1 1.10 christos /* $NetBSD: syscall.c,v 1.10 2019/01/25 15:31:11 christos Exp $ */ 2 1.1 dsl 3 1.1 dsl /*- 4 1.1 dsl * Copyright (c) 2006 The NetBSD Foundation, Inc. 5 1.1 dsl * All rights reserved. 6 1.1 dsl * 7 1.1 dsl * This code is derived from software contributed to The NetBSD Foundation 8 1.1 dsl * by David Laight. 9 1.1 dsl * 10 1.1 dsl * Redistribution and use in source and binary forms, with or without 11 1.1 dsl * modification, are permitted provided that the following conditions 12 1.1 dsl * are met: 13 1.1 dsl * 1. Redistributions of source code must retain the above copyright 14 1.1 dsl * notice, this list of conditions and the following disclaimer. 15 1.1 dsl * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 dsl * notice, this list of conditions and the following disclaimer in the 17 1.1 dsl * documentation and/or other materials provided with the distribution. 18 1.1 dsl * 19 1.1 dsl * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 20 1.1 dsl * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 21 1.1 dsl * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 1.1 dsl * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 23 1.1 dsl * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 24 1.1 dsl * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 25 1.1 dsl * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 26 1.1 dsl * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 27 1.1 dsl * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 28 1.1 dsl * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 29 1.1 dsl * POSSIBILITY OF SUCH DAMAGE. 30 1.1 dsl */ 31 1.1 dsl 32 1.1 dsl #include <sys/cdefs.h> 33 1.10 christos __RCSID("$NetBSD: syscall.c,v 1.10 2019/01/25 15:31:11 christos Exp $"); 34 1.1 dsl 35 1.1 dsl /* System call stats */ 36 1.1 dsl 37 1.1 dsl #include <sys/param.h> 38 1.1 dsl #include <sys/namei.h> 39 1.1 dsl #include <sys/sysctl.h> 40 1.1 dsl 41 1.1 dsl #include <uvm/uvm_extern.h> 42 1.1 dsl 43 1.2 dsl #include <errno.h> 44 1.1 dsl #include <stdlib.h> 45 1.1 dsl #include <string.h> 46 1.1 dsl #include <util.h> 47 1.1 dsl 48 1.1 dsl #include "systat.h" 49 1.1 dsl #include "extern.h" 50 1.2 dsl #include "drvstats.h" 51 1.1 dsl #include "utmpentry.h" 52 1.1 dsl #include "vmstat.h" 53 1.1 dsl 54 1.1 dsl #include <sys/syscall.h> 55 1.1 dsl #include <../../sys/kern/syscalls.c> 56 1.1 dsl 57 1.1 dsl static struct Info { 58 1.2 dsl struct uvmexp_sysctl uvmexp; 59 1.2 dsl struct vmtotal Total; 60 1.2 dsl uint64_t counts[SYS_NSYSENT]; 61 1.2 dsl uint64_t times[SYS_NSYSENT]; 62 1.3 dsl } s, s1, s2; 63 1.3 dsl 64 1.3 dsl static uint64_t irf[SYS_NSYSENT], val[SYS_NSYSENT]; 65 1.3 dsl static int irf_first = 1; 66 1.1 dsl 67 1.1 dsl int syscall_sort[SYS_NSYSENT]; 68 1.1 dsl 69 1.1 dsl static enum sort_order { UNSORTED, NAMES, COUNTS } sort_order = NAMES; 70 1.1 dsl 71 1.2 dsl #define SHOW_COUNTS 1 72 1.2 dsl #define SHOW_TIMES 2 73 1.2 dsl static int show = SHOW_COUNTS; 74 1.2 dsl 75 1.2 dsl static void getinfo(struct Info *, int); 76 1.1 dsl 77 1.3 dsl static char buf[32]; 78 1.1 dsl 79 1.2 dsl static size_t counts_mib_len, times_mib_len; 80 1.2 dsl static int counts_mib[4], times_mib[4]; 81 1.1 dsl 82 1.1 dsl WINDOW * 83 1.1 dsl opensyscall(void) 84 1.1 dsl { 85 1.1 dsl return (stdscr); 86 1.1 dsl } 87 1.1 dsl 88 1.1 dsl void 89 1.1 dsl closesyscall(WINDOW *w) 90 1.1 dsl { 91 1.1 dsl 92 1.1 dsl if (w == NULL) 93 1.1 dsl return; 94 1.1 dsl wclear(w); 95 1.1 dsl wrefresh(w); 96 1.1 dsl } 97 1.1 dsl 98 1.1 dsl 99 1.1 dsl /* 100 1.1 dsl * These constants define where the major pieces are laid out 101 1.1 dsl */ 102 1.1 dsl #define SYSCALLROW 9 /* Below the vmstat header */ 103 1.1 dsl 104 1.1 dsl int 105 1.1 dsl initsyscall(void) 106 1.1 dsl { 107 1.1 dsl static char name[] = "name"; 108 1.1 dsl 109 1.1 dsl hertz = stathz ? stathz : hz; 110 1.1 dsl 111 1.1 dsl syscall_order(name); 112 1.1 dsl 113 1.2 dsl /* drvinit gets number of cpus! */ 114 1.2 dsl drvinit(1); 115 1.1 dsl 116 1.8 christos counts_mib_len = __arraycount(counts_mib); 117 1.8 christos if (sysctlnametomib("kern.syscalls.counts", counts_mib, 118 1.8 christos &counts_mib_len)) 119 1.2 dsl counts_mib_len = 0; 120 1.2 dsl 121 1.8 christos times_mib_len = __arraycount(times_mib); 122 1.2 dsl if (sysctlnametomib("kern.syscalls.times", times_mib, ×_mib_len)) 123 1.2 dsl times_mib_len = 0; 124 1.1 dsl 125 1.2 dsl getinfo(&s2, SHOW_COUNTS | SHOW_TIMES); 126 1.1 dsl s1 = s2; 127 1.2 dsl 128 1.1 dsl return(1); 129 1.1 dsl } 130 1.1 dsl 131 1.1 dsl void 132 1.1 dsl fetchsyscall(void) 133 1.1 dsl { 134 1.1 dsl time_t now; 135 1.1 dsl 136 1.1 dsl time(&now); 137 1.1 dsl strlcpy(buf, ctime(&now), sizeof(buf)); 138 1.1 dsl buf[19] = '\0'; 139 1.2 dsl getinfo(&s, show); 140 1.1 dsl } 141 1.1 dsl 142 1.1 dsl void 143 1.1 dsl labelsyscall(void) 144 1.1 dsl { 145 1.1 dsl labelvmstat_top(); 146 1.1 dsl } 147 1.1 dsl 148 1.3 dsl static void 149 1.3 dsl putuint64(uint64_t v, int row, int col, int width) 150 1.1 dsl { 151 1.3 dsl static const char suffix[] = "KMDT"; 152 1.3 dsl int len, i; 153 1.1 dsl 154 1.3 dsl len = snprintf(buf, sizeof buf, "%" PRIu64, v); 155 1.3 dsl if (len > width) { 156 1.3 dsl i = (len - width) / 3; 157 1.6 lukem if (i >= (int)sizeof(suffix)) { 158 1.3 dsl memset(buf, '*', width); 159 1.3 dsl len = width; 160 1.3 dsl } else { 161 1.3 dsl len -= (i + 1) * 3; 162 1.3 dsl buf[len++] = suffix[i]; 163 1.3 dsl } 164 1.3 dsl buf[len] = 0; 165 1.3 dsl } 166 1.3 dsl mvprintw(row, col, "%*s", width, buf); 167 1.2 dsl } 168 1.2 dsl 169 1.2 dsl static int 170 1.3 dsl compare_irf(const void *a, const void *b) 171 1.2 dsl { 172 1.2 dsl int ia = *(const int *)a, ib = *(const int *)b; 173 1.2 dsl int64_t delta; 174 1.1 dsl 175 1.3 dsl delta = irf[ib] - irf[ia]; 176 1.2 dsl return delta ? delta < 0 ? -1 : 1 : 0; 177 1.1 dsl } 178 1.1 dsl 179 1.1 dsl void 180 1.1 dsl showsyscall(void) 181 1.1 dsl { 182 1.1 dsl int i, ii, l, c; 183 1.3 dsl uint64_t v; 184 1.1 dsl static int failcnt = 0; 185 1.1 dsl static int relabel = 0; 186 1.3 dsl uint64_t itime; 187 1.1 dsl 188 1.1 dsl if (relabel) { 189 1.1 dsl labelsyscall(); 190 1.1 dsl relabel = 0; 191 1.1 dsl } 192 1.1 dsl 193 1.1 dsl cpuswap(); 194 1.1 dsl if (display_mode == TIME) { 195 1.10 christos if (toofast(&failcnt)) 196 1.1 dsl return; 197 1.1 dsl } else 198 1.1 dsl etime = 1.0; 199 1.3 dsl itime = etime * 100; 200 1.1 dsl 201 1.1 dsl failcnt = 0; 202 1.1 dsl 203 1.1 dsl show_vmstat_top(&s.Total, &s.uvmexp, &s1.uvmexp); 204 1.1 dsl 205 1.3 dsl /* Sort out the values we are going to display */ 206 1.8 christos for (i = 0; i < (int)__arraycount(s.counts); i++) { 207 1.3 dsl switch (show) { 208 1.3 dsl default: 209 1.3 dsl case SHOW_COUNTS: 210 1.3 dsl v = s.counts[i] - s1.counts[i]; 211 1.3 dsl break; 212 1.3 dsl case SHOW_TIMES: 213 1.3 dsl v = s.times[i] - s1.times[i]; 214 1.3 dsl break; 215 1.3 dsl case SHOW_COUNTS | SHOW_TIMES: /* time/count */ 216 1.3 dsl v = s.counts[i] - s1.counts[i]; 217 1.3 dsl v = v ? (s.times[i] - s1.times[i]) / v : 0; 218 1.3 dsl } 219 1.3 dsl 220 1.3 dsl if (display_mode == TIME) 221 1.3 dsl v = (v * 100 + itime/2) / itime; 222 1.3 dsl 223 1.3 dsl val[i] = v; 224 1.3 dsl 225 1.1 dsl /* 226 1.1 dsl * We use an 'infinite response filter' in a vague 227 1.1 dsl * attempt to stop the data leaping around too much. 228 1.1 dsl * I suspect there are other/better methods in use. 229 1.1 dsl */ 230 1.3 dsl if (irf_first) { 231 1.3 dsl irf[i] = v; 232 1.3 dsl irf_first = 0; 233 1.3 dsl } else { 234 1.3 dsl irf[i] = irf[i] * 7 / 8 + v; 235 1.1 dsl } 236 1.3 dsl } 237 1.1 dsl 238 1.3 dsl if (sort_order == COUNTS) { 239 1.1 dsl /* mergesort() doesn't swap equal values about... */ 240 1.8 christos mergesort(syscall_sort, __arraycount(syscall_sort), 241 1.3 dsl sizeof syscall_sort[0], compare_irf); 242 1.1 dsl } 243 1.1 dsl 244 1.1 dsl l = SYSCALLROW; 245 1.1 dsl c = 0; 246 1.1 dsl move(l, c); 247 1.8 christos #define FMT "compile kernel with \"options SYSCALL_%s\" to get syscall %s" 248 1.8 christos if (counts_mib_len == 0) { 249 1.8 christos mvprintw(l, c, FMT, "STATS", "counts"); 250 1.8 christos l++; 251 1.8 christos } 252 1.8 christos if (times_mib_len == 0) { 253 1.8 christos mvprintw(l, c, FMT, "TIMES", "times"); 254 1.8 christos l++; 255 1.8 christos } 256 1.8 christos for (ii = 0; ii < (int)__arraycount(s.counts); ii++) { 257 1.1 dsl i = syscall_sort[ii]; 258 1.3 dsl if (val[i] == 0 && irf[i] == 0) 259 1.1 dsl continue; 260 1.1 dsl 261 1.8 christos if (i < (int)__arraycount(syscallnames)) { 262 1.1 dsl const char *name = syscallnames[i]; 263 1.1 dsl while (name[0] == '_') 264 1.1 dsl name++; 265 1.1 dsl if (name[0] == 'c' && !strcmp(name + 1, "ompat_")) 266 1.1 dsl name += 7; 267 1.1 dsl mvprintw(l, c, "%17.17s", name); 268 1.1 dsl } else 269 1.1 dsl mvprintw(l, c, "syscall #%d ", i); 270 1.1 dsl 271 1.3 dsl putuint64(val[i], l, c + 18, 8); 272 1.1 dsl c += 27; 273 1.1 dsl if (c + 26 > COLS) { 274 1.1 dsl c = 0; 275 1.1 dsl l++; 276 1.1 dsl if (l >= LINES - 1) 277 1.1 dsl break; 278 1.1 dsl } 279 1.1 dsl } 280 1.2 dsl if (display_mode == TIME) { 281 1.2 dsl memcpy(s1.counts, s.counts, sizeof s1.counts); 282 1.2 dsl memcpy(s1.times, s.times, sizeof s1.times); 283 1.2 dsl } 284 1.1 dsl while (l < LINES - 1) { 285 1.1 dsl clrtoeol(); 286 1.1 dsl move(++l, 0); 287 1.1 dsl } 288 1.1 dsl } 289 1.1 dsl 290 1.1 dsl void 291 1.1 dsl syscall_boot(char *args) 292 1.1 dsl { 293 1.1 dsl memset(&s1, 0, sizeof s1); 294 1.1 dsl display_mode = BOOT; 295 1.1 dsl } 296 1.1 dsl 297 1.1 dsl void 298 1.1 dsl syscall_run(char *args) 299 1.1 dsl { 300 1.1 dsl s1 = s2; 301 1.1 dsl display_mode = RUN; 302 1.1 dsl } 303 1.1 dsl 304 1.1 dsl void 305 1.1 dsl syscall_time(char *args) 306 1.1 dsl { 307 1.1 dsl display_mode = TIME; 308 1.1 dsl } 309 1.1 dsl 310 1.1 dsl void 311 1.1 dsl syscall_zero(char *args) 312 1.1 dsl { 313 1.1 dsl s1 = s; 314 1.1 dsl } 315 1.1 dsl 316 1.1 dsl static int 317 1.1 dsl compare_names(const void *a, const void *b) 318 1.1 dsl { 319 1.1 dsl const char *name_a = syscallnames[*(const int *)a]; 320 1.1 dsl const char *name_b = syscallnames[*(const int *)b]; 321 1.1 dsl 322 1.1 dsl while (*name_a == '_') 323 1.1 dsl name_a++; 324 1.1 dsl while (*name_b == '_') 325 1.1 dsl name_b++; 326 1.1 dsl 327 1.1 dsl return strcmp(name_a, name_b); 328 1.1 dsl } 329 1.1 dsl 330 1.1 dsl void 331 1.1 dsl syscall_order(char *args) 332 1.1 dsl { 333 1.1 dsl int i, len; 334 1.1 dsl 335 1.1 dsl if (args == NULL) 336 1.1 dsl goto usage; 337 1.1 dsl 338 1.1 dsl len = strcspn(args, " \t\r\n"); 339 1.1 dsl 340 1.1 dsl if (args[len + strspn(args + len, " \t\r\n")]) 341 1.1 dsl goto usage; 342 1.1 dsl 343 1.3 dsl if (memcmp(args, "count", len) == 0) 344 1.1 dsl sort_order = COUNTS; 345 1.3 dsl else if (memcmp(args, "name", len) == 0) 346 1.1 dsl sort_order = NAMES; 347 1.1 dsl else if (memcmp(args, "syscall", len) == 0) 348 1.1 dsl sort_order = UNSORTED; 349 1.1 dsl else 350 1.1 dsl goto usage; 351 1.1 dsl 352 1.1 dsl /* Undo all the sorting */ 353 1.8 christos for (i = 0; i < (int)__arraycount(syscall_sort); i++) 354 1.1 dsl syscall_sort[i] = i; 355 1.1 dsl 356 1.1 dsl if (sort_order == NAMES) { 357 1.1 dsl /* Only sort the entries we have names for */ 358 1.8 christos qsort(syscall_sort, __arraycount(syscallnames), sizeof syscall_sort[0], 359 1.1 dsl compare_names); 360 1.1 dsl } 361 1.1 dsl return; 362 1.1 dsl 363 1.1 dsl usage: 364 1.1 dsl error("Usage: sort [count|name|syscall]"); 365 1.1 dsl } 366 1.1 dsl 367 1.2 dsl void 368 1.2 dsl syscall_show(char *args) 369 1.2 dsl { 370 1.2 dsl int len; 371 1.2 dsl 372 1.2 dsl if (args == NULL) 373 1.2 dsl goto usage; 374 1.2 dsl 375 1.2 dsl len = strcspn(args, " \t\r\n"); 376 1.2 dsl 377 1.2 dsl if (args[len + strspn(args + len, " \t\r\n")]) 378 1.2 dsl goto usage; 379 1.2 dsl 380 1.2 dsl if (memcmp(args, "counts", len) == 0) 381 1.2 dsl show = SHOW_COUNTS; 382 1.2 dsl else if (memcmp(args, "times", len) == 0) 383 1.2 dsl show = SHOW_TIMES; 384 1.2 dsl else if (memcmp(args, "ratio", len) == 0) 385 1.2 dsl show = SHOW_COUNTS | SHOW_TIMES; 386 1.2 dsl else 387 1.2 dsl goto usage; 388 1.2 dsl 389 1.3 dsl memset(&irf, 0, sizeof irf); 390 1.3 dsl irf_first = 1; 391 1.3 dsl 392 1.2 dsl return; 393 1.2 dsl 394 1.2 dsl usage: 395 1.2 dsl error("Usage: show [counts|times|ratio]"); 396 1.2 dsl } 397 1.2 dsl 398 1.1 dsl static void 399 1.2 dsl getinfo(struct Info *stats, int get_what) 400 1.1 dsl { 401 1.1 dsl int mib[2]; 402 1.1 dsl size_t size; 403 1.1 dsl 404 1.1 dsl cpureadstats(); 405 1.1 dsl 406 1.2 dsl if (get_what & SHOW_COUNTS) { 407 1.2 dsl size = sizeof stats->counts; 408 1.8 christos if (counts_mib_len != 0) { 409 1.8 christos if (sysctl(counts_mib, counts_mib_len, &stats->counts, 410 1.8 christos &size, NULL, 0)) { 411 1.8 christos error("can't get syscall counts: %s\n", 412 1.8 christos strerror(errno)); 413 1.8 christos memset(&stats->counts, 0, sizeof stats->counts); 414 1.8 christos } 415 1.2 dsl } 416 1.2 dsl } 417 1.2 dsl 418 1.2 dsl if (get_what & SHOW_TIMES) { 419 1.2 dsl size = sizeof stats->times; 420 1.8 christos if (times_mib_len != 0) { 421 1.8 christos if (sysctl(times_mib, times_mib_len, &stats->times, 422 1.8 christos &size, NULL, 0)) { 423 1.8 christos error("can't get syscall times: %s\n", 424 1.8 christos strerror(errno)); 425 1.8 christos memset(&stats->times, 0, sizeof stats->times); 426 1.8 christos } 427 1.2 dsl } 428 1.1 dsl } 429 1.1 dsl 430 1.1 dsl size = sizeof(stats->uvmexp); 431 1.1 dsl mib[0] = CTL_VM; 432 1.1 dsl mib[1] = VM_UVMEXP2; 433 1.1 dsl if (sysctl(mib, 2, &stats->uvmexp, &size, NULL, 0) < 0) { 434 1.1 dsl error("can't get uvmexp: %s\n", strerror(errno)); 435 1.1 dsl memset(&stats->uvmexp, 0, sizeof(stats->uvmexp)); 436 1.1 dsl } 437 1.1 dsl size = sizeof(stats->Total); 438 1.1 dsl mib[0] = CTL_VM; 439 1.1 dsl mib[1] = VM_METER; 440 1.1 dsl if (sysctl(mib, 2, &stats->Total, &size, NULL, 0) < 0) { 441 1.1 dsl error("Can't get kernel info: %s\n", strerror(errno)); 442 1.1 dsl memset(&stats->Total, 0, sizeof(stats->Total)); 443 1.1 dsl } 444 1.1 dsl } 445
Indexes created Sat Sep 20 22:09:52 GMT 2025