kern_cpuset.c revision 176880
138032Speter/*- 238032Speter * Copyright (c) 2008, Jeffrey Roberson <jeff@freebsd.org> 338032Speter * All rights reserved. 438032Speter * 538032Speter * Redistribution and use in source and binary forms, with or without 638032Speter * modification, are permitted provided that the following conditions 738032Speter * are met: 838032Speter * 1. Redistributions of source code must retain the above copyright 938032Speter * notice unmodified, this list of conditions, and the following 1038032Speter * disclaimer. 1138032Speter * 2. Redistributions in binary form must reproduce the above copyright 1238032Speter * notice, this list of conditions and the following disclaimer in the 1338032Speter * documentation and/or other materials provided with the distribution. 1438032Speter * 1538032Speter * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 1638032Speter * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 1738032Speter * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 1838032Speter * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 1938032Speter * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT 20 * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, 21 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY 22 * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT 23 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF 24 * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. 25 * 26 */ 27 28#include <sys/cdefs.h> 29__FBSDID("$FreeBSD: head/sys/kern/kern_cpuset.c 176880 2008-03-06 20:11:24Z jeff $"); 30 31#include <sys/param.h> 32#include <sys/systm.h> 33#include <sys/sysproto.h> 34#include <sys/kernel.h> 35#include <sys/lock.h> 36#include <sys/malloc.h> 37#include <sys/mutex.h> 38#include <sys/priv.h> 39#include <sys/proc.h> 40#include <sys/refcount.h> 41#include <sys/sched.h> 42#include <sys/smp.h> 43#include <sys/syscallsubr.h> 44#include <sys/cpuset.h> 45#include <sys/sx.h> 46#include <sys/refcount.h> 47#include <sys/queue.h> 48#include <sys/limits.h> 49 50#include <vm/uma.h> 51 52/* 53 * cpusets provide a mechanism for creating and manipulating sets of 54 * processors for the purpose of constraining the scheduling of threads to 55 * specific processors. 56 * 57 * Each process belongs to an identified set, by default this is set 1. Each 58 * thread may further restrict the cpus it may run on to a subset of this 59 * named set. This creates an anonymous set which other threads and processes 60 * may not join by number. 61 * 62 * The named set is referred to herein as the 'base' set to avoid ambiguity. 63 * This set is usually a child of a 'root' set while the anonymous set may 64 * simply be referred to as a mask. In the syscall api these are referred to 65 * as the ROOT, CPUSET, and MASK levels where CPUSET is called 'base' here. 66 * 67 * Threads inherit their set from their creator whether it be anonymous or 68 * not. This means that anonymous sets are immutable because they may be 69 * shared. To modify an anonymous set a new set is created with the desired 70 * mask and the same parent as the existing anonymous set. This gives the 71 * illusion of each thread having a private mask.A 72 * 73 * Via the syscall apis a user may ask to retrieve or modify the root, base, 74 * or mask that is discovered via a pid, tid, or setid. Modifying a set 75 * modifies all numbered and anonymous child sets to comply with the new mask. 76 * Modifying a pid or tid's mask applies only to that tid but must still 77 * exist within the assigned parent set. 78 * 79 * A thread may not be assigned to a a group seperate from other threads in 80 * the process. This is to remove ambiguity when the setid is queried with 81 * a pid argument. There is no other technical limitation. 82 * 83 * This somewhat complex arrangement is intended to make it easy for 84 * applications to query available processors and bind their threads to 85 * specific processors while also allowing administrators to dynamically 86 * reprovision by changing sets which apply to groups of processes. 87 * 88 * A simple application should not concern itself with sets at all and 89 * rather apply masks to its own threads via CPU_WHICH_TID and a -1 id 90 * meaning 'curthread'. It may query availble cpus for that tid with a 91 * getaffinity call using (CPU_LEVEL_CPUSET, CPU_WHICH_PID, -1, ...). 92 */ 93static uma_zone_t cpuset_zone; 94static struct mtx cpuset_lock; 95static struct setlist cpuset_ids; 96struct cpuset *cpuset_zero; 97static struct unrhdr *cpuset_unr; 98 99/* 100 * Acquire a reference to a cpuset, all pointers must be tracked with refs. 101 */ 102struct cpuset * 103cpuset_ref(struct cpuset *set) 104{ 105 106 refcount_acquire(&set->cs_ref); 107 return (set); 108} 109 110/* 111 * Release a reference in a context where it is safe to allocte. 112 */ 113void 114cpuset_rel(struct cpuset *set) 115{ 116 cpusetid_t id; 117 118 if (refcount_release(&set->cs_ref) == 0) 119 return; 120 mtx_lock_spin(&cpuset_lock); 121 LIST_REMOVE(set, cs_siblings); 122 id = set->cs_id; 123 if (id != CPUSET_INVALID) 124 LIST_REMOVE(set, cs_link); 125 mtx_unlock_spin(&cpuset_lock); 126 cpuset_rel(set->cs_parent); 127 uma_zfree(cpuset_zone, set); 128 if (id != CPUSET_INVALID) 129 free_unr(cpuset_unr, id); 130} 131 132/* 133 * Deferred release must be used when in a context that is not safe to 134 * allocate/free. This places any unreferenced sets on the list 'head'. 135 */ 136static void 137cpuset_rel_defer(struct setlist *head, struct cpuset *set) 138{ 139 140 if (refcount_release(&set->cs_ref) == 0) 141 return; 142 mtx_lock_spin(&cpuset_lock); 143 LIST_REMOVE(set, cs_siblings); 144 if (set->cs_id != CPUSET_INVALID) 145 LIST_REMOVE(set, cs_link); 146 LIST_INSERT_HEAD(head, set, cs_link); 147 mtx_unlock_spin(&cpuset_lock); 148} 149 150/* 151 * Complete a deferred release. Removes the set from the list provided to 152 * cpuset_rel_defer. 153 */ 154static void 155cpuset_rel_complete(struct cpuset *set) 156{ 157 LIST_REMOVE(set, cs_link); 158 cpuset_rel(set->cs_parent); 159 uma_zfree(cpuset_zone, set); 160} 161 162/* 163 * Find a set based on an id. Returns it with a ref. 164 */ 165static struct cpuset * 166cpuset_lookup(cpusetid_t setid) 167{ 168 struct cpuset *set; 169 170 if (setid == CPUSET_INVALID) 171 return (NULL); 172 mtx_lock_spin(&cpuset_lock); 173 LIST_FOREACH(set, &cpuset_ids, cs_link) 174 if (set->cs_id == setid) 175 break; 176 if (set) 177 cpuset_ref(set); 178 mtx_unlock_spin(&cpuset_lock); 179 return (set); 180} 181 182/* 183 * Create a set in the space provided in 'set' with the provided parameters. 184 * The set is returned with a single ref. May return EDEADLK if the set 185 * will have no valid cpu based on restrictions from the parent. 186 */ 187static int 188_cpuset_create(struct cpuset *set, struct cpuset *parent, cpuset_t *mask, 189 cpusetid_t id) 190{ 191 192 if (!CPU_OVERLAP(&parent->cs_mask, mask)) 193 return (EDEADLK); 194 CPU_COPY(mask, &set->cs_mask); 195 LIST_INIT(&set->cs_children); 196 refcount_init(&set->cs_ref, 1); 197 set->cs_flags = 0; 198 mtx_lock_spin(&cpuset_lock); 199 CPU_AND(mask, &parent->cs_mask); 200 set->cs_id = id; 201 set->cs_parent = cpuset_ref(parent); 202 LIST_INSERT_HEAD(&parent->cs_children, set, cs_siblings); 203 if (set->cs_id != CPUSET_INVALID) 204 LIST_INSERT_HEAD(&cpuset_ids, set, cs_link); 205 mtx_unlock_spin(&cpuset_lock); 206 207 return (0); 208} 209 210/* 211 * Create a new non-anonymous set with the requested parent and mask. May 212 * return failures if the mask is invalid or a new number can not be 213 * allocated. 214 */ 215static int 216cpuset_create(struct cpuset **setp, struct cpuset *parent, cpuset_t *mask) 217{ 218 struct cpuset *set; 219 cpusetid_t id; 220 int error; 221 222 id = alloc_unr(cpuset_unr); 223 if (id == -1) 224 return (ENFILE); 225 *setp = set = uma_zalloc(cpuset_zone, M_WAITOK); 226 error = _cpuset_create(set, parent, mask, id); 227 if (error == 0) 228 return (0); 229 free_unr(cpuset_unr, id); 230 uma_zfree(cpuset_zone, set); 231 232 return (error); 233} 234 235/* 236 * Recursively check for errors that would occur from applying mask to 237 * the tree of sets starting at 'set'. Checks for sets that would become 238 * empty as well as RDONLY flags. 239 */ 240static int 241cpuset_testupdate(struct cpuset *set, cpuset_t *mask) 242{ 243 struct cpuset *nset; 244 cpuset_t newmask; 245 int error; 246 247 mtx_assert(&cpuset_lock, MA_OWNED); 248 if (set->cs_flags & CPU_SET_RDONLY) 249 return (EPERM); 250 if (!CPU_OVERLAP(&set->cs_mask, mask)) 251 return (EDEADLK); 252 CPU_COPY(&set->cs_mask, &newmask); 253 CPU_AND(&newmask, mask); 254 error = 0; 255 LIST_FOREACH(nset, &set->cs_children, cs_siblings) 256 if ((error = cpuset_testupdate(nset, &newmask)) != 0) 257 break; 258 return (error); 259} 260 261/* 262 * Applies the mask 'mask' without checking for empty sets or permissions. 263 */ 264static void 265cpuset_update(struct cpuset *set, cpuset_t *mask) 266{ 267 struct cpuset *nset; 268 269 mtx_assert(&cpuset_lock, MA_OWNED); 270 CPU_AND(&set->cs_mask, mask); 271 LIST_FOREACH(nset, &set->cs_children, cs_siblings) 272 cpuset_update(nset, &set->cs_mask); 273 274 return; 275} 276 277/* 278 * Modify the set 'set' to use a copy of the mask provided. Apply this new 279 * mask to restrict all children in the tree. Checks for validity before 280 * applying the changes. 281 */ 282static int 283cpuset_modify(struct cpuset *set, cpuset_t *mask) 284{ 285 struct cpuset *root; 286 int error; 287 288 error = suser(curthread); 289 if (error) 290 return (error); 291 /* 292 * Verify that we have access to this set of 293 * cpus. 294 */ 295 root = set->cs_parent; 296 if (root && !CPU_SUBSET(&root->cs_mask, mask)) 297 return (EINVAL); 298 mtx_lock_spin(&cpuset_lock); 299 error = cpuset_testupdate(set, mask); 300 if (error) 301 goto out; 302 cpuset_update(set, mask); 303 CPU_COPY(mask, &set->cs_mask); 304out: 305 mtx_unlock_spin(&cpuset_lock); 306 307 return (error); 308} 309 310/* 311 * Walks up the tree from 'set' to find the root. Returns the root 312 * referenced. 313 */ 314static struct cpuset * 315cpuset_root(struct cpuset *set) 316{ 317 318 for (; set->cs_parent != NULL; set = set->cs_parent) 319 if (set->cs_flags & CPU_SET_ROOT) 320 break; 321 cpuset_ref(set); 322 323 return (set); 324} 325 326/* 327 * Find the first non-anonymous set starting from 'set'. Returns this set 328 * referenced. May return the passed in set with an extra ref if it is 329 * not anonymous. 330 */ 331static struct cpuset * 332cpuset_base(struct cpuset *set) 333{ 334 335 if (set->cs_id == CPUSET_INVALID) 336 set = set->cs_parent; 337 cpuset_ref(set); 338 339 return (set); 340} 341 342/* 343 * Resolve the 'which' parameter of several cpuset apis. 344 * 345 * For WHICH_PID and WHICH_TID return a locked proc and valid proc/tid. Also 346 * checks for permission via p_cansched(). 347 * 348 * For WHICH_SET returns a valid set with a new reference. 349 * 350 * -1 may be supplied for any argument to mean the current proc/thread or 351 * the base set of the current thread. May fail with ESRCH/EPERM. 352 */ 353static int 354cpuset_which(cpuwhich_t which, id_t id, struct proc **pp, struct thread **tdp, 355 struct cpuset **setp) 356{ 357 struct cpuset *set; 358 struct thread *td; 359 struct proc *p; 360 int error; 361 362 *pp = p = NULL; 363 *tdp = td = NULL; 364 *setp = set = NULL; 365 switch (which) { 366 case CPU_WHICH_PID: 367 if (id == -1) { 368 PROC_LOCK(curproc); 369 p = curproc; 370 break; 371 } 372 if ((p = pfind(id)) == NULL) 373 return (ESRCH); 374 break; 375 case CPU_WHICH_TID: 376 if (id == -1) { 377 PROC_LOCK(curproc); 378 p = curproc; 379 td = curthread; 380 break; 381 } 382 sx_slock(&allproc_lock); 383 FOREACH_PROC_IN_SYSTEM(p) { 384 PROC_LOCK(p); 385 PROC_SLOCK(p); 386 FOREACH_THREAD_IN_PROC(p, td) 387 if (td->td_tid == id) 388 break; 389 PROC_SUNLOCK(p); 390 if (td != NULL) 391 break; 392 PROC_UNLOCK(p); 393 } 394 sx_sunlock(&allproc_lock); 395 if (td == NULL) 396 return (ESRCH); 397 break; 398 case CPU_WHICH_CPUSET: 399 if (id == -1) { 400 thread_lock(curthread); 401 set = cpuset_base(curthread->td_cpuset); 402 thread_unlock(curthread); 403 } else 404 set = cpuset_lookup(id); 405 if (set) { 406 *setp = set; 407 return (0); 408 } 409 return (ESRCH); 410 default: 411 return (EINVAL); 412 } 413 error = p_cansched(curthread, p); 414 if (error) { 415 PROC_UNLOCK(p); 416 return (error); 417 } 418 if (td == NULL) 419 td = FIRST_THREAD_IN_PROC(p); 420 *pp = p; 421 *tdp = td; 422 return (0); 423} 424 425/* 426 * Create an anonymous set with the provided mask in the space provided by 427 * 'fset'. If the passed in set is anonymous we use its parent otherwise 428 * the new set is a child of 'set'. 429 */ 430static int 431cpuset_shadow(struct cpuset *set, struct cpuset *fset, cpuset_t *mask) 432{ 433 struct cpuset *parent; 434 435 if (set->cs_id == CPUSET_INVALID) 436 parent = set->cs_parent; 437 else 438 parent = set; 439 if (!CPU_SUBSET(&parent->cs_mask, mask)) 440 return (EINVAL); 441 return (_cpuset_create(fset, parent, mask, CPUSET_INVALID)); 442} 443 444/* 445 * Handle two cases for replacing the base set or mask of an entire process. 446 * 447 * 1) Set is non-null and mask is null. This reparents all anonymous sets 448 * to the provided set and replaces all non-anonymous td_cpusets with the 449 * provided set. 450 * 2) Mask is non-null and set is null. This replaces or creates anonymous 451 * sets for every thread with the existing base as a parent. 452 * 453 * This is overly complicated because we can't allocate while holding a 454 * spinlock and spinlocks must be held while changing and examining thread 455 * state. 456 */ 457static int 458cpuset_setproc(pid_t pid, struct cpuset *set, cpuset_t *mask) 459{ 460 struct setlist freelist; 461 struct setlist droplist; 462 struct cpuset *tdset; 463 struct cpuset *nset; 464 struct thread *td; 465 struct proc *p; 466 int threads; 467 int nfree; 468 int error; 469 /* 470 * The algorithm requires two passes due to locking considerations. 471 * 472 * 1) Lookup the process and acquire the locks in the required order. 473 * 2) If enough cpusets have not been allocated release the locks and 474 * allocate them. Loop. 475 */ 476 LIST_INIT(&freelist); 477 LIST_INIT(&droplist); 478 nfree = 0; 479 for (;;) { 480 error = cpuset_which(CPU_WHICH_PID, pid, &p, &td, &nset); 481 if (error) 482 goto out; 483 PROC_SLOCK(p); 484 if (nfree >= p->p_numthreads) 485 break; 486 threads = p->p_numthreads; 487 PROC_SUNLOCK(p); 488 PROC_UNLOCK(p); 489 for (; nfree < threads; nfree++) { 490 nset = uma_zalloc(cpuset_zone, M_WAITOK); 491 LIST_INSERT_HEAD(&freelist, nset, cs_link); 492 } 493 } 494 PROC_LOCK_ASSERT(p, MA_OWNED); 495 PROC_SLOCK_ASSERT(p, MA_OWNED); 496 /* 497 * Now that the appropriate locks are held and we have enough cpusets, 498 * make sure the operation will succeed before applying changes. The 499 * proc lock prevents td_cpuset from changing between calls. 500 */ 501 error = 0; 502 FOREACH_THREAD_IN_PROC(p, td) { 503 thread_lock(td); 504 tdset = td->td_cpuset; 505 /* 506 * Verify that a new mask doesn't specify cpus outside of 507 * the set the thread is a member of. 508 */ 509 if (mask) { 510 if (tdset->cs_id == CPUSET_INVALID) 511 tdset = tdset->cs_parent; 512 if (!CPU_SUBSET(&tdset->cs_mask, mask)) 513 error = EINVAL; 514 /* 515 * Verify that a new set won't leave an existing thread 516 * mask without a cpu to run on. It can, however, restrict 517 * the set. 518 */ 519 } else if (tdset->cs_id == CPUSET_INVALID) { 520 if (!CPU_OVERLAP(&set->cs_mask, &tdset->cs_mask)) 521 error = EINVAL; 522 } 523 thread_unlock(td); 524 if (error) 525 goto unlock_out; 526 } 527 /* 528 * Replace each thread's cpuset while using deferred release. We 529 * must do this because the PROC_SLOCK has to be held while traversing 530 * the thread list and this limits the type of operations allowed. 531 */ 532 FOREACH_THREAD_IN_PROC(p, td) { 533 thread_lock(td); 534 /* 535 * If we presently have an anonymous set or are applying a 536 * mask we must create an anonymous shadow set. That is 537 * either parented to our existing base or the supplied set. 538 * 539 * If we have a base set with no anonymous shadow we simply 540 * replace it outright. 541 */ 542 tdset = td->td_cpuset; 543 if (tdset->cs_id == CPUSET_INVALID || mask) { 544 nset = LIST_FIRST(&freelist); 545 LIST_REMOVE(nset, cs_link); 546 if (mask) 547 error = cpuset_shadow(tdset, nset, mask); 548 else 549 error = _cpuset_create(nset, set, 550 &tdset->cs_mask, CPUSET_INVALID); 551 if (error) { 552 LIST_INSERT_HEAD(&freelist, nset, cs_link); 553 thread_unlock(td); 554 break; 555 } 556 } else 557 nset = cpuset_ref(set); 558 cpuset_rel_defer(&droplist, tdset); 559 td->td_cpuset = nset; 560 sched_affinity(td); 561 thread_unlock(td); 562 } 563unlock_out: 564 PROC_SUNLOCK(p); 565 PROC_UNLOCK(p); 566out: 567 while ((nset = LIST_FIRST(&droplist)) != NULL) 568 cpuset_rel_complete(nset); 569 while ((nset = LIST_FIRST(&freelist)) != NULL) { 570 LIST_REMOVE(nset, cs_link); 571 uma_zfree(cpuset_zone, nset); 572 } 573 return (error); 574} 575 576/* 577 * Apply an anonymous mask to a single thread. 578 */ 579static int 580cpuset_setthread(lwpid_t id, cpuset_t *mask) 581{ 582 struct cpuset *nset; 583 struct cpuset *set; 584 struct thread *td; 585 struct proc *p; 586 int error; 587 588 nset = uma_zalloc(cpuset_zone, M_WAITOK); 589 error = cpuset_which(CPU_WHICH_TID, id, &p, &td, &set); 590 if (error) 591 goto out; 592 thread_lock(td); 593 set = td->td_cpuset; 594 error = cpuset_shadow(set, nset, mask); 595 if (error == 0) { 596 cpuset_rel(td->td_cpuset); 597 td->td_cpuset = nset; 598 sched_affinity(td); 599 nset = NULL; 600 } 601 thread_unlock(td); 602 PROC_UNLOCK(p); 603out: 604 if (nset) 605 uma_zfree(cpuset_zone, nset); 606 return (error); 607} 608 609/* 610 * Creates the cpuset for thread0. We make two sets: 611 * 612 * 0 - The root set which should represent all valid processors in the 613 * system. It is initially created with a mask of all processors 614 * because we don't know what processors are valid until cpuset_init() 615 * runs. This set is immutable. 616 * 1 - The default set which all processes are a member of until changed. 617 * This allows an administrator to move all threads off of given cpus to 618 * dedicate them to high priority tasks or save power etc. 619 */ 620struct cpuset * 621cpuset_thread0(void) 622{ 623 struct cpuset *set; 624 int error; 625 626 cpuset_zone = uma_zcreate("cpuset", sizeof(struct cpuset), NULL, NULL, 627 NULL, NULL, UMA_ALIGN_PTR, 0); 628 mtx_init(&cpuset_lock, "cpuset", NULL, MTX_SPIN | MTX_RECURSE); 629 /* 630 * Create the root system set for the whole machine. Doesn't use 631 * cpuset_create() due to NULL parent. 632 */ 633 set = uma_zalloc(cpuset_zone, M_WAITOK | M_ZERO); 634 set->cs_mask.__bits[0] = -1; 635 LIST_INIT(&set->cs_children); 636 LIST_INSERT_HEAD(&cpuset_ids, set, cs_link); 637 set->cs_ref = 1; 638 set->cs_flags = CPU_SET_ROOT; 639 cpuset_zero = set; 640 /* 641 * Now derive a default, modifiable set from that to give out. 642 */ 643 set = uma_zalloc(cpuset_zone, M_WAITOK); 644 error = _cpuset_create(set, cpuset_zero, &cpuset_zero->cs_mask, 1); 645 KASSERT(error == 0, ("Error creating default set: %d\n", error)); 646 /* 647 * Initialize the unit allocator. 0 and 1 are allocated above. 648 */ 649 cpuset_unr = new_unrhdr(2, INT_MAX, NULL); 650 651 return (set); 652} 653 654/* 655 * This is called once the final set of system cpus is known. Modifies 656 * the root set and all children and mark the root readonly. 657 */ 658static void 659cpuset_init(void *arg) 660{ 661 cpuset_t mask; 662 663 CPU_ZERO(&mask); 664#ifdef SMP 665 mask.__bits[0] = all_cpus; 666#else 667 mask.__bits[0] = 1; 668#endif 669 if (cpuset_modify(cpuset_zero, &mask)) 670 panic("Can't set initial cpuset mask.\n"); 671 cpuset_zero->cs_flags |= CPU_SET_RDONLY; 672} 673SYSINIT(cpuset, SI_SUB_SMP, SI_ORDER_ANY, cpuset_init, NULL); 674 675#ifndef _SYS_SYSPROTO_H_ 676struct cpuset_args { 677 cpusetid_t *setid; 678}; 679#endif 680int 681cpuset(struct thread *td, struct cpuset_args *uap) 682{ 683 struct cpuset *root; 684 struct cpuset *set; 685 int error; 686 687 thread_lock(td); 688 root = cpuset_root(td->td_cpuset); 689 thread_unlock(td); 690 error = cpuset_create(&set, root, &root->cs_mask); 691 cpuset_rel(root); 692 if (error) 693 return (error); 694 error = cpuset_setproc(-1, set, NULL); 695 if (error == 0) 696 error = copyout(&set->cs_id, uap->setid, sizeof(set->cs_id)); 697 cpuset_rel(set); 698 return (error); 699} 700 701#ifndef _SYS_SYSPROTO_H_ 702struct cpuset_setid_args { 703 cpuwhich_t which; 704 id_t id; 705 cpusetid_t setid; 706}; 707#endif 708int 709cpuset_setid(struct thread *td, struct cpuset_setid_args *uap) 710{ 711 struct cpuset *set; 712 int error; 713 714 /* 715 * Presently we only support per-process sets. 716 */ 717 if (uap->which != CPU_WHICH_PID) 718 return (EINVAL); 719 set = cpuset_lookup(uap->setid); 720 if (set == NULL) 721 return (ESRCH); 722 error = cpuset_setproc(uap->id, set, NULL); 723 cpuset_rel(set); 724 return (error); 725} 726 727#ifndef _SYS_SYSPROTO_H_ 728struct cpuset_getid_args { 729 cpulevel_t level; 730 cpuwhich_t which; 731 id_t id; 732 cpusetid_t *setid; 733#endif 734int 735cpuset_getid(struct thread *td, struct cpuset_getid_args *uap) 736{ 737 struct cpuset *nset; 738 struct cpuset *set; 739 struct thread *ttd; 740 struct proc *p; 741 cpusetid_t id; 742 int error; 743 744 if (uap->level == CPU_LEVEL_WHICH && uap->which != CPU_WHICH_CPUSET) 745 return (EINVAL); 746 error = cpuset_which(uap->which, uap->id, &p, &ttd, &set); 747 if (error) 748 return (error); 749 switch (uap->which) { 750 case CPU_WHICH_TID: 751 case CPU_WHICH_PID: 752 thread_lock(ttd); 753 set = cpuset_base(ttd->td_cpuset); 754 thread_unlock(ttd); 755 PROC_UNLOCK(p); 756 break; 757 case CPU_WHICH_CPUSET: 758 break; 759 } 760 switch (uap->level) { 761 case CPU_LEVEL_ROOT: 762 nset = cpuset_root(set); 763 cpuset_rel(set); 764 set = nset; 765 break; 766 case CPU_LEVEL_CPUSET: 767 break; 768 case CPU_LEVEL_WHICH: 769 break; 770 } 771 id = set->cs_id; 772 cpuset_rel(set); 773 if (error == 0) 774 error = copyout(&id, uap->setid, sizeof(id)); 775 776 return (error); 777} 778 779#ifndef _SYS_SYSPROTO_H_ 780struct cpuset_getaffinity_args { 781 cpulevel_t level; 782 cpuwhich_t which; 783 int id; 784 int cpusetsize; 785 long *mask; 786}; 787#endif 788int 789cpuset_getaffinity(struct thread *td, struct cpuset_getaffinity_args *uap) 790{ 791 struct thread *ttd; 792 struct cpuset *nset; 793 struct cpuset *set; 794 struct proc *p; 795 cpuset_t *mask; 796 int error; 797 int size; 798 799 if (uap->cpusetsize < sizeof(cpuset_t) || 800 uap->cpusetsize * NBBY > CPU_MAXSIZE) 801 return (ERANGE); 802 size = uap->cpusetsize; 803 mask = malloc(size, M_TEMP, M_WAITOK | M_ZERO); 804 error = cpuset_which(uap->which, uap->id, &p, &ttd, &set); 805 if (error) 806 goto out; 807 error = 0; 808 switch (uap->level) { 809 case CPU_LEVEL_ROOT: 810 case CPU_LEVEL_CPUSET: 811 switch (uap->which) { 812 case CPU_WHICH_TID: 813 case CPU_WHICH_PID: 814 thread_lock(ttd); 815 set = cpuset_ref(ttd->td_cpuset); 816 thread_unlock(ttd); 817 break; 818 case CPU_WHICH_CPUSET: 819 break; 820 } 821 if (uap->level == CPU_LEVEL_ROOT) 822 nset = cpuset_root(set); 823 else 824 nset = cpuset_base(set); 825 CPU_COPY(&nset->cs_mask, mask); 826 cpuset_rel(nset); 827 break; 828 case CPU_LEVEL_WHICH: 829 switch (uap->which) { 830 case CPU_WHICH_TID: 831 thread_lock(ttd); 832 CPU_COPY(&ttd->td_cpuset->cs_mask, mask); 833 thread_unlock(ttd); 834 break; 835 case CPU_WHICH_PID: 836 PROC_SLOCK(p); 837 FOREACH_THREAD_IN_PROC(p, ttd) { 838 thread_lock(ttd); 839 CPU_OR(mask, &ttd->td_cpuset->cs_mask); 840 thread_unlock(ttd); 841 } 842 PROC_SUNLOCK(p); 843 break; 844 case CPU_WHICH_CPUSET: 845 CPU_COPY(&set->cs_mask, mask); 846 break; 847 } 848 break; 849 default: 850 error = EINVAL; 851 break; 852 } 853 if (set) 854 cpuset_rel(set); 855 if (p) 856 PROC_UNLOCK(p); 857 if (error == 0) 858 error = copyout(mask, uap->mask, size); 859out: 860 free(mask, M_TEMP); 861 return (error); 862} 863 864#ifndef _SYS_SYSPROTO_H_ 865struct cpuset_setaffinity_args { 866 cpulevel_t level; 867 cpuwhich_t which; 868 int id; 869 int cpusetsize; 870 long * mask; 871}; 872#endif 873int 874cpuset_setaffinity(struct thread *td, struct cpuset_setaffinity_args *uap) 875{ 876 struct cpuset *nset; 877 struct cpuset *set; 878 struct thread *ttd; 879 struct proc *p; 880 cpuset_t *mask; 881 int error; 882 883 if (uap->cpusetsize < sizeof(cpuset_t) || 884 uap->cpusetsize * NBBY > CPU_MAXSIZE) 885 return (ERANGE); 886 mask = malloc(uap->cpusetsize, M_TEMP, M_WAITOK | M_ZERO); 887 error = copyin(uap->mask, mask, uap->cpusetsize); 888 if (error) 889 goto out; 890 /* 891 * Verify that no high bits are set. 892 */ 893 if (uap->cpusetsize > sizeof(cpuset_t)) { 894 char *end; 895 char *cp; 896 897 end = cp = (char *)&mask->__bits; 898 end += uap->cpusetsize; 899 cp += sizeof(cpuset_t); 900 while (cp != end) 901 if (*cp++ != 0) { 902 error = EINVAL; 903 goto out; 904 } 905 906 } 907 switch (uap->level) { 908 case CPU_LEVEL_ROOT: 909 case CPU_LEVEL_CPUSET: 910 error = cpuset_which(uap->which, uap->id, &p, &ttd, &set); 911 if (error) 912 break; 913 switch (uap->which) { 914 case CPU_WHICH_TID: 915 case CPU_WHICH_PID: 916 thread_lock(ttd); 917 set = cpuset_ref(ttd->td_cpuset); 918 thread_unlock(ttd); 919 PROC_UNLOCK(p); 920 break; 921 case CPU_WHICH_CPUSET: 922 break; 923 } 924 if (uap->level == CPU_LEVEL_ROOT) 925 nset = cpuset_root(set); 926 else 927 nset = cpuset_base(set); 928 error = cpuset_modify(nset, mask); 929 cpuset_rel(nset); 930 cpuset_rel(set); 931 break; 932 case CPU_LEVEL_WHICH: 933 switch (uap->which) { 934 case CPU_WHICH_TID: 935 error = cpuset_setthread(uap->id, mask); 936 break; 937 case CPU_WHICH_PID: 938 error = cpuset_setproc(uap->id, NULL, mask); 939 break; 940 case CPU_WHICH_CPUSET: 941 error = cpuset_which(CPU_WHICH_CPUSET, uap->id, &p, 942 &ttd, &set); 943 if (error == 0) { 944 error = cpuset_modify(set, mask); 945 cpuset_rel(set); 946 } 947 break; 948 default: 949 error = EINVAL; 950 break; 951 } 952 break; 953 default: 954 error = EINVAL; 955 break; 956 } 957out: 958 free(mask, M_TEMP); 959 return (error); 960} 961