netbsd32_signal.c revision 1.49
1 1.48 rin /* $NetBSD: netbsd32_signal.c,v 1.49 2019/11/18 10:25:48 rin Exp $ */ 2 1.1 mrg 3 1.1 mrg /* 4 1.1 mrg * Copyright (c) 1998, 2001 Matthew R. Green 5 1.1 mrg * All rights reserved. 6 1.1 mrg * 7 1.1 mrg * Redistribution and use in source and binary forms, with or without 8 1.1 mrg * modification, are permitted provided that the following conditions 9 1.1 mrg * are met: 10 1.1 mrg * 1. Redistributions of source code must retain the above copyright 11 1.1 mrg * notice, this list of conditions and the following disclaimer. 12 1.1 mrg * 2. Redistributions in binary form must reproduce the above copyright 13 1.1 mrg * notice, this list of conditions and the following disclaimer in the 14 1.1 mrg * documentation and/or other materials provided with the distribution. 15 1.1 mrg * 16 1.1 mrg * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 17 1.1 mrg * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 18 1.1 mrg * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 19 1.1 mrg * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 20 1.1 mrg * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, 21 1.1 mrg * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; 22 1.1 mrg * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED 23 1.1 mrg * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, 24 1.1 mrg * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 25 1.1 mrg * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 26 1.1 mrg * SUCH DAMAGE. 27 1.1 mrg */ 28 1.2 lukem 29 1.2 lukem #include <sys/cdefs.h> 30 1.48 rin __KERNEL_RCSID(0, "$NetBSD: netbsd32_signal.c,v 1.49 2019/11/18 10:25:48 rin Exp $"); 31 1.41 christos 32 1.41 christos #if defined(_KERNEL_OPT) 33 1.41 christos #include "opt_ktrace.h" 34 1.41 christos #endif 35 1.1 mrg 36 1.1 mrg #include <sys/param.h> 37 1.1 mrg #include <sys/systm.h> 38 1.1 mrg #include <sys/mount.h> 39 1.1 mrg #include <sys/stat.h> 40 1.1 mrg #include <sys/time.h> 41 1.1 mrg #include <sys/signalvar.h> 42 1.40 martin #include <sys/ktrace.h> 43 1.1 mrg #include <sys/proc.h> 44 1.7 fvdl #include <sys/wait.h> 45 1.11 christos #include <sys/dirent.h> 46 1.7 fvdl 47 1.7 fvdl #include <uvm/uvm_extern.h> 48 1.1 mrg 49 1.1 mrg #include <compat/netbsd32/netbsd32.h> 50 1.10 cube #include <compat/netbsd32/netbsd32_conv.h> 51 1.1 mrg #include <compat/netbsd32/netbsd32_syscallargs.h> 52 1.1 mrg 53 1.12 christos #include <compat/sys/signal.h> 54 1.12 christos #include <compat/sys/signalvar.h> 55 1.13 christos #include <compat/sys/siginfo.h> 56 1.12 christos #include <compat/sys/ucontext.h> 57 1.25 dsl #include <compat/common/compat_sigaltstack.h> 58 1.12 christos 59 1.1 mrg int 60 1.28 dsl netbsd32_sigaction(struct lwp *l, const struct netbsd32_sigaction_args *uap, register_t *retval) 61 1.1 mrg { 62 1.28 dsl /* { 63 1.1 mrg syscallarg(int) signum; 64 1.1 mrg syscallarg(const netbsd32_sigactionp_t) nsa; 65 1.1 mrg syscallarg(netbsd32_sigactionp_t) osa; 66 1.28 dsl } */ 67 1.1 mrg struct sigaction nsa, osa; 68 1.38 christos struct netbsd32_sigaction13 *sa32p, sa32; 69 1.1 mrg int error; 70 1.1 mrg 71 1.23 dsl if (SCARG_P32(uap, nsa)) { 72 1.23 dsl sa32p = SCARG_P32(uap, nsa); 73 1.1 mrg if (copyin(sa32p, &sa32, sizeof(sa32))) 74 1.1 mrg return EFAULT; 75 1.5 atatat nsa.sa_handler = (void *)NETBSD32PTR64(sa32.netbsd32_sa_handler); 76 1.38 christos memset(&nsa.sa_mask, 0, sizeof(nsa.sa_mask)); 77 1.38 christos nsa.sa_mask.__bits[0] = sa32.netbsd32_sa_mask; 78 1.5 atatat nsa.sa_flags = sa32.netbsd32_sa_flags; 79 1.1 mrg } 80 1.19 ad error = sigaction1(l, SCARG(uap, signum), 81 1.23 dsl SCARG_P32(uap, nsa) ? &nsa : 0, 82 1.23 dsl SCARG_P32(uap, osa) ? &osa : 0, 83 1.3 thorpej NULL, 0); 84 1.8 perry 85 1.1 mrg if (error) 86 1.1 mrg return (error); 87 1.1 mrg 88 1.23 dsl if (SCARG_P32(uap, osa)) { 89 1.22 dsl NETBSD32PTR32(sa32.netbsd32_sa_handler, osa.sa_handler); 90 1.38 christos sa32.netbsd32_sa_mask = osa.sa_mask.__bits[0]; 91 1.5 atatat sa32.netbsd32_sa_flags = osa.sa_flags; 92 1.23 dsl sa32p = SCARG_P32(uap, osa); 93 1.1 mrg if (copyout(&sa32, sa32p, sizeof(sa32))) 94 1.1 mrg return EFAULT; 95 1.1 mrg } 96 1.1 mrg 97 1.1 mrg return (0); 98 1.1 mrg } 99 1.1 mrg 100 1.1 mrg int 101 1.28 dsl netbsd32___sigaltstack14(struct lwp *l, const struct netbsd32___sigaltstack14_args *uap, register_t *retval) 102 1.1 mrg { 103 1.28 dsl /* { 104 1.1 mrg syscallarg(const netbsd32_sigaltstackp_t) nss; 105 1.1 mrg syscallarg(netbsd32_sigaltstackp_t) oss; 106 1.28 dsl } */ 107 1.25 dsl compat_sigaltstack(uap, netbsd32_sigaltstack, SS_ONSTACK, SS_DISABLE); 108 1.1 mrg } 109 1.1 mrg 110 1.1 mrg /* ARGSUSED */ 111 1.1 mrg int 112 1.28 dsl netbsd32___sigaction14(struct lwp *l, const struct netbsd32___sigaction14_args *uap, register_t *retval) 113 1.1 mrg { 114 1.28 dsl /* { 115 1.1 mrg syscallarg(int) signum; 116 1.1 mrg syscallarg(const struct sigaction *) nsa; 117 1.1 mrg syscallarg(struct sigaction *) osa; 118 1.28 dsl } */ 119 1.1 mrg struct netbsd32_sigaction sa32; 120 1.1 mrg struct sigaction nsa, osa; 121 1.1 mrg int error; 122 1.1 mrg 123 1.23 dsl if (SCARG_P32(uap, nsa)) { 124 1.23 dsl error = copyin(SCARG_P32(uap, nsa), &sa32, sizeof(sa32)); 125 1.1 mrg if (error) 126 1.1 mrg return (error); 127 1.22 dsl nsa.sa_handler = NETBSD32PTR64(sa32.netbsd32_sa_handler); 128 1.5 atatat nsa.sa_mask = sa32.netbsd32_sa_mask; 129 1.5 atatat nsa.sa_flags = sa32.netbsd32_sa_flags; 130 1.1 mrg } 131 1.19 ad error = sigaction1(l, SCARG(uap, signum), 132 1.23 dsl SCARG_P32(uap, nsa) ? &nsa : 0, 133 1.23 dsl SCARG_P32(uap, osa) ? &osa : 0, 134 1.22 dsl NULL, 0); 135 1.1 mrg if (error) 136 1.1 mrg return (error); 137 1.23 dsl if (SCARG_P32(uap, osa)) { 138 1.22 dsl NETBSD32PTR32(sa32.netbsd32_sa_handler, osa.sa_handler); 139 1.5 atatat sa32.netbsd32_sa_mask = osa.sa_mask; 140 1.5 atatat sa32.netbsd32_sa_flags = osa.sa_flags; 141 1.23 dsl error = copyout(&sa32, SCARG_P32(uap, osa), sizeof(sa32)); 142 1.4 scw if (error) 143 1.4 scw return (error); 144 1.4 scw } 145 1.4 scw return (0); 146 1.4 scw } 147 1.4 scw 148 1.4 scw /* ARGSUSED */ 149 1.4 scw int 150 1.28 dsl netbsd32___sigaction_sigtramp(struct lwp *l, const struct netbsd32___sigaction_sigtramp_args *uap, register_t *retval) 151 1.4 scw { 152 1.28 dsl /* { 153 1.4 scw syscallarg(int) signum; 154 1.4 scw syscallarg(const netbsd32_sigactionp_t) nsa; 155 1.4 scw syscallarg(netbsd32_sigactionp_t) osa; 156 1.4 scw syscallarg(netbsd32_voidp) tramp; 157 1.4 scw syscallarg(int) vers; 158 1.28 dsl } */ 159 1.4 scw struct netbsd32_sigaction sa32; 160 1.4 scw struct sigaction nsa, osa; 161 1.4 scw int error; 162 1.4 scw 163 1.23 dsl if (SCARG_P32(uap, nsa)) { 164 1.23 dsl error = copyin(SCARG_P32(uap, nsa), &sa32, sizeof(sa32)); 165 1.4 scw if (error) 166 1.4 scw return (error); 167 1.22 dsl nsa.sa_handler = NETBSD32PTR64(sa32.netbsd32_sa_handler); 168 1.5 atatat nsa.sa_mask = sa32.netbsd32_sa_mask; 169 1.5 atatat nsa.sa_flags = sa32.netbsd32_sa_flags; 170 1.4 scw } 171 1.19 ad error = sigaction1(l, SCARG(uap, signum), 172 1.23 dsl SCARG_P32(uap, nsa) ? &nsa : 0, 173 1.23 dsl SCARG_P32(uap, osa) ? &osa : 0, 174 1.23 dsl SCARG_P32(uap, tramp), SCARG(uap, vers)); 175 1.4 scw if (error) 176 1.4 scw return (error); 177 1.23 dsl if (SCARG_P32(uap, osa)) { 178 1.22 dsl NETBSD32PTR32(sa32.netbsd32_sa_handler, osa.sa_handler); 179 1.5 atatat sa32.netbsd32_sa_mask = osa.sa_mask; 180 1.5 atatat sa32.netbsd32_sa_flags = osa.sa_flags; 181 1.23 dsl error = copyout(&sa32, SCARG_P32(uap, osa), sizeof(sa32)); 182 1.1 mrg if (error) 183 1.1 mrg return (error); 184 1.1 mrg } 185 1.1 mrg return (0); 186 1.7 fvdl } 187 1.7 fvdl 188 1.39 martin void 189 1.39 martin netbsd32_ksi32_to_ksi(struct _ksiginfo *si, const struct __ksiginfo32 *si32) 190 1.7 fvdl { 191 1.46 rin size_t i; 192 1.46 rin 193 1.7 fvdl memset(si, 0, sizeof (*si)); 194 1.39 martin si->_signo = si32->_signo; 195 1.39 martin si->_code = si32->_code; 196 1.39 martin si->_errno = si32->_errno; 197 1.7 fvdl 198 1.49 rin if (si32->_code == SI_NOINFO) 199 1.49 rin return; 200 1.49 rin else if (si32->_code <= 0) /* codes described in siginfo(2) */ 201 1.49 rin goto fill_rt; 202 1.49 rin 203 1.39 martin switch (si32->_signo) { 204 1.7 fvdl case SIGILL: 205 1.47 rin case SIGFPE: 206 1.7 fvdl case SIGBUS: 207 1.7 fvdl case SIGSEGV: 208 1.46 rin fill_fault: 209 1.42 christos si->_reason._fault._addr = 210 1.42 christos NETBSD32IPTR64(si32->_reason._fault._addr); 211 1.39 martin si->_reason._fault._trap = si32->_reason._fault._trap; 212 1.7 fvdl break; 213 1.46 rin case SIGTRAP: 214 1.48 rin switch (si32->_code) { 215 1.48 rin case TRAP_EXEC: 216 1.48 rin case TRAP_CHLD: 217 1.48 rin case TRAP_LWP: 218 1.48 rin si->_reason._ptrace_state._pe_report_event = 219 1.48 rin si32->_reason._ptrace_state._pe_report_event; 220 1.48 rin CTASSERT(sizeof(si->_reason._ptrace_state._option._pe_other_pid) == 221 1.48 rin sizeof(si->_reason._ptrace_state._option._pe_lwp)); 222 1.48 rin si->_reason._ptrace_state._option._pe_other_pid = 223 1.48 rin si32->_reason._ptrace_state._option._pe_other_pid; 224 1.48 rin break; 225 1.48 rin case TRAP_SCE: 226 1.48 rin case TRAP_SCX: 227 1.48 rin si->_reason._syscall._sysnum = 228 1.48 rin si32->_reason._syscall._sysnum; 229 1.48 rin si->_reason._syscall._retval[0] = 230 1.48 rin si32->_reason._syscall._retval[0]; 231 1.48 rin si->_reason._syscall._retval[1] = 232 1.48 rin si32->_reason._syscall._retval[1]; 233 1.48 rin si->_reason._syscall._error = 234 1.48 rin si32->_reason._syscall._error; 235 1.48 rin for (i = 0; 236 1.48 rin i < __arraycount(si->_reason._syscall._args); i++) 237 1.48 rin si->_reason._syscall._args[i] = 238 1.48 rin si32->_reason._syscall._args[i]; 239 1.48 rin break; 240 1.48 rin default: 241 1.46 rin goto fill_fault; 242 1.48 rin } 243 1.46 rin break; 244 1.7 fvdl case SIGALRM: 245 1.7 fvdl case SIGVTALRM: 246 1.7 fvdl case SIGPROF: 247 1.39 martin default: /* see sigqueue() and kill1() */ 248 1.49 rin fill_rt: 249 1.39 martin si->_reason._rt._pid = si32->_reason._rt._pid; 250 1.39 martin si->_reason._rt._uid = si32->_reason._rt._uid; 251 1.42 christos si->_reason._rt._value.sival_int = 252 1.42 christos si32->_reason._rt._value.sival_int; 253 1.7 fvdl break; 254 1.47 rin case SIGURG: 255 1.47 rin case SIGIO: 256 1.47 rin si->_reason._poll._band = si32->_reason._poll._band; 257 1.47 rin si->_reason._poll._fd = si32->_reason._poll._fd; 258 1.47 rin break; 259 1.7 fvdl case SIGCHLD: 260 1.39 martin si->_reason._child._pid = si32->_reason._child._pid; 261 1.39 martin si->_reason._child._uid = si32->_reason._child._uid; 262 1.46 rin si->_reason._child._status = si32->_reason._child._status; 263 1.39 martin si->_reason._child._utime = si32->_reason._child._utime; 264 1.39 martin si->_reason._child._stime = si32->_reason._child._stime; 265 1.7 fvdl break; 266 1.7 fvdl } 267 1.7 fvdl } 268 1.7 fvdl 269 1.47 rin void 270 1.47 rin netbsd32_si32_to_si(siginfo_t *si, const siginfo32_t *si32) 271 1.47 rin { 272 1.47 rin 273 1.47 rin memset(si, 0, sizeof (*si)); 274 1.47 rin netbsd32_ksi32_to_ksi(&si->_info, &si32->_info); 275 1.47 rin } 276 1.47 rin 277 1.40 martin static void 278 1.40 martin netbsd32_ksi_to_ksi32(struct __ksiginfo32 *si32, const struct _ksiginfo *si) 279 1.40 martin { 280 1.46 rin size_t i; 281 1.46 rin 282 1.40 martin memset(si32, 0, sizeof (*si32)); 283 1.40 martin si32->_signo = si->_signo; 284 1.40 martin si32->_code = si->_code; 285 1.40 martin si32->_errno = si->_errno; 286 1.40 martin 287 1.49 rin if (si->_code == SI_NOINFO) 288 1.49 rin return; 289 1.49 rin else if (si->_code <= 0) /* codes described in siginfo(2) */ 290 1.49 rin goto fill_rt; 291 1.49 rin 292 1.40 martin switch (si->_signo) { 293 1.40 martin case SIGILL: 294 1.47 rin case SIGFPE: 295 1.40 martin case SIGBUS: 296 1.40 martin case SIGSEGV: 297 1.46 rin fill_fault: 298 1.40 martin si32->_reason._fault._addr = 299 1.40 martin NETBSD32PTR32I(si->_reason._fault._addr); 300 1.40 martin si32->_reason._fault._trap = si->_reason._fault._trap; 301 1.40 martin break; 302 1.46 rin case SIGTRAP: 303 1.48 rin switch (si->_code) { 304 1.48 rin case TRAP_EXEC: 305 1.48 rin case TRAP_CHLD: 306 1.48 rin case TRAP_LWP: 307 1.48 rin si32->_reason._ptrace_state._pe_report_event = 308 1.48 rin si->_reason._ptrace_state._pe_report_event; 309 1.48 rin CTASSERT(sizeof(si32->_reason._ptrace_state._option._pe_other_pid) == 310 1.48 rin sizeof(si32->_reason._ptrace_state._option._pe_lwp)); 311 1.48 rin si32->_reason._ptrace_state._option._pe_other_pid = 312 1.48 rin si->_reason._ptrace_state._option._pe_other_pid; 313 1.48 rin break; 314 1.48 rin case TRAP_SCE: 315 1.48 rin case TRAP_SCX: 316 1.48 rin si32->_reason._syscall._sysnum = 317 1.48 rin si->_reason._syscall._sysnum; 318 1.48 rin si32->_reason._syscall._retval[0] = 319 1.48 rin si->_reason._syscall._retval[0]; 320 1.48 rin si32->_reason._syscall._retval[1] = 321 1.48 rin si->_reason._syscall._retval[1]; 322 1.48 rin si32->_reason._syscall._error = 323 1.48 rin si->_reason._syscall._error; 324 1.48 rin for (i = 0; 325 1.48 rin i < __arraycount(si->_reason._syscall._args); i++) 326 1.48 rin si32->_reason._syscall._args[i] = 327 1.48 rin si->_reason._syscall._args[i]; 328 1.48 rin break; 329 1.48 rin default: 330 1.46 rin goto fill_fault; 331 1.48 rin } 332 1.46 rin break; 333 1.40 martin case SIGALRM: 334 1.40 martin case SIGVTALRM: 335 1.40 martin case SIGPROF: 336 1.40 martin default: /* see sigqueue() and kill1() */ 337 1.49 rin fill_rt: 338 1.40 martin si32->_reason._rt._pid = si->_reason._rt._pid; 339 1.40 martin si32->_reason._rt._uid = si->_reason._rt._uid; 340 1.42 christos si32->_reason._rt._value.sival_int = 341 1.42 christos si->_reason._rt._value.sival_int; 342 1.40 martin break; 343 1.47 rin case SIGURG: 344 1.47 rin case SIGIO: 345 1.47 rin si32->_reason._poll._band = si->_reason._poll._band; 346 1.47 rin si32->_reason._poll._fd = si->_reason._poll._fd; 347 1.47 rin break; 348 1.40 martin case SIGCHLD: 349 1.40 martin si32->_reason._child._pid = si->_reason._child._pid; 350 1.40 martin si32->_reason._child._uid = si->_reason._child._uid; 351 1.46 rin si32->_reason._child._status = si->_reason._child._status; 352 1.40 martin si32->_reason._child._utime = si->_reason._child._utime; 353 1.40 martin si32->_reason._child._stime = si->_reason._child._stime; 354 1.40 martin break; 355 1.40 martin } 356 1.40 martin } 357 1.40 martin 358 1.15 chs void 359 1.9 drochner netbsd32_si_to_si32(siginfo32_t *si32, const siginfo_t *si) 360 1.7 fvdl { 361 1.46 rin 362 1.7 fvdl memset(si32, 0, sizeof (*si32)); 363 1.46 rin netbsd32_ksi_to_ksi32(&si32->_info, &si->_info); 364 1.7 fvdl } 365 1.7 fvdl 366 1.7 fvdl void 367 1.7 fvdl getucontext32(struct lwp *l, ucontext32_t *ucp) 368 1.7 fvdl { 369 1.20 cube struct proc *p = l->l_proc; 370 1.7 fvdl 371 1.29 ad KASSERT(mutex_owned(p->p_lock)); 372 1.7 fvdl 373 1.7 fvdl ucp->uc_flags = 0; 374 1.7 fvdl ucp->uc_link = (uint32_t)(intptr_t)l->l_ctxlink; 375 1.37 rmind ucp->uc_sigmask = l->l_sigmask; 376 1.7 fvdl ucp->uc_flags |= _UC_SIGMASK; 377 1.7 fvdl 378 1.7 fvdl /* 379 1.7 fvdl * The (unsupplied) definition of the `current execution stack' 380 1.7 fvdl * in the System V Interface Definition appears to allow returning 381 1.7 fvdl * the main context stack. 382 1.7 fvdl */ 383 1.19 ad if ((l->l_sigstk.ss_flags & SS_ONSTACK) == 0) { 384 1.7 fvdl ucp->uc_stack.ss_sp = USRSTACK32; 385 1.7 fvdl ucp->uc_stack.ss_size = ctob(p->p_vmspace->vm_ssize); 386 1.7 fvdl ucp->uc_stack.ss_flags = 0; /* XXX, def. is Very Fishy */ 387 1.7 fvdl } else { 388 1.7 fvdl /* Simply copy alternate signal execution stack. */ 389 1.7 fvdl ucp->uc_stack.ss_sp = 390 1.19 ad (uint32_t)(intptr_t)l->l_sigstk.ss_sp; 391 1.19 ad ucp->uc_stack.ss_size = l->l_sigstk.ss_size; 392 1.19 ad ucp->uc_stack.ss_flags = l->l_sigstk.ss_flags; 393 1.7 fvdl } 394 1.7 fvdl ucp->uc_flags |= _UC_STACK; 395 1.29 ad mutex_exit(p->p_lock); 396 1.7 fvdl cpu_getmcontext32(l, &ucp->uc_mcontext, &ucp->uc_flags); 397 1.29 ad mutex_enter(p->p_lock); 398 1.7 fvdl } 399 1.7 fvdl 400 1.7 fvdl int 401 1.28 dsl netbsd32_getcontext(struct lwp *l, const struct netbsd32_getcontext_args *uap, register_t *retval) 402 1.7 fvdl { 403 1.28 dsl /* { 404 1.7 fvdl syscallarg(netbsd32_ucontextp) ucp; 405 1.28 dsl } */ 406 1.20 cube struct proc *p = l->l_proc; 407 1.7 fvdl ucontext32_t uc; 408 1.7 fvdl 409 1.35 joerg memset(&uc, 0, sizeof(uc)); 410 1.35 joerg 411 1.29 ad mutex_enter(p->p_lock); 412 1.7 fvdl getucontext32(l, &uc); 413 1.29 ad mutex_exit(p->p_lock); 414 1.7 fvdl 415 1.23 dsl return copyout(&uc, SCARG_P32(uap, ucp), sizeof (ucontext32_t)); 416 1.7 fvdl } 417 1.7 fvdl 418 1.7 fvdl int 419 1.7 fvdl setucontext32(struct lwp *l, const ucontext32_t *ucp) 420 1.7 fvdl { 421 1.20 cube struct proc *p = l->l_proc; 422 1.20 cube int error; 423 1.20 cube 424 1.29 ad KASSERT(mutex_owned(p->p_lock)); 425 1.20 cube 426 1.20 cube if ((ucp->uc_flags & _UC_SIGMASK) != 0) { 427 1.20 cube error = sigprocmask1(l, SIG_SETMASK, &ucp->uc_sigmask, NULL); 428 1.20 cube if (error != 0) 429 1.20 cube return error; 430 1.20 cube } 431 1.7 fvdl 432 1.29 ad mutex_exit(p->p_lock); 433 1.20 cube error = cpu_setmcontext32(l, &ucp->uc_mcontext, ucp->uc_flags); 434 1.29 ad mutex_enter(p->p_lock); 435 1.20 cube if (error != 0) 436 1.7 fvdl return (error); 437 1.20 cube 438 1.7 fvdl l->l_ctxlink = (void *)(intptr_t)ucp->uc_link; 439 1.20 cube 440 1.7 fvdl /* 441 1.20 cube * If there was stack information, update whether or not we are 442 1.20 cube * still running on an alternate signal stack. 443 1.7 fvdl */ 444 1.20 cube if ((ucp->uc_flags & _UC_STACK) != 0) { 445 1.20 cube if (ucp->uc_stack.ss_flags & SS_ONSTACK) 446 1.20 cube l->l_sigstk.ss_flags |= SS_ONSTACK; 447 1.20 cube else 448 1.20 cube l->l_sigstk.ss_flags &= ~SS_ONSTACK; 449 1.20 cube } 450 1.7 fvdl 451 1.7 fvdl return 0; 452 1.7 fvdl } 453 1.7 fvdl 454 1.7 fvdl /* ARGSUSED */ 455 1.7 fvdl int 456 1.28 dsl netbsd32_setcontext(struct lwp *l, const struct netbsd32_setcontext_args *uap, register_t *retval) 457 1.7 fvdl { 458 1.28 dsl /* { 459 1.7 fvdl syscallarg(netbsd32_ucontextp) ucp; 460 1.28 dsl } */ 461 1.7 fvdl ucontext32_t uc; 462 1.7 fvdl int error; 463 1.20 cube struct proc *p = l->l_proc; 464 1.7 fvdl 465 1.23 dsl error = copyin(SCARG_P32(uap, ucp), &uc, sizeof (uc)); 466 1.18 drochner if (error) 467 1.18 drochner return (error); 468 1.18 drochner if (!(uc.uc_flags & _UC_CPU)) 469 1.18 drochner return (EINVAL); 470 1.29 ad mutex_enter(p->p_lock); 471 1.18 drochner error = setucontext32(l, &uc); 472 1.29 ad mutex_exit(p->p_lock); 473 1.18 drochner if (error) 474 1.7 fvdl return (error); 475 1.7 fvdl 476 1.7 fvdl return (EJUSTRETURN); 477 1.1 mrg } 478 1.10 cube 479 1.10 cube static int 480 1.10 cube netbsd32_sigtimedwait_put_info(const void *src, void *dst, size_t size) 481 1.10 cube { 482 1.10 cube const siginfo_t *info = src; 483 1.10 cube siginfo32_t info32; 484 1.10 cube 485 1.10 cube netbsd32_si_to_si32(&info32, info); 486 1.10 cube 487 1.10 cube return copyout(&info32, dst, sizeof(info32)); 488 1.10 cube } 489 1.10 cube 490 1.10 cube static int 491 1.10 cube netbsd32_sigtimedwait_fetch_timeout(const void *src, void *dst, size_t size) 492 1.10 cube { 493 1.10 cube struct timespec *ts = dst; 494 1.10 cube struct netbsd32_timespec ts32; 495 1.10 cube int error; 496 1.10 cube 497 1.10 cube error = copyin(src, &ts32, sizeof(ts32)); 498 1.10 cube if (error) 499 1.10 cube return error; 500 1.10 cube 501 1.10 cube netbsd32_to_timespec(&ts32, ts); 502 1.10 cube return 0; 503 1.10 cube } 504 1.10 cube 505 1.10 cube static int 506 1.10 cube netbsd32_sigtimedwait_put_timeout(const void *src, void *dst, size_t size) 507 1.10 cube { 508 1.10 cube const struct timespec *ts = src; 509 1.10 cube struct netbsd32_timespec ts32; 510 1.10 cube 511 1.10 cube netbsd32_from_timespec(ts, &ts32); 512 1.10 cube 513 1.10 cube return copyout(&ts32, dst, sizeof(ts32)); 514 1.10 cube } 515 1.10 cube 516 1.10 cube int 517 1.32 christos netbsd32_____sigtimedwait50(struct lwp *l, const struct netbsd32_____sigtimedwait50_args *uap, register_t *retval) 518 1.10 cube { 519 1.28 dsl /* { 520 1.10 cube syscallarg(netbsd32_sigsetp_t) set; 521 1.10 cube syscallarg(netbsd32_siginfop_t) info; 522 1.32 christos syscallarg(netbsd32_timespec50p_t) timeout; 523 1.28 dsl } */ 524 1.32 christos struct sys_____sigtimedwait50_args ua; 525 1.10 cube 526 1.10 cube NETBSD32TOP_UAP(set, const sigset_t); 527 1.10 cube NETBSD32TOP_UAP(info, siginfo_t); 528 1.10 cube NETBSD32TOP_UAP(timeout, struct timespec); 529 1.10 cube 530 1.33 pooka return sigtimedwait1(l, &ua, retval, 531 1.36 christos copyin, 532 1.32 christos netbsd32_sigtimedwait_put_info, 533 1.10 cube netbsd32_sigtimedwait_fetch_timeout, 534 1.10 cube netbsd32_sigtimedwait_put_timeout); 535 1.10 cube } 536 1.39 martin 537 1.39 martin int 538 1.39 martin netbsd32_sigqueueinfo(struct lwp *l, 539 1.39 martin const struct netbsd32_sigqueueinfo_args *uap, register_t *retval) 540 1.39 martin { 541 1.39 martin /* { 542 1.39 martin syscallarg(pid_t) pid; 543 1.39 martin syscallarg(const netbsd32_siginfop_t) info; 544 1.39 martin } */ 545 1.39 martin struct __ksiginfo32 ksi32; 546 1.39 martin ksiginfo_t ksi; 547 1.39 martin int error; 548 1.39 martin 549 1.39 martin if ((error = copyin(SCARG_P32(uap, info), &ksi32, 550 1.39 martin sizeof(ksi32))) != 0) 551 1.39 martin return error; 552 1.39 martin 553 1.39 martin KSI_INIT(&ksi); 554 1.39 martin netbsd32_ksi32_to_ksi(&ksi.ksi_info, &ksi32); 555 1.39 martin 556 1.39 martin return kill1(l, SCARG(uap, pid), &ksi, retval); 557 1.39 martin } 558 1.40 martin 559 1.40 martin struct netbsd32_ktr_psig { 560 1.40 martin int signo; 561 1.40 martin netbsd32_pointer_t action; 562 1.40 martin sigset_t mask; 563 1.40 martin int code; 564 1.40 martin /* and optional siginfo_t */ 565 1.40 martin }; 566 1.40 martin 567 1.44 christos #ifdef notyet 568 1.41 christos #ifdef KTRACE 569 1.40 martin void 570 1.40 martin netbsd32_ktrpsig(int sig, sig_t action, const sigset_t *mask, 571 1.40 martin const ksiginfo_t *ksi) 572 1.40 martin { 573 1.40 martin struct ktrace_entry *kte; 574 1.40 martin lwp_t *l = curlwp; 575 1.40 martin struct { 576 1.40 martin struct netbsd32_ktr_psig kp; 577 1.40 martin siginfo32_t si; 578 1.40 martin } *kbuf; 579 1.40 martin 580 1.40 martin if (!KTRPOINT(l->l_proc, KTR_PSIG)) 581 1.40 martin return; 582 1.40 martin 583 1.40 martin if (ktealloc(&kte, (void *)&kbuf, l, KTR_PSIG, sizeof(*kbuf))) 584 1.40 martin return; 585 1.40 martin 586 1.40 martin kbuf->kp.signo = (char)sig; 587 1.40 martin NETBSD32PTR32(kbuf->kp.action, action); 588 1.40 martin kbuf->kp.mask = *mask; 589 1.40 martin 590 1.40 martin if (ksi) { 591 1.40 martin kbuf->kp.code = KSI_TRAPCODE(ksi); 592 1.40 martin (void)memset(&kbuf->si, 0, sizeof(kbuf->si)); 593 1.40 martin netbsd32_ksi_to_ksi32(&kbuf->si._info, &ksi->ksi_info); 594 1.40 martin ktesethdrlen(kte, sizeof(*kbuf)); 595 1.40 martin } else { 596 1.40 martin kbuf->kp.code = 0; 597 1.40 martin ktesethdrlen(kte, sizeof(struct netbsd32_ktr_psig)); 598 1.40 martin } 599 1.40 martin 600 1.40 martin ktraddentry(l, kte, KTA_WAITOK); 601 1.40 martin } 602 1.41 christos #endif 603 1.44 christos #endif 604
Indexes created Mon Sep 22 13:09:51 GMT 2025