2 * Copyright (c) 1989, 1992, 1993
3 * The Regents of the University of California. All rights reserved.
5 * This code is derived from software developed by the Computer Systems
6 * Engineering group at Lawrence Berkeley Laboratory under DARPA contract
7 * BG 91-66 and contributed to Berkeley.
9 * Redistribution and use in source and binary forms, with or without
10 * modification, are permitted provided that the following conditions
12 * 1. Redistributions of source code must retain the above copyright
13 * notice, this list of conditions and the following disclaimer.
14 * 2. Redistributions in binary form must reproduce the above copyright
15 * notice, this list of conditions and the following disclaimer in the
16 * documentation and/or other materials provided with the distribution.
17 * 3. All advertising materials mentioning features or use of this software
18 * must display the following acknowledgement:
19 * This product includes software developed by the University of
20 * California, Berkeley and its contributors.
21 * 4. Neither the name of the University nor the names of its contributors
22 * may be used to endorse or promote products derived from this software
23 * without specific prior written permission.
25 * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND
26 * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
27 * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
28 * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE
29 * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
30 * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS
31 * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION)
32 * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT
33 * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY
34 * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
40 #include <sys/cdefs.h>
41 __FBSDID("$FreeBSD$");
43 #if defined(LIBC_SCCS) && !defined(lint)
44 static char sccsid[] = "@(#)kvm_proc.c 8.3 (Berkeley) 9/23/93";
45 #endif /* LIBC_SCCS and not lint */
48 * Proc traversal interface for kvm. ps and w are (probably) the exclusive
49 * users of this code, so we've factored it out into a separate module.
50 * Thus, we keep this grunge out of the other kvm applications (i.e.,
51 * most other applications are interested only in open/close/read/nlist).
54 #include <sys/param.h>
59 #include <sys/ioctl.h>
69 #include <vm/vm_param.h>
70 #include <vm/swap_pager.h>
72 #include <sys/sysctl.h>
78 #include "kvm_private.h"
82 kvm_readswap(kd, p, va, cnt)
89 /* XXX Stubbed out, our vm system is differnet */
90 _kvm_err(kd, kd->program, "kvm_readswap not implemented");
92 #endif /* __FreeBSD__ */
96 #define KREAD(kd, addr, obj) \
97 (kvm_read(kd, addr, (char *)(obj), sizeof(*obj)) != sizeof(*obj))
100 * Read proc's from memory file into buffer bp, which has space to hold
101 * at most maxcnt procs.
104 kvm_proclist(kd, what, arg, p, bp, maxcnt)
108 struct kinfo_proc *bp;
111 register int cnt = 0;
112 struct kinfo_proc kinfo_proc, *kp;
116 struct vmspace vmspace;
117 struct procsig procsig;
118 struct pstats pstats;
120 struct thread mainthread;
126 kp->ki_structsize = sizeof(kinfo_proc);
127 for (; cnt < maxcnt && p != NULL; p = LIST_NEXT(&proc, p_list)) {
128 memset(kp, 0, sizeof *kp);
129 if (KREAD(kd, (u_long)p, &proc)) {
130 _kvm_err(kd, kd->program, "can't read proc at %x", p);
133 if (KREAD(kd, (u_long)TAILQ_FIRST(&proc.p_threads),
135 _kvm_err(kd, kd->program, "can't read thread at %x",
136 TAILQ_FIRST(&proc.p_threads));
139 if (KREAD(kd, (u_long)proc.p_ucred, &ucred) == 0) {
140 kp->ki_ruid = ucred.cr_ruid;
141 kp->ki_svuid = ucred.cr_svuid;
142 kp->ki_rgid = ucred.cr_rgid;
143 kp->ki_svgid = ucred.cr_svgid;
144 kp->ki_ngroups = ucred.cr_ngroups;
145 bcopy(ucred.cr_groups, kp->ki_groups,
146 NGROUPS * sizeof(gid_t));
147 kp->ki_uid = ucred.cr_uid;
153 if (proc.p_pid != (pid_t)arg)
158 if (kp->ki_uid != (uid_t)arg)
163 if (kp->ki_ruid != (uid_t)arg)
168 * We're going to add another proc to the set. If this
169 * will overflow the buffer, assume the reason is because
170 * nprocs (or the proc list) is corrupt and declare an error.
173 _kvm_err(kd, kd->program, "nprocs corrupt");
180 kp->ki_addr = proc.p_uarea;
181 /* kp->ki_kstack = proc.p_thread.td_kstack; XXXKSE */
182 kp->ki_args = proc.p_args;
183 kp->ki_tracep = proc.p_tracep;
184 kp->ki_textvp = proc.p_textvp;
185 kp->ki_fd = proc.p_fd;
186 kp->ki_vmspace = proc.p_vmspace;
187 if (proc.p_procsig != NULL) {
188 if (KREAD(kd, (u_long)proc.p_procsig, &procsig)) {
189 _kvm_err(kd, kd->program,
190 "can't read procsig at %x", proc.p_procsig);
193 kp->ki_sigignore = procsig.ps_sigignore;
194 kp->ki_sigcatch = procsig.ps_sigcatch;
196 if ((proc.p_sflag & PS_INMEM) && proc.p_stats != NULL) {
197 if (KREAD(kd, (u_long)proc.p_stats, &pstats)) {
198 _kvm_err(kd, kd->program,
199 "can't read stats at %x", proc.p_stats);
202 kp->ki_start = pstats.p_start;
203 kp->ki_rusage = pstats.p_ru;
204 kp->ki_childtime.tv_sec = pstats.p_cru.ru_utime.tv_sec +
205 pstats.p_cru.ru_stime.tv_sec;
206 kp->ki_childtime.tv_usec =
207 pstats.p_cru.ru_utime.tv_usec +
208 pstats.p_cru.ru_stime.tv_usec;
211 kp->ki_ppid = proc.p_oppid;
212 else if (proc.p_pptr) {
213 if (KREAD(kd, (u_long)proc.p_pptr, &pproc)) {
214 _kvm_err(kd, kd->program,
215 "can't read pproc at %x", proc.p_pptr);
218 kp->ki_ppid = pproc.p_pid;
221 if (proc.p_pgrp == NULL)
223 if (KREAD(kd, (u_long)proc.p_pgrp, &pgrp)) {
224 _kvm_err(kd, kd->program, "can't read pgrp at %x",
228 kp->ki_pgid = pgrp.pg_id;
229 kp->ki_jobc = pgrp.pg_jobc;
230 if (KREAD(kd, (u_long)pgrp.pg_session, &sess)) {
231 _kvm_err(kd, kd->program, "can't read session at %x",
235 kp->ki_sid = sess.s_sid;
236 (void)memcpy(kp->ki_login, sess.s_login,
237 sizeof(kp->ki_login));
238 kp->ki_kiflag = sess.s_ttyvp ? KI_CTTY : 0;
239 if (sess.s_leader == p)
240 kp->ki_kiflag |= KI_SLEADER;
241 if ((proc.p_flag & P_CONTROLT) && sess.s_ttyp != NULL) {
242 if (KREAD(kd, (u_long)sess.s_ttyp, &tty)) {
243 _kvm_err(kd, kd->program,
244 "can't read tty at %x", sess.s_ttyp);
247 kp->ki_tdev = tty.t_dev;
248 if (tty.t_pgrp != NULL) {
249 if (KREAD(kd, (u_long)tty.t_pgrp, &pgrp)) {
250 _kvm_err(kd, kd->program,
251 "can't read tpgrp at &x",
255 kp->ki_tpgid = pgrp.pg_id;
258 if (tty.t_session != NULL) {
259 if (KREAD(kd, (u_long)tty.t_session, &sess)) {
260 _kvm_err(kd, kd->program,
261 "can't read session at %x",
265 kp->ki_tsid = sess.s_sid;
271 if (mainthread.td_wmesg) /* XXXKSE */
272 (void)kvm_read(kd, (u_long)mainthread.td_wmesg,
273 kp->ki_wmesg, WMESGLEN);
276 (void)kvm_read(kd, (u_long)&proc.p_vmspace->vm_rssize,
277 (char *)&kp->ki_rssize,
278 sizeof(kp->ki_rssize));
279 (void)kvm_read(kd, (u_long)&proc.p_vmspace->vm_tsize,
280 (char *)&kp->ki_tsize,
281 3 * sizeof(kp->ki_rssize)); /* XXX */
283 (void)kvm_read(kd, (u_long)proc.p_vmspace,
284 (char *)&vmspace, sizeof(vmspace));
285 kp->ki_size = vmspace.vm_map.size;
286 kp->ki_rssize = vmspace.vm_swrss; /* XXX */
287 kp->ki_swrss = vmspace.vm_swrss;
288 kp->ki_tsize = vmspace.vm_tsize;
289 kp->ki_dsize = vmspace.vm_dsize;
290 kp->ki_ssize = vmspace.vm_ssize;
296 if (kp->ki_pgid != (pid_t)arg)
301 if ((proc.p_flag & P_CONTROLT) == 0 ||
302 kp->ki_tdev != (dev_t)arg)
306 if (proc.p_comm[0] != 0) {
307 strncpy(kp->ki_comm, proc.p_comm, MAXCOMLEN);
308 kp->ki_comm[MAXCOMLEN] = 0;
310 if (mainthread.td_blocked != 0) { /* XXXKSE */
311 kp->ki_kiflag |= KI_MTXBLOCK;
312 if (mainthread.td_mtxname) /* XXXKSE */
313 (void)kvm_read(kd, (u_long)mainthread.td_mtxname,
314 kp->ki_mtxname, MTXNAMELEN);
315 kp->ki_mtxname[MTXNAMELEN] = 0;
317 bintime2timeval(&proc.p_runtime, &tv);
318 kp->ki_runtime = (u_int64_t)tv.tv_sec * 1000000 + tv.tv_usec;
319 kp->ki_pid = proc.p_pid;
320 kp->ki_siglist = proc.p_siglist;
321 kp->ki_sigmask = proc.p_sigmask;
322 kp->ki_xstat = proc.p_xstat;
323 kp->ki_acflag = proc.p_acflag;
324 kp->ki_pctcpu = proc.p_kse.ke_pctcpu; /* XXXKSE */
325 kp->ki_estcpu = proc.p_ksegrp.kg_estcpu; /* XXXKSE */
326 kp->ki_slptime = proc.p_kse.ke_slptime; /* XXXKSE */
327 kp->ki_swtime = proc.p_swtime;
328 kp->ki_flag = proc.p_flag;
329 kp->ki_sflag = proc.p_sflag;
330 kp->ki_wchan = mainthread.td_wchan; /* XXXKSE */
331 kp->ki_traceflag = proc.p_traceflag;
332 kp->ki_stat = proc.p_stat;
333 kp->ki_pri.pri_class = proc.p_ksegrp.kg_pri_class; /* XXXKSE */
334 kp->ki_pri.pri_user = proc.p_ksegrp.kg_user_pri; /* XXXKSE */
335 kp->ki_pri.pri_level = mainthread.td_priority; /* XXXKSE */
336 kp->ki_pri.pri_native = mainthread.td_base_pri; /* XXXKSE */
337 kp->ki_nice = proc.p_ksegrp.kg_nice; /* XXXKSE */
338 kp->ki_lock = proc.p_lock;
339 kp->ki_rqindex = proc.p_kse.ke_rqindex; /* XXXKSE */
340 kp->ki_oncpu = proc.p_kse.ke_oncpu; /* XXXKSE */
341 kp->ki_lastcpu = mainthread.td_lastcpu; /* XXXKSE */
342 bcopy(&kinfo_proc, bp, sizeof(kinfo_proc));
350 * Build proc info array by reading in proc list from a crash dump.
351 * Return number of procs read. maxcnt is the max we will read.
354 kvm_deadprocs(kd, what, arg, a_allproc, a_zombproc, maxcnt)
361 register struct kinfo_proc *bp = kd->procbase;
362 register int acnt, zcnt;
365 if (KREAD(kd, a_allproc, &p)) {
366 _kvm_err(kd, kd->program, "cannot read allproc");
369 acnt = kvm_proclist(kd, what, arg, p, bp, maxcnt);
373 if (KREAD(kd, a_zombproc, &p)) {
374 _kvm_err(kd, kd->program, "cannot read zombproc");
377 zcnt = kvm_proclist(kd, what, arg, p, bp + acnt, maxcnt - acnt);
381 return (acnt + zcnt);
385 kvm_getprocs(kd, op, arg, cnt)
390 int mib[4], st, nprocs;
393 if (kd->procbase != 0) {
394 free((void *)kd->procbase);
396 * Clear this pointer in case this call fails. Otherwise,
397 * kvm_close() will free it again.
407 st = sysctl(mib, op == KERN_PROC_ALL ? 3 : 4, NULL, &size, NULL, 0);
409 _kvm_syserr(kd, kd->program, "kvm_getprocs");
414 kd->procbase = (struct kinfo_proc *)
415 _kvm_realloc(kd, kd->procbase, size);
416 if (kd->procbase == 0)
418 st = sysctl(mib, op == KERN_PROC_ALL ? 3 : 4,
419 kd->procbase, &size, NULL, 0);
420 } while (st == -1 && errno == ENOMEM);
422 _kvm_syserr(kd, kd->program, "kvm_getprocs");
426 kd->procbase->ki_structsize != sizeof(struct kinfo_proc)) {
427 _kvm_err(kd, kd->program,
428 "kinfo_proc size mismatch (expected %d, got %d)",
429 sizeof(struct kinfo_proc),
430 kd->procbase->ki_structsize);
433 nprocs = size == 0 ? 0 : size / kd->procbase->ki_structsize;
435 struct nlist nl[4], *p;
437 nl[0].n_name = "_nprocs";
438 nl[1].n_name = "_allproc";
439 nl[2].n_name = "_zombproc";
442 if (kvm_nlist(kd, nl) != 0) {
443 for (p = nl; p->n_type != 0; ++p)
445 _kvm_err(kd, kd->program,
446 "%s: no such symbol", p->n_name);
449 if (KREAD(kd, nl[0].n_value, &nprocs)) {
450 _kvm_err(kd, kd->program, "can't read nprocs");
453 size = nprocs * sizeof(struct kinfo_proc);
454 kd->procbase = (struct kinfo_proc *)_kvm_malloc(kd, size);
455 if (kd->procbase == 0)
458 nprocs = kvm_deadprocs(kd, op, arg, nl[1].n_value,
459 nl[2].n_value, nprocs);
461 size = nprocs * sizeof(struct kinfo_proc);
462 (void)realloc(kd->procbase, size);
466 return (kd->procbase);
480 _kvm_realloc(kd, p, n)
485 void *np = (void *)realloc(p, n);
489 _kvm_err(kd, kd->program, "out of memory");
495 #define MAX(a, b) ((a) > (b) ? (a) : (b))
499 * Read in an argument vector from the user address space of process kp.
500 * addr if the user-space base address of narg null-terminated contiguous
501 * strings. This is used to read in both the command arguments and
502 * environment strings. Read at most maxcnt characters of strings.
505 kvm_argv(kd, kp, addr, narg, maxcnt)
507 struct kinfo_proc *kp;
508 register u_long addr;
512 register char *np, *cp, *ep, *ap;
513 register u_long oaddr = -1;
514 register int len, cc;
515 register char **argv;
518 * Check that there aren't an unreasonable number of agruments,
519 * and that the address is in user space.
521 if (narg > 512 || addr < VM_MIN_ADDRESS || addr >= VM_MAXUSER_ADDRESS)
525 * kd->argv : work space for fetching the strings from the target
526 * process's space, and is converted for returning to caller
530 * Try to avoid reallocs.
532 kd->argc = MAX(narg + 1, 32);
533 kd->argv = (char **)_kvm_malloc(kd, kd->argc *
537 } else if (narg + 1 > kd->argc) {
538 kd->argc = MAX(2 * kd->argc, narg + 1);
539 kd->argv = (char **)_kvm_realloc(kd, kd->argv, kd->argc *
545 * kd->argspc : returned to user, this is where the kd->argv
546 * arrays are left pointing to the collected strings.
548 if (kd->argspc == 0) {
549 kd->argspc = (char *)_kvm_malloc(kd, PAGE_SIZE);
552 kd->arglen = PAGE_SIZE;
555 * kd->argbuf : used to pull in pages from the target process.
556 * the strings are copied out of here.
558 if (kd->argbuf == 0) {
559 kd->argbuf = (char *)_kvm_malloc(kd, PAGE_SIZE);
564 /* Pull in the target process'es argv vector */
565 cc = sizeof(char *) * narg;
566 if (kvm_uread(kd, kp, addr, (char *)kd->argv, cc) != cc)
569 * ap : saved start address of string we're working on in kd->argspc
570 * np : pointer to next place to write in kd->argspc
571 * len: length of data in kd->argspc
572 * argv: pointer to the argv vector that we are hunting around the
573 * target process space for, and converting to addresses in
574 * our address space (kd->argspc).
576 ap = np = kd->argspc;
580 * Loop over pages, filling in the argument vector.
581 * Note that the argv strings could be pointing *anywhere* in
582 * the user address space and are no longer contiguous.
583 * Note that *argv is modified when we are going to fetch a string
584 * that crosses a page boundary. We copy the next part of the string
585 * into to "np" and eventually convert the pointer.
587 while (argv < kd->argv + narg && *argv != 0) {
589 /* get the address that the current argv string is on */
590 addr = (u_long)*argv & ~(PAGE_SIZE - 1);
592 /* is it the same page as the last one? */
594 if (kvm_uread(kd, kp, addr, kd->argbuf, PAGE_SIZE) !=
600 /* offset within the page... kd->argbuf */
601 addr = (u_long)*argv & (PAGE_SIZE - 1);
603 /* cp = start of string, cc = count of chars in this chunk */
604 cp = kd->argbuf + addr;
605 cc = PAGE_SIZE - addr;
607 /* dont get more than asked for by user process */
608 if (maxcnt > 0 && cc > maxcnt - len)
611 /* pointer to end of string if we found it in this page */
612 ep = memchr(cp, '\0', cc);
616 * at this point, cc is the count of the chars that we are
617 * going to retrieve this time. we may or may not have found
618 * the end of it. (ep points to the null if the end is known)
621 /* will we exceed the malloc/realloced buffer? */
622 if (len + cc > kd->arglen) {
625 register char *op = kd->argspc;
628 kd->argspc = (char *)_kvm_realloc(kd, kd->argspc,
633 * Adjust argv pointers in case realloc moved
636 off = kd->argspc - op;
637 for (pp = kd->argv; pp < argv; pp++)
642 /* np = where to put the next part of the string in kd->argspc*/
643 /* np is kinda redundant.. could use "kd->argspc + len" */
645 np += cc; /* inc counters */
649 * if end of string found, set the *argv pointer to the
650 * saved beginning of string, and advance. argv points to
651 * somewhere in kd->argv.. This is initially relative
652 * to the target process, but when we close it off, we set
653 * it to point in our address space.
659 /* update the address relative to the target process */
663 if (maxcnt > 0 && len >= maxcnt) {
665 * We're stopping prematurely. Terminate the
675 /* Make sure argv is terminated. */
682 struct ps_strings *p;
686 *addr = (u_long)p->ps_argvstr;
692 struct ps_strings *p;
696 *addr = (u_long)p->ps_envstr;
701 * Determine if the proc indicated by p is still active.
702 * This test is not 100% foolproof in theory, but chances of
703 * being wrong are very low.
707 struct kinfo_proc *curkp;
709 struct kinfo_proc newkp;
715 mib[2] = KERN_PROC_PID;
716 mib[3] = curkp->ki_pid;
718 if (sysctl(mib, 4, &newkp, &len, NULL, 0) == -1)
720 return (curkp->ki_pid == newkp.ki_pid &&
721 (newkp.ki_stat != SZOMB || curkp->ki_stat == SZOMB));
725 kvm_doargv(kd, kp, nchr, info)
727 struct kinfo_proc *kp;
729 void (*info)(struct ps_strings *, u_long *, int *);
734 static struct ps_strings arginfo;
735 static u_long ps_strings;
738 if (ps_strings == NULL) {
739 len = sizeof(ps_strings);
740 if (sysctlbyname("kern.ps_strings", &ps_strings, &len, NULL,
742 ps_strings = PS_STRINGS;
746 * Pointers are stored at the top of the user stack.
748 if (kp->ki_stat == SZOMB ||
749 kvm_uread(kd, kp, ps_strings, (char *)&arginfo,
750 sizeof(arginfo)) != sizeof(arginfo))
753 (*info)(&arginfo, &addr, &cnt);
756 ap = kvm_argv(kd, kp, addr, cnt, nchr);
758 * For live kernels, make sure this process didn't go away.
760 if (ap != 0 && ISALIVE(kd) && !proc_verify(kp))
766 * Get the command args. This code is now machine independent.
769 kvm_getargv(kd, kp, nchr)
771 const struct kinfo_proc *kp;
777 static unsigned long buflen;
778 static char *buf, *p;
783 _kvm_err(kd, kd->program,
784 "cannot read user space from dead kernel");
789 bufsz = sizeof(buflen);
790 i = sysctlbyname("kern.ps_arg_cache_limit",
791 &buflen, &bufsz, NULL, 0);
795 buf = malloc(buflen);
799 bufp = malloc(sizeof(char *) * argc);
805 oid[2] = KERN_PROC_ARGS;
808 i = sysctl(oid, 4, buf, &bufsz, 0, 0);
809 if (i == 0 && bufsz > 0) {
818 sizeof(char *) * argc);
820 } while (p < buf + bufsz);
825 if (kp->ki_flag & P_SYSTEM)
827 return (kvm_doargv(kd, kp, nchr, ps_str_a));
831 kvm_getenvv(kd, kp, nchr)
833 const struct kinfo_proc *kp;
836 return (kvm_doargv(kd, kp, nchr, ps_str_e));
840 * Read from user space. The user context is given by p.
843 kvm_uread(kd, kp, uva, buf, len)
845 struct kinfo_proc *kp;
851 char procfile[MAXPATHLEN];
856 _kvm_err(kd, kd->program,
857 "cannot read user space from dead kernel");
861 sprintf(procfile, "/proc/%d/mem", kp->ki_pid);
862 fd = open(procfile, O_RDONLY, 0);
864 _kvm_err(kd, kd->program, "cannot open %s", procfile);
872 if (lseek(fd, (off_t)uva, 0) == -1 && errno != 0) {
873 _kvm_err(kd, kd->program, "invalid address (%x) in %s",
877 amount = read(fd, cp, len);
879 _kvm_syserr(kd, kd->program, "error reading %s",
884 _kvm_err(kd, kd->program, "EOF reading %s", procfile);
893 return ((ssize_t)(cp - buf));
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