rf_dagfuncs.c revision 1.11.6.4
1 1.11.6.4 skrll /* $NetBSD: rf_dagfuncs.c,v 1.11.6.4 2005/02/15 21:33:28 skrll Exp $ */ 2 1.1 oster /* 3 1.1 oster * Copyright (c) 1995 Carnegie-Mellon University. 4 1.1 oster * All rights reserved. 5 1.1 oster * 6 1.1 oster * Author: Mark Holland, William V. Courtright II 7 1.1 oster * 8 1.1 oster * Permission to use, copy, modify and distribute this software and 9 1.1 oster * its documentation is hereby granted, provided that both the copyright 10 1.1 oster * notice and this permission notice appear in all copies of the 11 1.1 oster * software, derivative works or modified versions, and any portions 12 1.1 oster * thereof, and that both notices appear in supporting documentation. 13 1.1 oster * 14 1.1 oster * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS" 15 1.1 oster * CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND 16 1.1 oster * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE. 17 1.1 oster * 18 1.1 oster * Carnegie Mellon requests users of this software to return to 19 1.1 oster * 20 1.1 oster * Software Distribution Coordinator or Software.Distribution (at) CS.CMU.EDU 21 1.1 oster * School of Computer Science 22 1.1 oster * Carnegie Mellon University 23 1.1 oster * Pittsburgh PA 15213-3890 24 1.1 oster * 25 1.1 oster * any improvements or extensions that they make and grant Carnegie the 26 1.1 oster * rights to redistribute these changes. 27 1.1 oster */ 28 1.1 oster 29 1.1 oster /* 30 1.1 oster * dagfuncs.c -- DAG node execution routines 31 1.1 oster * 32 1.1 oster * Rules: 33 1.1 oster * 1. Every DAG execution function must eventually cause node->status to 34 1.1 oster * get set to "good" or "bad", and "FinishNode" to be called. In the 35 1.1 oster * case of nodes that complete immediately (xor, NullNodeFunc, etc), 36 1.1 oster * the node execution function can do these two things directly. In 37 1.1 oster * the case of nodes that have to wait for some event (a disk read to 38 1.1 oster * complete, a lock to be released, etc) to occur before they can 39 1.1 oster * complete, this is typically achieved by having whatever module 40 1.1 oster * is doing the operation call GenericWakeupFunc upon completion. 41 1.1 oster * 2. DAG execution functions should check the status in the DAG header 42 1.1 oster * and NOP out their operations if the status is not "enable". However, 43 1.1 oster * execution functions that release resources must be sure to release 44 1.1 oster * them even when they NOP out the function that would use them. 45 1.1 oster * Functions that acquire resources should go ahead and acquire them 46 1.1 oster * even when they NOP, so that a downstream release node will not have 47 1.1 oster * to check to find out whether or not the acquire was suppressed. 48 1.1 oster */ 49 1.8 lukem 50 1.8 lukem #include <sys/cdefs.h> 51 1.11.6.4 skrll __KERNEL_RCSID(0, "$NetBSD: rf_dagfuncs.c,v 1.11.6.4 2005/02/15 21:33:28 skrll Exp $"); 52 1.1 oster 53 1.7 mrg #include <sys/param.h> 54 1.1 oster #include <sys/ioctl.h> 55 1.1 oster 56 1.1 oster #include "rf_archs.h" 57 1.1 oster #include "rf_raid.h" 58 1.1 oster #include "rf_dag.h" 59 1.1 oster #include "rf_layout.h" 60 1.1 oster #include "rf_etimer.h" 61 1.1 oster #include "rf_acctrace.h" 62 1.1 oster #include "rf_diskqueue.h" 63 1.1 oster #include "rf_dagfuncs.h" 64 1.1 oster #include "rf_general.h" 65 1.1 oster #include "rf_engine.h" 66 1.1 oster #include "rf_dagutils.h" 67 1.1 oster 68 1.1 oster #include "rf_kintf.h" 69 1.1 oster 70 1.1 oster #if RF_INCLUDE_PARITYLOGGING > 0 71 1.1 oster #include "rf_paritylog.h" 72 1.3 oster #endif /* RF_INCLUDE_PARITYLOGGING > 0 */ 73 1.1 oster 74 1.3 oster int (*rf_DiskReadFunc) (RF_DagNode_t *); 75 1.3 oster int (*rf_DiskWriteFunc) (RF_DagNode_t *); 76 1.3 oster int (*rf_DiskReadUndoFunc) (RF_DagNode_t *); 77 1.3 oster int (*rf_DiskWriteUndoFunc) (RF_DagNode_t *); 78 1.3 oster int (*rf_DiskUnlockFunc) (RF_DagNode_t *); 79 1.3 oster int (*rf_DiskUnlockUndoFunc) (RF_DagNode_t *); 80 1.3 oster int (*rf_RegularXorUndoFunc) (RF_DagNode_t *); 81 1.3 oster int (*rf_SimpleXorUndoFunc) (RF_DagNode_t *); 82 1.3 oster int (*rf_RecoveryXorUndoFunc) (RF_DagNode_t *); 83 1.1 oster 84 1.11.6.1 skrll /***************************************************************************** 85 1.1 oster * main (only) configuration routine for this module 86 1.11.6.1 skrll ****************************************************************************/ 87 1.3 oster int 88 1.11.6.1 skrll rf_ConfigureDAGFuncs(RF_ShutdownList_t **listp) 89 1.3 oster { 90 1.11.6.1 skrll RF_ASSERT(((sizeof(long) == 8) && RF_LONGSHIFT == 3) || 91 1.11.6.1 skrll ((sizeof(long) == 4) && RF_LONGSHIFT == 2)); 92 1.3 oster rf_DiskReadFunc = rf_DiskReadFuncForThreads; 93 1.3 oster rf_DiskReadUndoFunc = rf_DiskUndoFunc; 94 1.3 oster rf_DiskWriteFunc = rf_DiskWriteFuncForThreads; 95 1.3 oster rf_DiskWriteUndoFunc = rf_DiskUndoFunc; 96 1.3 oster rf_DiskUnlockFunc = rf_DiskUnlockFuncForThreads; 97 1.3 oster rf_DiskUnlockUndoFunc = rf_NullNodeUndoFunc; 98 1.3 oster rf_RegularXorUndoFunc = rf_NullNodeUndoFunc; 99 1.3 oster rf_SimpleXorUndoFunc = rf_NullNodeUndoFunc; 100 1.3 oster rf_RecoveryXorUndoFunc = rf_NullNodeUndoFunc; 101 1.3 oster return (0); 102 1.1 oster } 103 1.1 oster 104 1.1 oster 105 1.1 oster 106 1.11.6.1 skrll /***************************************************************************** 107 1.1 oster * the execution function associated with a terminate node 108 1.11.6.1 skrll ****************************************************************************/ 109 1.3 oster int 110 1.11.6.1 skrll rf_TerminateFunc(RF_DagNode_t *node) 111 1.1 oster { 112 1.3 oster RF_ASSERT(node->dagHdr->numCommits == node->dagHdr->numCommitNodes); 113 1.3 oster node->status = rf_good; 114 1.3 oster return (rf_FinishNode(node, RF_THREAD_CONTEXT)); 115 1.1 oster } 116 1.1 oster 117 1.3 oster int 118 1.11.6.1 skrll rf_TerminateUndoFunc(RF_DagNode_t *node) 119 1.1 oster { 120 1.3 oster return (0); 121 1.1 oster } 122 1.1 oster 123 1.1 oster 124 1.11.6.1 skrll /***************************************************************************** 125 1.1 oster * execution functions associated with a mirror node 126 1.1 oster * 127 1.1 oster * parameters: 128 1.1 oster * 129 1.1 oster * 0 - physical disk addres of data 130 1.1 oster * 1 - buffer for holding read data 131 1.1 oster * 2 - parity stripe ID 132 1.1 oster * 3 - flags 133 1.1 oster * 4 - physical disk address of mirror (parity) 134 1.1 oster * 135 1.11.6.1 skrll ****************************************************************************/ 136 1.1 oster 137 1.3 oster int 138 1.11.6.1 skrll rf_DiskReadMirrorIdleFunc(RF_DagNode_t *node) 139 1.1 oster { 140 1.3 oster /* select the mirror copy with the shortest queue and fill in node 141 1.3 oster * parameters with physical disk address */ 142 1.1 oster 143 1.3 oster rf_SelectMirrorDiskIdle(node); 144 1.3 oster return (rf_DiskReadFunc(node)); 145 1.1 oster } 146 1.1 oster 147 1.11 oster #if (RF_INCLUDE_CHAINDECLUSTER > 0) || (RF_INCLUDE_INTERDECLUSTER > 0) || (RF_DEBUG_VALIDATE_DAG > 0) 148 1.3 oster int 149 1.11.6.1 skrll rf_DiskReadMirrorPartitionFunc(RF_DagNode_t *node) 150 1.1 oster { 151 1.3 oster /* select the mirror copy with the shortest queue and fill in node 152 1.3 oster * parameters with physical disk address */ 153 1.1 oster 154 1.3 oster rf_SelectMirrorDiskPartition(node); 155 1.3 oster return (rf_DiskReadFunc(node)); 156 1.1 oster } 157 1.11 oster #endif 158 1.1 oster 159 1.3 oster int 160 1.11.6.1 skrll rf_DiskReadMirrorUndoFunc(RF_DagNode_t *node) 161 1.1 oster { 162 1.3 oster return (0); 163 1.1 oster } 164 1.1 oster 165 1.1 oster 166 1.1 oster 167 1.1 oster #if RF_INCLUDE_PARITYLOGGING > 0 168 1.11.6.1 skrll /***************************************************************************** 169 1.1 oster * the execution function associated with a parity log update node 170 1.11.6.1 skrll ****************************************************************************/ 171 1.3 oster int 172 1.11.6.1 skrll rf_ParityLogUpdateFunc(RF_DagNode_t *node) 173 1.3 oster { 174 1.3 oster RF_PhysDiskAddr_t *pda = (RF_PhysDiskAddr_t *) node->params[0].p; 175 1.3 oster caddr_t buf = (caddr_t) node->params[1].p; 176 1.3 oster RF_ParityLogData_t *logData; 177 1.11.6.1 skrll #if RF_ACC_TRACE > 0 178 1.3 oster RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec; 179 1.3 oster RF_Etimer_t timer; 180 1.11.6.1 skrll #endif 181 1.3 oster 182 1.3 oster if (node->dagHdr->status == rf_enable) { 183 1.11.6.1 skrll #if RF_ACC_TRACE > 0 184 1.3 oster RF_ETIMER_START(timer); 185 1.11.6.1 skrll #endif 186 1.3 oster logData = rf_CreateParityLogData(RF_UPDATE, pda, buf, 187 1.3 oster (RF_Raid_t *) (node->dagHdr->raidPtr), 188 1.3 oster node->wakeFunc, (void *) node, 189 1.3 oster node->dagHdr->tracerec, timer); 190 1.3 oster if (logData) 191 1.3 oster rf_ParityLogAppend(logData, RF_FALSE, NULL, RF_FALSE); 192 1.3 oster else { 193 1.11.6.1 skrll #if RF_ACC_TRACE > 0 194 1.3 oster RF_ETIMER_STOP(timer); 195 1.3 oster RF_ETIMER_EVAL(timer); 196 1.3 oster tracerec->plog_us += RF_ETIMER_VAL_US(timer); 197 1.11.6.1 skrll #endif 198 1.3 oster (node->wakeFunc) (node, ENOMEM); 199 1.3 oster } 200 1.1 oster } 201 1.3 oster return (0); 202 1.1 oster } 203 1.1 oster 204 1.1 oster 205 1.11.6.1 skrll /***************************************************************************** 206 1.1 oster * the execution function associated with a parity log overwrite node 207 1.11.6.1 skrll ****************************************************************************/ 208 1.3 oster int 209 1.11.6.1 skrll rf_ParityLogOverwriteFunc(RF_DagNode_t *node) 210 1.3 oster { 211 1.3 oster RF_PhysDiskAddr_t *pda = (RF_PhysDiskAddr_t *) node->params[0].p; 212 1.3 oster caddr_t buf = (caddr_t) node->params[1].p; 213 1.3 oster RF_ParityLogData_t *logData; 214 1.11.6.1 skrll #if RF_ACC_TRACE > 0 215 1.3 oster RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec; 216 1.3 oster RF_Etimer_t timer; 217 1.11.6.1 skrll #endif 218 1.3 oster 219 1.3 oster if (node->dagHdr->status == rf_enable) { 220 1.11.6.1 skrll #if RF_ACC_TRACE > 0 221 1.3 oster RF_ETIMER_START(timer); 222 1.11.6.1 skrll #endif 223 1.11.6.1 skrll logData = rf_CreateParityLogData(RF_OVERWRITE, pda, buf, 224 1.11.6.1 skrll (RF_Raid_t *) (node->dagHdr->raidPtr), 225 1.3 oster node->wakeFunc, (void *) node, node->dagHdr->tracerec, timer); 226 1.3 oster if (logData) 227 1.3 oster rf_ParityLogAppend(logData, RF_FALSE, NULL, RF_FALSE); 228 1.3 oster else { 229 1.11.6.1 skrll #if RF_ACC_TRACE > 0 230 1.3 oster RF_ETIMER_STOP(timer); 231 1.3 oster RF_ETIMER_EVAL(timer); 232 1.3 oster tracerec->plog_us += RF_ETIMER_VAL_US(timer); 233 1.11.6.1 skrll #endif 234 1.3 oster (node->wakeFunc) (node, ENOMEM); 235 1.3 oster } 236 1.1 oster } 237 1.3 oster return (0); 238 1.1 oster } 239 1.1 oster 240 1.3 oster int 241 1.11.6.1 skrll rf_ParityLogUpdateUndoFunc(RF_DagNode_t *node) 242 1.1 oster { 243 1.3 oster return (0); 244 1.1 oster } 245 1.1 oster 246 1.3 oster int 247 1.11.6.1 skrll rf_ParityLogOverwriteUndoFunc(RF_DagNode_t *node) 248 1.1 oster { 249 1.3 oster return (0); 250 1.1 oster } 251 1.10 oster #endif /* RF_INCLUDE_PARITYLOGGING > 0 */ 252 1.10 oster 253 1.11.6.1 skrll /***************************************************************************** 254 1.1 oster * the execution function associated with a NOP node 255 1.11.6.1 skrll ****************************************************************************/ 256 1.3 oster int 257 1.11.6.1 skrll rf_NullNodeFunc(RF_DagNode_t *node) 258 1.1 oster { 259 1.3 oster node->status = rf_good; 260 1.3 oster return (rf_FinishNode(node, RF_THREAD_CONTEXT)); 261 1.1 oster } 262 1.1 oster 263 1.3 oster int 264 1.11.6.1 skrll rf_NullNodeUndoFunc(RF_DagNode_t *node) 265 1.1 oster { 266 1.3 oster node->status = rf_undone; 267 1.3 oster return (rf_FinishNode(node, RF_THREAD_CONTEXT)); 268 1.1 oster } 269 1.1 oster 270 1.1 oster 271 1.11.6.1 skrll /***************************************************************************** 272 1.1 oster * the execution function associated with a disk-read node 273 1.11.6.1 skrll ****************************************************************************/ 274 1.3 oster int 275 1.11.6.1 skrll rf_DiskReadFuncForThreads(RF_DagNode_t *node) 276 1.3 oster { 277 1.3 oster RF_DiskQueueData_t *req; 278 1.3 oster RF_PhysDiskAddr_t *pda = (RF_PhysDiskAddr_t *) node->params[0].p; 279 1.3 oster caddr_t buf = (caddr_t) node->params[1].p; 280 1.3 oster RF_StripeNum_t parityStripeID = (RF_StripeNum_t) node->params[2].v; 281 1.3 oster unsigned priority = RF_EXTRACT_PRIORITY(node->params[3].v); 282 1.3 oster unsigned which_ru = RF_EXTRACT_RU(node->params[3].v); 283 1.3 oster RF_IoType_t iotype = (node->dagHdr->status == rf_enable) ? RF_IO_TYPE_READ : RF_IO_TYPE_NOP; 284 1.11.6.1 skrll RF_DiskQueue_t *dqs = ((RF_Raid_t *) (node->dagHdr->raidPtr))->Queues; 285 1.3 oster void *b_proc = NULL; 286 1.1 oster 287 1.3 oster if (node->dagHdr->bp) 288 1.3 oster b_proc = (void *) ((struct buf *) node->dagHdr->bp)->b_proc; 289 1.1 oster 290 1.3 oster req = rf_CreateDiskQueueData(iotype, pda->startSector, pda->numSector, 291 1.3 oster buf, parityStripeID, which_ru, 292 1.3 oster (int (*) (void *, int)) node->wakeFunc, 293 1.11.6.4 skrll node, 294 1.11.6.1 skrll #if RF_ACC_TRACE > 0 295 1.11.6.1 skrll node->dagHdr->tracerec, 296 1.11.6.1 skrll #else 297 1.11.6.1 skrll NULL, 298 1.11.6.1 skrll #endif 299 1.11.6.4 skrll (void *) (node->dagHdr->raidPtr), 0, b_proc, PR_NOWAIT); 300 1.3 oster if (!req) { 301 1.3 oster (node->wakeFunc) (node, ENOMEM); 302 1.3 oster } else { 303 1.3 oster node->dagFuncData = (void *) req; 304 1.11.6.1 skrll rf_DiskIOEnqueue(&(dqs[pda->col]), req, priority); 305 1.3 oster } 306 1.3 oster return (0); 307 1.1 oster } 308 1.1 oster 309 1.1 oster 310 1.11.6.1 skrll /***************************************************************************** 311 1.1 oster * the execution function associated with a disk-write node 312 1.11.6.1 skrll ****************************************************************************/ 313 1.3 oster int 314 1.11.6.1 skrll rf_DiskWriteFuncForThreads(RF_DagNode_t *node) 315 1.3 oster { 316 1.3 oster RF_DiskQueueData_t *req; 317 1.3 oster RF_PhysDiskAddr_t *pda = (RF_PhysDiskAddr_t *) node->params[0].p; 318 1.3 oster caddr_t buf = (caddr_t) node->params[1].p; 319 1.3 oster RF_StripeNum_t parityStripeID = (RF_StripeNum_t) node->params[2].v; 320 1.3 oster unsigned priority = RF_EXTRACT_PRIORITY(node->params[3].v); 321 1.3 oster unsigned which_ru = RF_EXTRACT_RU(node->params[3].v); 322 1.3 oster RF_IoType_t iotype = (node->dagHdr->status == rf_enable) ? RF_IO_TYPE_WRITE : RF_IO_TYPE_NOP; 323 1.11.6.1 skrll RF_DiskQueue_t *dqs = ((RF_Raid_t *) (node->dagHdr->raidPtr))->Queues; 324 1.3 oster void *b_proc = NULL; 325 1.1 oster 326 1.3 oster if (node->dagHdr->bp) 327 1.3 oster b_proc = (void *) ((struct buf *) node->dagHdr->bp)->b_proc; 328 1.1 oster 329 1.3 oster /* normal processing (rollaway or forward recovery) begins here */ 330 1.3 oster req = rf_CreateDiskQueueData(iotype, pda->startSector, pda->numSector, 331 1.3 oster buf, parityStripeID, which_ru, 332 1.3 oster (int (*) (void *, int)) node->wakeFunc, 333 1.11.6.4 skrll (void *) node, 334 1.11.6.1 skrll #if RF_ACC_TRACE > 0 335 1.3 oster node->dagHdr->tracerec, 336 1.11.6.1 skrll #else 337 1.11.6.1 skrll NULL, 338 1.11.6.1 skrll #endif 339 1.3 oster (void *) (node->dagHdr->raidPtr), 340 1.11.6.4 skrll 0, b_proc, PR_NOWAIT); 341 1.3 oster 342 1.3 oster if (!req) { 343 1.3 oster (node->wakeFunc) (node, ENOMEM); 344 1.3 oster } else { 345 1.3 oster node->dagFuncData = (void *) req; 346 1.11.6.1 skrll rf_DiskIOEnqueue(&(dqs[pda->col]), req, priority); 347 1.3 oster } 348 1.3 oster 349 1.3 oster return (0); 350 1.1 oster } 351 1.11.6.1 skrll /***************************************************************************** 352 1.1 oster * the undo function for disk nodes 353 1.1 oster * Note: this is not a proper undo of a write node, only locks are released. 354 1.1 oster * old data is not restored to disk! 355 1.11.6.1 skrll ****************************************************************************/ 356 1.3 oster int 357 1.11.6.1 skrll rf_DiskUndoFunc(RF_DagNode_t *node) 358 1.3 oster { 359 1.3 oster RF_DiskQueueData_t *req; 360 1.3 oster RF_PhysDiskAddr_t *pda = (RF_PhysDiskAddr_t *) node->params[0].p; 361 1.11.6.1 skrll RF_DiskQueue_t *dqs = ((RF_Raid_t *) (node->dagHdr->raidPtr))->Queues; 362 1.3 oster 363 1.3 oster req = rf_CreateDiskQueueData(RF_IO_TYPE_NOP, 364 1.3 oster 0L, 0, NULL, 0L, 0, 365 1.3 oster (int (*) (void *, int)) node->wakeFunc, 366 1.3 oster (void *) node, 367 1.11.6.1 skrll #if RF_ACC_TRACE > 0 368 1.11.6.1 skrll node->dagHdr->tracerec, 369 1.11.6.1 skrll #else 370 1.11.6.1 skrll NULL, 371 1.11.6.1 skrll #endif 372 1.3 oster (void *) (node->dagHdr->raidPtr), 373 1.11.6.4 skrll RF_UNLOCK_DISK_QUEUE, NULL, PR_NOWAIT); 374 1.3 oster if (!req) 375 1.3 oster (node->wakeFunc) (node, ENOMEM); 376 1.3 oster else { 377 1.3 oster node->dagFuncData = (void *) req; 378 1.11.6.1 skrll rf_DiskIOEnqueue(&(dqs[pda->col]), req, RF_IO_NORMAL_PRIORITY); 379 1.3 oster } 380 1.1 oster 381 1.3 oster return (0); 382 1.1 oster } 383 1.11.6.1 skrll /***************************************************************************** 384 1.1 oster * the execution function associated with an "unlock disk queue" node 385 1.11.6.1 skrll ****************************************************************************/ 386 1.3 oster int 387 1.11.6.1 skrll rf_DiskUnlockFuncForThreads(RF_DagNode_t *node) 388 1.3 oster { 389 1.3 oster RF_DiskQueueData_t *req; 390 1.3 oster RF_PhysDiskAddr_t *pda = (RF_PhysDiskAddr_t *) node->params[0].p; 391 1.11.6.1 skrll RF_DiskQueue_t *dqs = ((RF_Raid_t *) (node->dagHdr->raidPtr))->Queues; 392 1.3 oster 393 1.3 oster req = rf_CreateDiskQueueData(RF_IO_TYPE_NOP, 394 1.3 oster 0L, 0, NULL, 0L, 0, 395 1.3 oster (int (*) (void *, int)) node->wakeFunc, 396 1.3 oster (void *) node, 397 1.11.6.1 skrll #if RF_ACC_TRACE > 0 398 1.11.6.1 skrll node->dagHdr->tracerec, 399 1.11.6.1 skrll #else 400 1.11.6.1 skrll NULL, 401 1.11.6.1 skrll #endif 402 1.3 oster (void *) (node->dagHdr->raidPtr), 403 1.11.6.4 skrll RF_UNLOCK_DISK_QUEUE, NULL, PR_NOWAIT); 404 1.3 oster if (!req) 405 1.3 oster (node->wakeFunc) (node, ENOMEM); 406 1.3 oster else { 407 1.3 oster node->dagFuncData = (void *) req; 408 1.11.6.1 skrll rf_DiskIOEnqueue(&(dqs[pda->col]), req, RF_IO_NORMAL_PRIORITY); 409 1.3 oster } 410 1.1 oster 411 1.3 oster return (0); 412 1.1 oster } 413 1.11.6.1 skrll /***************************************************************************** 414 1.11.6.1 skrll * Callback routine for DiskRead and DiskWrite nodes. When the disk 415 1.11.6.1 skrll * op completes, the routine is called to set the node status and 416 1.11.6.1 skrll * inform the execution engine that the node has fired. 417 1.11.6.1 skrll ****************************************************************************/ 418 1.3 oster int 419 1.11.6.1 skrll rf_GenericWakeupFunc(RF_DagNode_t *node, int status) 420 1.3 oster { 421 1.11.6.1 skrll 422 1.3 oster switch (node->status) { 423 1.3 oster case rf_fired: 424 1.3 oster if (status) 425 1.3 oster node->status = rf_bad; 426 1.3 oster else 427 1.3 oster node->status = rf_good; 428 1.3 oster break; 429 1.3 oster case rf_recover: 430 1.3 oster /* probably should never reach this case */ 431 1.3 oster if (status) 432 1.3 oster node->status = rf_panic; 433 1.3 oster else 434 1.3 oster node->status = rf_undone; 435 1.3 oster break; 436 1.3 oster default: 437 1.4 oster printf("rf_GenericWakeupFunc:"); 438 1.4 oster printf("node->status is %d,", node->status); 439 1.4 oster printf("status is %d \n", status); 440 1.3 oster RF_PANIC(); 441 1.3 oster break; 442 1.3 oster } 443 1.3 oster if (node->dagFuncData) 444 1.3 oster rf_FreeDiskQueueData((RF_DiskQueueData_t *) node->dagFuncData); 445 1.3 oster return (rf_FinishNode(node, RF_INTR_CONTEXT)); 446 1.1 oster } 447 1.1 oster 448 1.1 oster 449 1.11.6.1 skrll /***************************************************************************** 450 1.11.6.1 skrll * there are three distinct types of xor nodes: 451 1.11.6.1 skrll 452 1.11.6.1 skrll * A "regular xor" is used in the fault-free case where the access 453 1.11.6.1 skrll * spans a complete stripe unit. It assumes that the result buffer is 454 1.11.6.1 skrll * one full stripe unit in size, and uses the stripe-unit-offset 455 1.11.6.1 skrll * values that it computes from the PDAs to determine where within the 456 1.11.6.1 skrll * stripe unit to XOR each argument buffer. 457 1.11.6.1 skrll * 458 1.11.6.1 skrll * A "simple xor" is used in the fault-free case where the access 459 1.11.6.1 skrll * touches only a portion of one (or two, in some cases) stripe 460 1.11.6.1 skrll * unit(s). It assumes that all the argument buffers are of the same 461 1.11.6.1 skrll * size and have the same stripe unit offset. 462 1.11.6.1 skrll * 463 1.11.6.1 skrll * A "recovery xor" is used in the degraded-mode case. It's similar 464 1.11.6.1 skrll * to the regular xor function except that it takes the failed PDA as 465 1.11.6.1 skrll * an additional parameter, and uses it to determine what portions of 466 1.11.6.1 skrll * the argument buffers need to be xor'd into the result buffer, and 467 1.11.6.1 skrll * where in the result buffer they should go. 468 1.11.6.1 skrll ****************************************************************************/ 469 1.1 oster 470 1.1 oster /* xor the params together and store the result in the result field. 471 1.11.6.1 skrll * assume the result field points to a buffer that is the size of one 472 1.11.6.1 skrll * SU, and use the pda params to determine where within the buffer to 473 1.11.6.1 skrll * XOR the input buffers. */ 474 1.3 oster int 475 1.11.6.1 skrll rf_RegularXorFunc(RF_DagNode_t *node) 476 1.3 oster { 477 1.3 oster RF_Raid_t *raidPtr = (RF_Raid_t *) node->params[node->numParams - 1].p; 478 1.11.6.1 skrll #if RF_ACC_TRACE > 0 479 1.3 oster RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec; 480 1.3 oster RF_Etimer_t timer; 481 1.11.6.1 skrll #endif 482 1.3 oster int i, retcode; 483 1.1 oster 484 1.3 oster retcode = 0; 485 1.3 oster if (node->dagHdr->status == rf_enable) { 486 1.3 oster /* don't do the XOR if the input is the same as the output */ 487 1.11.6.1 skrll #if RF_ACC_TRACE > 0 488 1.3 oster RF_ETIMER_START(timer); 489 1.11.6.1 skrll #endif 490 1.3 oster for (i = 0; i < node->numParams - 1; i += 2) 491 1.3 oster if (node->params[i + 1].p != node->results[0]) { 492 1.3 oster retcode = rf_XorIntoBuffer(raidPtr, (RF_PhysDiskAddr_t *) node->params[i].p, 493 1.11.6.1 skrll (char *) node->params[i + 1].p, (char *) node->results[0]); 494 1.3 oster } 495 1.11.6.1 skrll #if RF_ACC_TRACE > 0 496 1.3 oster RF_ETIMER_STOP(timer); 497 1.3 oster RF_ETIMER_EVAL(timer); 498 1.3 oster tracerec->xor_us += RF_ETIMER_VAL_US(timer); 499 1.11.6.1 skrll #endif 500 1.3 oster } 501 1.3 oster return (rf_GenericWakeupFunc(node, retcode)); /* call wake func 502 1.3 oster * explicitly since no 503 1.3 oster * I/O in this node */ 504 1.1 oster } 505 1.1 oster /* xor the inputs into the result buffer, ignoring placement issues */ 506 1.3 oster int 507 1.11.6.1 skrll rf_SimpleXorFunc(RF_DagNode_t *node) 508 1.3 oster { 509 1.3 oster RF_Raid_t *raidPtr = (RF_Raid_t *) node->params[node->numParams - 1].p; 510 1.3 oster int i, retcode = 0; 511 1.11.6.1 skrll #if RF_ACC_TRACE > 0 512 1.3 oster RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec; 513 1.3 oster RF_Etimer_t timer; 514 1.11.6.1 skrll #endif 515 1.1 oster 516 1.3 oster if (node->dagHdr->status == rf_enable) { 517 1.11.6.1 skrll #if RF_ACC_TRACE > 0 518 1.3 oster RF_ETIMER_START(timer); 519 1.11.6.1 skrll #endif 520 1.3 oster /* don't do the XOR if the input is the same as the output */ 521 1.3 oster for (i = 0; i < node->numParams - 1; i += 2) 522 1.3 oster if (node->params[i + 1].p != node->results[0]) { 523 1.3 oster retcode = rf_bxor((char *) node->params[i + 1].p, (char *) node->results[0], 524 1.11.6.1 skrll rf_RaidAddressToByte(raidPtr, ((RF_PhysDiskAddr_t *) node->params[i].p)->numSector)); 525 1.3 oster } 526 1.11.6.1 skrll #if RF_ACC_TRACE > 0 527 1.3 oster RF_ETIMER_STOP(timer); 528 1.3 oster RF_ETIMER_EVAL(timer); 529 1.3 oster tracerec->xor_us += RF_ETIMER_VAL_US(timer); 530 1.11.6.1 skrll #endif 531 1.3 oster } 532 1.3 oster return (rf_GenericWakeupFunc(node, retcode)); /* call wake func 533 1.3 oster * explicitly since no 534 1.3 oster * I/O in this node */ 535 1.1 oster } 536 1.11.6.1 skrll /* this xor is used by the degraded-mode dag functions to recover lost 537 1.11.6.1 skrll * data. the second-to-last parameter is the PDA for the failed 538 1.11.6.1 skrll * portion of the access. the code here looks at this PDA and assumes 539 1.11.6.1 skrll * that the xor target buffer is equal in size to the number of 540 1.11.6.1 skrll * sectors in the failed PDA. It then uses the other PDAs in the 541 1.11.6.1 skrll * parameter list to determine where within the target buffer the 542 1.11.6.1 skrll * corresponding data should be xored. */ 543 1.3 oster int 544 1.11.6.1 skrll rf_RecoveryXorFunc(RF_DagNode_t *node) 545 1.3 oster { 546 1.3 oster RF_Raid_t *raidPtr = (RF_Raid_t *) node->params[node->numParams - 1].p; 547 1.3 oster RF_RaidLayout_t *layoutPtr = (RF_RaidLayout_t *) & raidPtr->Layout; 548 1.3 oster RF_PhysDiskAddr_t *failedPDA = (RF_PhysDiskAddr_t *) node->params[node->numParams - 2].p; 549 1.3 oster int i, retcode = 0; 550 1.3 oster RF_PhysDiskAddr_t *pda; 551 1.3 oster int suoffset, failedSUOffset = rf_StripeUnitOffset(layoutPtr, failedPDA->startSector); 552 1.3 oster char *srcbuf, *destbuf; 553 1.11.6.1 skrll #if RF_ACC_TRACE > 0 554 1.3 oster RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec; 555 1.3 oster RF_Etimer_t timer; 556 1.11.6.1 skrll #endif 557 1.1 oster 558 1.3 oster if (node->dagHdr->status == rf_enable) { 559 1.11.6.1 skrll #if RF_ACC_TRACE > 0 560 1.3 oster RF_ETIMER_START(timer); 561 1.11.6.1 skrll #endif 562 1.3 oster for (i = 0; i < node->numParams - 2; i += 2) 563 1.3 oster if (node->params[i + 1].p != node->results[0]) { 564 1.3 oster pda = (RF_PhysDiskAddr_t *) node->params[i].p; 565 1.3 oster srcbuf = (char *) node->params[i + 1].p; 566 1.3 oster suoffset = rf_StripeUnitOffset(layoutPtr, pda->startSector); 567 1.3 oster destbuf = ((char *) node->results[0]) + rf_RaidAddressToByte(raidPtr, suoffset - failedSUOffset); 568 1.11.6.1 skrll retcode = rf_bxor(srcbuf, destbuf, rf_RaidAddressToByte(raidPtr, pda->numSector)); 569 1.3 oster } 570 1.11.6.1 skrll #if RF_ACC_TRACE > 0 571 1.3 oster RF_ETIMER_STOP(timer); 572 1.3 oster RF_ETIMER_EVAL(timer); 573 1.3 oster tracerec->xor_us += RF_ETIMER_VAL_US(timer); 574 1.11.6.1 skrll #endif 575 1.3 oster } 576 1.3 oster return (rf_GenericWakeupFunc(node, retcode)); 577 1.1 oster } 578 1.11.6.1 skrll /***************************************************************************** 579 1.11.6.1 skrll * The next three functions are utilities used by the above 580 1.11.6.1 skrll * xor-execution functions. 581 1.11.6.1 skrll ****************************************************************************/ 582 1.1 oster 583 1.1 oster 584 1.1 oster /* 585 1.11.6.1 skrll * this is just a glorified buffer xor. targbuf points to a buffer 586 1.11.6.1 skrll * that is one full stripe unit in size. srcbuf points to a buffer 587 1.11.6.1 skrll * that may be less than 1 SU, but never more. When the access 588 1.11.6.1 skrll * described by pda is one SU in size (which by implication means it's 589 1.11.6.1 skrll * SU-aligned), all that happens is (targbuf) <- (srcbuf ^ targbuf). 590 1.11.6.1 skrll * When the access is less than one SU in size the XOR occurs on only 591 1.11.6.1 skrll * the portion of targbuf identified in the pda. */ 592 1.1 oster 593 1.3 oster int 594 1.11.6.1 skrll rf_XorIntoBuffer(RF_Raid_t *raidPtr, RF_PhysDiskAddr_t *pda, 595 1.11.6.1 skrll char *srcbuf, char *targbuf) 596 1.3 oster { 597 1.3 oster char *targptr; 598 1.3 oster int sectPerSU = raidPtr->Layout.sectorsPerStripeUnit; 599 1.3 oster int SUOffset = pda->startSector % sectPerSU; 600 1.3 oster int length, retcode = 0; 601 1.3 oster 602 1.3 oster RF_ASSERT(pda->numSector <= sectPerSU); 603 1.3 oster 604 1.3 oster targptr = targbuf + rf_RaidAddressToByte(raidPtr, SUOffset); 605 1.3 oster length = rf_RaidAddressToByte(raidPtr, pda->numSector); 606 1.11.6.1 skrll retcode = rf_bxor(srcbuf, targptr, length); 607 1.3 oster return (retcode); 608 1.1 oster } 609 1.11.6.1 skrll /* it really should be the case that the buffer pointers (returned by 610 1.11.6.1 skrll * malloc) are aligned to the natural word size of the machine, so 611 1.11.6.1 skrll * this is the only case we optimize for. The length should always be 612 1.11.6.1 skrll * a multiple of the sector size, so there should be no problem with 613 1.11.6.1 skrll * leftover bytes at the end. */ 614 1.3 oster int 615 1.11.6.1 skrll rf_bxor(char *src, char *dest, int len) 616 1.3 oster { 617 1.3 oster unsigned mask = sizeof(long) - 1, retcode = 0; 618 1.3 oster 619 1.11.6.1 skrll if (!(((unsigned long) src) & mask) && 620 1.11.6.1 skrll !(((unsigned long) dest) & mask) && !(len & mask)) { 621 1.11.6.1 skrll retcode = rf_longword_bxor((unsigned long *) src, 622 1.11.6.1 skrll (unsigned long *) dest, 623 1.11.6.1 skrll len >> RF_LONGSHIFT); 624 1.3 oster } else { 625 1.3 oster RF_ASSERT(0); 626 1.3 oster } 627 1.3 oster return (retcode); 628 1.1 oster } 629 1.1 oster 630 1.11.6.1 skrll /* When XORing in kernel mode, we need to map each user page to kernel 631 1.11.6.1 skrll * space before we can access it. We don't want to assume anything 632 1.11.6.1 skrll * about which input buffers are in kernel/user space, nor about their 633 1.11.6.1 skrll * alignment, so in each loop we compute the maximum number of bytes 634 1.11.6.1 skrll * that we can xor without crossing any page boundaries, and do only 635 1.11.6.1 skrll * this many bytes before the next remap. 636 1.11.6.1 skrll * 637 1.11.6.1 skrll * len - is in longwords 638 1.1 oster */ 639 1.3 oster int 640 1.11.6.1 skrll rf_longword_bxor(unsigned long *src, unsigned long *dest, int len) 641 1.3 oster { 642 1.6 augustss unsigned long *end = src + len; 643 1.6 augustss unsigned long d0, d1, d2, d3, s0, s1, s2, s3; /* temps */ 644 1.11.6.1 skrll unsigned long *pg_src, *pg_dest; /* per-page source/dest pointers */ 645 1.3 oster int longs_this_time;/* # longwords to xor in the current iteration */ 646 1.3 oster 647 1.11.6.1 skrll pg_src = src; 648 1.11.6.1 skrll pg_dest = dest; 649 1.3 oster if (!pg_src || !pg_dest) 650 1.3 oster return (EFAULT); 651 1.3 oster 652 1.3 oster while (len >= 4) { 653 1.3 oster longs_this_time = RF_MIN(len, RF_MIN(RF_BLIP(pg_src), RF_BLIP(pg_dest)) >> RF_LONGSHIFT); /* note len in longwords */ 654 1.3 oster src += longs_this_time; 655 1.3 oster dest += longs_this_time; 656 1.3 oster len -= longs_this_time; 657 1.3 oster while (longs_this_time >= 4) { 658 1.3 oster d0 = pg_dest[0]; 659 1.3 oster d1 = pg_dest[1]; 660 1.3 oster d2 = pg_dest[2]; 661 1.3 oster d3 = pg_dest[3]; 662 1.3 oster s0 = pg_src[0]; 663 1.3 oster s1 = pg_src[1]; 664 1.3 oster s2 = pg_src[2]; 665 1.3 oster s3 = pg_src[3]; 666 1.3 oster pg_dest[0] = d0 ^ s0; 667 1.3 oster pg_dest[1] = d1 ^ s1; 668 1.3 oster pg_dest[2] = d2 ^ s2; 669 1.3 oster pg_dest[3] = d3 ^ s3; 670 1.3 oster pg_src += 4; 671 1.3 oster pg_dest += 4; 672 1.3 oster longs_this_time -= 4; 673 1.3 oster } 674 1.3 oster while (longs_this_time > 0) { /* cannot cross any page 675 1.3 oster * boundaries here */ 676 1.3 oster *pg_dest++ ^= *pg_src++; 677 1.3 oster longs_this_time--; 678 1.3 oster } 679 1.3 oster 680 1.3 oster /* either we're done, or we've reached a page boundary on one 681 1.3 oster * (or possibly both) of the pointers */ 682 1.3 oster if (len) { 683 1.3 oster if (RF_PAGE_ALIGNED(src)) 684 1.11.6.1 skrll pg_src = src; 685 1.3 oster if (RF_PAGE_ALIGNED(dest)) 686 1.11.6.1 skrll pg_dest = dest; 687 1.3 oster if (!pg_src || !pg_dest) 688 1.3 oster return (EFAULT); 689 1.3 oster } 690 1.3 oster } 691 1.3 oster while (src < end) { 692 1.3 oster *pg_dest++ ^= *pg_src++; 693 1.3 oster src++; 694 1.3 oster dest++; 695 1.3 oster len--; 696 1.3 oster if (RF_PAGE_ALIGNED(src)) 697 1.11.6.1 skrll pg_src = src; 698 1.3 oster if (RF_PAGE_ALIGNED(dest)) 699 1.11.6.1 skrll pg_dest = dest; 700 1.3 oster } 701 1.3 oster RF_ASSERT(len == 0); 702 1.3 oster return (0); 703 1.1 oster } 704 1.1 oster 705 1.9 oster #if 0 706 1.1 oster /* 707 1.1 oster dst = a ^ b ^ c; 708 1.1 oster a may equal dst 709 1.1 oster see comment above longword_bxor 710 1.11.6.1 skrll len is length in longwords 711 1.1 oster */ 712 1.3 oster int 713 1.11.6.1 skrll rf_longword_bxor3(unsigned long *dst, unsigned long *a, unsigned long *b, 714 1.11.6.1 skrll unsigned long *c, int len, void *bp) 715 1.3 oster { 716 1.3 oster unsigned long a0, a1, a2, a3, b0, b1, b2, b3; 717 1.6 augustss unsigned long *pg_a, *pg_b, *pg_c, *pg_dst; /* per-page source/dest 718 1.3 oster * pointers */ 719 1.3 oster int longs_this_time;/* # longs to xor in the current iteration */ 720 1.3 oster char dst_is_a = 0; 721 1.3 oster 722 1.11.6.1 skrll pg_a = a; 723 1.11.6.1 skrll pg_b = b; 724 1.11.6.1 skrll pg_c = c; 725 1.3 oster if (a == dst) { 726 1.3 oster pg_dst = pg_a; 727 1.3 oster dst_is_a = 1; 728 1.3 oster } else { 729 1.11.6.1 skrll pg_dst = dst; 730 1.3 oster } 731 1.3 oster 732 1.3 oster /* align dest to cache line. Can't cross a pg boundary on dst here. */ 733 1.3 oster while ((((unsigned long) pg_dst) & 0x1f)) { 734 1.3 oster *pg_dst++ = *pg_a++ ^ *pg_b++ ^ *pg_c++; 735 1.3 oster dst++; 736 1.3 oster a++; 737 1.3 oster b++; 738 1.3 oster c++; 739 1.3 oster if (RF_PAGE_ALIGNED(a)) { 740 1.11.6.1 skrll pg_a = a; 741 1.3 oster if (!pg_a) 742 1.3 oster return (EFAULT); 743 1.3 oster } 744 1.3 oster if (RF_PAGE_ALIGNED(b)) { 745 1.11.6.1 skrll pg_b = a; 746 1.3 oster if (!pg_b) 747 1.3 oster return (EFAULT); 748 1.3 oster } 749 1.3 oster if (RF_PAGE_ALIGNED(c)) { 750 1.11.6.1 skrll pg_c = a; 751 1.3 oster if (!pg_c) 752 1.3 oster return (EFAULT); 753 1.3 oster } 754 1.3 oster len--; 755 1.3 oster } 756 1.3 oster 757 1.3 oster while (len > 4) { 758 1.3 oster longs_this_time = RF_MIN(len, RF_MIN(RF_BLIP(a), RF_MIN(RF_BLIP(b), RF_MIN(RF_BLIP(c), RF_BLIP(dst)))) >> RF_LONGSHIFT); 759 1.3 oster a += longs_this_time; 760 1.3 oster b += longs_this_time; 761 1.3 oster c += longs_this_time; 762 1.3 oster dst += longs_this_time; 763 1.3 oster len -= longs_this_time; 764 1.3 oster while (longs_this_time >= 4) { 765 1.3 oster a0 = pg_a[0]; 766 1.3 oster longs_this_time -= 4; 767 1.3 oster 768 1.3 oster a1 = pg_a[1]; 769 1.3 oster a2 = pg_a[2]; 770 1.3 oster 771 1.3 oster a3 = pg_a[3]; 772 1.3 oster pg_a += 4; 773 1.3 oster 774 1.3 oster b0 = pg_b[0]; 775 1.3 oster b1 = pg_b[1]; 776 1.3 oster 777 1.3 oster b2 = pg_b[2]; 778 1.3 oster b3 = pg_b[3]; 779 1.3 oster /* start dual issue */ 780 1.3 oster a0 ^= b0; 781 1.3 oster b0 = pg_c[0]; 782 1.3 oster 783 1.3 oster pg_b += 4; 784 1.3 oster a1 ^= b1; 785 1.3 oster 786 1.3 oster a2 ^= b2; 787 1.3 oster a3 ^= b3; 788 1.3 oster 789 1.3 oster b1 = pg_c[1]; 790 1.3 oster a0 ^= b0; 791 1.3 oster 792 1.3 oster b2 = pg_c[2]; 793 1.3 oster a1 ^= b1; 794 1.3 oster 795 1.3 oster b3 = pg_c[3]; 796 1.3 oster a2 ^= b2; 797 1.3 oster 798 1.3 oster pg_dst[0] = a0; 799 1.3 oster a3 ^= b3; 800 1.3 oster pg_dst[1] = a1; 801 1.3 oster pg_c += 4; 802 1.3 oster pg_dst[2] = a2; 803 1.3 oster pg_dst[3] = a3; 804 1.3 oster pg_dst += 4; 805 1.3 oster } 806 1.3 oster while (longs_this_time > 0) { /* cannot cross any page 807 1.3 oster * boundaries here */ 808 1.3 oster *pg_dst++ = *pg_a++ ^ *pg_b++ ^ *pg_c++; 809 1.3 oster longs_this_time--; 810 1.3 oster } 811 1.3 oster 812 1.3 oster if (len) { 813 1.3 oster if (RF_PAGE_ALIGNED(a)) { 814 1.11.6.1 skrll pg_a = a; 815 1.3 oster if (!pg_a) 816 1.3 oster return (EFAULT); 817 1.3 oster if (dst_is_a) 818 1.3 oster pg_dst = pg_a; 819 1.3 oster } 820 1.3 oster if (RF_PAGE_ALIGNED(b)) { 821 1.11.6.1 skrll pg_b = b; 822 1.3 oster if (!pg_b) 823 1.3 oster return (EFAULT); 824 1.3 oster } 825 1.3 oster if (RF_PAGE_ALIGNED(c)) { 826 1.11.6.1 skrll pg_c = c; 827 1.3 oster if (!pg_c) 828 1.3 oster return (EFAULT); 829 1.3 oster } 830 1.3 oster if (!dst_is_a) 831 1.3 oster if (RF_PAGE_ALIGNED(dst)) { 832 1.11.6.1 skrll pg_dst = dst; 833 1.3 oster if (!pg_dst) 834 1.3 oster return (EFAULT); 835 1.3 oster } 836 1.3 oster } 837 1.3 oster } 838 1.3 oster while (len) { 839 1.3 oster *pg_dst++ = *pg_a++ ^ *pg_b++ ^ *pg_c++; 840 1.3 oster dst++; 841 1.3 oster a++; 842 1.3 oster b++; 843 1.3 oster c++; 844 1.3 oster if (RF_PAGE_ALIGNED(a)) { 845 1.11.6.1 skrll pg_a = a; 846 1.3 oster if (!pg_a) 847 1.3 oster return (EFAULT); 848 1.3 oster if (dst_is_a) 849 1.3 oster pg_dst = pg_a; 850 1.3 oster } 851 1.3 oster if (RF_PAGE_ALIGNED(b)) { 852 1.11.6.1 skrll pg_b = b; 853 1.3 oster if (!pg_b) 854 1.3 oster return (EFAULT); 855 1.3 oster } 856 1.3 oster if (RF_PAGE_ALIGNED(c)) { 857 1.11.6.1 skrll pg_c = c; 858 1.3 oster if (!pg_c) 859 1.3 oster return (EFAULT); 860 1.3 oster } 861 1.3 oster if (!dst_is_a) 862 1.3 oster if (RF_PAGE_ALIGNED(dst)) { 863 1.11.6.1 skrll pg_dst = dst; 864 1.3 oster if (!pg_dst) 865 1.3 oster return (EFAULT); 866 1.3 oster } 867 1.3 oster len--; 868 1.3 oster } 869 1.3 oster return (0); 870 1.3 oster } 871 1.3 oster 872 1.3 oster int 873 1.11.6.1 skrll rf_bxor3(unsigned char *dst, unsigned char *a, unsigned char *b, 874 1.11.6.1 skrll unsigned char *c, unsigned long len, void *bp) 875 1.1 oster { 876 1.3 oster RF_ASSERT(((RF_UL(dst) | RF_UL(a) | RF_UL(b) | RF_UL(c) | len) & 0x7) == 0); 877 1.1 oster 878 1.3 oster return (rf_longword_bxor3((unsigned long *) dst, (unsigned long *) a, 879 1.3 oster (unsigned long *) b, (unsigned long *) c, len >> RF_LONGSHIFT, bp)); 880 1.1 oster } 881 1.9 oster #endif 882
Indexes created Tue Sep 30 17:09:57 GMT 2025