1 /* 2 * top - a top users display for Unix 3 * 4 * SYNOPSIS: For DragonFly 2.x and later 5 * 6 * DESCRIPTION: 7 * Originally written for BSD4.4 system by Christos Zoulas. 8 * Ported to FreeBSD 2.x by Steven Wallace && Wolfram Schneider 9 * Order support hacked in from top-3.5beta6/machine/m_aix41.c 10 * by Monte Mitzelfelt (for latest top see http://www.groupsys.com/topinfo/) 11 * 12 * This is the machine-dependent module for DragonFly 2.5.1 13 * Should work for: 14 * DragonFly 2.x and above 15 * 16 * LIBS: -lkvm 17 * 18 * AUTHOR: Jan Lentfer <Jan.Lentfer@web.de> 19 * This module has been put together from different sources and is based on the 20 * work of many other people, e.g. Matthew Dillon, Simon Schubert, Jordan Gordeev. 21 * 22 * $FreeBSD: src/usr.bin/top/machine.c,v 1.29.2.2 2001/07/31 20:27:05 tmm Exp $ 23 */ 24 25 #include <sys/user.h> 26 #include <sys/types.h> 27 #include <sys/time.h> 28 #include <sys/signal.h> 29 #include <sys/param.h> 30 31 #include "os.h" 32 #include <err.h> 33 #include <fcntl.h> 34 #include <kvm.h> 35 #include <stdio.h> 36 #include <unistd.h> 37 #include <math.h> 38 #include <pwd.h> 39 #include <sys/errno.h> 40 #include <sys/sysctl.h> 41 #include <sys/vmmeter.h> 42 #include <sys/resource.h> 43 #include <sys/rtprio.h> 44 45 /* Swap */ 46 #include <stdlib.h> 47 #include <string.h> 48 #include <sys/conf.h> 49 50 #include <osreldate.h> /* for changes in kernel structures */ 51 52 #include <sys/kinfo.h> 53 #include <kinfo.h> 54 #include "top.h" 55 #include "display.h" 56 #include "machine.h" 57 #include "screen.h" 58 #include "utils.h" 59 60 int swapmode(int *retavail, int *retfree); 61 static int namelength; 62 static int cmdlength; 63 static int show_fullcmd; 64 65 int n_cpus, enable_ncpus; 66 67 /* get_process_info passes back a handle. This is what it looks like: */ 68 69 struct handle { 70 struct kinfo_proc **next_proc; /* points to next valid proc pointer */ 71 int remaining; /* number of pointers remaining */ 72 int show_threads; 73 }; 74 75 /* declarations for load_avg */ 76 #include "loadavg.h" 77 78 #define PP(pp, field) ((pp)->kp_ ## field) 79 #define LP(pp, field) ((pp)->kp_lwp.kl_ ## field) 80 #define VP(pp, field) ((pp)->kp_vm_ ## field) 81 82 /* what we consider to be process size: */ 83 #define PROCSIZE(pp) (VP((pp), map_size) / 1024) 84 85 /* 86 * These definitions control the format of the per-process area 87 */ 88 89 static char smp_header[] = 90 " PID %-*.*s NICE SIZE RES STATE C TIME CTIME CPU COMMAND"; 91 92 #define smp_Proc_format \ 93 "%6d %-*.*s %3d%7s %6s %8.8s %3d %6s %7s %5.2f%% %.*s" 94 95 /* process state names for the "STATE" column of the display */ 96 /* 97 * the extra nulls in the string "run" are for adding a slash and the 98 * processor number when needed 99 */ 100 101 const char *state_abbrev[] = { 102 "", "RUN\0\0\0", "STOP", "SLEEP", 103 }; 104 105 106 static kvm_t *kd; 107 108 /* values that we stash away in _init and use in later routines */ 109 110 static long lastpid; 111 112 /* these are for calculating cpu state percentages */ 113 114 static struct kinfo_cputime *cp_time, *cp_old; 115 116 /* these are for detailing the process states */ 117 118 #define MAXPSTATES 6 119 120 int process_states[MAXPSTATES]; 121 122 char *procstatenames[] = { 123 " running, ", " idle, ", " active, ", " stopped, ", " zombie, ", 124 NULL 125 }; 126 127 /* these are for detailing the cpu states */ 128 #define CPU_STATES 5 129 int *cpu_states; 130 int* cpu_averages; 131 char *cpustatenames[CPU_STATES + 1] = { 132 "user", "nice", "system", "interrupt", "idle", NULL 133 }; 134 135 /* these are for detailing the memory statistics */ 136 137 long memory_stats[7]; 138 char *memorynames[] = { 139 "K Active, ", "K Inact, ", "K Wired, ", "K Cache, ", "K Buf, ", "K Free", 140 NULL 141 }; 142 143 long swap_stats[7]; 144 char *swapnames[] = { 145 /* 0 1 2 3 4 5 */ 146 "K Total, ", "K Used, ", "K Free, ", "% Inuse, ", "K In, ", "K Out", 147 NULL 148 }; 149 150 151 /* these are for keeping track of the proc array */ 152 153 static int nproc; 154 static int onproc = -1; 155 static int pref_len; 156 static struct kinfo_proc *pbase; 157 static struct kinfo_proc **pref; 158 159 static uint64_t prev_pbase_time; /* unit: us */ 160 static struct kinfo_proc *prev_pbase; 161 static int prev_pbase_alloc; 162 static int prev_nproc; 163 static int fscale; 164 165 /* these are for getting the memory statistics */ 166 167 static int pageshift; /* log base 2 of the pagesize */ 168 169 /* define pagetok in terms of pageshift */ 170 171 #define pagetok(size) ((size) << pageshift) 172 173 /* sorting orders. first is default */ 174 char *ordernames[] = { 175 "cpu", "size", "res", "time", "pri", "thr", "pid", "ctime", "pres", NULL 176 }; 177 178 /* compare routines */ 179 int proc_compare (struct kinfo_proc **, struct kinfo_proc **); 180 int compare_size (struct kinfo_proc **, struct kinfo_proc **); 181 int compare_res (struct kinfo_proc **, struct kinfo_proc **); 182 int compare_time (struct kinfo_proc **, struct kinfo_proc **); 183 int compare_ctime (struct kinfo_proc **, struct kinfo_proc **); 184 int compare_prio(struct kinfo_proc **, struct kinfo_proc **); 185 int compare_thr (struct kinfo_proc **, struct kinfo_proc **); 186 int compare_pid (struct kinfo_proc **, struct kinfo_proc **); 187 int compare_pres(struct kinfo_proc **, struct kinfo_proc **); 188 189 int (*proc_compares[]) (struct kinfo_proc **,struct kinfo_proc **) = { 190 proc_compare, 191 compare_size, 192 compare_res, 193 compare_time, 194 compare_prio, 195 compare_thr, 196 compare_pid, 197 compare_ctime, 198 compare_pres, 199 NULL 200 }; 201 202 static void 203 cputime_percentages(int out[CPU_STATES], struct kinfo_cputime *new, 204 struct kinfo_cputime *old) 205 { 206 struct kinfo_cputime diffs; 207 uint64_t total_change, half_total; 208 209 /* initialization */ 210 total_change = 0; 211 212 diffs.cp_user = new->cp_user - old->cp_user; 213 diffs.cp_nice = new->cp_nice - old->cp_nice; 214 diffs.cp_sys = new->cp_sys - old->cp_sys; 215 diffs.cp_intr = new->cp_intr - old->cp_intr; 216 diffs.cp_idle = new->cp_idle - old->cp_idle; 217 total_change = diffs.cp_user + diffs.cp_nice + diffs.cp_sys + 218 diffs.cp_intr + diffs.cp_idle; 219 old->cp_user = new->cp_user; 220 old->cp_nice = new->cp_nice; 221 old->cp_sys = new->cp_sys; 222 old->cp_intr = new->cp_intr; 223 old->cp_idle = new->cp_idle; 224 225 /* avoid divide by zero potential */ 226 if (total_change == 0) 227 total_change = 1; 228 229 /* calculate percentages based on overall change, rounding up */ 230 half_total = total_change >> 1; 231 232 out[0] = ((diffs.cp_user * 1000LL + half_total) / total_change); 233 out[1] = ((diffs.cp_nice * 1000LL + half_total) / total_change); 234 out[2] = ((diffs.cp_sys * 1000LL + half_total) / total_change); 235 out[3] = ((diffs.cp_intr * 1000LL + half_total) / total_change); 236 out[4] = ((diffs.cp_idle * 1000LL + half_total) / total_change); 237 } 238 239 int 240 machine_init(struct statics *statics) 241 { 242 int pagesize; 243 size_t prmlen; 244 struct passwd *pw; 245 246 if (n_cpus < 1) { 247 if (kinfo_get_cpus(&n_cpus)) 248 err(1, "kinfo_get_cpus failed"); 249 } 250 /* get boot time */ 251 252 prmlen = sizeof(fscale); 253 if (sysctlbyname("kern.fscale", &fscale, &prmlen, NULL, 0) == -1) 254 err(1, "sysctl kern.fscale failed"); 255 256 while ((pw = getpwent()) != NULL) { 257 if ((int)strlen(pw->pw_name) > namelength) 258 namelength = strlen(pw->pw_name); 259 } 260 if (namelength < 8) 261 namelength = 8; 262 if (namelength > 13) 263 namelength = 13; 264 265 if ((kd = kvm_open(NULL, NULL, NULL, O_RDONLY, NULL)) == NULL) 266 return -1; 267 268 pbase = NULL; 269 pref = NULL; 270 nproc = 0; 271 onproc = -1; 272 prev_pbase = NULL; 273 prev_pbase_alloc = 0; 274 prev_pbase_time = 0; 275 prev_nproc = 0; 276 /* 277 * get the page size with "getpagesize" and calculate pageshift from 278 * it 279 */ 280 pagesize = getpagesize(); 281 pageshift = 0; 282 while (pagesize > 1) { 283 pageshift++; 284 pagesize >>= 1; 285 } 286 287 /* we only need the amount of log(2)1024 for our conversion */ 288 pageshift -= LOG1024; 289 290 /* fill in the statics information */ 291 statics->procstate_names = procstatenames; 292 statics->cpustate_names = cpustatenames; 293 statics->memory_names = memorynames; 294 statics->unused01 = 0; 295 statics->swap_names = swapnames; 296 statics->order_names = ordernames; 297 /* we need kvm descriptor in order to show full commands */ 298 statics->flags.fullcmds = kd != NULL; 299 statics->flags.threads = 1; 300 301 /* all done! */ 302 return (0); 303 } 304 305 char * 306 format_header(char *uname_field) 307 { 308 static char Header[128]; 309 310 snprintf(Header, sizeof(Header), smp_header, 311 namelength, namelength, uname_field); 312 313 if (screen_width <= 79) 314 cmdlength = 80; 315 else 316 cmdlength = screen_width; 317 318 cmdlength = cmdlength - strlen(Header) + 6; 319 320 return Header; 321 } 322 323 static int swappgsin = -1; 324 static int swappgsout = -1; 325 extern struct timeval timeout; 326 327 void 328 get_system_info(struct system_info *si) 329 { 330 size_t len; 331 int cpu; 332 333 if (cpu_states == NULL) { 334 cpu_states = malloc(sizeof(*cpu_states) * CPU_STATES * n_cpus); 335 if (cpu_states == NULL) 336 err(1, "malloc"); 337 bzero(cpu_states, sizeof(*cpu_states) * CPU_STATES * n_cpus); 338 } 339 if (cp_time == NULL) { 340 cp_time = malloc(2 * n_cpus * sizeof(cp_time[0])); 341 if (cp_time == NULL) 342 err(1, "cp_time"); 343 cp_old = cp_time + n_cpus; 344 len = n_cpus * sizeof(cp_old[0]); 345 bzero(cp_time, len); 346 if (sysctlbyname("kern.cputime", cp_old, &len, NULL, 0)) 347 err(1, "kern.cputime"); 348 } 349 len = n_cpus * sizeof(cp_time[0]); 350 bzero(cp_time, len); 351 if (sysctlbyname("kern.cputime", cp_time, &len, NULL, 0)) 352 err(1, "kern.cputime"); 353 354 getloadavg(si->load_avg, 3); 355 356 lastpid = 0; 357 358 /* convert cp_time counts to percentages */ 359 int combine_cpus = (enable_ncpus == 0 && n_cpus > 1); 360 for (cpu = 0; cpu < n_cpus; ++cpu) { 361 cputime_percentages(cpu_states + cpu * CPU_STATES, 362 &cp_time[cpu], &cp_old[cpu]); 363 } 364 if (combine_cpus) { 365 if (cpu_averages == NULL) { 366 cpu_averages = malloc(sizeof(*cpu_averages) * CPU_STATES); 367 if (cpu_averages == NULL) 368 err(1, "cpu_averages"); 369 } 370 bzero(cpu_averages, sizeof(*cpu_averages) * CPU_STATES); 371 for (cpu = 0; cpu < n_cpus; ++cpu) { 372 int j = 0; 373 cpu_averages[0] += *(cpu_states + ((cpu * CPU_STATES) + j++) ); 374 cpu_averages[1] += *(cpu_states + ((cpu * CPU_STATES) + j++) ); 375 cpu_averages[2] += *(cpu_states + ((cpu * CPU_STATES) + j++) ); 376 cpu_averages[3] += *(cpu_states + ((cpu * CPU_STATES) + j++) ); 377 cpu_averages[4] += *(cpu_states + ((cpu * CPU_STATES) + j++) ); 378 } 379 for (int i = 0; i < CPU_STATES; ++i) 380 cpu_averages[i] /= n_cpus; 381 } 382 383 /* sum memory & swap statistics */ 384 { 385 struct vmmeter vmm; 386 struct vmstats vms; 387 size_t vms_size = sizeof(vms); 388 size_t vmm_size = sizeof(vmm); 389 static unsigned int swap_delay = 0; 390 static int swapavail = 0; 391 static int swapfree = 0; 392 static long bufspace = 0; 393 394 if (sysctlbyname("vm.vmstats", &vms, &vms_size, NULL, 0)) 395 err(1, "sysctlbyname: vm.vmstats"); 396 397 if (sysctlbyname("vm.vmmeter", &vmm, &vmm_size, NULL, 0)) 398 err(1, "sysctlbyname: vm.vmmeter"); 399 400 if (kinfo_get_vfs_bufspace(&bufspace)) 401 err(1, "kinfo_get_vfs_bufspace"); 402 403 /* convert memory stats to Kbytes */ 404 memory_stats[0] = pagetok(vms.v_active_count); 405 memory_stats[1] = pagetok(vms.v_inactive_count); 406 memory_stats[2] = pagetok(vms.v_wire_count); 407 memory_stats[3] = pagetok(vms.v_cache_count); 408 memory_stats[4] = bufspace / 1024; 409 memory_stats[5] = pagetok(vms.v_free_count); 410 memory_stats[6] = -1; 411 412 /* first interval */ 413 if (swappgsin < 0) { 414 swap_stats[4] = 0; 415 swap_stats[5] = 0; 416 } 417 /* compute differences between old and new swap statistic */ 418 else { 419 swap_stats[4] = pagetok(((vmm.v_swappgsin - swappgsin))); 420 swap_stats[5] = pagetok(((vmm.v_swappgsout - swappgsout))); 421 } 422 423 swappgsin = vmm.v_swappgsin; 424 swappgsout = vmm.v_swappgsout; 425 426 /* call CPU heavy swapmode() only for changes */ 427 if (swap_stats[4] > 0 || swap_stats[5] > 0 || swap_delay == 0) { 428 swap_stats[3] = swapmode(&swapavail, &swapfree); 429 swap_stats[0] = swapavail; 430 swap_stats[1] = swapavail - swapfree; 431 swap_stats[2] = swapfree; 432 } 433 swap_delay = 1; 434 swap_stats[6] = -1; 435 } 436 437 /* set arrays and strings */ 438 si->cpustates = combine_cpus == 1 ? 439 cpu_averages : cpu_states; 440 si->memory = memory_stats; 441 si->swap = swap_stats; 442 443 444 if (lastpid > 0) { 445 si->last_pid = lastpid; 446 } else { 447 si->last_pid = -1; 448 } 449 } 450 451 452 static struct handle handle; 453 454 static void 455 fixup_pctcpu(struct kinfo_proc *fixit, uint64_t d) 456 { 457 struct kinfo_proc *pp; 458 uint64_t ticks; 459 int i; 460 461 if (prev_nproc == 0 || d == 0) 462 return; 463 464 if (LP(fixit, pid) == -1) { 465 /* Skip kernel "idle" threads */ 466 if (PP(fixit, stat) == SIDL) 467 return; 468 for (pp = prev_pbase, i = 0; i < prev_nproc; pp++, i++) { 469 if (LP(pp, pid) == -1 && 470 PP(pp, ktaddr) == PP(fixit, ktaddr)) 471 break; 472 } 473 } else { 474 for (pp = prev_pbase, i = 0; i < prev_nproc; pp++, i++) { 475 if (LP(pp, pid) == LP(fixit, pid) && 476 LP(pp, tid) == LP(fixit, tid)) { 477 if (PP(pp, paddr) != PP(fixit, paddr)) { 478 /* pid/tid are reused */ 479 pp = NULL; 480 } 481 break; 482 } 483 } 484 } 485 if (i == prev_nproc || pp == NULL) 486 return; 487 488 ticks = LP(fixit, iticks) - LP(pp, iticks); 489 ticks += LP(fixit, sticks) - LP(pp, sticks); 490 ticks += LP(fixit, uticks) - LP(pp, uticks); 491 if (ticks > d * 1000) 492 ticks = d * 1000; 493 LP(fixit, pctcpu) = (ticks * (uint64_t)fscale) / d; 494 } 495 496 caddr_t 497 get_process_info(struct system_info *si, struct process_select *sel, 498 int compare_index) 499 { 500 struct timespec tv; 501 uint64_t t, d = 0; 502 503 int i; 504 int total_procs; 505 int active_procs; 506 struct kinfo_proc **prefp; 507 struct kinfo_proc *pp; 508 509 /* these are copied out of sel for speed */ 510 int show_idle; 511 int show_system; 512 int show_uid; 513 int show_threads; 514 int kvmflags; 515 char *match_command; 516 517 show_threads = sel->threads; 518 show_system = sel->system; 519 520 kvmflags = 0; 521 if (show_threads) 522 kvmflags |= KERN_PROC_FLAG_LWP; 523 #ifdef KERN_PROC_FLAG_LWKT 524 if (show_system) 525 kvmflags |= KERN_PROC_FLAG_LWKT; 526 #endif 527 pbase = kvm_getprocs(kd, KERN_PROC_ALL | kvmflags, 0, &nproc); 528 if (nproc > onproc) 529 pref = (struct kinfo_proc **)realloc(pref, sizeof(struct kinfo_proc *) 530 * (onproc = nproc)); 531 if (pref == NULL || pbase == NULL) { 532 (void)fprintf(stderr, "top: Out of memory.\n"); 533 quit(23); 534 } 535 536 clock_gettime(CLOCK_MONOTONIC_PRECISE, &tv); 537 t = (tv.tv_sec * 1000000ULL) + (tv.tv_nsec / 1000ULL); 538 if (prev_pbase_time > 0 && t > prev_pbase_time) 539 d = t - prev_pbase_time; 540 541 /* get a pointer to the states summary array */ 542 si->procstates = process_states; 543 544 /* set up flags which define what we are going to select */ 545 show_idle = sel->idle; 546 show_uid = sel->uid != -1; 547 show_fullcmd = sel->fullcmd; 548 match_command = sel->command; 549 550 /* count up process states and get pointers to interesting procs */ 551 total_procs = 0; 552 active_procs = 0; 553 memset((char *)process_states, 0, sizeof(process_states)); 554 prefp = pref; 555 for (pp = pbase, i = 0; i < nproc; pp++, i++) { 556 /* 557 * Place pointers to each valid proc structure in pref[]. 558 * Process slots that are actually in use have a non-zero 559 * status field. Processes with P_SYSTEM set are system 560 * processes---these get ignored unless show_sysprocs is set. 561 */ 562 if ((show_system && (LP(pp, pid) == -1)) || 563 (show_system || ((PP(pp, flags) & P_SYSTEM) == 0))) { 564 int lpstate = LP(pp, stat); 565 int pstate = PP(pp, stat); 566 567 total_procs++; 568 if (lpstate == LSRUN) 569 process_states[0]++; 570 if (pstate >= 0 && pstate < MAXPSTATES - 1) 571 process_states[pstate]++; 572 573 if (match_command != NULL && 574 strstr(PP(pp, comm), match_command) == NULL) { 575 /* Command does not match */ 576 continue; 577 } 578 579 if (show_uid && PP(pp, ruid) != (uid_t)sel->uid) { 580 /* UID does not match */ 581 continue; 582 } 583 584 if (!show_system && LP(pp, pid) == -1) { 585 /* Don't show system processes */ 586 continue; 587 } 588 589 /* Fix up pctcpu before show_idle test */ 590 fixup_pctcpu(pp, d); 591 592 if (!show_idle && LP(pp, pctcpu) == 0 && 593 lpstate != LSRUN) { 594 /* Don't show idle processes */ 595 continue; 596 } 597 598 *prefp++ = pp; 599 active_procs++; 600 } 601 } 602 603 /* 604 * Save kinfo_procs for later pctcpu fixup. 605 */ 606 if (prev_pbase_alloc < nproc) { 607 prev_pbase_alloc = nproc; 608 prev_pbase = realloc(prev_pbase, 609 prev_pbase_alloc * sizeof(struct kinfo_proc)); 610 if (prev_pbase == NULL) { 611 fprintf(stderr, "top: Out of memory.\n"); 612 quit(23); 613 } 614 } 615 prev_nproc = nproc; 616 prev_pbase_time = t; 617 memcpy(prev_pbase, pbase, nproc * sizeof(struct kinfo_proc)); 618 619 qsort((char *)pref, active_procs, sizeof(struct kinfo_proc *), 620 (int (*)(const void *, const void *))proc_compares[compare_index]); 621 622 /* remember active and total counts */ 623 si->p_total = total_procs; 624 si->p_active = pref_len = active_procs; 625 626 /* pass back a handle */ 627 handle.next_proc = pref; 628 handle.remaining = active_procs; 629 handle.show_threads = show_threads; 630 return ((caddr_t) & handle); 631 } 632 633 char fmt[MAX_COLS]; /* static area where result is built */ 634 635 char * 636 format_next_process(caddr_t xhandle, char *(*get_userid) (int)) 637 { 638 struct kinfo_proc *pp; 639 long cputime; 640 long ccputime; 641 double pct; 642 struct handle *hp; 643 char status[16]; 644 int state; 645 int xnice; 646 char *comm; 647 char cputime_fmt[10], ccputime_fmt[10]; 648 649 /* find and remember the next proc structure */ 650 hp = (struct handle *)xhandle; 651 pp = *(hp->next_proc++); 652 hp->remaining--; 653 654 /* get the process's command name */ 655 if (show_fullcmd) { 656 char **comm_full = kvm_getargv(kd, pp, 0); 657 if (comm_full != NULL) 658 comm = *comm_full; 659 else 660 comm = PP(pp, comm); 661 } 662 else { 663 comm = PP(pp, comm); 664 } 665 666 /* the actual field to display */ 667 char cmdfield[MAX_COLS]; 668 669 if (PP(pp, flags) & P_SYSTEM) { 670 /* system process */ 671 snprintf(cmdfield, sizeof cmdfield, "[%s]", comm); 672 } else if (hp->show_threads && PP(pp, nthreads) > 1) { 673 /* display it as a thread */ 674 if (strcmp(PP(pp, comm), LP(pp, comm)) == 0) { 675 snprintf(cmdfield, sizeof cmdfield, "%s{%d}", comm, 676 LP(pp, tid)); 677 } else { 678 /* show thread name in addition to tid */ 679 snprintf(cmdfield, sizeof cmdfield, "%s{%d/%s}", comm, 680 LP(pp, tid), LP(pp, comm)); 681 } 682 } else { 683 snprintf(cmdfield, sizeof cmdfield, "%s", comm); 684 } 685 686 /* 687 * Convert the process's runtime from microseconds to seconds. This 688 * time includes the interrupt time to be in compliance with ps output. 689 */ 690 cputime = (LP(pp, uticks) + LP(pp, sticks) + LP(pp, iticks)) / 1000000; 691 ccputime = cputime + PP(pp, cru).ru_stime.tv_sec + PP(pp, cru).ru_utime.tv_sec; 692 format_time(cputime, cputime_fmt, sizeof(cputime_fmt)); 693 format_time(ccputime, ccputime_fmt, sizeof(ccputime_fmt)); 694 695 /* calculate the base for cpu percentages */ 696 pct = pctdouble(LP(pp, pctcpu)); 697 698 /* generate "STATE" field */ 699 switch (state = LP(pp, stat)) { 700 case LSRUN: 701 if (LP(pp, tdflags) & TDF_RUNNING) 702 sprintf(status, "CPU%d", LP(pp, cpuid)); 703 else 704 strcpy(status, "RUN"); 705 break; 706 case LSSLEEP: 707 if (LP(pp, wmesg) != NULL) { 708 sprintf(status, "%.8s", LP(pp, wmesg)); /* WMESGLEN */ 709 break; 710 } 711 /* fall through */ 712 default: 713 714 if (state >= 0 && (unsigned)state < NELEM(state_abbrev)) 715 sprintf(status, "%.6s", state_abbrev[(unsigned char)state]); 716 else 717 sprintf(status, "?%5d", state); 718 break; 719 } 720 721 if (PP(pp, stat) == SZOMB) 722 strcpy(status, "ZOMB"); 723 724 /* 725 * idle time 0 - 31 -> nice value +21 - +52 normal time -> nice 726 * value -20 - +20 real time 0 - 31 -> nice value -52 - -21 thread 727 * 0 - 31 -> nice value -53 - 728 */ 729 switch (LP(pp, rtprio.type)) { 730 case RTP_PRIO_REALTIME: 731 xnice = PRIO_MIN - 1 - RTP_PRIO_MAX + LP(pp, rtprio.prio); 732 break; 733 case RTP_PRIO_IDLE: 734 xnice = PRIO_MAX + 1 + LP(pp, rtprio.prio); 735 break; 736 case RTP_PRIO_THREAD: 737 xnice = PRIO_MIN - 1 - RTP_PRIO_MAX - LP(pp, rtprio.prio); 738 break; 739 default: 740 xnice = PP(pp, nice); 741 break; 742 } 743 744 /* format this entry */ 745 snprintf(fmt, sizeof(fmt), 746 smp_Proc_format, 747 (int)PP(pp, pid), 748 namelength, namelength, 749 get_userid(PP(pp, ruid)), 750 (int)xnice, 751 format_k(PROCSIZE(pp)), 752 format_k(pagetok(VP(pp, rssize))), 753 status, 754 LP(pp, cpuid), 755 cputime_fmt, 756 ccputime_fmt, 757 100.0 * pct, 758 cmdlength, 759 cmdfield); 760 761 /* return the result */ 762 return (fmt); 763 } 764 765 /* comparison routines for qsort */ 766 767 /* 768 * proc_compare - comparison function for "qsort" 769 * Compares the resource consumption of two processes using five 770 * distinct keys. The keys (in descending order of importance) are: 771 * percent cpu, cpu ticks, state, resident set size, total virtual 772 * memory usage. The process states are ordered as follows (from least 773 * to most important): WAIT, zombie, sleep, stop, start, run. The 774 * array declaration below maps a process state index into a number 775 * that reflects this ordering. 776 */ 777 778 static unsigned char sorted_state[] = 779 { 780 0, /* not used */ 781 3, /* sleep */ 782 1, /* ABANDONED (WAIT) */ 783 6, /* run */ 784 5, /* start */ 785 2, /* zombie */ 786 4 /* stop */ 787 }; 788 789 790 #define ORDERKEY_PCTCPU \ 791 if (lresult = (long) LP(p2, pctcpu) - (long) LP(p1, pctcpu), \ 792 (result = lresult > 0 ? 1 : lresult < 0 ? -1 : 0) == 0) 793 794 #define CPTICKS(p) (LP(p, uticks) + LP(p, sticks) + LP(p, iticks)) 795 796 #define ORDERKEY_CPTICKS \ 797 if ((result = CPTICKS(p2) > CPTICKS(p1) ? 1 : \ 798 CPTICKS(p2) < CPTICKS(p1) ? -1 : 0) == 0) 799 800 #define CTIME(p) (((LP(p, uticks) + LP(p, sticks) + LP(p, iticks))/1000000) + \ 801 PP(p, cru).ru_stime.tv_sec + PP(p, cru).ru_utime.tv_sec) 802 803 #define ORDERKEY_CTIME \ 804 if ((result = CTIME(p2) > CTIME(p1) ? 1 : \ 805 CTIME(p2) < CTIME(p1) ? -1 : 0) == 0) 806 807 #define ORDERKEY_STATE \ 808 if ((result = sorted_state[(unsigned char) PP(p2, stat)] - \ 809 sorted_state[(unsigned char) PP(p1, stat)]) == 0) 810 811 #define ORDERKEY_PRIO \ 812 if ((result = LP(p2, prio) - LP(p1, prio)) == 0) 813 814 #define ORDERKEY_KTHREADS \ 815 if ((result = (LP(p1, pid) == 0) - (LP(p2, pid) == 0)) == 0) 816 817 #define ORDERKEY_KTHREADS_PRIO \ 818 if ((result = LP(p2, tdprio) - LP(p1, tdprio)) == 0) 819 820 #define ORDERKEY_RSSIZE \ 821 if ((result = VP(p2, rssize) - VP(p1, rssize)) == 0) 822 823 #define ORDERKEY_MEM \ 824 if ( (result = PROCSIZE(p2) - PROCSIZE(p1)) == 0 ) 825 826 #define ORDERKEY_PID \ 827 if ( (result = PP(p1, pid) - PP(p2, pid)) == 0) 828 829 #define ORDERKEY_PRSSIZE \ 830 if((result = VP(p2, prssize) - VP(p1, prssize)) == 0) 831 832 static __inline int 833 orderkey_kernidle(const struct kinfo_proc *p1, const struct kinfo_proc *p2) 834 { 835 int p1_kidle = 0, p2_kidle = 0; 836 837 if (LP(p1, pid) == -1 && PP(p1, stat) == SIDL) 838 p1_kidle = 1; 839 if (LP(p2, pid) == -1 && PP(p2, stat) == SIDL) 840 p2_kidle = 1; 841 842 if (!p2_kidle && p1_kidle) 843 return 1; 844 if (p2_kidle && !p1_kidle) 845 return -1; 846 return 0; 847 } 848 849 #define ORDERKEY_KIDLE if ((result = orderkey_kernidle(p1, p2)) == 0) 850 851 /* compare_cpu - the comparison function for sorting by cpu percentage */ 852 853 int 854 proc_compare(struct kinfo_proc **pp1, struct kinfo_proc **pp2) 855 { 856 struct kinfo_proc *p1; 857 struct kinfo_proc *p2; 858 int result; 859 pctcpu lresult; 860 861 /* remove one level of indirection */ 862 p1 = *(struct kinfo_proc **) pp1; 863 p2 = *(struct kinfo_proc **) pp2; 864 865 ORDERKEY_KIDLE 866 ORDERKEY_PCTCPU 867 ORDERKEY_CPTICKS 868 ORDERKEY_STATE 869 ORDERKEY_PRIO 870 ORDERKEY_RSSIZE 871 ORDERKEY_MEM 872 {} 873 874 return (result); 875 } 876 877 /* compare_size - the comparison function for sorting by total memory usage */ 878 879 int 880 compare_size(struct kinfo_proc **pp1, struct kinfo_proc **pp2) 881 { 882 struct kinfo_proc *p1; 883 struct kinfo_proc *p2; 884 int result; 885 pctcpu lresult; 886 887 /* remove one level of indirection */ 888 p1 = *(struct kinfo_proc **) pp1; 889 p2 = *(struct kinfo_proc **) pp2; 890 891 ORDERKEY_MEM 892 ORDERKEY_RSSIZE 893 ORDERKEY_KIDLE 894 ORDERKEY_PCTCPU 895 ORDERKEY_CPTICKS 896 ORDERKEY_STATE 897 ORDERKEY_PRIO 898 {} 899 900 return (result); 901 } 902 903 /* compare_res - the comparison function for sorting by resident set size */ 904 905 int 906 compare_res(struct kinfo_proc **pp1, struct kinfo_proc **pp2) 907 { 908 struct kinfo_proc *p1; 909 struct kinfo_proc *p2; 910 int result; 911 pctcpu lresult; 912 913 /* remove one level of indirection */ 914 p1 = *(struct kinfo_proc **) pp1; 915 p2 = *(struct kinfo_proc **) pp2; 916 917 ORDERKEY_RSSIZE 918 ORDERKEY_MEM 919 ORDERKEY_KIDLE 920 ORDERKEY_PCTCPU 921 ORDERKEY_CPTICKS 922 ORDERKEY_STATE 923 ORDERKEY_PRIO 924 {} 925 926 return (result); 927 } 928 929 /* compare_pres - the comparison function for sorting by proportional resident set size */ 930 931 int 932 compare_pres(struct kinfo_proc **pp1, struct kinfo_proc **pp2) 933 { 934 struct kinfo_proc *p1; 935 struct kinfo_proc *p2; 936 int result; 937 pctcpu lresult; 938 939 /* remove one level of indirection */ 940 p1 = *(struct kinfo_proc **) pp1; 941 p2 = *(struct kinfo_proc **) pp2; 942 943 ORDERKEY_PRSSIZE 944 ORDERKEY_RSSIZE 945 ORDERKEY_MEM 946 ORDERKEY_KIDLE 947 ORDERKEY_PCTCPU 948 ORDERKEY_CPTICKS 949 ORDERKEY_STATE 950 ORDERKEY_PRIO 951 {} 952 953 return (result); 954 } 955 956 /* compare_time - the comparison function for sorting by total cpu time */ 957 958 int 959 compare_time(struct kinfo_proc **pp1, struct kinfo_proc **pp2) 960 { 961 struct kinfo_proc *p1; 962 struct kinfo_proc *p2; 963 int result; 964 pctcpu lresult; 965 966 /* remove one level of indirection */ 967 p1 = *(struct kinfo_proc **) pp1; 968 p2 = *(struct kinfo_proc **) pp2; 969 970 ORDERKEY_KIDLE 971 ORDERKEY_CPTICKS 972 ORDERKEY_PCTCPU 973 ORDERKEY_KTHREADS 974 ORDERKEY_KTHREADS_PRIO 975 ORDERKEY_STATE 976 ORDERKEY_PRIO 977 ORDERKEY_RSSIZE 978 ORDERKEY_MEM 979 {} 980 981 return (result); 982 } 983 984 int 985 compare_ctime(struct kinfo_proc **pp1, struct kinfo_proc **pp2) 986 { 987 struct kinfo_proc *p1; 988 struct kinfo_proc *p2; 989 int result; 990 pctcpu lresult; 991 992 /* remove one level of indirection */ 993 p1 = *(struct kinfo_proc **) pp1; 994 p2 = *(struct kinfo_proc **) pp2; 995 996 ORDERKEY_KIDLE 997 ORDERKEY_CTIME 998 ORDERKEY_PCTCPU 999 ORDERKEY_KTHREADS 1000 ORDERKEY_KTHREADS_PRIO 1001 ORDERKEY_STATE 1002 ORDERKEY_PRIO 1003 ORDERKEY_RSSIZE 1004 ORDERKEY_MEM 1005 {} 1006 1007 return (result); 1008 } 1009 1010 /* compare_prio - the comparison function for sorting by cpu percentage */ 1011 1012 int 1013 compare_prio(struct kinfo_proc **pp1, struct kinfo_proc **pp2) 1014 { 1015 struct kinfo_proc *p1; 1016 struct kinfo_proc *p2; 1017 int result; 1018 pctcpu lresult; 1019 1020 /* remove one level of indirection */ 1021 p1 = *(struct kinfo_proc **) pp1; 1022 p2 = *(struct kinfo_proc **) pp2; 1023 1024 ORDERKEY_KTHREADS 1025 ORDERKEY_KTHREADS_PRIO 1026 ORDERKEY_PRIO 1027 ORDERKEY_KIDLE 1028 ORDERKEY_CPTICKS 1029 ORDERKEY_PCTCPU 1030 ORDERKEY_STATE 1031 ORDERKEY_RSSIZE 1032 ORDERKEY_MEM 1033 {} 1034 1035 return (result); 1036 } 1037 1038 int 1039 compare_thr(struct kinfo_proc **pp1, struct kinfo_proc **pp2) 1040 { 1041 struct kinfo_proc *p1; 1042 struct kinfo_proc *p2; 1043 int result; 1044 pctcpu lresult; 1045 1046 /* remove one level of indirection */ 1047 p1 = *(struct kinfo_proc **)pp1; 1048 p2 = *(struct kinfo_proc **)pp2; 1049 1050 ORDERKEY_KTHREADS 1051 ORDERKEY_KTHREADS_PRIO 1052 ORDERKEY_KIDLE 1053 ORDERKEY_CPTICKS 1054 ORDERKEY_PCTCPU 1055 ORDERKEY_STATE 1056 ORDERKEY_RSSIZE 1057 ORDERKEY_MEM 1058 {} 1059 1060 return (result); 1061 } 1062 1063 /* compare_pid - the comparison function for sorting by process id */ 1064 1065 int 1066 compare_pid(struct kinfo_proc **pp1, struct kinfo_proc **pp2) 1067 { 1068 struct kinfo_proc *p1; 1069 struct kinfo_proc *p2; 1070 int result; 1071 1072 /* remove one level of indirection */ 1073 p1 = *(struct kinfo_proc **) pp1; 1074 p2 = *(struct kinfo_proc **) pp2; 1075 1076 ORDERKEY_PID 1077 ; 1078 1079 return(result); 1080 } 1081 1082 /* 1083 * proc_owner(pid) - returns the uid that owns process "pid", or -1 if 1084 * the process does not exist. 1085 * It is EXTREMLY IMPORTANT that this function work correctly. 1086 * If top runs setuid root (as in SVR4), then this function 1087 * is the only thing that stands in the way of a serious 1088 * security problem. It validates requests for the "kill" 1089 * and "renice" commands. 1090 */ 1091 1092 int 1093 proc_owner(int pid) 1094 { 1095 int xcnt; 1096 struct kinfo_proc **prefp; 1097 struct kinfo_proc *pp; 1098 1099 prefp = pref; 1100 xcnt = pref_len; 1101 while (--xcnt >= 0) { 1102 pp = *prefp++; 1103 if (PP(pp, pid) == (pid_t) pid) { 1104 return ((int)PP(pp, ruid)); 1105 } 1106 } 1107 return (-1); 1108 } 1109 1110 1111 /* 1112 * swapmode is based on a program called swapinfo written 1113 * by Kevin Lahey <kml@rokkaku.atl.ga.us>. 1114 */ 1115 int 1116 swapmode(int *retavail, int *retfree) 1117 { 1118 int n; 1119 int pagesize = getpagesize(); 1120 struct kvm_swap swapary[1]; 1121 1122 *retavail = 0; 1123 *retfree = 0; 1124 1125 #define CONVERT(v) ((quad_t)(v) * pagesize / 1024) 1126 1127 n = kvm_getswapinfo(kd, swapary, 1, 0); 1128 if (n < 0 || swapary[0].ksw_total == 0) 1129 return (0); 1130 1131 *retavail = CONVERT(swapary[0].ksw_total); 1132 *retfree = CONVERT(swapary[0].ksw_total - swapary[0].ksw_used); 1133 1134 n = (int)((double)swapary[0].ksw_used * 100.0 / 1135 (double)swapary[0].ksw_total); 1136 return (n); 1137 } 1138