trap.c revision 1.120
1 1.120 skrll /* $NetBSD: trap.c,v 1.120 2022/06/09 16:45:38 skrll Exp $ */ 2 1.1 fredette 3 1.1 fredette /*- 4 1.1 fredette * Copyright (c) 2001, 2002 The NetBSD Foundation, Inc. 5 1.1 fredette * All rights reserved. 6 1.1 fredette * 7 1.1 fredette * This code is derived from software contributed to The NetBSD Foundation 8 1.1 fredette * by Matthew Fredette. 9 1.1 fredette * 10 1.1 fredette * Redistribution and use in source and binary forms, with or without 11 1.1 fredette * modification, are permitted provided that the following conditions 12 1.1 fredette * are met: 13 1.1 fredette * 1. Redistributions of source code must retain the above copyright 14 1.1 fredette * notice, this list of conditions and the following disclaimer. 15 1.1 fredette * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 fredette * notice, this list of conditions and the following disclaimer in the 17 1.1 fredette * documentation and/or other materials provided with the distribution. 18 1.1 fredette * 19 1.1 fredette * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 20 1.1 fredette * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 21 1.1 fredette * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 22 1.1 fredette * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 23 1.1 fredette * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 24 1.1 fredette * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 25 1.1 fredette * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 26 1.1 fredette * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 27 1.1 fredette * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 28 1.1 fredette * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 29 1.1 fredette * POSSIBILITY OF SUCH DAMAGE. 30 1.1 fredette */ 31 1.1 fredette 32 1.1 fredette /* $OpenBSD: trap.c,v 1.30 2001/09/19 20:50:56 mickey Exp $ */ 33 1.1 fredette 34 1.1 fredette /* 35 1.60 snj * Copyright (c) 1998-2004 Michael Shalayeff 36 1.1 fredette * All rights reserved. 37 1.1 fredette * 38 1.1 fredette * Redistribution and use in source and binary forms, with or without 39 1.1 fredette * modification, are permitted provided that the following conditions 40 1.1 fredette * are met: 41 1.1 fredette * 1. Redistributions of source code must retain the above copyright 42 1.1 fredette * notice, this list of conditions and the following disclaimer. 43 1.1 fredette * 2. Redistributions in binary form must reproduce the above copyright 44 1.1 fredette * notice, this list of conditions and the following disclaimer in the 45 1.1 fredette * documentation and/or other materials provided with the distribution. 46 1.1 fredette * 47 1.1 fredette * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 48 1.1 fredette * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 49 1.1 fredette * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 50 1.60 snj * IN NO EVENT SHALL THE AUTHOR OR HIS RELATIVES BE LIABLE FOR ANY DIRECT, 51 1.60 snj * INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES 52 1.60 snj * (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR 53 1.60 snj * SERVICES; LOSS OF MIND, USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) 54 1.60 snj * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, 55 1.60 snj * STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING 56 1.60 snj * IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF 57 1.60 snj * THE POSSIBILITY OF SUCH DAMAGE. 58 1.1 fredette */ 59 1.8 lukem 60 1.8 lukem #include <sys/cdefs.h> 61 1.120 skrll __KERNEL_RCSID(0, "$NetBSD: trap.c,v 1.120 2022/06/09 16:45:38 skrll Exp $"); 62 1.1 fredette 63 1.1 fredette /* #define INTRDEBUG */ 64 1.1 fredette /* #define TRAPDEBUG */ 65 1.1 fredette /* #define USERTRACE */ 66 1.1 fredette 67 1.1 fredette #include "opt_kgdb.h" 68 1.51 skrll #include "opt_ptrace.h" 69 1.1 fredette 70 1.1 fredette #include <sys/param.h> 71 1.1 fredette #include <sys/systm.h> 72 1.1 fredette #include <sys/kernel.h> 73 1.1 fredette #include <sys/syscall.h> 74 1.57 ad #include <sys/syscallvar.h> 75 1.40 ad #include <sys/mutex.h> 76 1.1 fredette #include <sys/ktrace.h> 77 1.1 fredette #include <sys/proc.h> 78 1.1 fredette #include <sys/signalvar.h> 79 1.1 fredette #include <sys/acct.h> 80 1.1 fredette #include <sys/signal.h> 81 1.1 fredette #include <sys/device.h> 82 1.107 martin #include <sys/kauth.h> 83 1.88 rmind #include <sys/kmem.h> 84 1.20 chs #include <sys/userret.h> 85 1.1 fredette 86 1.1 fredette #include <net/netisr.h> 87 1.1 fredette 88 1.1 fredette #ifdef KGDB 89 1.1 fredette #include <sys/kgdb.h> 90 1.1 fredette #endif 91 1.1 fredette 92 1.1 fredette #include <uvm/uvm.h> 93 1.1 fredette 94 1.1 fredette #include <machine/iomod.h> 95 1.1 fredette #include <machine/cpufunc.h> 96 1.1 fredette #include <machine/reg.h> 97 1.1 fredette #include <machine/autoconf.h> 98 1.1 fredette 99 1.1 fredette #include <machine/db_machdep.h> 100 1.1 fredette 101 1.1 fredette #include <hppa/hppa/machdep.h> 102 1.1 fredette 103 1.1 fredette #include <ddb/db_output.h> 104 1.19 chs #include <ddb/db_interface.h> 105 1.1 fredette 106 1.51 skrll #ifdef PTRACE 107 1.51 skrll void ss_clear_breakpoints(struct lwp *l); 108 1.51 skrll int ss_put_value(struct lwp *, vaddr_t, u_int); 109 1.51 skrll int ss_get_value(struct lwp *, vaddr_t, u_int *); 110 1.51 skrll 111 1.51 skrll /* single-step breakpoint */ 112 1.51 skrll #define SSBREAKPOINT (HPPA_BREAK_KERNEL | (HPPA_BREAK_SS << 13)) 113 1.51 skrll 114 1.87 skrll #endif 115 1.87 skrll 116 1.1 fredette #if defined(DEBUG) || defined(DIAGNOSTIC) 117 1.1 fredette /* 118 1.1 fredette * 0x6fc1000 is a stwm r1, d(sr0, sp), which is the last 119 1.1 fredette * instruction in the function prologue that gcc -O0 uses. 120 1.1 fredette * When we have this instruction we know the relationship 121 1.111 skrll * between the stack pointer and the gcc -O0 frame pointer 122 1.1 fredette * (in r3, loaded with the initial sp) for the body of a 123 1.1 fredette * function. 124 1.1 fredette * 125 1.1 fredette * If the given instruction is a stwm r1, d(sr0, sp) where 126 1.1 fredette * d > 0, we evaluate to d, else we evaluate to zero. 127 1.1 fredette */ 128 1.1 fredette #define STWM_R1_D_SR0_SP(inst) \ 129 1.1 fredette (((inst) & 0xffffc001) == 0x6fc10000 ? (((inst) & 0x00003ff) >> 1) : 0) 130 1.1 fredette #endif /* DEBUG || DIAGNOSTIC */ 131 1.1 fredette 132 1.1 fredette const char *trap_type[] = { 133 1.1 fredette "invalid", 134 1.1 fredette "HPMC", 135 1.1 fredette "power failure", 136 1.1 fredette "recovery counter", 137 1.1 fredette "external interrupt", 138 1.1 fredette "LPMC", 139 1.1 fredette "ITLB miss fault", 140 1.1 fredette "instruction protection", 141 1.1 fredette "Illegal instruction", 142 1.1 fredette "break instruction", 143 1.1 fredette "privileged operation", 144 1.1 fredette "privileged register", 145 1.1 fredette "overflow", 146 1.1 fredette "conditional", 147 1.1 fredette "assist exception", 148 1.1 fredette "DTLB miss", 149 1.1 fredette "ITLB non-access miss", 150 1.1 fredette "DTLB non-access miss", 151 1.1 fredette "data protection/rights/alignment", 152 1.1 fredette "data break", 153 1.1 fredette "TLB dirty", 154 1.1 fredette "page reference", 155 1.1 fredette "assist emulation", 156 1.1 fredette "higher-priv transfer", 157 1.1 fredette "lower-priv transfer", 158 1.1 fredette "taken branch", 159 1.1 fredette "data access rights", 160 1.1 fredette "data protection", 161 1.1 fredette "unaligned data ref", 162 1.1 fredette }; 163 1.72 skrll int trap_types = __arraycount(trap_type); 164 1.1 fredette 165 1.23 chs uint8_t fpopmap[] = { 166 1.23 chs 0x00, 0x00, 0x00, 0x06, 0x00, 0x00, 0x00, 0x00, 167 1.23 chs 0x00, 0x0c, 0x00, 0x0e, 0x00, 0x00, 0x00, 0x00, 168 1.23 chs 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 169 1.23 chs 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 170 1.23 chs 0x00, 0x00, 0x00, 0x26, 0x00, 0x00, 0x00, 0x00, 171 1.23 chs 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 172 1.23 chs 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 173 1.23 chs 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 174 1.23 chs }; 175 1.23 chs 176 1.14 chs void pmap_hptdump(void); 177 1.14 chs void syscall(struct trapframe *, int *); 178 1.1 fredette 179 1.53 skrll #if defined(DEBUG) 180 1.53 skrll struct trapframe *sanity_frame; 181 1.53 skrll struct lwp *sanity_lwp; 182 1.81 skrll const char *sanity_string; 183 1.81 skrll void frame_sanity_check(const char *, int, int, struct trapframe *, 184 1.81 skrll struct lwp *); 185 1.53 skrll #endif 186 1.53 skrll 187 1.53 skrll 188 1.1 fredette #ifdef USERTRACE 189 1.1 fredette /* 190 1.82 skrll * USERTRACE is a crude facility that traces the PC of a single user process. 191 1.82 skrll * This tracing is normally activated by the dispatching of a certain syscall 192 1.82 skrll * with certain arguments - see the activation code in syscall(). 193 1.1 fredette */ 194 1.53 skrll static void user_backtrace(struct trapframe *, struct lwp *, int); 195 1.53 skrll static void user_backtrace_raw(u_int, u_int); 196 1.53 skrll 197 1.1 fredette u_int rctr_next_iioq; 198 1.1 fredette #endif 199 1.1 fredette 200 1.30 perry static inline void 201 1.114 skrll userret(struct lwp *l, struct trapframe *tf) 202 1.1 fredette { 203 1.9 chs struct proc *p = l->l_proc; 204 1.114 skrll int oticks = 0; /* XXX why zero? */ 205 1.1 fredette 206 1.113 ad do { 207 1.113 ad l->l_md.md_astpending = 0; 208 1.113 ad //curcpu()->ci_data.cpu_nast++; 209 1.113 ad mi_userret(l); 210 1.113 ad } while (l->l_md.md_astpending); 211 1.20 chs 212 1.1 fredette /* 213 1.1 fredette * If profiling, charge recent system time to the trapped pc. 214 1.1 fredette */ 215 1.40 ad if (p->p_stflag & PST_PROFIL) { 216 1.1 fredette extern int psratio; 217 1.1 fredette 218 1.114 skrll addupc_task(l, tf->tf_iioq_head, 219 1.114 skrll (int)(p->p_sticks - oticks) * psratio); 220 1.1 fredette } 221 1.1 fredette } 222 1.1 fredette 223 1.1 fredette /* 224 1.1 fredette * This handles some messy kernel debugger details. 225 1.1 fredette * It dispatches into either kgdb or DDB, and knows 226 1.1 fredette * about some special things to do, like skipping over 227 1.1 fredette * break instructions and how to really set up for 228 1.1 fredette * a single-step. 229 1.1 fredette */ 230 1.1 fredette #if defined(KGDB) || defined(DDB) 231 1.1 fredette static int 232 1.1 fredette trap_kdebug(int type, int code, struct trapframe *frame) 233 1.1 fredette { 234 1.1 fredette int handled; 235 1.1 fredette u_int tf_iioq_head_old; 236 1.1 fredette u_int tf_iioq_tail_old; 237 1.1 fredette 238 1.89 skrll for (;;) { 239 1.1 fredette 240 1.1 fredette /* This trap has not been handled. */ 241 1.1 fredette handled = 0; 242 1.1 fredette 243 1.1 fredette /* Remember the instruction offset queue. */ 244 1.1 fredette tf_iioq_head_old = frame->tf_iioq_head; 245 1.1 fredette tf_iioq_tail_old = frame->tf_iioq_tail; 246 1.1 fredette 247 1.1 fredette #ifdef KGDB 248 1.1 fredette /* Let KGDB handle it (if connected) */ 249 1.1 fredette if (!handled) 250 1.1 fredette handled = kgdb_trap(type, frame); 251 1.1 fredette #endif 252 1.1 fredette #ifdef DDB 253 1.1 fredette /* Let DDB handle it. */ 254 1.1 fredette if (!handled) 255 1.1 fredette handled = kdb_trap(type, code, frame); 256 1.1 fredette #endif 257 1.1 fredette 258 1.1 fredette /* If this trap wasn't handled, return now. */ 259 1.1 fredette if (!handled) 260 1.1 fredette return(0); 261 1.1 fredette 262 1.1 fredette /* 263 1.77 skrll * If the instruction offset queue head changed, but the offset 264 1.77 skrll * queue tail didn't, assume that the user wants to jump to the 265 1.77 skrll * head offset, and adjust the tail accordingly. This should 266 1.77 skrll * fix the kgdb `jump' command, and can help DDB users who `set' 267 1.77 skrll * the offset head but forget the tail. 268 1.1 fredette */ 269 1.1 fredette if (frame->tf_iioq_head != tf_iioq_head_old && 270 1.1 fredette frame->tf_iioq_tail == tf_iioq_tail_old) 271 1.1 fredette frame->tf_iioq_tail = frame->tf_iioq_head + 4; 272 1.1 fredette 273 1.1 fredette /* 274 1.77 skrll * This is some single-stepping support. If we're trying to 275 1.77 skrll * step through a nullified instruction, just advance by hand 276 1.77 skrll * and trap again. Otherwise, load the recovery counter with 277 1.77 skrll * zero. 278 1.1 fredette */ 279 1.1 fredette if (frame->tf_ipsw & PSW_R) { 280 1.1 fredette #ifdef TRAPDEBUG 281 1.44 skrll printf("(single stepping at head 0x%x tail 0x%x)\n", 282 1.44 skrll frame->tf_iioq_head, frame->tf_iioq_tail); 283 1.1 fredette #endif 284 1.1 fredette if (frame->tf_ipsw & PSW_N) { 285 1.1 fredette #ifdef TRAPDEBUG 286 1.1 fredette printf("(single stepping past nullified)\n"); 287 1.1 fredette #endif 288 1.1 fredette 289 1.1 fredette /* Advance the program counter. */ 290 1.1 fredette frame->tf_iioq_head = frame->tf_iioq_tail; 291 1.1 fredette frame->tf_iioq_tail = frame->tf_iioq_head + 4; 292 1.1 fredette 293 1.1 fredette /* Clear flags. */ 294 1.1 fredette frame->tf_ipsw &= ~(PSW_N|PSW_X|PSW_Y|PSW_Z|PSW_B|PSW_T|PSW_H|PSW_L); 295 1.1 fredette 296 1.1 fredette /* Simulate another trap. */ 297 1.1 fredette type = T_RECOVERY; 298 1.1 fredette continue; 299 1.1 fredette } 300 1.1 fredette frame->tf_rctr = 0; 301 1.1 fredette } 302 1.111 skrll 303 1.1 fredette /* We handled this trap. */ 304 1.1 fredette return (1); 305 1.1 fredette } 306 1.1 fredette /* NOTREACHED */ 307 1.1 fredette } 308 1.1 fredette #else /* !KGDB && !DDB */ 309 1.1 fredette #define trap_kdebug(t, c, f) (0) 310 1.1 fredette #endif /* !KGDB && !DDB */ 311 1.1 fredette 312 1.24 tsutsui #if defined(DEBUG) || defined(USERTRACE) 313 1.1 fredette /* 314 1.77 skrll * These functions give a crude usermode backtrace. They really only work when 315 1.77 skrll * code has been compiled without optimization, as they assume a certain func- 316 1.77 skrll * tion prologue sets up a frame pointer and stores the return pointer and arg- 317 1.77 skrll * uments in it. 318 1.1 fredette */ 319 1.1 fredette static void 320 1.1 fredette user_backtrace_raw(u_int pc, u_int fp) 321 1.1 fredette { 322 1.1 fredette int frame_number; 323 1.1 fredette int arg_number; 324 1.109 thorpej uint32_t val; 325 1.1 fredette 326 1.111 skrll for (frame_number = 0; 327 1.3 fredette frame_number < 100 && pc > HPPA_PC_PRIV_MASK && fp; 328 1.3 fredette frame_number++) { 329 1.3 fredette 330 1.111 skrll printf("%3d: pc=%08x%s fp=0x%08x", frame_number, 331 1.44 skrll pc & ~HPPA_PC_PRIV_MASK, USERMODE(pc) ? " " : "**", fp); 332 1.109 thorpej for (arg_number = 0; arg_number < 4; arg_number++) { 333 1.109 thorpej if (ufetch_32(HPPA_FRAME_CARG(arg_number, fp), 334 1.109 thorpej &val) == 0) { 335 1.109 thorpej printf(" arg%d=0x%08x", arg_number, val); 336 1.109 thorpej } else { 337 1.109 thorpej printf(" arg%d=<bad address>", arg_number); 338 1.109 thorpej } 339 1.109 thorpej } 340 1.1 fredette printf("\n"); 341 1.109 thorpej if (ufetch_int((((uint32_t *) fp) - 5), &pc) != 0) { 342 1.109 thorpej printf(" ufetch for pc failed\n"); 343 1.1 fredette break; 344 1.1 fredette } 345 1.109 thorpej if (ufetch_int((((uint32_t *) fp) + 0), &fp) != 0) { 346 1.109 thorpej printf(" ufetch for fp failed\n"); 347 1.1 fredette break; 348 1.1 fredette } 349 1.1 fredette } 350 1.1 fredette printf(" backtrace stopped with pc %08x fp 0x%08x\n", pc, fp); 351 1.1 fredette } 352 1.1 fredette 353 1.1 fredette static void 354 1.9 chs user_backtrace(struct trapframe *tf, struct lwp *l, int type) 355 1.1 fredette { 356 1.9 chs struct proc *p = l->l_proc; 357 1.1 fredette u_int pc, fp, inst; 358 1.1 fredette 359 1.1 fredette /* 360 1.3 fredette * Display any trap type that we have. 361 1.3 fredette */ 362 1.3 fredette if (type >= 0) 363 1.111 skrll printf("pid %d (%s) trap #%d\n", 364 1.3 fredette p->p_pid, p->p_comm, type & ~T_USER); 365 1.3 fredette 366 1.3 fredette /* 367 1.1 fredette * Assuming that the frame pointer in r3 is valid, 368 1.1 fredette * dump out a stack trace. 369 1.1 fredette */ 370 1.1 fredette fp = tf->tf_r3; 371 1.1 fredette printf("pid %d (%s) backtrace, starting with fp 0x%08x\n", 372 1.1 fredette p->p_pid, p->p_comm, fp); 373 1.1 fredette user_backtrace_raw(tf->tf_iioq_head, fp); 374 1.1 fredette 375 1.1 fredette /* 376 1.82 skrll * In case the frame pointer in r3 is not valid, assuming the stack 377 1.82 skrll * pointer is valid and the faulting function is a non-leaf, if we can 378 1.82 skrll * find its prologue we can recover its frame pointer. 379 1.1 fredette */ 380 1.1 fredette pc = tf->tf_iioq_head; 381 1.1 fredette fp = tf->tf_sp - HPPA_FRAME_SIZE; 382 1.1 fredette printf("pid %d (%s) backtrace, starting with sp 0x%08x pc 0x%08x\n", 383 1.82 skrll p->p_pid, p->p_comm, tf->tf_sp, pc); 384 1.44 skrll for (pc &= ~HPPA_PC_PRIV_MASK; pc > 0; pc -= sizeof(inst)) { 385 1.109 thorpej if (ufetch_int((u_int *) pc, &inst) != 0) { 386 1.109 thorpej printf(" ufetch for inst at pc %08x failed\n", pc); 387 1.1 fredette break; 388 1.1 fredette } 389 1.1 fredette /* Check for the prologue instruction that sets sp. */ 390 1.1 fredette if (STWM_R1_D_SR0_SP(inst)) { 391 1.1 fredette fp = tf->tf_sp - STWM_R1_D_SR0_SP(inst); 392 1.1 fredette printf(" sp from fp at pc %08x: %08x\n", pc, inst); 393 1.1 fredette break; 394 1.1 fredette } 395 1.1 fredette } 396 1.1 fredette user_backtrace_raw(tf->tf_iioq_head, fp); 397 1.1 fredette } 398 1.24 tsutsui #endif /* DEBUG || USERTRACE */ 399 1.1 fredette 400 1.1 fredette #ifdef DEBUG 401 1.1 fredette /* 402 1.82 skrll * This sanity-checks a trapframe. It is full of various assumptions about 403 1.82 skrll * what a healthy CPU state should be, with some documented elsewhere, some not. 404 1.1 fredette */ 405 1.1 fredette void 406 1.81 skrll frame_sanity_check(const char *func, int line, int type, struct trapframe *tf, 407 1.81 skrll struct lwp *l) 408 1.1 fredette { 409 1.94 skrll #if 0 410 1.1 fredette extern int kernel_text; 411 1.1 fredette extern int etext; 412 1.94 skrll #endif 413 1.96 skrll struct cpu_info *ci = curcpu(); 414 1.62 rmind 415 1.1 fredette #define SANITY(e) \ 416 1.1 fredette do { \ 417 1.1 fredette if (sanity_frame == NULL && !(e)) { \ 418 1.1 fredette sanity_frame = tf; \ 419 1.9 chs sanity_lwp = l; \ 420 1.81 skrll sanity_string = #e; \ 421 1.1 fredette } \ 422 1.1 fredette } while (/* CONSTCOND */ 0) 423 1.1 fredette 424 1.79 skrll KASSERT(l != NULL); 425 1.96 skrll SANITY((tf->tf_ipsw & ci->ci_psw) == ci->ci_psw); 426 1.96 skrll SANITY((ci->ci_psw & PSW_I) == 0 || tf->tf_eiem != 0); 427 1.1 fredette if (tf->tf_iisq_head == HPPA_SID_KERNEL) { 428 1.62 rmind vaddr_t minsp, maxsp, uv; 429 1.45 skrll 430 1.63 skrll uv = uvm_lwp_getuarea(l); 431 1.63 skrll 432 1.1 fredette /* 433 1.82 skrll * If the trap happened in the gateway page, we take the easy 434 1.82 skrll * way out and assume that the trapframe is okay. 435 1.1 fredette */ 436 1.45 skrll if ((tf->tf_iioq_head & ~PAGE_MASK) == SYSCALLGATE) 437 1.45 skrll goto out; 438 1.45 skrll 439 1.45 skrll SANITY(!USERMODE(tf->tf_iioq_head)); 440 1.45 skrll SANITY(!USERMODE(tf->tf_iioq_tail)); 441 1.45 skrll 442 1.45 skrll /* 443 1.45 skrll * Don't check the instruction queues or stack on interrupts 444 1.116 msaitoh * as we could be in the sti code (outside normal kernel 445 1.45 skrll * text) or switching LWPs (curlwp and sp are not in sync) 446 1.45 skrll */ 447 1.45 skrll if ((type & ~T_USER) == T_INTERRUPT) 448 1.45 skrll goto out; 449 1.94 skrll #if 0 450 1.45 skrll SANITY(tf->tf_iioq_head >= (u_int) &kernel_text); 451 1.45 skrll SANITY(tf->tf_iioq_head < (u_int) &etext); 452 1.45 skrll SANITY(tf->tf_iioq_tail >= (u_int) &kernel_text); 453 1.45 skrll SANITY(tf->tf_iioq_tail < (u_int) &etext); 454 1.94 skrll #endif 455 1.43 yamt 456 1.62 rmind maxsp = uv + USPACE + PAGE_SIZE; 457 1.62 rmind minsp = uv + PAGE_SIZE; 458 1.43 yamt 459 1.79 skrll SANITY(tf->tf_sp >= minsp && tf->tf_sp < maxsp); 460 1.1 fredette } else { 461 1.79 skrll struct pcb *pcb = lwp_getpcb(l); 462 1.71 skrll 463 1.1 fredette SANITY(USERMODE(tf->tf_iioq_head)); 464 1.1 fredette SANITY(USERMODE(tf->tf_iioq_tail)); 465 1.79 skrll SANITY(tf->tf_cr30 == (u_int)pcb->pcb_fpregs); 466 1.1 fredette } 467 1.1 fredette #undef SANITY 468 1.45 skrll out: 469 1.1 fredette if (sanity_frame == tf) { 470 1.90 skrll printf("insanity: '%s' at %s:%d type 0x%x tf %p lwp %p " 471 1.90 skrll "sp 0x%x pc 0x%x\n", 472 1.90 skrll sanity_string, func, line, type, sanity_frame, sanity_lwp, 473 1.90 skrll tf->tf_sp, tf->tf_iioq_head); 474 1.4 fredette (void) trap_kdebug(T_IBREAK, 0, tf); 475 1.1 fredette sanity_frame = NULL; 476 1.9 chs sanity_lwp = NULL; 477 1.1 fredette } 478 1.1 fredette } 479 1.1 fredette #endif /* DEBUG */ 480 1.1 fredette 481 1.119 skrll 482 1.119 skrll #define __PABITS(x, y) __BITS(31 - (x), 31 - (y)) 483 1.119 skrll #define __PABIT(x) __BIT(31 - (x)) 484 1.119 skrll 485 1.119 skrll #define LPA_MASK \ 486 1.119 skrll ( __PABITS(0, 5) | \ 487 1.119 skrll __PABITS(18, 25)) 488 1.119 skrll #define LPA \ 489 1.119 skrll (__SHIFTIN(1, __PABITS(0, 5)) | \ 490 1.119 skrll __SHIFTIN(0x4d, __PABITS(18, 25))) 491 1.119 skrll 492 1.119 skrll 493 1.119 skrll #define PROBE_ENCS (0x46 | 0xc6 | 0x47 | 0xc7) 494 1.119 skrll #define PROBE_PL __PABITS(14, 15) 495 1.119 skrll #define PROBE_IMMED __PABIT(18) 496 1.119 skrll #define PROBE_RW __PABIT(25) 497 1.119 skrll 498 1.119 skrll #define PROBE_MASK \ 499 1.119 skrll (( __PABITS(0, 5) | \ 500 1.119 skrll __PABITS(18, 25) | \ 501 1.119 skrll __PABIT(26)) ^ \ 502 1.119 skrll (PROBE_IMMED | PROBE_RW)) 503 1.119 skrll 504 1.119 skrll #define PROBE \ 505 1.119 skrll ((__SHIFTIN(1, __PABITS(0, 5)) | \ 506 1.119 skrll __SHIFTIN(PROBE_ENCS, __PABITS(18, 25)) | \ 507 1.119 skrll __SHIFTIN(0, __PABIT(26))) ^ \ 508 1.119 skrll (PROBE_IMMED | PROBE_RW)) 509 1.119 skrll 510 1.119 skrll /* for hppa64 */ 511 1.119 skrll CTASSERT(sizeof(register_t) == sizeof(u_int)); 512 1.119 skrll size_t hppa_regmap[] = { 513 1.119 skrll 0, /* r0 is special case */ 514 1.119 skrll offsetof(struct trapframe, tf_r1 ) / sizeof(register_t), 515 1.119 skrll offsetof(struct trapframe, tf_rp ) / sizeof(register_t), 516 1.119 skrll offsetof(struct trapframe, tf_r3 ) / sizeof(register_t), 517 1.119 skrll offsetof(struct trapframe, tf_r4 ) / sizeof(register_t), 518 1.119 skrll offsetof(struct trapframe, tf_r5 ) / sizeof(register_t), 519 1.119 skrll offsetof(struct trapframe, tf_r6 ) / sizeof(register_t), 520 1.119 skrll offsetof(struct trapframe, tf_r7 ) / sizeof(register_t), 521 1.119 skrll offsetof(struct trapframe, tf_r8 ) / sizeof(register_t), 522 1.119 skrll offsetof(struct trapframe, tf_r9 ) / sizeof(register_t), 523 1.119 skrll offsetof(struct trapframe, tf_r10 ) / sizeof(register_t), 524 1.119 skrll offsetof(struct trapframe, tf_r11 ) / sizeof(register_t), 525 1.119 skrll offsetof(struct trapframe, tf_r12 ) / sizeof(register_t), 526 1.119 skrll offsetof(struct trapframe, tf_r13 ) / sizeof(register_t), 527 1.119 skrll offsetof(struct trapframe, tf_r14 ) / sizeof(register_t), 528 1.119 skrll offsetof(struct trapframe, tf_r15 ) / sizeof(register_t), 529 1.119 skrll offsetof(struct trapframe, tf_r16 ) / sizeof(register_t), 530 1.119 skrll offsetof(struct trapframe, tf_r17 ) / sizeof(register_t), 531 1.119 skrll offsetof(struct trapframe, tf_r18 ) / sizeof(register_t), 532 1.119 skrll offsetof(struct trapframe, tf_t4 ) / sizeof(register_t), 533 1.119 skrll offsetof(struct trapframe, tf_t3 ) / sizeof(register_t), 534 1.119 skrll offsetof(struct trapframe, tf_t2 ) / sizeof(register_t), 535 1.119 skrll offsetof(struct trapframe, tf_t1 ) / sizeof(register_t), 536 1.119 skrll offsetof(struct trapframe, tf_arg3) / sizeof(register_t), 537 1.119 skrll offsetof(struct trapframe, tf_arg2) / sizeof(register_t), 538 1.119 skrll offsetof(struct trapframe, tf_arg1) / sizeof(register_t), 539 1.119 skrll offsetof(struct trapframe, tf_arg0) / sizeof(register_t), 540 1.119 skrll offsetof(struct trapframe, tf_dp ) / sizeof(register_t), 541 1.119 skrll offsetof(struct trapframe, tf_ret0) / sizeof(register_t), 542 1.119 skrll offsetof(struct trapframe, tf_ret1) / sizeof(register_t), 543 1.119 skrll offsetof(struct trapframe, tf_sp ) / sizeof(register_t), 544 1.119 skrll offsetof(struct trapframe, tf_r31 ) / sizeof(register_t), 545 1.119 skrll }; 546 1.119 skrll 547 1.119 skrll 548 1.119 skrll static inline register_t 549 1.119 skrll tf_getregno(struct trapframe *tf, u_int regno) 550 1.119 skrll { 551 1.119 skrll register_t *tf_reg = (register_t *)tf; 552 1.119 skrll if (regno == 0) 553 1.119 skrll return 0; 554 1.119 skrll else 555 1.119 skrll return tf_reg[hppa_regmap[regno]]; 556 1.119 skrll } 557 1.119 skrll 558 1.119 skrll static inline void 559 1.119 skrll tf_setregno(struct trapframe *tf, u_int regno, register_t val) 560 1.119 skrll { 561 1.119 skrll register_t *tf_reg = (register_t *)tf; 562 1.119 skrll if (regno == 0) 563 1.119 skrll return; 564 1.119 skrll else 565 1.119 skrll tf_reg[hppa_regmap[regno]] = val; 566 1.119 skrll } 567 1.119 skrll 568 1.1 fredette void 569 1.14 chs trap(int type, struct trapframe *frame) 570 1.1 fredette { 571 1.13 tsutsui struct lwp *l; 572 1.13 tsutsui struct proc *p; 573 1.61 rmind struct pcb *pcb; 574 1.9 chs vaddr_t va; 575 1.9 chs struct vm_map *map; 576 1.1 fredette struct vmspace *vm; 577 1.9 chs vm_prot_t vftype; 578 1.9 chs pa_space_t space; 579 1.22 chs ksiginfo_t ksi; 580 1.19 chs u_int opcode, onfault; 581 1.1 fredette int ret; 582 1.73 skrll const char *tts = "reserved"; 583 1.67 skrll int trapnum; 584 1.1 fredette #ifdef DIAGNOSTIC 585 1.1 fredette extern int emergency_stack_start, emergency_stack_end; 586 1.85 skrll struct cpu_info *ci = curcpu(); 587 1.85 skrll int oldcpl = ci->ci_cpl; 588 1.1 fredette #endif 589 1.1 fredette 590 1.67 skrll trapnum = type & ~T_USER; 591 1.1 fredette opcode = frame->tf_iir; 592 1.84 skrll 593 1.84 skrll if (trapnum <= T_EXCEPTION || trapnum == T_HIGHERPL || 594 1.84 skrll trapnum == T_LOWERPL || trapnum == T_TAKENBR || 595 1.84 skrll trapnum == T_IDEBUG || trapnum == T_PERFMON) { 596 1.1 fredette va = frame->tf_iioq_head; 597 1.1 fredette space = frame->tf_iisq_head; 598 1.17 chs vftype = VM_PROT_EXECUTE; 599 1.1 fredette } else { 600 1.1 fredette va = frame->tf_ior; 601 1.1 fredette space = frame->tf_isr; 602 1.1 fredette vftype = inst_store(opcode) ? VM_PROT_WRITE : VM_PROT_READ; 603 1.1 fredette } 604 1.13 tsutsui 605 1.64 skrll KASSERT(curlwp != NULL); 606 1.18 chs l = curlwp; 607 1.64 skrll p = l->l_proc; 608 1.36 ad if ((type & T_USER) != 0) 609 1.36 ad LWP_CACHE_CREDS(l, p); 610 1.1 fredette 611 1.1 fredette #ifdef DIAGNOSTIC 612 1.1 fredette /* 613 1.1 fredette * If we are on the emergency stack, then we either got 614 1.1 fredette * a fault on the kernel stack, or we're just handling 615 1.111 skrll * a trap for the machine check handler (which also 616 1.1 fredette * runs on the emergency stack). 617 1.1 fredette * 618 1.1 fredette * We *very crudely* differentiate between the two cases 619 1.1 fredette * by checking the faulting instruction: if it is the 620 1.1 fredette * function prologue instruction that stores the old 621 1.1 fredette * frame pointer and updates the stack pointer, we assume 622 1.1 fredette * that we faulted on the kernel stack. 623 1.1 fredette * 624 1.1 fredette * In this case, not completing that instruction will 625 1.1 fredette * probably confuse backtraces in kgdb/ddb. Completing 626 1.1 fredette * it would be difficult, because we already faulted on 627 1.111 skrll * that part of the stack, so instead we fix up the 628 1.1 fredette * frame as if the function called has just returned. 629 1.1 fredette * This has peculiar knowledge about what values are in 630 1.1 fredette * what registers during the "normal gcc -g" prologue. 631 1.1 fredette */ 632 1.1 fredette if (&type >= &emergency_stack_start && 633 1.1 fredette &type < &emergency_stack_end && 634 1.1 fredette type != T_IBREAK && STWM_R1_D_SR0_SP(opcode)) { 635 1.1 fredette /* Restore the caller's frame pointer. */ 636 1.1 fredette frame->tf_r3 = frame->tf_r1; 637 1.1 fredette /* Restore the caller's instruction offsets. */ 638 1.1 fredette frame->tf_iioq_head = frame->tf_rp; 639 1.1 fredette frame->tf_iioq_tail = frame->tf_iioq_head + 4; 640 1.1 fredette goto dead_end; 641 1.1 fredette } 642 1.1 fredette #endif /* DIAGNOSTIC */ 643 1.111 skrll 644 1.1 fredette #ifdef DEBUG 645 1.81 skrll frame_sanity_check(__func__, __LINE__, type, frame, l); 646 1.1 fredette #endif /* DEBUG */ 647 1.1 fredette 648 1.1 fredette if (frame->tf_flags & TFF_LAST) 649 1.9 chs l->l_md.md_regs = frame; 650 1.1 fredette 651 1.73 skrll if (trapnum <= trap_types) 652 1.73 skrll tts = trap_type[trapnum]; 653 1.73 skrll 654 1.1 fredette #ifdef TRAPDEBUG 655 1.67 skrll if (trapnum != T_INTERRUPT && trapnum != T_IBREAK) 656 1.75 skrll printf("trap: %d, %s for %x:%lx at %x:%x, fp=%p, rp=%x\n", 657 1.75 skrll type, tts, space, va, frame->tf_iisq_head, 658 1.1 fredette frame->tf_iioq_head, frame, frame->tf_rp); 659 1.67 skrll else if (trapnum == T_IBREAK) 660 1.1 fredette printf("trap: break instruction %x:%x at %x:%x, fp=%p\n", 661 1.1 fredette break5(opcode), break13(opcode), 662 1.1 fredette frame->tf_iisq_head, frame->tf_iioq_head, frame); 663 1.1 fredette 664 1.1 fredette { 665 1.1 fredette extern int etext; 666 1.1 fredette if (frame < (struct trapframe *)&etext) { 667 1.1 fredette printf("trap: bogus frame ptr %p\n", frame); 668 1.1 fredette goto dead_end; 669 1.1 fredette } 670 1.1 fredette } 671 1.1 fredette #endif 672 1.73 skrll 673 1.61 rmind pcb = lwp_getpcb(l); 674 1.61 rmind 675 1.66 skrll /* If this is a trap, not an interrupt, reenable interrupts. */ 676 1.67 skrll if (trapnum != T_INTERRUPT) { 677 1.95 matt curcpu()->ci_data.cpu_ntrap++; 678 1.66 skrll mtctl(frame->tf_eiem, CR_EIEM); 679 1.66 skrll } 680 1.66 skrll 681 1.119 skrll const bool user = (type & T_USER) != 0; 682 1.1 fredette switch (type) { 683 1.1 fredette case T_NONEXIST: 684 1.118 skrll case T_NONEXIST | T_USER: 685 1.1 fredette #if !defined(DDB) && !defined(KGDB) 686 1.1 fredette /* we've got screwed up by the central scrutinizer */ 687 1.1 fredette panic ("trap: elvis has just left the building!"); 688 1.1 fredette break; 689 1.1 fredette #else 690 1.1 fredette goto dead_end; 691 1.1 fredette #endif 692 1.118 skrll case T_RECOVERY | T_USER: 693 1.1 fredette #ifdef USERTRACE 694 1.89 skrll for (;;) { 695 1.1 fredette if (frame->tf_iioq_head != rctr_next_iioq) 696 1.1 fredette printf("-%08x\nr %08x", 697 1.1 fredette rctr_next_iioq - 4, 698 1.1 fredette frame->tf_iioq_head); 699 1.1 fredette rctr_next_iioq = frame->tf_iioq_head + 4; 700 1.1 fredette if (frame->tf_ipsw & PSW_N) { 701 1.1 fredette /* Advance the program counter. */ 702 1.1 fredette frame->tf_iioq_head = frame->tf_iioq_tail; 703 1.1 fredette frame->tf_iioq_tail = frame->tf_iioq_head + 4; 704 1.1 fredette /* Clear flags. */ 705 1.1 fredette frame->tf_ipsw &= ~(PSW_N|PSW_X|PSW_Y|PSW_Z|PSW_B|PSW_T|PSW_H|PSW_L); 706 1.1 fredette /* Simulate another trap. */ 707 1.1 fredette continue; 708 1.1 fredette } 709 1.1 fredette break; 710 1.1 fredette } 711 1.1 fredette frame->tf_rctr = 0; 712 1.1 fredette break; 713 1.1 fredette #endif /* USERTRACE */ 714 1.1 fredette case T_RECOVERY: 715 1.1 fredette #if !defined(DDB) && !defined(KGDB) 716 1.1 fredette /* XXX will implement later */ 717 1.1 fredette printf ("trap: handicapped"); 718 1.1 fredette break; 719 1.1 fredette #else 720 1.1 fredette goto dead_end; 721 1.1 fredette #endif 722 1.1 fredette 723 1.1 fredette case T_EMULATION | T_USER: 724 1.21 chs hppa_fpu_emulate(frame, l, opcode); 725 1.1 fredette break; 726 1.1 fredette 727 1.25 chs case T_DATALIGN: 728 1.80 chs onfault = pcb->pcb_onfault; 729 1.80 chs if (onfault) { 730 1.80 chs ret = EFAULT; 731 1.25 chs do_onfault: 732 1.80 chs frame->tf_iioq_head = onfault; 733 1.80 chs frame->tf_iioq_tail = frame->tf_iioq_head + 4; 734 1.80 chs frame->tf_ret0 = ret; 735 1.25 chs break; 736 1.25 chs } 737 1.25 chs /*FALLTHROUGH*/ 738 1.25 chs 739 1.1 fredette #ifdef DIAGNOSTIC 740 1.1 fredette /* these just can't happen ever */ 741 1.1 fredette case T_PRIV_OP: 742 1.1 fredette case T_PRIV_REG: 743 1.1 fredette /* these just can't make it to the trap() ever */ 744 1.25 chs case T_HPMC: 745 1.25 chs case T_HPMC | T_USER: 746 1.1 fredette case T_EMULATION: 747 1.25 chs case T_EXCEPTION: 748 1.1 fredette #endif 749 1.1 fredette case T_IBREAK: 750 1.1 fredette case T_DBREAK: 751 1.1 fredette dead_end: 752 1.3 fredette if (type & T_USER) { 753 1.3 fredette #ifdef DEBUG 754 1.9 chs user_backtrace(frame, l, type); 755 1.3 fredette #endif 756 1.22 chs KSI_INIT_TRAP(&ksi); 757 1.22 chs ksi.ksi_signo = SIGILL; 758 1.22 chs ksi.ksi_code = ILL_ILLTRP; 759 1.22 chs ksi.ksi_trap = type; 760 1.22 chs ksi.ksi_addr = (void *)frame->tf_iioq_head; 761 1.22 chs trapsignal(l, &ksi); 762 1.3 fredette break; 763 1.3 fredette } 764 1.1 fredette if (trap_kdebug(type, va, frame)) 765 1.1 fredette return; 766 1.1 fredette else if (type == T_DATALIGN) 767 1.1 fredette panic ("trap: %s at 0x%x", tts, (u_int) va); 768 1.1 fredette else 769 1.1 fredette panic ("trap: no debugger for \"%s\" (%d)", tts, type); 770 1.1 fredette break; 771 1.1 fredette 772 1.1 fredette case T_IBREAK | T_USER: 773 1.1 fredette case T_DBREAK | T_USER: 774 1.51 skrll KSI_INIT_TRAP(&ksi); 775 1.51 skrll ksi.ksi_signo = SIGTRAP; 776 1.120 skrll ksi.ksi_code = TRAP_BRKPT; 777 1.67 skrll ksi.ksi_trap = trapnum; 778 1.101 skrll ksi.ksi_addr = (void *)(frame->tf_iioq_head & ~HPPA_PC_PRIV_MASK); 779 1.51 skrll #ifdef PTRACE 780 1.51 skrll ss_clear_breakpoints(l); 781 1.51 skrll if (opcode == SSBREAKPOINT) 782 1.120 skrll ksi.ksi_code = TRAP_TRACE; 783 1.51 skrll #endif 784 1.1 fredette /* pass to user debugger */ 785 1.51 skrll trapsignal(l, &ksi); 786 1.51 skrll break; 787 1.51 skrll 788 1.51 skrll #ifdef PTRACE 789 1.51 skrll case T_TAKENBR | T_USER: 790 1.51 skrll ss_clear_breakpoints(l); 791 1.51 skrll 792 1.51 skrll KSI_INIT_TRAP(&ksi); 793 1.51 skrll ksi.ksi_signo = SIGTRAP; 794 1.51 skrll ksi.ksi_code = TRAP_TRACE; 795 1.67 skrll ksi.ksi_trap = trapnum; 796 1.101 skrll ksi.ksi_addr = (void *)(frame->tf_iioq_head & ~HPPA_PC_PRIV_MASK); 797 1.51 skrll 798 1.51 skrll /* pass to user debugger */ 799 1.51 skrll trapsignal(l, &ksi); 800 1.1 fredette break; 801 1.51 skrll #endif 802 1.1 fredette 803 1.21 chs case T_EXCEPTION | T_USER: { /* co-proc assist trap */ 804 1.21 chs uint64_t *fpp; 805 1.23 chs uint32_t *pex, ex, inst; 806 1.23 chs int i; 807 1.21 chs 808 1.21 chs hppa_fpu_flush(l); 809 1.79 skrll fpp = (uint64_t *)pcb->pcb_fpregs; 810 1.78 skrll 811 1.78 skrll /* skip the status register */ 812 1.78 skrll pex = (uint32_t *)&fpp[0]; 813 1.78 skrll pex++; 814 1.78 skrll 815 1.78 skrll /* loop through the exception registers */ 816 1.23 chs for (i = 1; i < 8 && !*pex; i++, pex++) 817 1.21 chs ; 818 1.23 chs KASSERT(i < 8); 819 1.23 chs ex = *pex; 820 1.23 chs *pex = 0; 821 1.23 chs 822 1.21 chs /* reset the trap flag, as if there was none */ 823 1.21 chs fpp[0] &= ~(((uint64_t)HPPA_FPU_T) << 32); 824 1.21 chs 825 1.23 chs /* emulate the instruction */ 826 1.23 chs inst = ((uint32_t)fpopmap[ex >> 26] << 26) | (ex & 0x03ffffff); 827 1.21 chs hppa_fpu_emulate(frame, l, inst); 828 1.21 chs } 829 1.1 fredette break; 830 1.1 fredette 831 1.1 fredette case T_OVERFLOW | T_USER: 832 1.22 chs KSI_INIT_TRAP(&ksi); 833 1.22 chs ksi.ksi_signo = SIGFPE; 834 1.22 chs ksi.ksi_code = SI_NOINFO; 835 1.22 chs ksi.ksi_trap = type; 836 1.22 chs ksi.ksi_addr = (void *)va; 837 1.22 chs trapsignal(l, &ksi); 838 1.1 fredette break; 839 1.111 skrll 840 1.1 fredette case T_CONDITION | T_USER: 841 1.23 chs KSI_INIT_TRAP(&ksi); 842 1.23 chs ksi.ksi_signo = SIGFPE; 843 1.23 chs ksi.ksi_code = FPE_INTDIV; 844 1.23 chs ksi.ksi_trap = type; 845 1.23 chs ksi.ksi_addr = (void *)va; 846 1.23 chs trapsignal(l, &ksi); 847 1.1 fredette break; 848 1.1 fredette 849 1.1 fredette case T_ILLEGAL | T_USER: 850 1.3 fredette #ifdef DEBUG 851 1.9 chs user_backtrace(frame, l, type); 852 1.3 fredette #endif 853 1.22 chs KSI_INIT_TRAP(&ksi); 854 1.22 chs ksi.ksi_signo = SIGILL; 855 1.22 chs ksi.ksi_code = ILL_ILLOPC; 856 1.22 chs ksi.ksi_trap = type; 857 1.22 chs ksi.ksi_addr = (void *)va; 858 1.22 chs trapsignal(l, &ksi); 859 1.1 fredette break; 860 1.1 fredette 861 1.1 fredette case T_PRIV_OP | T_USER: 862 1.3 fredette #ifdef DEBUG 863 1.9 chs user_backtrace(frame, l, type); 864 1.3 fredette #endif 865 1.22 chs KSI_INIT_TRAP(&ksi); 866 1.22 chs ksi.ksi_signo = SIGILL; 867 1.22 chs ksi.ksi_code = ILL_PRVOPC; 868 1.22 chs ksi.ksi_trap = type; 869 1.22 chs ksi.ksi_addr = (void *)va; 870 1.22 chs trapsignal(l, &ksi); 871 1.1 fredette break; 872 1.1 fredette 873 1.1 fredette case T_PRIV_REG | T_USER: 874 1.3 fredette #ifdef DEBUG 875 1.9 chs user_backtrace(frame, l, type); 876 1.3 fredette #endif 877 1.22 chs KSI_INIT_TRAP(&ksi); 878 1.22 chs ksi.ksi_signo = SIGILL; 879 1.22 chs ksi.ksi_code = ILL_PRVREG; 880 1.22 chs ksi.ksi_trap = type; 881 1.22 chs ksi.ksi_addr = (void *)va; 882 1.22 chs trapsignal(l, &ksi); 883 1.1 fredette break; 884 1.1 fredette 885 1.1 fredette /* these should never got here */ 886 1.1 fredette case T_HIGHERPL | T_USER: 887 1.1 fredette case T_LOWERPL | T_USER: 888 1.22 chs KSI_INIT_TRAP(&ksi); 889 1.22 chs ksi.ksi_signo = SIGSEGV; 890 1.22 chs ksi.ksi_code = SEGV_ACCERR; 891 1.22 chs ksi.ksi_trap = type; 892 1.22 chs ksi.ksi_addr = (void *)va; 893 1.22 chs trapsignal(l, &ksi); 894 1.1 fredette break; 895 1.1 fredette 896 1.1 fredette case T_IPROT | T_USER: 897 1.1 fredette case T_DPROT | T_USER: 898 1.22 chs KSI_INIT_TRAP(&ksi); 899 1.22 chs ksi.ksi_signo = SIGSEGV; 900 1.22 chs ksi.ksi_code = SEGV_ACCERR; 901 1.22 chs ksi.ksi_trap = type; 902 1.22 chs ksi.ksi_addr = (void *)va; 903 1.22 chs trapsignal(l, &ksi); 904 1.1 fredette break; 905 1.1 fredette 906 1.119 skrll case T_ITLBMISSNA: case T_USER | T_ITLBMISSNA: 907 1.119 skrll case T_DTLBMISSNA: case T_USER | T_DTLBMISSNA: 908 1.119 skrll vm = p->p_vmspace; 909 1.119 skrll 910 1.119 skrll if (!vm) { 911 1.119 skrll #ifdef TRAPDEBUG 912 1.119 skrll printf("trap: no vm, p=%p\n", p); 913 1.119 skrll #endif 914 1.119 skrll goto dead_end; 915 1.119 skrll } 916 1.119 skrll 917 1.119 skrll /* 918 1.119 skrll * it could be a kernel map for exec_map faults 919 1.119 skrll */ 920 1.119 skrll if (!user && space == HPPA_SID_KERNEL) 921 1.119 skrll map = kernel_map; 922 1.119 skrll else { 923 1.119 skrll map = &vm->vm_map; 924 1.119 skrll } 925 1.119 skrll 926 1.119 skrll va = trunc_page(va); 927 1.119 skrll 928 1.119 skrll if ((opcode & LPA_MASK) == LPA) { 929 1.119 skrll /* lpa failure case */ 930 1.119 skrll const u_int regno = 931 1.119 skrll __SHIFTOUT(opcode, __PABITS(27, 31)); 932 1.119 skrll tf_setregno(frame, regno, 0); 933 1.119 skrll frame->tf_ipsw |= PSW_N; 934 1.119 skrll } else if ((opcode & PROBE_MASK) == PROBE) { 935 1.119 skrll u_int pl; 936 1.119 skrll if ((opcode & PROBE_IMMED) == 0) { 937 1.119 skrll pl = __SHIFTOUT(opcode, __PABITS(14, 15)); 938 1.119 skrll } else { 939 1.119 skrll const u_int plreg = 940 1.119 skrll __SHIFTOUT(opcode, __PABITS(11, 15)); 941 1.119 skrll pl = tf_getregno(frame, plreg); 942 1.119 skrll } 943 1.119 skrll bool ok = true; 944 1.119 skrll if ((user && space == HPPA_SID_KERNEL) || 945 1.119 skrll (frame->tf_iioq_head & 3) != pl || 946 1.119 skrll (user && va >= VM_MAXUSER_ADDRESS)) { 947 1.119 skrll ok = false; 948 1.119 skrll } else { 949 1.119 skrll /* Never call uvm_fault in interrupt context. */ 950 1.119 skrll KASSERT(curcpu()->ci_intr_depth == 0); 951 1.119 skrll 952 1.119 skrll const bool read = 953 1.119 skrll __SHIFTOUT(opcode, PROBE_RW) == 0; 954 1.119 skrll onfault = pcb->pcb_onfault; 955 1.119 skrll pcb->pcb_onfault = 0; 956 1.119 skrll ret = uvm_fault(map, va, read ? 957 1.119 skrll VM_PROT_READ : VM_PROT_WRITE); 958 1.119 skrll pcb->pcb_onfault = onfault; 959 1.119 skrll 960 1.119 skrll if (ret) 961 1.119 skrll ok = false; 962 1.119 skrll } 963 1.119 skrll if (!ok) { 964 1.119 skrll const u_int regno = 965 1.119 skrll __SHIFTOUT(opcode, __PABITS(27, 31)); 966 1.119 skrll tf_setregno(frame, regno, 0); 967 1.119 skrll frame->tf_ipsw |= PSW_N; 968 1.119 skrll } 969 1.119 skrll } else { 970 1.119 skrll } 971 1.119 skrll break; 972 1.119 skrll 973 1.1 fredette case T_DATACC: case T_USER | T_DATACC: 974 1.1 fredette case T_ITLBMISS: case T_USER | T_ITLBMISS: 975 1.1 fredette case T_DTLBMISS: case T_USER | T_DTLBMISS: 976 1.1 fredette case T_TLB_DIRTY: case T_USER | T_TLB_DIRTY: 977 1.1 fredette vm = p->p_vmspace; 978 1.1 fredette 979 1.1 fredette if (!vm) { 980 1.1 fredette #ifdef TRAPDEBUG 981 1.1 fredette printf("trap: no vm, p=%p\n", p); 982 1.1 fredette #endif 983 1.1 fredette goto dead_end; 984 1.1 fredette } 985 1.1 fredette 986 1.1 fredette /* 987 1.1 fredette * it could be a kernel map for exec_map faults 988 1.1 fredette */ 989 1.1 fredette if (!(type & T_USER) && space == HPPA_SID_KERNEL) 990 1.1 fredette map = kernel_map; 991 1.56 wrstuden else { 992 1.1 fredette map = &vm->vm_map; 993 1.56 wrstuden } 994 1.10 cl 995 1.41 skrll va = trunc_page(va); 996 1.1 fredette 997 1.59 skrll if (map->pmap->pm_space != space) { 998 1.1 fredette #ifdef TRAPDEBUG 999 1.37 skrll printf("trap: space mismatch %d != %d\n", 1000 1.59 skrll space, map->pmap->pm_space); 1001 1.1 fredette #endif 1002 1.1 fredette /* actually dump the user, crap the kernel */ 1003 1.1 fredette goto dead_end; 1004 1.1 fredette } 1005 1.1 fredette 1006 1.1 fredette /* Never call uvm_fault in interrupt context. */ 1007 1.115 skrll KASSERT(curcpu()->ci_intr_depth == 0); 1008 1.1 fredette 1009 1.61 rmind onfault = pcb->pcb_onfault; 1010 1.61 rmind pcb->pcb_onfault = 0; 1011 1.33 drochner ret = uvm_fault(map, va, vftype); 1012 1.61 rmind pcb->pcb_onfault = onfault; 1013 1.1 fredette 1014 1.1 fredette #ifdef TRAPDEBUG 1015 1.33 drochner printf("uvm_fault(%p, %x, %d)=%d\n", 1016 1.33 drochner map, (u_int)va, vftype, ret); 1017 1.1 fredette #endif 1018 1.1 fredette 1019 1.1 fredette /* 1020 1.1 fredette * If this was a stack access we keep track of the maximum 1021 1.1 fredette * accessed stack size. Also, if uvm_fault gets a protection 1022 1.1 fredette * failure it is due to accessing the stack region outside 1023 1.1 fredette * the current limit and we need to reflect that as an access 1024 1.1 fredette * error. 1025 1.1 fredette */ 1026 1.39 skrll if (map != kernel_map && va >= (vaddr_t)vm->vm_minsaddr) { 1027 1.39 skrll if (ret == 0) 1028 1.39 skrll uvm_grow(l->l_proc, va); 1029 1.39 skrll else if (ret == EACCES) 1030 1.1 fredette ret = EFAULT; 1031 1.1 fredette } 1032 1.1 fredette 1033 1.1 fredette if (ret != 0) { 1034 1.1 fredette if (type & T_USER) { 1035 1.1 fredette #ifdef DEBUG 1036 1.9 chs user_backtrace(frame, l, type); 1037 1.1 fredette #endif 1038 1.22 chs KSI_INIT_TRAP(&ksi); 1039 1.107 martin switch (ret) { 1040 1.107 martin case EACCES: 1041 1.107 martin ksi.ksi_signo = SIGSEGV; 1042 1.107 martin ksi.ksi_code = SEGV_ACCERR; 1043 1.107 martin break; 1044 1.107 martin case ENOMEM: 1045 1.107 martin ksi.ksi_signo = SIGKILL; 1046 1.107 martin printf("UVM: pid %d (%s), uid %d " 1047 1.107 martin "killed: out of swap\n", 1048 1.107 martin p->p_pid, p->p_comm, 1049 1.111 skrll l->l_cred ? 1050 1.107 martin kauth_cred_geteuid(l->l_cred) 1051 1.107 martin : -1); 1052 1.107 martin break; 1053 1.107 martin case EINVAL: 1054 1.107 martin ksi.ksi_signo = SIGBUS; 1055 1.107 martin ksi.ksi_code = BUS_ADRERR; 1056 1.107 martin break; 1057 1.107 martin default: 1058 1.107 martin ksi.ksi_signo = SIGSEGV; 1059 1.107 martin ksi.ksi_code = SEGV_MAPERR; 1060 1.107 martin break; 1061 1.107 martin } 1062 1.22 chs ksi.ksi_trap = type; 1063 1.22 chs ksi.ksi_addr = (void *)va; 1064 1.22 chs trapsignal(l, &ksi); 1065 1.1 fredette } else { 1066 1.80 chs if (onfault) { 1067 1.25 chs goto do_onfault; 1068 1.1 fredette } 1069 1.33 drochner panic("trap: uvm_fault(%p, %lx, %d): %d", 1070 1.33 drochner map, va, vftype, ret); 1071 1.1 fredette } 1072 1.1 fredette } 1073 1.1 fredette break; 1074 1.1 fredette 1075 1.1 fredette case T_DATALIGN | T_USER: 1076 1.3 fredette #ifdef DEBUG 1077 1.9 chs user_backtrace(frame, l, type); 1078 1.3 fredette #endif 1079 1.22 chs KSI_INIT_TRAP(&ksi); 1080 1.22 chs ksi.ksi_signo = SIGBUS; 1081 1.22 chs ksi.ksi_code = BUS_ADRALN; 1082 1.22 chs ksi.ksi_trap = type; 1083 1.22 chs ksi.ksi_addr = (void *)va; 1084 1.22 chs trapsignal(l, &ksi); 1085 1.1 fredette break; 1086 1.1 fredette 1087 1.1 fredette case T_INTERRUPT: 1088 1.118 skrll case T_INTERRUPT | T_USER: 1089 1.1 fredette hppa_intr(frame); 1090 1.1 fredette mtctl(frame->tf_eiem, CR_EIEM); 1091 1.1 fredette break; 1092 1.22 chs 1093 1.1 fredette case T_LOWERPL: 1094 1.1 fredette case T_DPROT: 1095 1.1 fredette case T_IPROT: 1096 1.1 fredette case T_OVERFLOW: 1097 1.1 fredette case T_CONDITION: 1098 1.1 fredette case T_ILLEGAL: 1099 1.1 fredette case T_HIGHERPL: 1100 1.1 fredette case T_TAKENBR: 1101 1.1 fredette case T_POWERFAIL: 1102 1.1 fredette case T_LPMC: 1103 1.1 fredette case T_PAGEREF: 1104 1.1 fredette case T_DATAPID: case T_DATAPID | T_USER: 1105 1.1 fredette if (0 /* T-chip */) { 1106 1.1 fredette break; 1107 1.1 fredette } 1108 1.1 fredette /* FALLTHROUGH to unimplemented */ 1109 1.1 fredette default: 1110 1.1 fredette panic ("trap: unimplemented \'%s\' (%d)", tts, type); 1111 1.1 fredette } 1112 1.1 fredette 1113 1.69 skrll #ifdef DIAGNOSTIC 1114 1.85 skrll if (ci->ci_cpl != oldcpl) 1115 1.69 skrll printf("WARNING: SPL (%d) NOT LOWERED ON TRAP (%d) EXIT\n", 1116 1.85 skrll ci->ci_cpl, trapnum); 1117 1.69 skrll #endif 1118 1.69 skrll 1119 1.1 fredette if (type & T_USER) 1120 1.114 skrll userret(l, l->l_md.md_regs); 1121 1.1 fredette 1122 1.1 fredette #ifdef DEBUG 1123 1.81 skrll frame_sanity_check(__func__, __LINE__, type, frame, l); 1124 1.43 yamt if (frame->tf_flags & TFF_LAST && (curlwp->l_flag & LW_IDLE) == 0) 1125 1.83 skrll frame_sanity_check(__func__, __LINE__, type, 1126 1.83 skrll curlwp->l_md.md_regs, curlwp); 1127 1.1 fredette #endif /* DEBUG */ 1128 1.1 fredette } 1129 1.1 fredette 1130 1.1 fredette void 1131 1.110 kamil md_child_return(struct lwp *l) 1132 1.1 fredette { 1133 1.68 skrll /* 1134 1.68 skrll * Return values in the frame set by cpu_lwp_fork(). 1135 1.68 skrll */ 1136 1.68 skrll 1137 1.114 skrll userret(l, l->l_md.md_regs); 1138 1.1 fredette #ifdef DEBUG 1139 1.81 skrll frame_sanity_check(__func__, __LINE__, 0, l->l_md.md_regs, l); 1140 1.1 fredette #endif /* DEBUG */ 1141 1.1 fredette } 1142 1.1 fredette 1143 1.97 martin /* 1144 1.97 martin * Process the tail end of a posix_spawn() for the child. 1145 1.97 martin */ 1146 1.97 martin void 1147 1.97 martin cpu_spawn_return(struct lwp *l) 1148 1.97 martin { 1149 1.99 skrll 1150 1.114 skrll userret(l, l->l_md.md_regs); 1151 1.97 martin #ifdef DEBUG 1152 1.97 martin frame_sanity_check(__func__, __LINE__, 0, l->l_md.md_regs, l); 1153 1.97 martin #endif /* DEBUG */ 1154 1.97 martin } 1155 1.97 martin 1156 1.51 skrll #ifdef PTRACE 1157 1.51 skrll 1158 1.51 skrll #include <sys/ptrace.h> 1159 1.51 skrll 1160 1.51 skrll int 1161 1.51 skrll ss_get_value(struct lwp *l, vaddr_t addr, u_int *value) 1162 1.51 skrll { 1163 1.51 skrll struct uio uio; 1164 1.51 skrll struct iovec iov; 1165 1.51 skrll 1166 1.51 skrll iov.iov_base = (void *)value; 1167 1.51 skrll iov.iov_len = sizeof(u_int); 1168 1.51 skrll uio.uio_iov = &iov; 1169 1.51 skrll uio.uio_iovcnt = 1; 1170 1.51 skrll uio.uio_offset = (off_t)addr; 1171 1.51 skrll uio.uio_resid = sizeof(u_int); 1172 1.51 skrll uio.uio_rw = UIO_READ; 1173 1.51 skrll UIO_SETUP_SYSSPACE(&uio); 1174 1.51 skrll 1175 1.51 skrll return (process_domem(curlwp, l, &uio)); 1176 1.51 skrll } 1177 1.51 skrll 1178 1.51 skrll int 1179 1.51 skrll ss_put_value(struct lwp *l, vaddr_t addr, u_int value) 1180 1.51 skrll { 1181 1.51 skrll struct uio uio; 1182 1.51 skrll struct iovec iov; 1183 1.51 skrll 1184 1.51 skrll iov.iov_base = (void *)&value; 1185 1.51 skrll iov.iov_len = sizeof(u_int); 1186 1.51 skrll uio.uio_iov = &iov; 1187 1.51 skrll uio.uio_iovcnt = 1; 1188 1.51 skrll uio.uio_offset = (off_t)addr; 1189 1.51 skrll uio.uio_resid = sizeof(u_int); 1190 1.51 skrll uio.uio_rw = UIO_WRITE; 1191 1.51 skrll UIO_SETUP_SYSSPACE(&uio); 1192 1.51 skrll 1193 1.51 skrll return (process_domem(curlwp, l, &uio)); 1194 1.51 skrll } 1195 1.51 skrll 1196 1.51 skrll void 1197 1.51 skrll ss_clear_breakpoints(struct lwp *l) 1198 1.51 skrll { 1199 1.117 andvar /* Restore original instructions. */ 1200 1.51 skrll if (l->l_md.md_bpva != 0) { 1201 1.51 skrll ss_put_value(l, l->l_md.md_bpva, l->l_md.md_bpsave[0]); 1202 1.51 skrll ss_put_value(l, l->l_md.md_bpva + 4, l->l_md.md_bpsave[1]); 1203 1.51 skrll l->l_md.md_bpva = 0; 1204 1.51 skrll } 1205 1.51 skrll } 1206 1.51 skrll 1207 1.51 skrll 1208 1.51 skrll int 1209 1.51 skrll process_sstep(struct lwp *l, int sstep) 1210 1.51 skrll { 1211 1.51 skrll struct trapframe *tf = l->l_md.md_regs; 1212 1.51 skrll int error; 1213 1.51 skrll 1214 1.51 skrll ss_clear_breakpoints(l); 1215 1.51 skrll 1216 1.51 skrll /* We're continuing... */ 1217 1.91 skrll if (sstep == 0) { 1218 1.92 skrll tf->tf_ipsw &= ~PSW_T; 1219 1.51 skrll return 0; 1220 1.51 skrll } 1221 1.51 skrll 1222 1.51 skrll /* 1223 1.91 skrll * Don't touch the syscall gateway page. Instead, insert a 1224 1.91 skrll * breakpoint where we're supposed to return. 1225 1.51 skrll */ 1226 1.91 skrll if ((tf->tf_iioq_tail & ~PAGE_MASK) == SYSCALLGATE) 1227 1.91 skrll l->l_md.md_bpva = tf->tf_r31 & ~HPPA_PC_PRIV_MASK; 1228 1.91 skrll else 1229 1.91 skrll l->l_md.md_bpva = tf->tf_iioq_tail & ~HPPA_PC_PRIV_MASK; 1230 1.51 skrll 1231 1.51 skrll error = ss_get_value(l, l->l_md.md_bpva, &l->l_md.md_bpsave[0]); 1232 1.51 skrll if (error) 1233 1.91 skrll return error; 1234 1.51 skrll error = ss_get_value(l, l->l_md.md_bpva + 4, &l->l_md.md_bpsave[1]); 1235 1.51 skrll if (error) 1236 1.91 skrll return error; 1237 1.51 skrll 1238 1.51 skrll error = ss_put_value(l, l->l_md.md_bpva, SSBREAKPOINT); 1239 1.51 skrll if (error) 1240 1.51 skrll return error; 1241 1.51 skrll error = ss_put_value(l, l->l_md.md_bpva + 4, SSBREAKPOINT); 1242 1.51 skrll if (error) 1243 1.51 skrll return error; 1244 1.51 skrll 1245 1.91 skrll if ((tf->tf_iioq_tail & ~PAGE_MASK) == SYSCALLGATE) 1246 1.92 skrll tf->tf_ipsw &= ~PSW_T; 1247 1.91 skrll else 1248 1.91 skrll tf->tf_ipsw |= PSW_T; 1249 1.51 skrll 1250 1.51 skrll return 0; 1251 1.51 skrll } 1252 1.51 skrll #endif 1253 1.51 skrll 1254 1.51 skrll 1255 1.1 fredette /* 1256 1.1 fredette * call actual syscall routine 1257 1.1 fredette * from the low-level syscall handler: 1258 1.1 fredette * - all HPPA_FRAME_NARGS syscall's arguments supposed to be copied onto 1259 1.1 fredette * our stack, this wins compared to copyin just needed amount anyway 1260 1.1 fredette * - register args are copied onto stack too 1261 1.1 fredette */ 1262 1.1 fredette void 1263 1.14 chs syscall(struct trapframe *frame, int *args) 1264 1.1 fredette { 1265 1.9 chs struct lwp *l; 1266 1.9 chs struct proc *p; 1267 1.9 chs const struct sysent *callp; 1268 1.65 skrll size_t nargs64; 1269 1.54 dsl int nsys, code, error; 1270 1.1 fredette int tmp; 1271 1.1 fredette int rval[2]; 1272 1.69 skrll #ifdef DIAGNOSTIC 1273 1.85 skrll struct cpu_info *ci = curcpu(); 1274 1.85 skrll int oldcpl = ci->ci_cpl; 1275 1.69 skrll #endif 1276 1.1 fredette 1277 1.95 matt curcpu()->ci_data.cpu_nsyscall++; 1278 1.1 fredette 1279 1.1 fredette #ifdef DEBUG 1280 1.81 skrll frame_sanity_check(__func__, __LINE__, 0, frame, curlwp); 1281 1.1 fredette #endif /* DEBUG */ 1282 1.1 fredette 1283 1.1 fredette if (!USERMODE(frame->tf_iioq_head)) 1284 1.1 fredette panic("syscall"); 1285 1.1 fredette 1286 1.64 skrll KASSERT(curlwp != NULL); 1287 1.9 chs l = curlwp; 1288 1.9 chs p = l->l_proc; 1289 1.9 chs l->l_md.md_regs = frame; 1290 1.1 fredette nsys = p->p_emul->e_nsysent; 1291 1.1 fredette callp = p->p_emul->e_sysent; 1292 1.1 fredette code = frame->tf_t1; 1293 1.36 ad LWP_CACHE_CREDS(l, p); 1294 1.1 fredette 1295 1.1 fredette /* 1296 1.65 skrll * Restarting a system call is touchy on the HPPA, because syscall 1297 1.65 skrll * arguments are passed in registers and the program counter of the 1298 1.65 skrll * syscall "point" isn't easily divined. 1299 1.1 fredette * 1300 1.65 skrll * We handle the first problem by assuming that we will have to restart 1301 1.65 skrll * this system call, so we stuff the first four words of the original 1302 1.65 skrll * arguments back into the frame as arg0...arg3, which is where we 1303 1.65 skrll * found them in the first place. Any further arguments are (still) on 1304 1.65 skrll * the user's stack and the syscall code will fetch them from there 1305 1.65 skrll * (again). 1306 1.1 fredette * 1307 1.1 fredette * The program counter problem is addressed below. 1308 1.1 fredette */ 1309 1.1 fredette frame->tf_arg0 = args[0]; 1310 1.1 fredette frame->tf_arg1 = args[1]; 1311 1.1 fredette frame->tf_arg2 = args[2]; 1312 1.1 fredette frame->tf_arg3 = args[3]; 1313 1.1 fredette 1314 1.1 fredette /* 1315 1.111 skrll * Some special handling for the syscall(2) and 1316 1.1 fredette * __syscall(2) system calls. 1317 1.1 fredette */ 1318 1.1 fredette switch (code) { 1319 1.1 fredette case SYS_syscall: 1320 1.1 fredette code = *args; 1321 1.1 fredette args += 1; 1322 1.1 fredette break; 1323 1.1 fredette case SYS___syscall: 1324 1.1 fredette if (callp != sysent) 1325 1.1 fredette break; 1326 1.1 fredette /* 1327 1.65 skrll * NB: even though __syscall(2) takes a quad_t containing the 1328 1.65 skrll * system call number, because our argument copying word-swaps 1329 1.65 skrll * 64-bit arguments, the least significant word of that quad_t 1330 1.1 fredette * is the first word in the argument array. 1331 1.1 fredette */ 1332 1.1 fredette code = *args; 1333 1.1 fredette args += 2; 1334 1.1 fredette } 1335 1.1 fredette 1336 1.1 fredette /* 1337 1.65 skrll * Stacks growing from lower addresses to higher addresses are not 1338 1.65 skrll * really such a good idea, because it makes it impossible to overlay a 1339 1.65 skrll * struct on top of C stack arguments (the arguments appear in 1340 1.1 fredette * reversed order). 1341 1.1 fredette * 1342 1.65 skrll * You can do the obvious thing (as locore.S does) and copy argument 1343 1.65 skrll * words one by one, laying them out in the "right" order in the dest- 1344 1.65 skrll * ination buffer, but this ends up word-swapping multi-word arguments 1345 1.65 skrll * (like off_t). 1346 1.1 fredette * 1347 1.1 fredette * FIXME - this works only on native binaries and 1348 1.1 fredette * will probably screw up any and all emulation. 1349 1.65 skrll * 1350 1.1 fredette */ 1351 1.65 skrll 1352 1.65 skrll if (code < 0 || code >= nsys) 1353 1.65 skrll callp += p->p_emul->e_nosys; /* bad syscall # */ 1354 1.65 skrll else 1355 1.65 skrll callp += code; 1356 1.65 skrll 1357 1.65 skrll nargs64 = SYCALL_NARGS64(callp); 1358 1.65 skrll if (nargs64 != 0) { 1359 1.65 skrll size_t nargs = callp->sy_narg; 1360 1.65 skrll 1361 1.65 skrll for (size_t i = 0; i < nargs + nargs64;) { 1362 1.65 skrll if (SYCALL_ARG_64_P(callp, i)) { 1363 1.65 skrll tmp = args[i]; 1364 1.65 skrll args[i] = args[i + 1]; 1365 1.65 skrll args[i + 1] = tmp; 1366 1.65 skrll i += 2; 1367 1.65 skrll } else 1368 1.65 skrll i++; 1369 1.65 skrll } 1370 1.1 fredette } 1371 1.1 fredette 1372 1.1 fredette #ifdef USERTRACE 1373 1.1 fredette if (0) { 1374 1.35 skrll user_backtrace(frame, l, -1); 1375 1.1 fredette frame->tf_ipsw |= PSW_R; 1376 1.1 fredette frame->tf_rctr = 0; 1377 1.1 fredette printf("r %08x", frame->tf_iioq_head); 1378 1.1 fredette rctr_next_iioq = frame->tf_iioq_head + 4; 1379 1.1 fredette } 1380 1.1 fredette #endif 1381 1.1 fredette 1382 1.102 skrll error = sy_invoke(callp, l, args, rval, code); 1383 1.1 fredette 1384 1.27 christos switch (error) { 1385 1.1 fredette case 0: 1386 1.9 chs l = curlwp; /* changes on exec() */ 1387 1.9 chs frame = l->l_md.md_regs; 1388 1.1 fredette frame->tf_ret0 = rval[0]; 1389 1.1 fredette frame->tf_ret1 = rval[1]; 1390 1.1 fredette frame->tf_t1 = 0; 1391 1.1 fredette break; 1392 1.1 fredette case ERESTART: 1393 1.1 fredette /* 1394 1.74 skrll * Now we have to wind back the instruction offset queue to the 1395 1.74 skrll * point where the system call will be made again. This is 1396 1.74 skrll * inherently tied to the SYSCALL macro. 1397 1.1 fredette * 1398 1.74 skrll * Currently, the part of the SYSCALL macro that we want to re- 1399 1.74 skrll * run reads as: 1400 1.1 fredette * 1401 1.1 fredette * ldil L%SYSCALLGATE, r1 1402 1.106 skrll * ble 4(srX, r1) 1403 1.1 fredette * ldi __CONCAT(SYS_,x), t1 1404 1.52 skrll * comb,<> %r0, %t1, __cerror 1405 1.1 fredette * 1406 1.74 skrll * And our offset queue head points to the comb instruction. 1407 1.74 skrll * So we need to subtract twelve to reach the ldil. 1408 1.1 fredette */ 1409 1.1 fredette frame->tf_iioq_head -= 12; 1410 1.1 fredette frame->tf_iioq_tail = frame->tf_iioq_head + 4; 1411 1.1 fredette break; 1412 1.1 fredette case EJUSTRETURN: 1413 1.1 fredette p = curproc; 1414 1.1 fredette break; 1415 1.1 fredette default: 1416 1.1 fredette if (p->p_emul->e_errno) 1417 1.1 fredette error = p->p_emul->e_errno[error]; 1418 1.1 fredette frame->tf_t1 = error; 1419 1.1 fredette break; 1420 1.1 fredette } 1421 1.2 christos 1422 1.114 skrll userret(l, frame); 1423 1.69 skrll 1424 1.69 skrll #ifdef DIAGNOSTIC 1425 1.85 skrll if (ci->ci_cpl != oldcpl) { 1426 1.69 skrll printf("WARNING: SPL (0x%x) NOT LOWERED ON " 1427 1.69 skrll "syscall(0x%x, 0x%x, 0x%x, 0x%x...) EXIT, PID %d\n", 1428 1.85 skrll ci->ci_cpl, code, args[0], args[1], args[2], p->p_pid); 1429 1.85 skrll ci->ci_cpl = oldcpl; 1430 1.69 skrll } 1431 1.69 skrll #endif 1432 1.69 skrll 1433 1.1 fredette #ifdef DEBUG 1434 1.81 skrll frame_sanity_check(__func__, __LINE__, 0, frame, l); 1435 1.1 fredette #endif /* DEBUG */ 1436 1.9 chs } 1437 1.9 chs 1438 1.111 skrll /* 1439 1.9 chs * Start a new LWP 1440 1.9 chs */ 1441 1.9 chs void 1442 1.14 chs startlwp(void *arg) 1443 1.9 chs { 1444 1.9 chs ucontext_t *uc = arg; 1445 1.88 rmind lwp_t *l = curlwp; 1446 1.104 martin int error __diagused; 1447 1.9 chs 1448 1.88 rmind error = cpu_setmcontext(l, &uc->uc_mcontext, uc->uc_flags); 1449 1.88 rmind KASSERT(error == 0); 1450 1.9 chs 1451 1.88 rmind kmem_free(uc, sizeof(ucontext_t)); 1452 1.114 skrll userret(l, l->l_md.md_regs); 1453 1.9 chs } 1454
Indexes created Tue Sep 30 11:09:46 GMT 2025