linux_sched.c revision 1.68.4.1
1 1.68.4.1 bouyer /* $NetBSD: linux_sched.c,v 1.68.4.1 2017/04/21 16:53:42 bouyer Exp $ */ 2 1.1 tron 3 1.1 tron /*- 4 1.1 tron * Copyright (c) 1999 The NetBSD Foundation, Inc. 5 1.1 tron * All rights reserved. 6 1.1 tron * 7 1.1 tron * This code is derived from software contributed to The NetBSD Foundation 8 1.2 thorpej * by Jason R. Thorpe of the Numerical Aerospace Simulation Facility, 9 1.1 tron * NASA Ames Research Center; by Matthias Scheler. 10 1.1 tron * 11 1.1 tron * Redistribution and use in source and binary forms, with or without 12 1.1 tron * modification, are permitted provided that the following conditions 13 1.1 tron * are met: 14 1.1 tron * 1. Redistributions of source code must retain the above copyright 15 1.1 tron * notice, this list of conditions and the following disclaimer. 16 1.1 tron * 2. Redistributions in binary form must reproduce the above copyright 17 1.1 tron * notice, this list of conditions and the following disclaimer in the 18 1.1 tron * documentation and/or other materials provided with the distribution. 19 1.1 tron * 20 1.1 tron * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 21 1.1 tron * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 22 1.1 tron * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 23 1.1 tron * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 24 1.1 tron * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 25 1.1 tron * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 26 1.1 tron * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 27 1.1 tron * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 28 1.1 tron * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 29 1.1 tron * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 30 1.1 tron * POSSIBILITY OF SUCH DAMAGE. 31 1.1 tron */ 32 1.1 tron 33 1.1 tron /* 34 1.1 tron * Linux compatibility module. Try to deal with scheduler related syscalls. 35 1.1 tron */ 36 1.8 lukem 37 1.8 lukem #include <sys/cdefs.h> 38 1.68.4.1 bouyer __KERNEL_RCSID(0, "$NetBSD: linux_sched.c,v 1.68.4.1 2017/04/21 16:53:42 bouyer Exp $"); 39 1.1 tron 40 1.1 tron #include <sys/param.h> 41 1.1 tron #include <sys/mount.h> 42 1.1 tron #include <sys/proc.h> 43 1.1 tron #include <sys/systm.h> 44 1.22 manu #include <sys/sysctl.h> 45 1.1 tron #include <sys/syscallargs.h> 46 1.14 jdolecek #include <sys/wait.h> 47 1.30 elad #include <sys/kauth.h> 48 1.34 manu #include <sys/ptrace.h> 49 1.63 chs #include <sys/atomic.h> 50 1.3 itohy 51 1.43 ad #include <sys/cpu.h> 52 1.1 tron 53 1.1 tron #include <compat/linux/common/linux_types.h> 54 1.1 tron #include <compat/linux/common/linux_signal.h> 55 1.19 manu #include <compat/linux/common/linux_emuldata.h> 56 1.44 njoly #include <compat/linux/common/linux_ipc.h> 57 1.44 njoly #include <compat/linux/common/linux_sem.h> 58 1.58 christos #include <compat/linux/common/linux_exec.h> 59 1.63 chs #include <compat/linux/common/linux_machdep.h> 60 1.1 tron 61 1.1 tron #include <compat/linux/linux_syscallargs.h> 62 1.1 tron 63 1.1 tron #include <compat/linux/common/linux_sched.h> 64 1.1 tron 65 1.65 christos static int linux_clone_nptl(struct lwp *, const struct linux_sys_clone_args *, 66 1.65 christos register_t *); 67 1.65 christos 68 1.68 christos /* Unlike Linux, dynamically calculate CPU mask size */ 69 1.68 christos #define LINUX_CPU_MASK_SIZE (sizeof(long) * ((ncpu + LONG_BIT - 1) / LONG_BIT)) 70 1.68 christos 71 1.65 christos #if DEBUG_LINUX 72 1.65 christos #define DPRINTF(x) uprintf x 73 1.65 christos #else 74 1.65 christos #define DPRINTF(x) 75 1.65 christos #endif 76 1.63 chs 77 1.63 chs static void 78 1.63 chs linux_child_return(void *arg) 79 1.63 chs { 80 1.63 chs struct lwp *l = arg; 81 1.63 chs struct proc *p = l->l_proc; 82 1.63 chs struct linux_emuldata *led = l->l_emuldata; 83 1.63 chs void *ctp = led->led_child_tidptr; 84 1.65 christos int error; 85 1.63 chs 86 1.63 chs if (ctp) { 87 1.65 christos if ((error = copyout(&p->p_pid, ctp, sizeof(p->p_pid))) != 0) 88 1.63 chs printf("%s: LINUX_CLONE_CHILD_SETTID " 89 1.65 christos "failed (child_tidptr = %p, tid = %d error =%d)\n", 90 1.65 christos __func__, ctp, p->p_pid, error); 91 1.63 chs } 92 1.63 chs child_return(arg); 93 1.63 chs } 94 1.63 chs 95 1.1 tron int 96 1.65 christos linux_sys_clone(struct lwp *l, const struct linux_sys_clone_args *uap, 97 1.65 christos register_t *retval) 98 1.1 tron { 99 1.46 dsl /* { 100 1.1 tron syscallarg(int) flags; 101 1.1 tron syscallarg(void *) stack; 102 1.19 manu syscallarg(void *) parent_tidptr; 103 1.63 chs syscallarg(void *) tls; 104 1.19 manu syscallarg(void *) child_tidptr; 105 1.46 dsl } */ 106 1.58 christos struct proc *p; 107 1.19 manu struct linux_emuldata *led; 108 1.63 chs int flags, sig, error; 109 1.1 tron 110 1.1 tron /* 111 1.1 tron * We don't support the Linux CLONE_PID or CLONE_PTRACE flags. 112 1.1 tron */ 113 1.1 tron if (SCARG(uap, flags) & (LINUX_CLONE_PID|LINUX_CLONE_PTRACE)) 114 1.65 christos return EINVAL; 115 1.1 tron 116 1.13 jdolecek /* 117 1.13 jdolecek * Thread group implies shared signals. Shared signals 118 1.13 jdolecek * imply shared VM. This matches what Linux kernel does. 119 1.13 jdolecek */ 120 1.13 jdolecek if (SCARG(uap, flags) & LINUX_CLONE_THREAD 121 1.13 jdolecek && (SCARG(uap, flags) & LINUX_CLONE_SIGHAND) == 0) 122 1.65 christos return EINVAL; 123 1.13 jdolecek if (SCARG(uap, flags) & LINUX_CLONE_SIGHAND 124 1.13 jdolecek && (SCARG(uap, flags) & LINUX_CLONE_VM) == 0) 125 1.65 christos return EINVAL; 126 1.13 jdolecek 127 1.63 chs /* 128 1.63 chs * The thread group flavor is implemented totally differently. 129 1.63 chs */ 130 1.65 christos if (SCARG(uap, flags) & LINUX_CLONE_THREAD) 131 1.63 chs return linux_clone_nptl(l, uap, retval); 132 1.63 chs 133 1.1 tron flags = 0; 134 1.1 tron if (SCARG(uap, flags) & LINUX_CLONE_VM) 135 1.1 tron flags |= FORK_SHAREVM; 136 1.1 tron if (SCARG(uap, flags) & LINUX_CLONE_FS) 137 1.1 tron flags |= FORK_SHARECWD; 138 1.1 tron if (SCARG(uap, flags) & LINUX_CLONE_FILES) 139 1.1 tron flags |= FORK_SHAREFILES; 140 1.1 tron if (SCARG(uap, flags) & LINUX_CLONE_SIGHAND) 141 1.1 tron flags |= FORK_SHARESIGS; 142 1.1 tron if (SCARG(uap, flags) & LINUX_CLONE_VFORK) 143 1.1 tron flags |= FORK_PPWAIT; 144 1.1 tron 145 1.34 manu sig = SCARG(uap, flags) & LINUX_CLONE_CSIGNAL; 146 1.34 manu if (sig < 0 || sig >= LINUX__NSIG) 147 1.65 christos return EINVAL; 148 1.34 manu sig = linux_to_native_signo[sig]; 149 1.1 tron 150 1.63 chs if (SCARG(uap, flags) & LINUX_CLONE_CHILD_SETTID) { 151 1.63 chs led = l->l_emuldata; 152 1.63 chs led->led_child_tidptr = SCARG(uap, child_tidptr); 153 1.63 chs } 154 1.19 manu 155 1.1 tron /* 156 1.1 tron * Note that Linux does not provide a portable way of specifying 157 1.1 tron * the stack area; the caller must know if the stack grows up 158 1.1 tron * or down. So, we pass a stack size of 0, so that the code 159 1.1 tron * that makes this adjustment is a noop. 160 1.1 tron */ 161 1.19 manu if ((error = fork1(l, flags, sig, SCARG(uap, stack), 0, 162 1.65 christos linux_child_return, NULL, retval, &p)) != 0) { 163 1.65 christos DPRINTF(("%s: fork1: error %d\n", __func__, error)); 164 1.63 chs return error; 165 1.65 christos } 166 1.63 chs 167 1.63 chs return 0; 168 1.63 chs } 169 1.63 chs 170 1.63 chs static int 171 1.63 chs linux_clone_nptl(struct lwp *l, const struct linux_sys_clone_args *uap, register_t *retval) 172 1.63 chs { 173 1.63 chs /* { 174 1.63 chs syscallarg(int) flags; 175 1.63 chs syscallarg(void *) stack; 176 1.63 chs syscallarg(void *) parent_tidptr; 177 1.63 chs syscallarg(void *) tls; 178 1.63 chs syscallarg(void *) child_tidptr; 179 1.63 chs } */ 180 1.63 chs struct proc *p; 181 1.63 chs struct lwp *l2; 182 1.63 chs struct linux_emuldata *led; 183 1.63 chs void *parent_tidptr, *tls, *child_tidptr; 184 1.63 chs struct schedstate_percpu *spc; 185 1.63 chs vaddr_t uaddr; 186 1.63 chs lwpid_t lid; 187 1.63 chs int flags, tnprocs, error; 188 1.63 chs 189 1.63 chs p = l->l_proc; 190 1.63 chs flags = SCARG(uap, flags); 191 1.63 chs parent_tidptr = SCARG(uap, parent_tidptr); 192 1.63 chs tls = SCARG(uap, tls); 193 1.63 chs child_tidptr = SCARG(uap, child_tidptr); 194 1.63 chs 195 1.63 chs tnprocs = atomic_inc_uint_nv(&nprocs); 196 1.63 chs if (__predict_false(tnprocs >= maxproc) || 197 1.63 chs kauth_authorize_process(l->l_cred, KAUTH_PROCESS_FORK, p, 198 1.65 christos KAUTH_ARG(tnprocs), NULL, NULL) != 0) { 199 1.63 chs atomic_dec_uint(&nprocs); 200 1.63 chs return EAGAIN; 201 1.63 chs } 202 1.63 chs 203 1.63 chs uaddr = uvm_uarea_alloc(); 204 1.63 chs if (__predict_false(uaddr == 0)) { 205 1.63 chs atomic_dec_uint(&nprocs); 206 1.63 chs return ENOMEM; 207 1.63 chs } 208 1.63 chs 209 1.63 chs error = lwp_create(l, p, uaddr, LWP_DETACHED | LWP_PIDLID, 210 1.68.4.1 bouyer SCARG(uap, stack), 0, child_return, NULL, &l2, l->l_class, 211 1.68.4.1 bouyer &l->l_sigmask, &l->l_sigstk); 212 1.63 chs if (__predict_false(error)) { 213 1.65 christos DPRINTF(("%s: lwp_create error=%d\n", __func__, error)); 214 1.63 chs atomic_dec_uint(&nprocs); 215 1.63 chs uvm_uarea_free(uaddr); 216 1.19 manu return error; 217 1.63 chs } 218 1.63 chs lid = l2->l_lid; 219 1.19 manu 220 1.63 chs /* LINUX_CLONE_CHILD_CLEARTID: clear TID in child's memory on exit() */ 221 1.63 chs if (flags & LINUX_CLONE_CHILD_CLEARTID) { 222 1.63 chs led = l2->l_emuldata; 223 1.63 chs led->led_clear_tid = child_tidptr; 224 1.63 chs } 225 1.63 chs 226 1.63 chs /* LINUX_CLONE_PARENT_SETTID: store child's TID in parent's memory */ 227 1.63 chs if (flags & LINUX_CLONE_PARENT_SETTID) { 228 1.65 christos if ((error = copyout(&lid, parent_tidptr, sizeof(lid))) != 0) 229 1.63 chs printf("%s: LINUX_CLONE_PARENT_SETTID " 230 1.65 christos "failed (parent_tidptr = %p tid = %d error=%d)\n", 231 1.65 christos __func__, parent_tidptr, lid, error); 232 1.63 chs } 233 1.63 chs 234 1.63 chs /* LINUX_CLONE_CHILD_SETTID: store child's TID in child's memory */ 235 1.63 chs if (flags & LINUX_CLONE_CHILD_SETTID) { 236 1.65 christos if ((error = copyout(&lid, child_tidptr, sizeof(lid))) != 0) 237 1.63 chs printf("%s: LINUX_CLONE_CHILD_SETTID " 238 1.65 christos "failed (child_tidptr = %p, tid = %d error=%d)\n", 239 1.65 christos __func__, child_tidptr, lid, error); 240 1.63 chs } 241 1.63 chs 242 1.63 chs if (flags & LINUX_CLONE_SETTLS) { 243 1.63 chs error = LINUX_LWP_SETPRIVATE(l2, tls); 244 1.63 chs if (error) { 245 1.65 christos DPRINTF(("%s: LINUX_LWP_SETPRIVATE %d\n", __func__, 246 1.65 christos error)); 247 1.63 chs lwp_exit(l2); 248 1.63 chs return error; 249 1.63 chs } 250 1.63 chs } 251 1.63 chs 252 1.63 chs /* 253 1.63 chs * Set the new LWP running, unless the process is stopping, 254 1.63 chs * then the LWP is created stopped. 255 1.63 chs */ 256 1.63 chs mutex_enter(p->p_lock); 257 1.63 chs lwp_lock(l2); 258 1.63 chs spc = &l2->l_cpu->ci_schedstate; 259 1.63 chs if ((l->l_flag & (LW_WREBOOT | LW_WSUSPEND | LW_WEXIT)) == 0) { 260 1.63 chs if (p->p_stat == SSTOP || (p->p_sflag & PS_STOPPING) != 0) { 261 1.63 chs KASSERT(l2->l_wchan == NULL); 262 1.63 chs l2->l_stat = LSSTOP; 263 1.63 chs p->p_nrlwps--; 264 1.63 chs lwp_unlock_to(l2, spc->spc_lwplock); 265 1.63 chs } else { 266 1.63 chs KASSERT(lwp_locked(l2, spc->spc_mutex)); 267 1.63 chs l2->l_stat = LSRUN; 268 1.63 chs sched_enqueue(l2, false); 269 1.63 chs lwp_unlock(l2); 270 1.63 chs } 271 1.63 chs } else { 272 1.63 chs l2->l_stat = LSSUSPENDED; 273 1.63 chs p->p_nrlwps--; 274 1.63 chs lwp_unlock_to(l2, spc->spc_lwplock); 275 1.63 chs } 276 1.63 chs mutex_exit(p->p_lock); 277 1.58 christos 278 1.63 chs retval[0] = lid; 279 1.63 chs retval[1] = 0; 280 1.19 manu return 0; 281 1.1 tron } 282 1.1 tron 283 1.49 elad /* 284 1.49 elad * linux realtime priority 285 1.49 elad * 286 1.49 elad * - SCHED_RR and SCHED_FIFO tasks have priorities [1,99]. 287 1.49 elad * 288 1.49 elad * - SCHED_OTHER tasks don't have realtime priorities. 289 1.49 elad * in particular, sched_param::sched_priority is always 0. 290 1.49 elad */ 291 1.49 elad 292 1.49 elad #define LINUX_SCHED_RTPRIO_MIN 1 293 1.49 elad #define LINUX_SCHED_RTPRIO_MAX 99 294 1.49 elad 295 1.49 elad static int 296 1.49 elad sched_linux2native(int linux_policy, struct linux_sched_param *linux_params, 297 1.49 elad int *native_policy, struct sched_param *native_params) 298 1.49 elad { 299 1.49 elad 300 1.49 elad switch (linux_policy) { 301 1.49 elad case LINUX_SCHED_OTHER: 302 1.49 elad if (native_policy != NULL) { 303 1.49 elad *native_policy = SCHED_OTHER; 304 1.49 elad } 305 1.49 elad break; 306 1.49 elad 307 1.49 elad case LINUX_SCHED_FIFO: 308 1.49 elad if (native_policy != NULL) { 309 1.49 elad *native_policy = SCHED_FIFO; 310 1.49 elad } 311 1.49 elad break; 312 1.49 elad 313 1.49 elad case LINUX_SCHED_RR: 314 1.49 elad if (native_policy != NULL) { 315 1.49 elad *native_policy = SCHED_RR; 316 1.49 elad } 317 1.49 elad break; 318 1.49 elad 319 1.49 elad default: 320 1.49 elad return EINVAL; 321 1.49 elad } 322 1.49 elad 323 1.49 elad if (linux_params != NULL) { 324 1.49 elad int prio = linux_params->sched_priority; 325 1.49 elad 326 1.49 elad KASSERT(native_params != NULL); 327 1.49 elad 328 1.49 elad if (linux_policy == LINUX_SCHED_OTHER) { 329 1.49 elad if (prio != 0) { 330 1.49 elad return EINVAL; 331 1.49 elad } 332 1.49 elad native_params->sched_priority = PRI_NONE; /* XXX */ 333 1.49 elad } else { 334 1.49 elad if (prio < LINUX_SCHED_RTPRIO_MIN || 335 1.49 elad prio > LINUX_SCHED_RTPRIO_MAX) { 336 1.49 elad return EINVAL; 337 1.49 elad } 338 1.49 elad native_params->sched_priority = 339 1.49 elad (prio - LINUX_SCHED_RTPRIO_MIN) 340 1.49 elad * (SCHED_PRI_MAX - SCHED_PRI_MIN) 341 1.49 elad / (LINUX_SCHED_RTPRIO_MAX - LINUX_SCHED_RTPRIO_MIN) 342 1.49 elad + SCHED_PRI_MIN; 343 1.49 elad } 344 1.49 elad } 345 1.49 elad 346 1.49 elad return 0; 347 1.49 elad } 348 1.49 elad 349 1.49 elad static int 350 1.49 elad sched_native2linux(int native_policy, struct sched_param *native_params, 351 1.49 elad int *linux_policy, struct linux_sched_param *linux_params) 352 1.49 elad { 353 1.49 elad 354 1.49 elad switch (native_policy) { 355 1.49 elad case SCHED_OTHER: 356 1.49 elad if (linux_policy != NULL) { 357 1.49 elad *linux_policy = LINUX_SCHED_OTHER; 358 1.49 elad } 359 1.49 elad break; 360 1.49 elad 361 1.49 elad case SCHED_FIFO: 362 1.49 elad if (linux_policy != NULL) { 363 1.49 elad *linux_policy = LINUX_SCHED_FIFO; 364 1.49 elad } 365 1.49 elad break; 366 1.49 elad 367 1.49 elad case SCHED_RR: 368 1.49 elad if (linux_policy != NULL) { 369 1.49 elad *linux_policy = LINUX_SCHED_RR; 370 1.49 elad } 371 1.49 elad break; 372 1.49 elad 373 1.49 elad default: 374 1.49 elad panic("%s: unknown policy %d\n", __func__, native_policy); 375 1.49 elad } 376 1.49 elad 377 1.49 elad if (native_params != NULL) { 378 1.49 elad int prio = native_params->sched_priority; 379 1.49 elad 380 1.49 elad KASSERT(prio >= SCHED_PRI_MIN); 381 1.49 elad KASSERT(prio <= SCHED_PRI_MAX); 382 1.49 elad KASSERT(linux_params != NULL); 383 1.56 jmcneill 384 1.65 christos DPRINTF(("%s: native: policy %d, priority %d\n", 385 1.65 christos __func__, native_policy, prio)); 386 1.49 elad 387 1.49 elad if (native_policy == SCHED_OTHER) { 388 1.49 elad linux_params->sched_priority = 0; 389 1.49 elad } else { 390 1.49 elad linux_params->sched_priority = 391 1.49 elad (prio - SCHED_PRI_MIN) 392 1.49 elad * (LINUX_SCHED_RTPRIO_MAX - LINUX_SCHED_RTPRIO_MIN) 393 1.49 elad / (SCHED_PRI_MAX - SCHED_PRI_MIN) 394 1.49 elad + LINUX_SCHED_RTPRIO_MIN; 395 1.49 elad } 396 1.65 christos DPRINTF(("%s: linux: policy %d, priority %d\n", 397 1.65 christos __func__, -1, linux_params->sched_priority)); 398 1.49 elad } 399 1.49 elad 400 1.49 elad return 0; 401 1.49 elad } 402 1.49 elad 403 1.1 tron int 404 1.46 dsl linux_sys_sched_setparam(struct lwp *l, const struct linux_sys_sched_setparam_args *uap, register_t *retval) 405 1.1 tron { 406 1.46 dsl /* { 407 1.1 tron syscallarg(linux_pid_t) pid; 408 1.1 tron syscallarg(const struct linux_sched_param *) sp; 409 1.46 dsl } */ 410 1.49 elad int error, policy; 411 1.1 tron struct linux_sched_param lp; 412 1.49 elad struct sched_param sp; 413 1.49 elad 414 1.49 elad if (SCARG(uap, pid) < 0 || SCARG(uap, sp) == NULL) { 415 1.49 elad error = EINVAL; 416 1.49 elad goto out; 417 1.49 elad } 418 1.1 tron 419 1.49 elad error = copyin(SCARG(uap, sp), &lp, sizeof(lp)); 420 1.49 elad if (error) 421 1.49 elad goto out; 422 1.1 tron 423 1.49 elad /* We need the current policy in Linux terms. */ 424 1.66 njoly error = do_sched_getparam(SCARG(uap, pid), 0, &policy, NULL); 425 1.49 elad if (error) 426 1.49 elad goto out; 427 1.49 elad error = sched_native2linux(policy, NULL, &policy, NULL); 428 1.49 elad if (error) 429 1.49 elad goto out; 430 1.1 tron 431 1.49 elad error = sched_linux2native(policy, &lp, &policy, &sp); 432 1.1 tron if (error) 433 1.49 elad goto out; 434 1.1 tron 435 1.66 njoly error = do_sched_setparam(SCARG(uap, pid), 0, policy, &sp); 436 1.49 elad if (error) 437 1.49 elad goto out; 438 1.1 tron 439 1.49 elad out: 440 1.49 elad return error; 441 1.1 tron } 442 1.1 tron 443 1.1 tron int 444 1.46 dsl linux_sys_sched_getparam(struct lwp *l, const struct linux_sys_sched_getparam_args *uap, register_t *retval) 445 1.1 tron { 446 1.46 dsl /* { 447 1.1 tron syscallarg(linux_pid_t) pid; 448 1.1 tron syscallarg(struct linux_sched_param *) sp; 449 1.46 dsl } */ 450 1.1 tron struct linux_sched_param lp; 451 1.49 elad struct sched_param sp; 452 1.50 elad int error, policy; 453 1.49 elad 454 1.49 elad if (SCARG(uap, pid) < 0 || SCARG(uap, sp) == NULL) { 455 1.49 elad error = EINVAL; 456 1.49 elad goto out; 457 1.49 elad } 458 1.1 tron 459 1.66 njoly error = do_sched_getparam(SCARG(uap, pid), 0, &policy, &sp); 460 1.49 elad if (error) 461 1.49 elad goto out; 462 1.65 christos DPRINTF(("%s: native: policy %d, priority %d\n", 463 1.65 christos __func__, policy, sp.sched_priority)); 464 1.1 tron 465 1.50 elad error = sched_native2linux(policy, &sp, NULL, &lp); 466 1.49 elad if (error) 467 1.49 elad goto out; 468 1.65 christos DPRINTF(("%s: linux: policy %d, priority %d\n", 469 1.65 christos __func__, policy, lp.sched_priority)); 470 1.47 elad 471 1.49 elad error = copyout(&lp, SCARG(uap, sp), sizeof(lp)); 472 1.49 elad if (error) 473 1.49 elad goto out; 474 1.1 tron 475 1.49 elad out: 476 1.49 elad return error; 477 1.1 tron } 478 1.1 tron 479 1.1 tron int 480 1.46 dsl linux_sys_sched_setscheduler(struct lwp *l, const struct linux_sys_sched_setscheduler_args *uap, register_t *retval) 481 1.1 tron { 482 1.46 dsl /* { 483 1.1 tron syscallarg(linux_pid_t) pid; 484 1.1 tron syscallarg(int) policy; 485 1.61 njoly syscallarg(cont struct linux_sched_param *) sp; 486 1.46 dsl } */ 487 1.49 elad int error, policy; 488 1.1 tron struct linux_sched_param lp; 489 1.49 elad struct sched_param sp; 490 1.1 tron 491 1.49 elad if (SCARG(uap, pid) < 0 || SCARG(uap, sp) == NULL) { 492 1.49 elad error = EINVAL; 493 1.49 elad goto out; 494 1.49 elad } 495 1.1 tron 496 1.1 tron error = copyin(SCARG(uap, sp), &lp, sizeof(lp)); 497 1.1 tron if (error) 498 1.49 elad goto out; 499 1.65 christos DPRINTF(("%s: linux: policy %d, priority %d\n", 500 1.65 christos __func__, SCARG(uap, policy), lp.sched_priority)); 501 1.1 tron 502 1.49 elad error = sched_linux2native(SCARG(uap, policy), &lp, &policy, &sp); 503 1.49 elad if (error) 504 1.49 elad goto out; 505 1.65 christos DPRINTF(("%s: native: policy %d, priority %d\n", 506 1.65 christos __func__, policy, sp.sched_priority)); 507 1.1 tron 508 1.66 njoly error = do_sched_setparam(SCARG(uap, pid), 0, policy, &sp); 509 1.49 elad if (error) 510 1.49 elad goto out; 511 1.1 tron 512 1.49 elad out: 513 1.49 elad return error; 514 1.1 tron } 515 1.1 tron 516 1.1 tron int 517 1.46 dsl linux_sys_sched_getscheduler(struct lwp *l, const struct linux_sys_sched_getscheduler_args *uap, register_t *retval) 518 1.1 tron { 519 1.46 dsl /* { 520 1.1 tron syscallarg(linux_pid_t) pid; 521 1.46 dsl } */ 522 1.49 elad int error, policy; 523 1.1 tron 524 1.1 tron *retval = -1; 525 1.1 tron 526 1.66 njoly error = do_sched_getparam(SCARG(uap, pid), 0, &policy, NULL); 527 1.49 elad if (error) 528 1.49 elad goto out; 529 1.49 elad 530 1.49 elad error = sched_native2linux(policy, NULL, &policy, NULL); 531 1.49 elad if (error) 532 1.49 elad goto out; 533 1.49 elad 534 1.49 elad *retval = policy; 535 1.1 tron 536 1.49 elad out: 537 1.49 elad return error; 538 1.1 tron } 539 1.1 tron 540 1.1 tron int 541 1.46 dsl linux_sys_sched_yield(struct lwp *l, const void *v, register_t *retval) 542 1.1 tron { 543 1.11 gmcgarry 544 1.11 gmcgarry yield(); 545 1.1 tron return 0; 546 1.1 tron } 547 1.1 tron 548 1.1 tron int 549 1.46 dsl linux_sys_sched_get_priority_max(struct lwp *l, const struct linux_sys_sched_get_priority_max_args *uap, register_t *retval) 550 1.1 tron { 551 1.46 dsl /* { 552 1.1 tron syscallarg(int) policy; 553 1.46 dsl } */ 554 1.1 tron 555 1.55 njoly switch (SCARG(uap, policy)) { 556 1.55 njoly case LINUX_SCHED_OTHER: 557 1.55 njoly *retval = 0; 558 1.55 njoly break; 559 1.55 njoly case LINUX_SCHED_FIFO: 560 1.55 njoly case LINUX_SCHED_RR: 561 1.55 njoly *retval = LINUX_SCHED_RTPRIO_MAX; 562 1.55 njoly break; 563 1.55 njoly default: 564 1.1 tron return EINVAL; 565 1.1 tron } 566 1.1 tron 567 1.1 tron return 0; 568 1.1 tron } 569 1.1 tron 570 1.1 tron int 571 1.46 dsl linux_sys_sched_get_priority_min(struct lwp *l, const struct linux_sys_sched_get_priority_min_args *uap, register_t *retval) 572 1.1 tron { 573 1.46 dsl /* { 574 1.1 tron syscallarg(int) policy; 575 1.46 dsl } */ 576 1.1 tron 577 1.55 njoly switch (SCARG(uap, policy)) { 578 1.55 njoly case LINUX_SCHED_OTHER: 579 1.55 njoly *retval = 0; 580 1.55 njoly break; 581 1.55 njoly case LINUX_SCHED_FIFO: 582 1.55 njoly case LINUX_SCHED_RR: 583 1.55 njoly *retval = LINUX_SCHED_RTPRIO_MIN; 584 1.55 njoly break; 585 1.55 njoly default: 586 1.1 tron return EINVAL; 587 1.1 tron } 588 1.1 tron 589 1.1 tron return 0; 590 1.1 tron } 591 1.14 jdolecek 592 1.63 chs int 593 1.63 chs linux_sys_exit(struct lwp *l, const struct linux_sys_exit_args *uap, register_t *retval) 594 1.63 chs { 595 1.63 chs 596 1.63 chs lwp_exit(l); 597 1.63 chs return 0; 598 1.63 chs } 599 1.63 chs 600 1.14 jdolecek #ifndef __m68k__ 601 1.14 jdolecek /* Present on everything but m68k */ 602 1.14 jdolecek int 603 1.46 dsl linux_sys_exit_group(struct lwp *l, const struct linux_sys_exit_group_args *uap, register_t *retval) 604 1.14 jdolecek { 605 1.14 jdolecek 606 1.46 dsl return sys_exit(l, (const void *)uap, retval); 607 1.14 jdolecek } 608 1.14 jdolecek #endif /* !__m68k__ */ 609 1.19 manu 610 1.19 manu int 611 1.46 dsl linux_sys_set_tid_address(struct lwp *l, const struct linux_sys_set_tid_address_args *uap, register_t *retval) 612 1.19 manu { 613 1.46 dsl /* { 614 1.19 manu syscallarg(int *) tidptr; 615 1.46 dsl } */ 616 1.19 manu struct linux_emuldata *led; 617 1.19 manu 618 1.63 chs led = (struct linux_emuldata *)l->l_emuldata; 619 1.63 chs led->led_clear_tid = SCARG(uap, tid); 620 1.63 chs *retval = l->l_lid; 621 1.19 manu 622 1.19 manu return 0; 623 1.19 manu } 624 1.20 manu 625 1.20 manu /* ARGUSED1 */ 626 1.20 manu int 627 1.46 dsl linux_sys_gettid(struct lwp *l, const void *v, register_t *retval) 628 1.20 manu { 629 1.31 manu 630 1.63 chs *retval = l->l_lid; 631 1.31 manu return 0; 632 1.31 manu } 633 1.31 manu 634 1.68 christos /* 635 1.68 christos * The affinity syscalls assume that the layout of our cpu kcpuset is 636 1.68 christos * the same as linux's: a linear bitmask. 637 1.68 christos */ 638 1.22 manu int 639 1.46 dsl linux_sys_sched_getaffinity(struct lwp *l, const struct linux_sys_sched_getaffinity_args *uap, register_t *retval) 640 1.22 manu { 641 1.46 dsl /* { 642 1.63 chs syscallarg(linux_pid_t) pid; 643 1.22 manu syscallarg(unsigned int) len; 644 1.22 manu syscallarg(unsigned long *) mask; 645 1.46 dsl } */ 646 1.68 christos struct lwp *t; 647 1.68 christos kcpuset_t *kcset; 648 1.68 christos size_t size; 649 1.68 christos cpuid_t i; 650 1.68 christos int error; 651 1.22 manu 652 1.68 christos size = LINUX_CPU_MASK_SIZE; 653 1.60 njoly if (SCARG(uap, len) < size) 654 1.22 manu return EINVAL; 655 1.22 manu 656 1.68 christos /* Lock the LWP */ 657 1.68 christos t = lwp_find2(SCARG(uap, pid), l->l_lid); 658 1.68 christos if (t == NULL) 659 1.22 manu return ESRCH; 660 1.22 manu 661 1.68 christos /* Check the permission */ 662 1.68 christos if (kauth_authorize_process(l->l_cred, 663 1.68 christos KAUTH_PROCESS_SCHEDULER_GETAFFINITY, t->l_proc, NULL, NULL, NULL)) { 664 1.68 christos mutex_exit(t->l_proc->p_lock); 665 1.68 christos return EPERM; 666 1.68 christos } 667 1.68 christos 668 1.68 christos kcpuset_create(&kcset, true); 669 1.68 christos lwp_lock(t); 670 1.68 christos if (t->l_affinity != NULL) 671 1.68 christos kcpuset_copy(kcset, t->l_affinity); 672 1.68 christos else { 673 1.68 christos /* 674 1.68 christos * All available CPUs should be masked when affinity has not 675 1.68 christos * been set. 676 1.68 christos */ 677 1.68 christos kcpuset_zero(kcset); 678 1.68 christos for (i = 0; i < ncpu; i++) 679 1.68 christos kcpuset_set(kcset, i); 680 1.68 christos } 681 1.68 christos lwp_unlock(t); 682 1.68 christos mutex_exit(t->l_proc->p_lock); 683 1.68 christos error = kcpuset_copyout(kcset, (cpuset_t *)SCARG(uap, mask), size); 684 1.68 christos kcpuset_unuse(kcset, NULL); 685 1.60 njoly *retval = size; 686 1.59 njoly return error; 687 1.22 manu } 688 1.22 manu 689 1.22 manu int 690 1.46 dsl linux_sys_sched_setaffinity(struct lwp *l, const struct linux_sys_sched_setaffinity_args *uap, register_t *retval) 691 1.22 manu { 692 1.46 dsl /* { 693 1.63 chs syscallarg(linux_pid_t) pid; 694 1.22 manu syscallarg(unsigned int) len; 695 1.22 manu syscallarg(unsigned long *) mask; 696 1.46 dsl } */ 697 1.68 christos struct sys__sched_setaffinity_args ssa; 698 1.68 christos size_t size; 699 1.68 christos 700 1.68 christos size = LINUX_CPU_MASK_SIZE; 701 1.68 christos if (SCARG(uap, len) < size) 702 1.68 christos return EINVAL; 703 1.22 manu 704 1.68 christos SCARG(&ssa, pid) = SCARG(uap, pid); 705 1.68 christos SCARG(&ssa, lid) = l->l_lid; 706 1.68 christos SCARG(&ssa, size) = size; 707 1.68 christos SCARG(&ssa, cpuset) = (cpuset_t *)SCARG(uap, mask); 708 1.22 manu 709 1.68 christos return sys__sched_setaffinity(l, &ssa, retval); 710 1.64 dsl } 711
Indexes created Tue Sep 23 14:10:03 GMT 2025