kern_ras.c revision 1.5.2.5
1 1.5.2.5 christos /* $NetBSD: kern_ras.c,v 1.5.2.5 2005/12/11 10:29:11 christos Exp $ */ 2 1.1 gmcgarry 3 1.1 gmcgarry /*- 4 1.1 gmcgarry * Copyright (c) 2002 The NetBSD Foundation, Inc. 5 1.1 gmcgarry * All rights reserved. 6 1.1 gmcgarry * 7 1.1 gmcgarry * This code is derived from software contributed to The NetBSD Foundation 8 1.1 gmcgarry * by Gregory McGarry. 9 1.1 gmcgarry * 10 1.1 gmcgarry * Redistribution and use in source and binary forms, with or without 11 1.1 gmcgarry * modification, are permitted provided that the following conditions 12 1.1 gmcgarry * are met: 13 1.1 gmcgarry * 1. Redistributions of source code must retain the above copyright 14 1.1 gmcgarry * notice, this list of conditions and the following disclaimer. 15 1.1 gmcgarry * 2. Redistributions in binary form must reproduce the above copyright 16 1.1 gmcgarry * notice, this list of conditions and the following disclaimer in the 17 1.1 gmcgarry * documentation and/or other materials provided with the distribution. 18 1.1 gmcgarry * 3. All advertising materials mentioning features or use of this software 19 1.1 gmcgarry * must display the following acknowledgement: 20 1.1 gmcgarry * This product includes software developed by the NetBSD 21 1.1 gmcgarry * Foundation, Inc. and its contributors. 22 1.1 gmcgarry * 4. Neither the name of The NetBSD Foundation nor the names of its 23 1.1 gmcgarry * contributors may be used to endorse or promote products derived 24 1.1 gmcgarry * from this software without specific prior written permission. 25 1.1 gmcgarry * 26 1.1 gmcgarry * THIS SOFTWARE IS PROVIDED BY THE NETBSD FOUNDATION, INC. AND CONTRIBUTORS 27 1.1 gmcgarry * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED 28 1.1 gmcgarry * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR 29 1.1 gmcgarry * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE FOUNDATION OR CONTRIBUTORS 30 1.1 gmcgarry * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR 31 1.1 gmcgarry * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF 32 1.1 gmcgarry * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS 33 1.1 gmcgarry * INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN 34 1.1 gmcgarry * CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) 35 1.1 gmcgarry * ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE 36 1.1 gmcgarry * POSSIBILITY OF SUCH DAMAGE. 37 1.1 gmcgarry */ 38 1.1 gmcgarry 39 1.1 gmcgarry #include <sys/cdefs.h> 40 1.5.2.5 christos __KERNEL_RCSID(0, "$NetBSD: kern_ras.c,v 1.5.2.5 2005/12/11 10:29:11 christos Exp $"); 41 1.1 gmcgarry 42 1.1 gmcgarry #include <sys/param.h> 43 1.1 gmcgarry #include <sys/lock.h> 44 1.1 gmcgarry #include <sys/systm.h> 45 1.1 gmcgarry #include <sys/pool.h> 46 1.1 gmcgarry #include <sys/proc.h> 47 1.1 gmcgarry #include <sys/ras.h> 48 1.4 thorpej #include <sys/sa.h> 49 1.4 thorpej #include <sys/savar.h> 50 1.1 gmcgarry 51 1.1 gmcgarry #include <sys/mount.h> 52 1.1 gmcgarry #include <sys/syscallargs.h> 53 1.1 gmcgarry 54 1.1 gmcgarry #include <uvm/uvm_extern.h> 55 1.1 gmcgarry 56 1.1 gmcgarry #define MAX_RAS_PER_PROC 16 57 1.1 gmcgarry 58 1.3 thorpej u_int ras_per_proc = MAX_RAS_PER_PROC; 59 1.1 gmcgarry 60 1.1 gmcgarry #ifdef DEBUG 61 1.1 gmcgarry int ras_debug = 0; 62 1.1 gmcgarry #define DPRINTF(x) if (ras_debug) printf x 63 1.1 gmcgarry #else 64 1.1 gmcgarry #define DPRINTF(x) /* nothing */ 65 1.1 gmcgarry #endif 66 1.1 gmcgarry 67 1.1 gmcgarry /* 68 1.1 gmcgarry * Check the specified address to see if it is within the 69 1.1 gmcgarry * sequence. If it is found, we return the restart address, 70 1.1 gmcgarry * otherwise we return -1. If we do perform a restart, we 71 1.1 gmcgarry * mark the sequence as hit. 72 1.1 gmcgarry */ 73 1.1 gmcgarry caddr_t 74 1.1 gmcgarry ras_lookup(struct proc *p, caddr_t addr) 75 1.1 gmcgarry { 76 1.1 gmcgarry struct ras *rp; 77 1.1 gmcgarry 78 1.1 gmcgarry #ifdef DIAGNOSTIC 79 1.1 gmcgarry if (addr < (caddr_t)VM_MIN_ADDRESS || 80 1.1 gmcgarry addr > (caddr_t)VM_MAXUSER_ADDRESS) 81 1.1 gmcgarry return ((caddr_t)-1); 82 1.1 gmcgarry #endif 83 1.1 gmcgarry 84 1.5.2.1 skrll simple_lock(&p->p_lock); 85 1.1 gmcgarry LIST_FOREACH(rp, &p->p_raslist, ras_list) { 86 1.1 gmcgarry if (addr > rp->ras_startaddr && addr < rp->ras_endaddr) { 87 1.1 gmcgarry rp->ras_hits++; 88 1.5.2.1 skrll simple_unlock(&p->p_lock); 89 1.1 gmcgarry #ifdef DIAGNOSTIC 90 1.1 gmcgarry DPRINTF(("RAS hit: p=%p %p\n", p, addr)); 91 1.1 gmcgarry #endif 92 1.1 gmcgarry return (rp->ras_startaddr); 93 1.1 gmcgarry } 94 1.1 gmcgarry } 95 1.5.2.1 skrll simple_unlock(&p->p_lock); 96 1.1 gmcgarry 97 1.1 gmcgarry return ((caddr_t)-1); 98 1.1 gmcgarry } 99 1.1 gmcgarry 100 1.1 gmcgarry /* 101 1.1 gmcgarry * During a fork, we copy all of the sequences from parent p1 to 102 1.1 gmcgarry * the child p2. 103 1.1 gmcgarry */ 104 1.1 gmcgarry int 105 1.1 gmcgarry ras_fork(struct proc *p1, struct proc *p2) 106 1.1 gmcgarry { 107 1.1 gmcgarry struct ras *rp, *nrp; 108 1.5.2.1 skrll int nras; 109 1.1 gmcgarry 110 1.5.2.1 skrll again: 111 1.5.2.1 skrll /* 112 1.5.2.1 skrll * first, try to shortcut. 113 1.5.2.1 skrll */ 114 1.5.2.1 skrll 115 1.5.2.1 skrll if (LIST_EMPTY(&p1->p_raslist)) 116 1.5.2.1 skrll return (0); 117 1.5.2.1 skrll 118 1.5.2.1 skrll /* 119 1.5.2.1 skrll * count entries. 120 1.5.2.1 skrll */ 121 1.5.2.1 skrll 122 1.5.2.1 skrll nras = 0; 123 1.5.2.1 skrll simple_lock(&p1->p_lock); 124 1.5.2.1 skrll LIST_FOREACH(rp, &p1->p_raslist, ras_list) 125 1.5.2.1 skrll nras++; 126 1.5.2.1 skrll simple_unlock(&p1->p_lock); 127 1.5.2.1 skrll 128 1.5.2.1 skrll /* 129 1.5.2.1 skrll * allocate entries. 130 1.5.2.1 skrll */ 131 1.5.2.1 skrll 132 1.5.2.1 skrll for ( ; nras > 0; nras--) { 133 1.5.2.1 skrll nrp = pool_get(&ras_pool, PR_WAITOK); 134 1.5.2.1 skrll nrp->ras_hits = 0; 135 1.5.2.1 skrll LIST_INSERT_HEAD(&p2->p_raslist, nrp, ras_list); 136 1.5.2.1 skrll } 137 1.5.2.1 skrll 138 1.5.2.1 skrll /* 139 1.5.2.1 skrll * copy entries. 140 1.5.2.1 skrll */ 141 1.1 gmcgarry 142 1.5.2.1 skrll simple_lock(&p1->p_lock); 143 1.5.2.1 skrll nrp = LIST_FIRST(&p2->p_raslist); 144 1.1 gmcgarry LIST_FOREACH(rp, &p1->p_raslist, ras_list) { 145 1.5.2.1 skrll if (nrp == NULL) 146 1.5.2.1 skrll break; 147 1.1 gmcgarry nrp->ras_startaddr = rp->ras_startaddr; 148 1.1 gmcgarry nrp->ras_endaddr = rp->ras_endaddr; 149 1.5.2.1 skrll nrp = LIST_NEXT(nrp, ras_list); 150 1.1 gmcgarry } 151 1.5.2.1 skrll simple_unlock(&p1->p_lock); 152 1.5.2.1 skrll 153 1.5.2.1 skrll /* 154 1.5.2.1 skrll * if we lose a race, retry. 155 1.5.2.1 skrll */ 156 1.5.2.1 skrll 157 1.5.2.1 skrll if (rp != NULL || nrp != NULL) { 158 1.5.2.1 skrll ras_purgeall(p2); 159 1.5.2.1 skrll goto again; 160 1.5.2.1 skrll } 161 1.5.2.1 skrll 162 1.5.2.1 skrll DPRINTF(("ras_fork: p1=%p, p2=%p, nras=%d\n", p1, p2, nras)); 163 1.1 gmcgarry 164 1.1 gmcgarry return (0); 165 1.1 gmcgarry } 166 1.1 gmcgarry 167 1.1 gmcgarry /* 168 1.1 gmcgarry * Nuke all sequences for this process. 169 1.1 gmcgarry */ 170 1.1 gmcgarry int 171 1.1 gmcgarry ras_purgeall(struct proc *p) 172 1.1 gmcgarry { 173 1.1 gmcgarry struct ras *rp; 174 1.1 gmcgarry 175 1.5.2.1 skrll simple_lock(&p->p_lock); 176 1.1 gmcgarry while (!LIST_EMPTY(&p->p_raslist)) { 177 1.1 gmcgarry rp = LIST_FIRST(&p->p_raslist); 178 1.5.2.4 skrll DPRINTF(("RAS %p-%p, hits %d\n", rp->ras_startaddr, 179 1.1 gmcgarry rp->ras_endaddr, rp->ras_hits)); 180 1.1 gmcgarry LIST_REMOVE(rp, ras_list); 181 1.1 gmcgarry pool_put(&ras_pool, rp); 182 1.1 gmcgarry } 183 1.5.2.1 skrll simple_unlock(&p->p_lock); 184 1.1 gmcgarry 185 1.1 gmcgarry return (0); 186 1.1 gmcgarry } 187 1.1 gmcgarry 188 1.5.2.5 christos #if defined(__HAVE_RAS) 189 1.5.2.5 christos 190 1.1 gmcgarry /* 191 1.1 gmcgarry * Install the new sequence. If it already exists, return 192 1.1 gmcgarry * an error. 193 1.1 gmcgarry */ 194 1.5.2.5 christos static int 195 1.1 gmcgarry ras_install(struct proc *p, caddr_t addr, size_t len) 196 1.1 gmcgarry { 197 1.1 gmcgarry struct ras *rp; 198 1.5.2.1 skrll struct ras *newrp; 199 1.1 gmcgarry caddr_t endaddr = addr + len; 200 1.5.2.1 skrll int nras = 0; 201 1.1 gmcgarry 202 1.1 gmcgarry if (addr < (caddr_t)VM_MIN_ADDRESS || 203 1.5.2.1 skrll endaddr > (caddr_t)VM_MAXUSER_ADDRESS) 204 1.1 gmcgarry return (EINVAL); 205 1.1 gmcgarry 206 1.1 gmcgarry if (len <= 0) 207 1.1 gmcgarry return (EINVAL); 208 1.1 gmcgarry 209 1.5.2.1 skrll newrp = NULL; 210 1.5.2.1 skrll again: 211 1.5.2.1 skrll simple_lock(&p->p_lock); 212 1.1 gmcgarry LIST_FOREACH(rp, &p->p_raslist, ras_list) { 213 1.5.2.1 skrll if (++nras >= ras_per_proc || 214 1.5.2.1 skrll (addr < rp->ras_endaddr && endaddr > rp->ras_startaddr)) { 215 1.5.2.1 skrll simple_unlock(&p->p_lock); 216 1.1 gmcgarry return (EINVAL); 217 1.1 gmcgarry } 218 1.1 gmcgarry } 219 1.5.2.1 skrll if (newrp == NULL) { 220 1.5.2.1 skrll simple_unlock(&p->p_lock); 221 1.5.2.1 skrll newrp = pool_get(&ras_pool, PR_WAITOK); 222 1.5.2.1 skrll goto again; 223 1.5.2.1 skrll } 224 1.5.2.1 skrll newrp->ras_startaddr = addr; 225 1.5.2.1 skrll newrp->ras_endaddr = endaddr; 226 1.5.2.1 skrll newrp->ras_hits = 0; 227 1.5.2.1 skrll LIST_INSERT_HEAD(&p->p_raslist, newrp, ras_list); 228 1.5.2.1 skrll simple_unlock(&p->p_lock); 229 1.1 gmcgarry 230 1.1 gmcgarry return (0); 231 1.1 gmcgarry } 232 1.1 gmcgarry 233 1.1 gmcgarry /* 234 1.1 gmcgarry * Nuke the specified sequence. Both address and len must 235 1.1 gmcgarry * match, otherwise we return an error. 236 1.1 gmcgarry */ 237 1.5.2.5 christos static int 238 1.1 gmcgarry ras_purge(struct proc *p, caddr_t addr, size_t len) 239 1.1 gmcgarry { 240 1.1 gmcgarry struct ras *rp; 241 1.1 gmcgarry caddr_t endaddr = addr + len; 242 1.1 gmcgarry int error = ESRCH; 243 1.1 gmcgarry 244 1.5.2.1 skrll simple_lock(&p->p_lock); 245 1.1 gmcgarry LIST_FOREACH(rp, &p->p_raslist, ras_list) { 246 1.1 gmcgarry if (addr == rp->ras_startaddr && endaddr == rp->ras_endaddr) { 247 1.1 gmcgarry LIST_REMOVE(rp, ras_list); 248 1.1 gmcgarry pool_put(&ras_pool, rp); 249 1.1 gmcgarry error = 0; 250 1.1 gmcgarry break; 251 1.1 gmcgarry } 252 1.1 gmcgarry } 253 1.5.2.1 skrll simple_unlock(&p->p_lock); 254 1.1 gmcgarry 255 1.1 gmcgarry return (error); 256 1.1 gmcgarry } 257 1.1 gmcgarry 258 1.5.2.5 christos #endif /* defined(__HAVE_RAS) */ 259 1.5.2.5 christos 260 1.1 gmcgarry /*ARGSUSED*/ 261 1.1 gmcgarry int 262 1.4 thorpej sys_rasctl(struct lwp *l, void *v, register_t *retval) 263 1.1 gmcgarry { 264 1.1 gmcgarry 265 1.1 gmcgarry #if defined(__HAVE_RAS) 266 1.1 gmcgarry 267 1.1 gmcgarry struct sys_rasctl_args /* { 268 1.1 gmcgarry syscallarg(caddr_t) addr; 269 1.1 gmcgarry syscallarg(size_t) len; 270 1.1 gmcgarry syscallarg(int) op; 271 1.1 gmcgarry } */ *uap = v; 272 1.4 thorpej struct proc *p = l->l_proc; 273 1.1 gmcgarry caddr_t addr; 274 1.1 gmcgarry size_t len; 275 1.1 gmcgarry int op; 276 1.1 gmcgarry int error; 277 1.1 gmcgarry 278 1.1 gmcgarry /* 279 1.1 gmcgarry * first, extract syscall args from the uap. 280 1.1 gmcgarry */ 281 1.1 gmcgarry 282 1.1 gmcgarry addr = (caddr_t)SCARG(uap, addr); 283 1.1 gmcgarry len = (size_t)SCARG(uap, len); 284 1.1 gmcgarry op = SCARG(uap, op); 285 1.1 gmcgarry 286 1.2 thorpej DPRINTF(("sys_rasctl: p=%p addr=%p, len=%ld, op=0x%x\n", 287 1.2 thorpej p, addr, (long)len, op)); 288 1.1 gmcgarry 289 1.1 gmcgarry switch (op) { 290 1.1 gmcgarry case RAS_INSTALL: 291 1.1 gmcgarry error = ras_install(p, addr, len); 292 1.1 gmcgarry break; 293 1.1 gmcgarry case RAS_PURGE: 294 1.1 gmcgarry error = ras_purge(p, addr, len); 295 1.1 gmcgarry break; 296 1.1 gmcgarry case RAS_PURGE_ALL: 297 1.1 gmcgarry error = ras_purgeall(p); 298 1.1 gmcgarry break; 299 1.1 gmcgarry default: 300 1.1 gmcgarry error = EINVAL; 301 1.1 gmcgarry break; 302 1.1 gmcgarry } 303 1.1 gmcgarry 304 1.1 gmcgarry return (error); 305 1.1 gmcgarry 306 1.1 gmcgarry #else 307 1.1 gmcgarry 308 1.1 gmcgarry return (EOPNOTSUPP); 309 1.1 gmcgarry 310 1.1 gmcgarry #endif 311 1.1 gmcgarry 312 1.1 gmcgarry } 313
Indexes created Mon Sep 29 18:09:42 GMT 2025