->kp_eproc.e_flag;
if (P_ZOMBIE(&kp->kp_proc) || kp->kp_proc.p_addr == NULL ||
KREAD(kd, (u_long)kp->kp_proc.p_addr, &user)) {
kp2p->p_uvalid = 0;
} else {
kp2p->p_uvalid = 1;
kp2p->p_ustart_sec = user.u_stats.p_start.tv_sec;
kp2p->p_ustart_usec = user.u_stats.p_start.tv_usec;
kp2p->p_uutime_sec = user.u_stats.p_ru.ru_utime.tv_sec;
kp2p->p_uutime_usec = user.u_stats.p_ru.ru_utime.tv_usec;
kp2p->p_ustime_sec = user.u_stats.p_ru.ru_stime.tv_sec;
kp2p->p_ustime_usec = user.u_stats.p_ru.ru_stime.tv_usec;
kp2p->p_uru_maxrss = user.u_stats.p_ru.ru_maxrss;
kp2p->p_uru_ixrss = user.u_stats.p_ru.ru_ixrss;
kp2p->p_uru_idrss = user.u_stats.p_ru.ru_idrss;
kp2p->p_uru_isrss = user.u_stats.p_ru.ru_isrss;
kp2p->p_uru_minflt = user.u_stats.p_ru.ru_minflt;
kp2p->p_uru_majflt = user.u_stats.p_ru.ru_majflt;
kp2p->p_uru_nswap = user.u_stats.p_ru.ru_nswap;
kp2p->p_uru_inblock = user.u_stats.p_ru.ru_inblock;
kp2p->p_uru_oublock = user.u_stats.p_ru.ru_oublock;
kp2p->p_uru_msgsnd = user.u_stats.p_ru.ru_msgsnd;
kp2p->p_uru_msgrcv = user.u_stats.p_ru.ru_msgrcv;
kp2p->p_uru_nsignals = user.u_stats.p_ru.ru_nsignals;
kp2p->p_uru_nvcsw = user.u_stats.p_ru.ru_nvcsw;
kp2p->p_uru_nivcsw = user.u_stats.p_ru.ru_nivcsw;
kp2p->p_uctime_sec =
user.u_stats.p_cru.ru_utime.tv_sec +
user.u_stats.p_cru.ru_stime.tv_sec;
kp2p->p_uctime_usec =
user.u_stats.p_cru.ru_utime.tv_usec +
user.u_stats.p_cru.ru_stime.tv_usec;
}
memcpy(kp2c, &kp2, esize);
kp2c += esize;
}
free(kd->procbase);
}
*cnt = nprocs;
return (kd->procbase2);
}
struct kinfo_proc *
kvm_getprocs(kvm_t *kd, int op, int arg, int *cnt)
{
int mib[4], st, nprocs;
size_t size;
if (kd->procbase != 0) {
free((void *)kd->procbase);
/*
* Clear this pointer in case this call fails. Otherwise,
* kvm_close() will free it again.
*/
kd->procbase = 0;
}
if (ISALIVE(kd)) {
size = 0;
mib[0] = CTL_KERN;
mib[1] = KERN_PROC;
mib[2] = op;
mib[3] = arg;
st = sysctl(mib, 4, NULL, &size, NULL, 0);
if (st == -1) {
_kvm_syserr(kd, kd->program, "kvm_getprocs");
return (0);
}
kd->procbase = _kvm_malloc(kd, size);
if (kd->procbase == 0)
return (0);
st = sysctl(mib, 4, kd->procbase, &size, NULL, 0);
if (st == -1) {
_kvm_syserr(kd, kd->program, "kvm_getprocs");
return (0);
}
if (size % sizeof(struct kinfo_proc) != 0) {
_kvm_err(kd, kd->program,
"proc size mismatch (%d total, %d chunks)",
size, sizeof(struct kinfo_proc));
return (0);
}
nprocs = size / sizeof(struct kinfo_proc);
} else {
struct nlist nl[4], *p;
memset(nl, 0, sizeof(nl));
nl[0].n_name = "_nprocs";
nl[1].n_name = "_allproc";
nl[2].n_name = "_zombproc";
nl[3].n_name = NULL;
if (kvm_nlist(kd, nl) != 0) {
for (p = nl; p->n_type != 0; ++p)
;
_kvm_err(kd, kd->program,
"%s: no such symbol", p->n_name);
return (0);
}
if (KREAD(kd, nl[0].n_value, &nprocs)) {
_kvm_err(kd, kd->program, "can't read nprocs");
return (0);
}
size = nprocs * sizeof(struct kinfo_proc);
kd->procbase = _kvm_malloc(kd, size);
if (kd->procbase == 0)
return (0);
nprocs = kvm_deadprocs(kd, op, arg, nl[1].n_value,
nl[2].n_value, nprocs);
#ifdef notdef
size = nprocs * sizeof(struct kinfo_proc);
(void)realloc(kd->procbase, size);
#endif
}
*cnt = nprocs;
return (kd->procbase);
}
void
_kvm_freeprocs(kvm_t *kd)
{
if (kd->procbase) {
free(kd->procbase);
kd->procbase = 0;
}
}
void *
_kvm_realloc(kvm_t *kd, void *p, size_t n)
{
void *np = (void *)realloc(p, n);
if (np == 0)
_kvm_err(kd, kd->program, "out of memory");
return (np);
}
/*
* Read in an argument vector from the user address space of process p.
* addr if the user-space base address of narg null-terminated contiguous
* strings. This is used to read in both the command arguments and
* environment strings. Read at most maxcnt characters of strings.
*/
static char **
kvm_argv(kvm_t *kd, const struct miniproc *p, u_long addr, int narg,
int maxcnt)
{
char *np, *cp, *ep, *ap, **argv;
u_long oaddr = -1;
int len, cc;
/*
* Check that there aren't an unreasonable number of agruments,
* and that the address is in user space.
*/
if (narg > ARG_MAX || addr < VM_MIN_ADDRESS || addr >= VM_MAXUSER_ADDRESS)
return (0);
if (kd->argv == 0) {
/*
* Try to avoid reallocs.
*/
kd->argc = MAX(narg + 1, 32);
kd->argv = _kvm_malloc(kd, kd->argc *
sizeof(*kd->argv));
if (kd->argv == 0)
return (0);
} else if (narg + 1 > kd->argc) {
kd->argc = MAX(2 * kd->argc, narg + 1);
kd->argv = (char **)_kvm_realloc(kd, kd->argv, kd->argc *
sizeof(*kd->argv));
if (kd->argv == 0)
return (0);
}
if (kd->argspc == 0) {
kd->argspc = _kvm_malloc(kd, kd->nbpg);
if (kd->argspc == 0)
return (0);
kd->arglen = kd->nbpg;
}
if (kd->argbuf == 0) {
kd->argbuf = _kvm_malloc(kd, kd->nbpg);
if (kd->argbuf == 0)
return (0);
}
cc = sizeof(char *) * narg;
if (kvm_ureadm(kd, p, addr, (char *)kd->argv, cc) != cc)
return (0);
ap = np = kd->argspc;
argv = kd->argv;
len = 0;
/*
* Loop over pages, filling in the argument vector.
*/
while (argv < kd->argv + narg && *argv != 0) {
addr = (u_long)*argv & ~(kd->nbpg - 1);
if (addr != oaddr) {
if (kvm_ureadm(kd, p, addr, kd->argbuf, kd->nbpg) !=
kd->nbpg)
return (0);
oaddr = addr;
}
addr = (u_long)*argv & (kd->nbpg - 1);
cp = kd->argbuf + addr;
cc = kd->nbpg - addr;
if (maxcnt > 0 && cc > maxcnt - len)
cc = maxcnt - len;
ep = memchr(cp, '\0', cc);
if (ep != 0)
cc = ep - cp + 1;
if (len + cc > kd->arglen) {
int off;
char **pp;
char *op = kd->argspc;
kd->arglen *= 2;
kd->argspc = (char *)_kvm_realloc(kd, kd->argspc,
kd->arglen);
if (kd->argspc == 0)
return (0);
/*
* Adjust argv pointers in case realloc moved
* the string space.
*/
off = kd->argspc - op;
for (pp = kd->argv; pp < argv; pp++)
*pp += off;
ap += off;
np += off;
}
memcpy(np, cp, cc);
np += cc;
len += cc;
if (ep != 0) {
*argv++ = ap;
ap = np;
} else
*argv += cc;
if (maxcnt > 0 && len >= maxcnt) {
/*
* We're stopping prematurely. Terminate the
* current string.
*/
if (ep == 0) {
*np = '\0';
*argv++ = ap;
}
break;
}
}
/* Make sure argv is terminated. */
*argv = 0;
return (kd->argv);
}
static void
ps_str_a(struct ps_strings *p, u_long *addr, int *n)
{
*addr = (u_long)p->ps_argvstr;
*n = p->ps_nargvstr;
}
static void
ps_str_e(struct ps_strings *p, u_long *addr, int *n)
{
*addr = (u_long)p->ps_envstr;
*n = p->ps_nenvstr;
}
/*
* Determine if the proc indicated by p is still active.
* This test is not 100% foolproof in theory, but chances of
* being wrong are very low.
*/
static int
proc_verify(kvm_t *kd, const struct miniproc *p)
{
struct proc kernproc;
/*
* Just read in the whole proc. It's not that big relative
* to the cost of the read system call.
*/
if (kvm_read(kd, (u_long)p->p_paddr, &kernproc, sizeof(kernproc)) !=
sizeof(kernproc))
return (0);
return (p->p_pid == kernproc.p_pid &&
(kernproc.p_stat != SZOMB || p->p_stat == SZOMB));
}
static char **
kvm_doargv(kvm_t *kd, const struct miniproc *p, int nchr,
void (*info)(struct ps_strings *, u_long *, int *))
{
static struct ps_strings *ps;
struct ps_strings arginfo;
u_long addr;
char **ap;
int cnt;
if (ps == NULL) {
struct _ps_strings _ps;
int mib[2];
size_t len;
mib[0] = CTL_VM;
mib[1] = VM_PSSTRINGS;
len = sizeof(_ps);
sysctl(mib, 2, &_ps, &len, NULL, 0);
ps = (struct ps_strings *)_ps.val;
}
/*
* Pointers are stored at the top of the user stack.
*/
if (p->p_stat == SZOMB ||
kvm_ureadm(kd, p, (u_long)ps, (char *)&arginfo,
sizeof(arginfo)) != sizeof(arginfo))
return (0);
(*info)(&arginfo, &addr, &cnt);
if (cnt == 0)
return (0);
ap = kvm_argv(kd, p, addr, cnt, nchr);
/*
* For live kernels, make sure this process didn't go away.
*/
if (ap != 0 && ISALIVE(kd) && !proc_verify(kd, p))
ap = 0;
return (ap);
}
static char **
kvm_arg_sysctl(kvm_t *kd, pid_t pid, int nchr, int env)
{
size_t len, orglen;
int mib[4], ret;
char *buf;
orglen = env ? kd->nbpg : 8 * kd->nbpg; /* XXX - should be ARG_MAX */
if (kd->argbuf == NULL &&
(kd->argbuf = _kvm_malloc(kd, orglen)) == NULL)
return (NULL);
again:
mib[0] = CTL_KERN;
mib[1] = KERN_PROC_ARGS;
mib[2] = (int)pid;
mib[3] = env ? KERN_PROC_ENV : KERN_PROC_ARGV;
len = orglen;
ret = (sysctl(mib, 4, kd->argbuf, &len, NULL, 0) < 0);
if (ret && errno == ENOMEM) {
orglen *= 2;
buf = _kvm_realloc(kd, kd->argbuf, orglen);
if (buf == NULL)
return (NULL);
kd->argbuf = buf;
goto again;
}
if (ret) {
free(kd->argbuf);
kd->argbuf = NULL;
_kvm_syserr(kd, kd->program, "kvm_arg_sysctl");
return (NULL);
}
#if 0
for (argv = (char **)kd->argbuf; *argv != NULL; argv++)
if (strlen(*argv) > nchr)
*argv[nchr] = '\0';
#endif
return (char **)(kd->argbuf);
}
/*
* Get the command args. This code is now machine independent.
*/
char **
kvm_getargv(kvm_t *kd, const struct kinfo_proc *kp, int nchr)
{
struct miniproc p;
if (ISALIVE(kd))
return (kvm_arg_sysctl(kd, kp->kp_proc.p_pid, nchr, 0));
KPTOMINI(kp, &p);
return (kvm_doargv(kd, &p, nchr, ps_str_a));
}
char **
kvm_getenvv(kvm_t *kd, const struct kinfo_proc *kp, int nchr)
{
struct miniproc p;
if (ISALIVE(kd))
return (kvm_arg_sysctl(kd, kp->kp_proc.p_pid, nchr, 1));
KPTOMINI(kp, &p);
return (kvm_doargv(kd, &p, nchr, ps_str_e));
}
char **
kvm_getargv2(kvm_t *kd, const struct kinfo_proc2 *kp, int nchr)
{
struct miniproc p;
if (ISALIVE(kd))
return (kvm_arg_sysctl(kd, kp->p_pid, nchr, 0));
KP2TOMINI(kp, &p);
return (kvm_doargv(kd, &p, nchr, ps_str_a));
}
char **
kvm_getenvv2(kvm_t *kd, const struct kinfo_proc2 *kp, int nchr)
{
struct miniproc p;
if (ISALIVE(kd))
return (kvm_arg_sysctl(kd, kp->p_pid, nchr, 1));
KP2TOMINI(kp, &p);
return (kvm_doargv(kd, &p, nchr, ps_str_e));
}
/*
* Read from user space. The user context is given by p.
*/
static ssize_t
kvm_ureadm(kvm_t *kd, const struct miniproc *p, u_long uva, char *buf,
size_t len)
{
char *cp = buf;
while (len > 0) {
u_long cnt;
size_t cc;
char *dp;
dp = _kvm_ureadm(kd, p, uva, &cnt);
if (dp == 0) {
_kvm_err(kd, 0, "invalid address (%lx)", uva);
return (0);
}
cc = (size_t)MIN(cnt, len);
bcopy(dp, cp, cc);
cp += cc;
uva += cc;
len -= cc;
}
return (ssize_t)(cp - buf);
}
ssize_t
kvm_uread(kvm_t *kd, const struct proc *p, u_long uva, char *buf,
size_t len)
{
struct miniproc mp;
PTOMINI(p, &mp);
return (kvm_ureadm(kd, &mp, uva, buf, len));
}
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