dev/raidframe/rf_paritylog.c

1.18       mrg /*	$NetBSD: rf_paritylog.c,v 1.18 2011/05/11 06:03:06 mrg Exp $	*/
 1.1     oster /*
 1.1     oster  * Copyright (c) 1995 Carnegie-Mellon University.
 1.1     oster  * All rights reserved.
 1.1     oster  *
 1.1     oster  * Author: William V. Courtright II
 1.1     oster  *
 1.1     oster  * Permission to use, copy, modify and distribute this software and
 1.1     oster  * its documentation is hereby granted, provided that both the copyright
 1.1     oster  * notice and this permission notice appear in all copies of the
 1.1     oster  * software, derivative works or modified versions, and any portions
 1.1     oster  * thereof, and that both notices appear in supporting documentation.
 1.1     oster  *
 1.1     oster  * CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
 1.1     oster  * CONDITION.  CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND
 1.1     oster  * FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
 1.1     oster  *
 1.1     oster  * Carnegie Mellon requests users of this software to return to
 1.1     oster  *
 1.1     oster  *  Software Distribution Coordinator  or  Software.Distribution (at) CS.CMU.EDU
 1.1     oster  *  School of Computer Science
 1.1     oster  *  Carnegie Mellon University
 1.1     oster  *  Pittsburgh PA 15213-3890
 1.1     oster  *
 1.1     oster  * any improvements or extensions that they make and grant Carnegie the
 1.1     oster  * rights to redistribute these changes.
 1.1     oster  */
 1.1     oster
 1.1     oster /* Code for manipulating in-core parity logs
 1.1     oster  *
 1.1     oster  */
 1.7     lukem
 1.7     lukem #include <sys/cdefs.h>
1.18       mrg __KERNEL_RCSID(0, "$NetBSD: rf_paritylog.c,v 1.18 2011/05/11 06:03:06 mrg Exp $");
 1.1     oster
 1.1     oster #include "rf_archs.h"
 1.1     oster
 1.1     oster #if RF_INCLUDE_PARITYLOGGING > 0
 1.1     oster
 1.1     oster /*
 1.1     oster  * Append-only log for recording parity "update" and "overwrite" records
 1.1     oster  */
 1.1     oster
 1.6     oster #include <dev/raidframe/raidframevar.h>
 1.6     oster
 1.1     oster #include "rf_threadstuff.h"
 1.1     oster #include "rf_mcpair.h"
 1.1     oster #include "rf_raid.h"
 1.1     oster #include "rf_dag.h"
 1.1     oster #include "rf_dagfuncs.h"
 1.1     oster #include "rf_desc.h"
 1.1     oster #include "rf_layout.h"
 1.1     oster #include "rf_diskqueue.h"
 1.1     oster #include "rf_etimer.h"
 1.1     oster #include "rf_paritylog.h"
 1.1     oster #include "rf_general.h"
 1.1     oster #include "rf_map.h"
 1.1     oster #include "rf_paritylogging.h"
 1.1     oster #include "rf_paritylogDiskMgr.h"
 1.1     oster
 1.3     oster static RF_CommonLogData_t *
 1.3     oster AllocParityLogCommonData(RF_Raid_t * raidPtr)
 1.1     oster {
 1.3     oster 	RF_CommonLogData_t *common = NULL;
 1.1     oster
 1.3     oster 	/* Return a struct for holding common parity log information from the
 1.3     oster 	 * free list (rf_parityLogDiskQueue.freeCommonList).  If the free list
 1.3     oster 	 * is empty, call RF_Malloc to create a new structure. NON-BLOCKING */
 1.3     oster
1.15       mrg 	rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	if (raidPtr->parityLogDiskQueue.freeCommonList) {
 1.3     oster 		common = raidPtr->parityLogDiskQueue.freeCommonList;
 1.3     oster 		raidPtr->parityLogDiskQueue.freeCommonList = raidPtr->parityLogDiskQueue.freeCommonList->next;
1.15       mrg 		rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	} else {
1.15       mrg 		rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 		RF_Malloc(common, sizeof(RF_CommonLogData_t), (RF_CommonLogData_t *));
1.14       mrg 		/* destroy is in rf_paritylogging.c */
1.14       mrg 		rf_init_mutex2(common->mutex, IPL_VM);
 1.3     oster 	}
 1.3     oster 	common->next = NULL;
 1.3     oster 	return (common);
 1.3     oster }
 1.3     oster
1.10     perry static void
 1.3     oster FreeParityLogCommonData(RF_CommonLogData_t * common)
 1.3     oster {
 1.3     oster 	RF_Raid_t *raidPtr;
 1.3     oster
 1.3     oster 	/* Insert a single struct for holding parity log information (data)
 1.3     oster 	 * into the free list (rf_parityLogDiskQueue.freeCommonList).
 1.3     oster 	 * NON-BLOCKING */
 1.3     oster
 1.3     oster 	raidPtr = common->raidPtr;
1.15       mrg 	rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	common->next = raidPtr->parityLogDiskQueue.freeCommonList;
 1.3     oster 	raidPtr->parityLogDiskQueue.freeCommonList = common;
1.15       mrg 	rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster }
 1.3     oster
 1.3     oster static RF_ParityLogData_t *
 1.3     oster AllocParityLogData(RF_Raid_t * raidPtr)
 1.3     oster {
 1.3     oster 	RF_ParityLogData_t *data = NULL;
 1.3     oster
 1.3     oster 	/* Return a struct for holding parity log information from the free
 1.3     oster 	 * list (rf_parityLogDiskQueue.freeList).  If the free list is empty,
 1.3     oster 	 * call RF_Malloc to create a new structure. NON-BLOCKING */
 1.3     oster
1.15       mrg 	rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	if (raidPtr->parityLogDiskQueue.freeDataList) {
 1.3     oster 		data = raidPtr->parityLogDiskQueue.freeDataList;
 1.3     oster 		raidPtr->parityLogDiskQueue.freeDataList = raidPtr->parityLogDiskQueue.freeDataList->next;
1.15       mrg 		rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	} else {
1.15       mrg 		rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 		RF_Malloc(data, sizeof(RF_ParityLogData_t), (RF_ParityLogData_t *));
 1.3     oster 	}
 1.3     oster 	data->next = NULL;
 1.3     oster 	data->prev = NULL;
 1.3     oster 	return (data);
 1.3     oster }
 1.3     oster
 1.3     oster
1.10     perry static void
 1.3     oster FreeParityLogData(RF_ParityLogData_t * data)
 1.3     oster {
 1.3     oster 	RF_ParityLogData_t *nextItem;
 1.3     oster 	RF_Raid_t *raidPtr;
 1.3     oster
 1.3     oster 	/* Insert a linked list of structs for holding parity log information
 1.3     oster 	 * (data) into the free list (parityLogDiskQueue.freeList).
 1.3     oster 	 * NON-BLOCKING */
 1.3     oster
 1.3     oster 	raidPtr = data->common->raidPtr;
1.15       mrg 	rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	while (data) {
 1.3     oster 		nextItem = data->next;
 1.3     oster 		data->next = raidPtr->parityLogDiskQueue.freeDataList;
 1.3     oster 		raidPtr->parityLogDiskQueue.freeDataList = data;
 1.3     oster 		data = nextItem;
 1.3     oster 	}
1.15       mrg 	rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster }
 1.3     oster
 1.3     oster
1.10     perry static void
 1.3     oster EnqueueParityLogData(
 1.3     oster     RF_ParityLogData_t * data,
 1.3     oster     RF_ParityLogData_t ** head,
 1.3     oster     RF_ParityLogData_t ** tail)
 1.3     oster {
 1.3     oster 	RF_Raid_t *raidPtr;
 1.3     oster
 1.3     oster 	/* Insert an in-core parity log (*data) into the head of a disk queue
 1.3     oster 	 * (*head, *tail). NON-BLOCKING */
 1.3     oster
 1.3     oster 	raidPtr = data->common->raidPtr;
 1.3     oster 	if (rf_parityLogDebug)
 1.3     oster 		printf("[enqueueing parity log data, region %d, raidAddress %d, numSector %d]\n", data->regionID, (int) data->diskAddress.raidAddress, (int) data->diskAddress.numSector);
 1.3     oster 	RF_ASSERT(data->prev == NULL);
 1.3     oster 	RF_ASSERT(data->next == NULL);
1.15       mrg 	rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	if (*head) {
 1.3     oster 		/* insert into head of queue */
 1.3     oster 		RF_ASSERT((*head)->prev == NULL);
 1.3     oster 		RF_ASSERT((*tail)->next == NULL);
 1.3     oster 		data->next = *head;
 1.3     oster 		(*head)->prev = data;
 1.3     oster 		*head = data;
 1.3     oster 	} else {
 1.3     oster 		/* insert into empty list */
 1.3     oster 		RF_ASSERT(*head == NULL);
 1.3     oster 		RF_ASSERT(*tail == NULL);
 1.3     oster 		*head = data;
 1.3     oster 		*tail = data;
 1.3     oster 	}
 1.3     oster 	RF_ASSERT((*head)->prev == NULL);
 1.3     oster 	RF_ASSERT((*tail)->next == NULL);
1.15       mrg 	rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster }
 1.3     oster
 1.3     oster static RF_ParityLogData_t *
 1.3     oster DequeueParityLogData(
 1.3     oster     RF_Raid_t * raidPtr,
 1.3     oster     RF_ParityLogData_t ** head,
 1.3     oster     RF_ParityLogData_t ** tail,
 1.3     oster     int ignoreLocks)
 1.3     oster {
 1.3     oster 	RF_ParityLogData_t *data;
 1.3     oster
 1.3     oster 	/* Remove and return an in-core parity log from the tail of a disk
 1.3     oster 	 * queue (*head, *tail). NON-BLOCKING */
 1.3     oster
 1.3     oster 	/* remove from tail, preserving FIFO order */
 1.3     oster 	if (!ignoreLocks)
1.15       mrg 		rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	data = *tail;
 1.3     oster 	if (data) {
 1.3     oster 		if (*head == *tail) {
 1.3     oster 			/* removing last item from queue */
 1.3     oster 			*head = NULL;
 1.3     oster 			*tail = NULL;
 1.3     oster 		} else {
 1.3     oster 			*tail = (*tail)->prev;
 1.3     oster 			(*tail)->next = NULL;
 1.3     oster 			RF_ASSERT((*head)->prev == NULL);
 1.3     oster 			RF_ASSERT((*tail)->next == NULL);
 1.3     oster 		}
 1.3     oster 		data->next = NULL;
 1.3     oster 		data->prev = NULL;
 1.3     oster 		if (rf_parityLogDebug)
 1.3     oster 			printf("[dequeueing parity log data, region %d, raidAddress %d, numSector %d]\n", data->regionID, (int) data->diskAddress.raidAddress, (int) data->diskAddress.numSector);
 1.3     oster 	}
 1.3     oster 	if (*head) {
 1.3     oster 		RF_ASSERT((*head)->prev == NULL);
 1.3     oster 		RF_ASSERT((*tail)->next == NULL);
 1.3     oster 	}
 1.3     oster 	if (!ignoreLocks)
1.15       mrg 		rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	return (data);
 1.3     oster }
 1.3     oster
 1.3     oster
1.10     perry static void
 1.3     oster RequeueParityLogData(
 1.3     oster     RF_ParityLogData_t * data,
 1.3     oster     RF_ParityLogData_t ** head,
 1.3     oster     RF_ParityLogData_t ** tail)
 1.3     oster {
 1.3     oster 	RF_Raid_t *raidPtr;
 1.3     oster
 1.3     oster 	/* Insert an in-core parity log (*data) into the tail of a disk queue
 1.3     oster 	 * (*head, *tail). NON-BLOCKING */
 1.3     oster
 1.3     oster 	raidPtr = data->common->raidPtr;
 1.3     oster 	RF_ASSERT(data);
 1.3     oster 	if (rf_parityLogDebug)
 1.3     oster 		printf("[requeueing parity log data, region %d, raidAddress %d, numSector %d]\n", data->regionID, (int) data->diskAddress.raidAddress, (int) data->diskAddress.numSector);
1.15       mrg 	rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	if (*tail) {
 1.3     oster 		/* append to tail of list */
 1.3     oster 		data->prev = *tail;
 1.3     oster 		data->next = NULL;
 1.3     oster 		(*tail)->next = data;
 1.3     oster 		*tail = data;
 1.3     oster 	} else {
 1.3     oster 		/* inserting into an empty list */
 1.3     oster 		*head = data;
 1.3     oster 		*tail = data;
 1.3     oster 		(*head)->prev = NULL;
 1.3     oster 		(*tail)->next = NULL;
 1.3     oster 	}
 1.3     oster 	RF_ASSERT((*head)->prev == NULL);
 1.3     oster 	RF_ASSERT((*tail)->next == NULL);
1.15       mrg 	rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster }
 1.3     oster
 1.3     oster RF_ParityLogData_t *
 1.3     oster rf_CreateParityLogData(
 1.3     oster     RF_ParityRecordType_t operation,
 1.3     oster     RF_PhysDiskAddr_t * pda,
1.13  christos     void *bufPtr,
 1.3     oster     RF_Raid_t * raidPtr,
 1.3     oster     int (*wakeFunc) (RF_DagNode_t * node, int status),
 1.3     oster     void *wakeArg,
 1.3     oster     RF_AccTraceEntry_t * tracerec,
 1.3     oster     RF_Etimer_t startTime)
 1.3     oster {
 1.3     oster 	RF_ParityLogData_t *data, *resultHead = NULL, *resultTail = NULL;
 1.3     oster 	RF_CommonLogData_t *common;
 1.3     oster 	RF_PhysDiskAddr_t *diskAddress;
 1.3     oster 	int     boundary, offset = 0;
 1.3     oster
 1.3     oster 	/* Return an initialized struct of info to be logged. Build one item
 1.3     oster 	 * per physical disk address, one item per region.
1.10     perry 	 *
 1.3     oster 	 * NON-BLOCKING */
 1.3     oster
 1.3     oster 	diskAddress = pda;
 1.3     oster 	common = AllocParityLogCommonData(raidPtr);
 1.3     oster 	RF_ASSERT(common);
 1.3     oster
 1.3     oster 	common->operation = operation;
 1.3     oster 	common->bufPtr = bufPtr;
 1.3     oster 	common->raidPtr = raidPtr;
 1.3     oster 	common->wakeFunc = wakeFunc;
 1.3     oster 	common->wakeArg = wakeArg;
 1.3     oster 	common->tracerec = tracerec;
 1.3     oster 	common->startTime = startTime;
 1.3     oster 	common->cnt = 0;
 1.3     oster
 1.3     oster 	if (rf_parityLogDebug)
 1.3     oster 		printf("[entering CreateParityLogData]\n");
 1.3     oster 	while (diskAddress) {
 1.3     oster 		common->cnt++;
 1.3     oster 		data = AllocParityLogData(raidPtr);
 1.3     oster 		RF_ASSERT(data);
 1.3     oster 		data->common = common;
 1.3     oster 		data->next = NULL;
 1.3     oster 		data->prev = NULL;
 1.3     oster 		data->regionID = rf_MapRegionIDParityLogging(raidPtr, diskAddress->startSector);
 1.3     oster 		if (data->regionID == rf_MapRegionIDParityLogging(raidPtr, diskAddress->startSector + diskAddress->numSector - 1)) {
 1.3     oster 			/* disk address does not cross a region boundary */
 1.3     oster 			data->diskAddress = *diskAddress;
 1.3     oster 			data->bufOffset = offset;
 1.3     oster 			offset = offset + diskAddress->numSector;
 1.3     oster 			EnqueueParityLogData(data, &resultHead, &resultTail);
 1.3     oster 			/* adjust disk address */
 1.3     oster 			diskAddress = diskAddress->next;
 1.3     oster 		} else {
 1.3     oster 			/* disk address crosses a region boundary */
 1.3     oster 			/* find address where region is crossed */
 1.3     oster 			boundary = 0;
 1.3     oster 			while (data->regionID == rf_MapRegionIDParityLogging(raidPtr, diskAddress->startSector + boundary))
 1.3     oster 				boundary++;
 1.3     oster
 1.3     oster 			/* enter data before the boundary */
 1.3     oster 			data->diskAddress = *diskAddress;
 1.3     oster 			data->diskAddress.numSector = boundary;
 1.3     oster 			data->bufOffset = offset;
 1.3     oster 			offset += boundary;
 1.3     oster 			EnqueueParityLogData(data, &resultHead, &resultTail);
 1.3     oster 			/* adjust disk address */
 1.3     oster 			diskAddress->startSector += boundary;
 1.3     oster 			diskAddress->numSector -= boundary;
 1.3     oster 		}
 1.1     oster 	}
 1.3     oster 	if (rf_parityLogDebug)
 1.3     oster 		printf("[leaving CreateParityLogData]\n");
 1.3     oster 	return (resultHead);
 1.3     oster }
 1.3     oster
 1.3     oster
 1.3     oster RF_ParityLogData_t *
 1.3     oster rf_SearchAndDequeueParityLogData(
 1.3     oster     RF_Raid_t * raidPtr,
 1.3     oster     int regionID,
 1.3     oster     RF_ParityLogData_t ** head,
 1.3     oster     RF_ParityLogData_t ** tail,
 1.3     oster     int ignoreLocks)
 1.3     oster {
 1.3     oster 	RF_ParityLogData_t *w;
 1.3     oster
 1.3     oster 	/* Remove and return an in-core parity log from a specified region
 1.3     oster 	 * (regionID). If a matching log is not found, return NULL.
1.10     perry 	 *
 1.3     oster 	 * NON-BLOCKING. */
 1.3     oster
 1.3     oster 	/* walk backward through a list, looking for an entry with a matching
 1.3     oster 	 * region ID */
 1.3     oster 	if (!ignoreLocks)
1.15       mrg 		rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	w = (*tail);
 1.3     oster 	while (w) {
 1.3     oster 		if (w->regionID == regionID) {
 1.3     oster 			/* remove an element from the list */
 1.3     oster 			if (w == *tail) {
 1.3     oster 				if (*head == *tail) {
 1.3     oster 					/* removing only element in the list */
 1.3     oster 					*head = NULL;
 1.3     oster 					*tail = NULL;
 1.3     oster 				} else {
 1.3     oster 					/* removing last item in the list */
 1.3     oster 					*tail = (*tail)->prev;
 1.3     oster 					(*tail)->next = NULL;
 1.3     oster 					RF_ASSERT((*head)->prev == NULL);
 1.3     oster 					RF_ASSERT((*tail)->next == NULL);
 1.3     oster 				}
 1.3     oster 			} else {
 1.3     oster 				if (w == *head) {
 1.3     oster 					/* removing first item in the list */
 1.3     oster 					*head = (*head)->next;
 1.3     oster 					(*head)->prev = NULL;
 1.3     oster 					RF_ASSERT((*head)->prev == NULL);
 1.3     oster 					RF_ASSERT((*tail)->next == NULL);
 1.3     oster 				} else {
 1.3     oster 					/* removing an item from the middle of
 1.3     oster 					 * the list */
 1.3     oster 					w->prev->next = w->next;
 1.3     oster 					w->next->prev = w->prev;
 1.3     oster 					RF_ASSERT((*head)->prev == NULL);
 1.3     oster 					RF_ASSERT((*tail)->next == NULL);
 1.3     oster 				}
 1.3     oster 			}
 1.3     oster 			w->prev = NULL;
 1.3     oster 			w->next = NULL;
 1.3     oster 			if (rf_parityLogDebug)
 1.3     oster 				printf("[dequeueing parity log data, region %d, raidAddress %d, numSector %d]\n", w->regionID, (int) w->diskAddress.raidAddress, (int) w->diskAddress.numSector);
 1.3     oster 			return (w);
 1.3     oster 		} else
 1.3     oster 			w = w->prev;
 1.3     oster 	}
 1.3     oster 	if (!ignoreLocks)
1.15       mrg 		rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	return (NULL);
 1.3     oster }
 1.3     oster
 1.3     oster static RF_ParityLogData_t *
 1.3     oster DequeueMatchingLogData(
 1.3     oster     RF_Raid_t * raidPtr,
 1.3     oster     RF_ParityLogData_t ** head,
 1.3     oster     RF_ParityLogData_t ** tail)
 1.3     oster {
 1.3     oster 	RF_ParityLogData_t *logDataList, *logData;
 1.3     oster 	int     regionID;
 1.3     oster
 1.3     oster 	/* Remove and return an in-core parity log from the tail of a disk
 1.3     oster 	 * queue (*head, *tail).  Then remove all matching (identical
 1.3     oster 	 * regionIDs) logData and return as a linked list.
1.10     perry 	 *
 1.3     oster 	 * NON-BLOCKING */
 1.3     oster
 1.3     oster 	logDataList = DequeueParityLogData(raidPtr, head, tail, RF_TRUE);
 1.3     oster 	if (logDataList) {
 1.3     oster 		regionID = logDataList->regionID;
 1.3     oster 		logData = logDataList;
 1.3     oster 		logData->next = rf_SearchAndDequeueParityLogData(raidPtr, regionID, head, tail, RF_TRUE);
 1.3     oster 		while (logData->next) {
 1.3     oster 			logData = logData->next;
 1.3     oster 			logData->next = rf_SearchAndDequeueParityLogData(raidPtr, regionID, head, tail, RF_TRUE);
 1.3     oster 		}
 1.1     oster 	}
 1.3     oster 	return (logDataList);
 1.1     oster }
 1.1     oster
 1.1     oster
 1.3     oster static RF_ParityLog_t *
 1.3     oster AcquireParityLog(
 1.3     oster     RF_ParityLogData_t * logData,
 1.3     oster     int finish)
 1.3     oster {
 1.3     oster 	RF_ParityLog_t *log = NULL;
 1.3     oster 	RF_Raid_t *raidPtr;
 1.3     oster
 1.3     oster 	/* Grab a log buffer from the pool and return it. If no buffers are
 1.3     oster 	 * available, return NULL. NON-BLOCKING */
 1.3     oster 	raidPtr = logData->common->raidPtr;
1.18       mrg 	rf_lock_mutex2(raidPtr->parityLogPool.mutex);
 1.3     oster 	if (raidPtr->parityLogPool.parityLogs) {
 1.3     oster 		log = raidPtr->parityLogPool.parityLogs;
 1.3     oster 		raidPtr->parityLogPool.parityLogs = raidPtr->parityLogPool.parityLogs->next;
 1.3     oster 		log->regionID = logData->regionID;
 1.3     oster 		log->numRecords = 0;
 1.3     oster 		log->next = NULL;
 1.3     oster 		raidPtr->logsInUse++;
 1.3     oster 		RF_ASSERT(raidPtr->logsInUse >= 0 && raidPtr->logsInUse <= raidPtr->numParityLogs);
 1.3     oster 	} else {
 1.3     oster 		/* no logs available, so place ourselves on the queue of work
 1.3     oster 		 * waiting on log buffers this is done while
 1.3     oster 		 * parityLogPool.mutex is held, to ensure synchronization with
 1.3     oster 		 * ReleaseParityLogs. */
 1.3     oster 		if (rf_parityLogDebug)
 1.3     oster 			printf("[blocked on log, region %d, finish %d]\n", logData->regionID, finish);
 1.3     oster 		if (finish)
 1.3     oster 			RequeueParityLogData(logData, &raidPtr->parityLogDiskQueue.logBlockHead, &raidPtr->parityLogDiskQueue.logBlockTail);
 1.3     oster 		else
 1.3     oster 			EnqueueParityLogData(logData, &raidPtr->parityLogDiskQueue.logBlockHead, &raidPtr->parityLogDiskQueue.logBlockTail);
 1.1     oster 	}
1.18       mrg 	rf_unlock_mutex2(raidPtr->parityLogPool.mutex);
 1.3     oster 	return (log);
 1.1     oster }
 1.1     oster
1.10     perry void
 1.3     oster rf_ReleaseParityLogs(
 1.3     oster     RF_Raid_t * raidPtr,
 1.3     oster     RF_ParityLog_t * firstLog)
 1.3     oster {
 1.3     oster 	RF_ParityLogData_t *logDataList;
 1.3     oster 	RF_ParityLog_t *log, *lastLog;
 1.3     oster 	int     cnt;
 1.1     oster
 1.3     oster 	/* Insert a linked list of parity logs (firstLog) to the free list
 1.3     oster 	 * (parityLogPool.parityLogPool)
1.10     perry 	 *
 1.3     oster 	 * NON-BLOCKING. */
 1.3     oster
 1.3     oster 	RF_ASSERT(firstLog);
 1.3     oster
 1.3     oster 	/* Before returning logs to global free list, service all requests
 1.3     oster 	 * which are blocked on logs.  Holding mutexes for parityLogPool and
 1.3     oster 	 * parityLogDiskQueue forces synchronization with AcquireParityLog(). */
1.18       mrg 	rf_lock_mutex2(raidPtr->parityLogPool.mutex);
1.15       mrg 	rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.1     oster 	logDataList = DequeueMatchingLogData(raidPtr, &raidPtr->parityLogDiskQueue.logBlockHead, &raidPtr->parityLogDiskQueue.logBlockTail);
 1.3     oster 	log = firstLog;
 1.3     oster 	if (firstLog)
 1.3     oster 		firstLog = firstLog->next;
 1.3     oster 	log->numRecords = 0;
 1.3     oster 	log->next = NULL;
 1.3     oster 	while (logDataList && log) {
1.18       mrg 		rf_unlock_mutex2(raidPtr->parityLogPool.mutex);
1.15       mrg 		rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 		rf_ParityLogAppend(logDataList, RF_TRUE, &log, RF_FALSE);
 1.3     oster 		if (rf_parityLogDebug)
 1.3     oster 			printf("[finishing up buf-blocked log data, region %d]\n", logDataList->regionID);
 1.3     oster 		if (log == NULL) {
 1.3     oster 			log = firstLog;
 1.3     oster 			if (firstLog) {
 1.3     oster 				firstLog = firstLog->next;
 1.3     oster 				log->numRecords = 0;
 1.3     oster 				log->next = NULL;
 1.3     oster 			}
 1.3     oster 		}
1.18       mrg 		rf_lock_mutex2(raidPtr->parityLogPool.mutex);
1.15       mrg 		rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 		if (log)
 1.3     oster 			logDataList = DequeueMatchingLogData(raidPtr, &raidPtr->parityLogDiskQueue.logBlockHead, &raidPtr->parityLogDiskQueue.logBlockTail);
 1.3     oster 	}
 1.3     oster 	/* return remaining logs to pool */
 1.3     oster 	if (log) {
 1.3     oster 		log->next = firstLog;
 1.3     oster 		firstLog = log;
 1.3     oster 	}
 1.3     oster 	if (firstLog) {
 1.3     oster 		lastLog = firstLog;
 1.3     oster 		raidPtr->logsInUse--;
 1.3     oster 		RF_ASSERT(raidPtr->logsInUse >= 0 && raidPtr->logsInUse <= raidPtr->numParityLogs);
 1.3     oster 		while (lastLog->next) {
 1.3     oster 			lastLog = lastLog->next;
 1.3     oster 			raidPtr->logsInUse--;
 1.3     oster 			RF_ASSERT(raidPtr->logsInUse >= 0 && raidPtr->logsInUse <= raidPtr->numParityLogs);
 1.3     oster 		}
 1.3     oster 		lastLog->next = raidPtr->parityLogPool.parityLogs;
 1.3     oster 		raidPtr->parityLogPool.parityLogs = firstLog;
 1.3     oster 		cnt = 0;
 1.3     oster 		log = raidPtr->parityLogPool.parityLogs;
 1.3     oster 		while (log) {
 1.3     oster 			cnt++;
 1.3     oster 			log = log->next;
 1.3     oster 		}
 1.3     oster 		RF_ASSERT(cnt + raidPtr->logsInUse == raidPtr->numParityLogs);
 1.1     oster 	}
1.18       mrg 	rf_unlock_mutex2(raidPtr->parityLogPool.mutex);
1.15       mrg 	rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster }
 1.1     oster
1.10     perry static void
 1.3     oster ReintLog(
 1.3     oster     RF_Raid_t * raidPtr,
 1.3     oster     int regionID,
 1.3     oster     RF_ParityLog_t * log)
 1.3     oster {
 1.3     oster 	RF_ASSERT(log);
 1.3     oster
 1.3     oster 	/* Insert an in-core parity log (log) into the disk queue of
 1.3     oster 	 * reintegration work.  Set the flag (reintInProgress) for the
 1.3     oster 	 * specified region (regionID) to indicate that reintegration is in
 1.3     oster 	 * progress for this region. NON-BLOCKING */
 1.3     oster
1.16       mrg 	rf_lock_mutex2(raidPtr->regionInfo[regionID].reintMutex);
 1.3     oster 	raidPtr->regionInfo[regionID].reintInProgress = RF_TRUE;	/* cleared when reint
 1.3     oster 									 * complete */
 1.3     oster
 1.3     oster 	if (rf_parityLogDebug)
 1.3     oster 		printf("[requesting reintegration of region %d]\n", log->regionID);
 1.3     oster 	/* move record to reintegration queue */
1.15       mrg 	rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	log->next = raidPtr->parityLogDiskQueue.reintQueue;
 1.3     oster 	raidPtr->parityLogDiskQueue.reintQueue = log;
1.16       mrg 	rf_unlock_mutex2(raidPtr->regionInfo[regionID].reintMutex);
1.15       mrg 	rf_signal_cond2(raidPtr->parityLogDiskQueue.cond);
1.15       mrg 	rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster }
 1.3     oster
1.10     perry static void
 1.3     oster FlushLog(
 1.3     oster     RF_Raid_t * raidPtr,
 1.3     oster     RF_ParityLog_t * log)
 1.3     oster {
 1.3     oster 	/* insert a core log (log) into a list of logs
 1.3     oster 	 * (parityLogDiskQueue.flushQueue) waiting to be written to disk.
 1.3     oster 	 * NON-BLOCKING */
 1.3     oster
 1.3     oster 	RF_ASSERT(log);
 1.3     oster 	RF_ASSERT(log->numRecords == raidPtr->numSectorsPerLog);
 1.3     oster 	RF_ASSERT(log->next == NULL);
 1.3     oster 	/* move log to flush queue */
1.15       mrg 	rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	log->next = raidPtr->parityLogDiskQueue.flushQueue;
 1.3     oster 	raidPtr->parityLogDiskQueue.flushQueue = log;
1.15       mrg 	rf_signal_cond2(raidPtr->parityLogDiskQueue.cond);
1.15       mrg 	rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster }
 1.3     oster
1.10     perry static int
 1.3     oster DumpParityLogToDisk(
 1.3     oster     int finish,
 1.3     oster     RF_ParityLogData_t * logData)
 1.3     oster {
 1.3     oster 	int     i, diskCount, regionID = logData->regionID;
 1.3     oster 	RF_ParityLog_t *log;
 1.3     oster 	RF_Raid_t *raidPtr;
 1.3     oster
 1.3     oster 	raidPtr = logData->common->raidPtr;
 1.3     oster
 1.3     oster 	/* Move a core log to disk.  If the log disk is full, initiate
 1.3     oster 	 * reintegration.
1.10     perry 	 *
 1.3     oster 	 * Return (0) if we can enqueue the dump immediately, otherwise return
 1.3     oster 	 * (1) to indicate we are blocked on reintegration and control of the
 1.3     oster 	 * thread should be relinquished.
1.10     perry 	 *
 1.3     oster 	 * Caller must hold regionInfo[regionID].mutex
1.10     perry 	 *
 1.3     oster 	 * NON-BLOCKING */
 1.3     oster
1.17       mrg 	RF_ASSERT(rf_owned_mutex2(raidPtr->regionInfo[regionID].mutex));
1.17       mrg
 1.3     oster 	if (rf_parityLogDebug)
 1.3     oster 		printf("[dumping parity log to disk, region %d]\n", regionID);
 1.3     oster 	log = raidPtr->regionInfo[regionID].coreLog;
 1.3     oster 	RF_ASSERT(log->numRecords == raidPtr->numSectorsPerLog);
 1.3     oster 	RF_ASSERT(log->next == NULL);
 1.3     oster
 1.3     oster 	/* if reintegration is in progress, must queue work */
1.16       mrg 	rf_lock_mutex2(raidPtr->regionInfo[regionID].reintMutex);
 1.3     oster 	if (raidPtr->regionInfo[regionID].reintInProgress) {
 1.3     oster 		/* Can not proceed since this region is currently being
 1.3     oster 		 * reintegrated. We can not block, so queue remaining work and
 1.3     oster 		 * return */
 1.3     oster 		if (rf_parityLogDebug)
 1.3     oster 			printf("[region %d waiting on reintegration]\n", regionID);
 1.3     oster 		/* XXX not sure about the use of finish - shouldn't this
 1.3     oster 		 * always be "Enqueue"? */
 1.3     oster 		if (finish)
 1.3     oster 			RequeueParityLogData(logData, &raidPtr->parityLogDiskQueue.reintBlockHead, &raidPtr->parityLogDiskQueue.reintBlockTail);
 1.3     oster 		else
 1.3     oster 			EnqueueParityLogData(logData, &raidPtr->parityLogDiskQueue.reintBlockHead, &raidPtr->parityLogDiskQueue.reintBlockTail);
1.16       mrg 		rf_unlock_mutex2(raidPtr->regionInfo[regionID].reintMutex);
 1.3     oster 		return (1);	/* relenquish control of this thread */
 1.3     oster 	}
1.16       mrg 	rf_unlock_mutex2(raidPtr->regionInfo[regionID].reintMutex);
 1.3     oster 	raidPtr->regionInfo[regionID].coreLog = NULL;
 1.3     oster 	if ((raidPtr->regionInfo[regionID].diskCount) < raidPtr->regionInfo[regionID].capacity)
 1.3     oster 		/* IMPORTANT!! this loop bound assumes region disk holds an
 1.3     oster 		 * integral number of core logs */
 1.3     oster 	{
 1.3     oster 		/* update disk map for this region */
 1.3     oster 		diskCount = raidPtr->regionInfo[regionID].diskCount;
 1.3     oster 		for (i = 0; i < raidPtr->numSectorsPerLog; i++) {
 1.3     oster 			raidPtr->regionInfo[regionID].diskMap[i + diskCount].operation = log->records[i].operation;
 1.3     oster 			raidPtr->regionInfo[regionID].diskMap[i + diskCount].parityAddr = log->records[i].parityAddr;
 1.3     oster 		}
 1.3     oster 		log->diskOffset = diskCount;
 1.3     oster 		raidPtr->regionInfo[regionID].diskCount += raidPtr->numSectorsPerLog;
 1.3     oster 		FlushLog(raidPtr, log);
 1.3     oster 	} else {
 1.3     oster 		/* no room for log on disk, send it to disk manager and
 1.3     oster 		 * request reintegration */
 1.3     oster 		RF_ASSERT(raidPtr->regionInfo[regionID].diskCount == raidPtr->regionInfo[regionID].capacity);
 1.3     oster 		ReintLog(raidPtr, regionID, log);
 1.3     oster 	}
 1.3     oster 	if (rf_parityLogDebug)
 1.3     oster 		printf("[finished dumping parity log to disk, region %d]\n", regionID);
 1.3     oster 	return (0);
 1.3     oster }
 1.3     oster
1.10     perry int
 1.3     oster rf_ParityLogAppend(
 1.3     oster     RF_ParityLogData_t * logData,
 1.3     oster     int finish,
 1.3     oster     RF_ParityLog_t ** incomingLog,
 1.3     oster     int clearReintFlag)
 1.3     oster {
 1.3     oster 	int     regionID, logItem, itemDone;
 1.3     oster 	RF_ParityLogData_t *item;
 1.3     oster 	int     punt, done = RF_FALSE;
 1.3     oster 	RF_ParityLog_t *log;
 1.3     oster 	RF_Raid_t *raidPtr;
 1.3     oster 	RF_Etimer_t timer;
 1.3     oster 	int     (*wakeFunc) (RF_DagNode_t * node, int status);
 1.3     oster 	void   *wakeArg;
 1.3     oster
 1.3     oster 	/* Add parity to the appropriate log, one sector at a time. This
 1.3     oster 	 * routine is called is called by dag functions ParityLogUpdateFunc
 1.3     oster 	 * and ParityLogOverwriteFunc and therefore MUST BE NONBLOCKING.
1.10     perry 	 *
 1.3     oster 	 * Parity to be logged is contained in a linked-list (logData).  When
 1.3     oster 	 * this routine returns, every sector in the list will be in one of
 1.3     oster 	 * three places: 1) entered into the parity log 2) queued, waiting on
 1.3     oster 	 * reintegration 3) queued, waiting on a core log
1.10     perry 	 *
 1.3     oster 	 * Blocked work is passed to the ParityLoggingDiskManager for completion.
 1.3     oster 	 * Later, as conditions which required the block are removed, the work
 1.3     oster 	 * reenters this routine with the "finish" parameter set to "RF_TRUE."
1.10     perry 	 *
 1.3     oster 	 * NON-BLOCKING */
 1.3     oster
 1.3     oster 	raidPtr = logData->common->raidPtr;
 1.3     oster 	/* lock the region for the first item in logData */
 1.3     oster 	RF_ASSERT(logData != NULL);
 1.3     oster 	regionID = logData->regionID;
1.17       mrg 	rf_lock_mutex2(raidPtr->regionInfo[regionID].mutex);
 1.3     oster 	RF_ASSERT(raidPtr->regionInfo[regionID].loggingEnabled);
 1.3     oster
 1.3     oster 	if (clearReintFlag) {
 1.3     oster 		/* Enable flushing for this region.  Holding both locks
 1.3     oster 		 * provides a synchronization barrier with DumpParityLogToDisk */
1.16       mrg 		rf_lock_mutex2(raidPtr->regionInfo[regionID].reintMutex);
1.15       mrg 		/* XXXmrg need this? */
1.15       mrg 		rf_lock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 		RF_ASSERT(raidPtr->regionInfo[regionID].reintInProgress == RF_TRUE);
 1.3     oster 		raidPtr->regionInfo[regionID].diskCount = 0;
 1.3     oster 		raidPtr->regionInfo[regionID].reintInProgress = RF_FALSE;
1.16       mrg 		rf_unlock_mutex2(raidPtr->regionInfo[regionID].reintMutex);	/* flushing is now
 1.3     oster 										 * enabled */
1.15       mrg 		/* XXXmrg need this? */
1.15       mrg 		rf_unlock_mutex2(raidPtr->parityLogDiskQueue.mutex);
 1.3     oster 	}
 1.3     oster 	/* process each item in logData */
 1.3     oster 	while (logData) {
 1.3     oster 		/* remove an item from logData */
 1.3     oster 		item = logData;
 1.3     oster 		logData = logData->next;
 1.3     oster 		item->next = NULL;
 1.3     oster 		item->prev = NULL;
 1.3     oster
 1.3     oster 		if (rf_parityLogDebug)
 1.3     oster 			printf("[appending parity log data, region %d, raidAddress %d, numSector %d]\n", item->regionID, (int) item->diskAddress.raidAddress, (int) item->diskAddress.numSector);
 1.3     oster
 1.3     oster 		/* see if we moved to a new region */
 1.3     oster 		if (regionID != item->regionID) {
1.17       mrg 			rf_unlock_mutex2(raidPtr->regionInfo[regionID].mutex);
 1.3     oster 			regionID = item->regionID;
1.17       mrg 			rf_lock_mutex2(raidPtr->regionInfo[regionID].mutex);
 1.3     oster 			RF_ASSERT(raidPtr->regionInfo[regionID].loggingEnabled);
 1.3     oster 		}
 1.3     oster 		punt = RF_FALSE;/* Set to RF_TRUE if work is blocked.  This
 1.3     oster 				 * can happen in one of two ways: 1) no core
 1.3     oster 				 * log (AcquireParityLog) 2) waiting on
 1.3     oster 				 * reintegration (DumpParityLogToDisk) If punt
 1.3     oster 				 * is RF_TRUE, the dataItem was queued, so
 1.3     oster 				 * skip to next item. */
 1.3     oster
 1.3     oster 		/* process item, one sector at a time, until all sectors
 1.3     oster 		 * processed or we punt */
 1.3     oster 		if (item->diskAddress.numSector > 0)
 1.3     oster 			done = RF_FALSE;
 1.3     oster 		else
 1.3     oster 			RF_ASSERT(0);
 1.3     oster 		while (!punt && !done) {
 1.3     oster 			/* verify that a core log exists for this region */
 1.3     oster 			if (!raidPtr->regionInfo[regionID].coreLog) {
 1.3     oster 				/* Attempt to acquire a parity log. If
 1.3     oster 				 * acquisition fails, queue remaining work in
 1.3     oster 				 * data item and move to nextItem. */
 1.3     oster 				if (incomingLog)
 1.3     oster 					if (*incomingLog) {
 1.3     oster 						RF_ASSERT((*incomingLog)->next == NULL);
 1.3     oster 						raidPtr->regionInfo[regionID].coreLog = *incomingLog;
 1.3     oster 						raidPtr->regionInfo[regionID].coreLog->regionID = regionID;
 1.3     oster 						*incomingLog = NULL;
 1.3     oster 					} else
 1.3     oster 						raidPtr->regionInfo[regionID].coreLog = AcquireParityLog(item, finish);
 1.3     oster 				else
 1.3     oster 					raidPtr->regionInfo[regionID].coreLog = AcquireParityLog(item, finish);
 1.3     oster 				/* Note: AcquireParityLog either returns a log
 1.3     oster 				 * or enqueues currentItem */
 1.3     oster 			}
 1.3     oster 			if (!raidPtr->regionInfo[regionID].coreLog)
 1.3     oster 				punt = RF_TRUE;	/* failed to find a core log */
 1.3     oster 			else {
 1.3     oster 				RF_ASSERT(raidPtr->regionInfo[regionID].coreLog->next == NULL);
 1.3     oster 				/* verify that the log has room for new
 1.3     oster 				 * entries */
 1.3     oster 				/* if log is full, dump it to disk and grab a
 1.3     oster 				 * new log */
 1.3     oster 				if (raidPtr->regionInfo[regionID].coreLog->numRecords == raidPtr->numSectorsPerLog) {
 1.3     oster 					/* log is full, dump it to disk */
 1.3     oster 					if (DumpParityLogToDisk(finish, item))
 1.3     oster 						punt = RF_TRUE;	/* dump unsuccessful,
 1.3     oster 								 * blocked on
 1.3     oster 								 * reintegration */
 1.3     oster 					else {
 1.3     oster 						/* dump was successful */
 1.3     oster 						if (incomingLog)
 1.3     oster 							if (*incomingLog) {
 1.3     oster 								RF_ASSERT((*incomingLog)->next == NULL);
 1.3     oster 								raidPtr->regionInfo[regionID].coreLog = *incomingLog;
 1.3     oster 								raidPtr->regionInfo[regionID].coreLog->regionID = regionID;
 1.3     oster 								*incomingLog = NULL;
 1.3     oster 							} else
 1.3     oster 								raidPtr->regionInfo[regionID].coreLog = AcquireParityLog(item, finish);
 1.3     oster 						else
 1.3     oster 							raidPtr->regionInfo[regionID].coreLog = AcquireParityLog(item, finish);
 1.3     oster 						/* if a core log is not
 1.3     oster 						 * available, must queue work
 1.3     oster 						 * and return */
 1.3     oster 						if (!raidPtr->regionInfo[regionID].coreLog)
 1.3     oster 							punt = RF_TRUE;	/* blocked on log
 1.3     oster 									 * availability */
 1.3     oster 					}
 1.3     oster 				}
 1.3     oster 			}
 1.3     oster 			/* if we didn't punt on this item, attempt to add a
 1.3     oster 			 * sector to the core log */
 1.3     oster 			if (!punt) {
 1.3     oster 				RF_ASSERT(raidPtr->regionInfo[regionID].coreLog->next == NULL);
 1.3     oster 				/* at this point, we have a core log with
 1.3     oster 				 * enough room for a sector */
 1.3     oster 				/* copy a sector into the log */
 1.3     oster 				log = raidPtr->regionInfo[regionID].coreLog;
 1.3     oster 				RF_ASSERT(log->numRecords < raidPtr->numSectorsPerLog);
 1.3     oster 				logItem = log->numRecords++;
 1.3     oster 				log->records[logItem].parityAddr = item->diskAddress;
 1.3     oster 				RF_ASSERT(log->records[logItem].parityAddr.startSector >= raidPtr->regionInfo[regionID].parityStartAddr);
 1.3     oster 				RF_ASSERT(log->records[logItem].parityAddr.startSector < raidPtr->regionInfo[regionID].parityStartAddr + raidPtr->regionInfo[regionID].numSectorsParity);
 1.3     oster 				log->records[logItem].parityAddr.numSector = 1;
 1.3     oster 				log->records[logItem].operation = item->common->operation;
1.13  christos 				memcpy((char *)log->bufPtr + (logItem * (1 << item->common->raidPtr->logBytesPerSector)), ((char *)item->common->bufPtr + (item->bufOffset++ * (1 << item->common->raidPtr->logBytesPerSector))), (1 << item->common->raidPtr->logBytesPerSector));
 1.3     oster 				item->diskAddress.numSector--;
 1.3     oster 				item->diskAddress.startSector++;
 1.3     oster 				if (item->diskAddress.numSector == 0)
 1.3     oster 					done = RF_TRUE;
 1.3     oster 			}
 1.3     oster 		}
 1.1     oster
 1.3     oster 		if (!punt) {
 1.3     oster 			/* Processed this item completely, decrement count of
 1.3     oster 			 * items to be processed. */
 1.3     oster 			RF_ASSERT(item->diskAddress.numSector == 0);
1.14       mrg 			rf_lock_mutex2(item->common->mutex);
 1.3     oster 			item->common->cnt--;
 1.3     oster 			if (item->common->cnt == 0)
 1.3     oster 				itemDone = RF_TRUE;
 1.1     oster 			else
 1.3     oster 				itemDone = RF_FALSE;
1.14       mrg 			rf_unlock_mutex2(item->common->mutex);
 1.3     oster 			if (itemDone) {
 1.3     oster 				/* Finished processing all log data for this
 1.3     oster 				 * IO Return structs to free list and invoke
 1.3     oster 				 * wakeup function. */
 1.3     oster 				timer = item->common->startTime;	/* grab initial value of
 1.3     oster 									 * timer */
 1.3     oster 				RF_ETIMER_STOP(timer);
 1.3     oster 				RF_ETIMER_EVAL(timer);
 1.3     oster 				item->common->tracerec->plog_us += RF_ETIMER_VAL_US(timer);
 1.3     oster 				if (rf_parityLogDebug)
 1.3     oster 					printf("[waking process for region %d]\n", item->regionID);
 1.3     oster 				wakeFunc = item->common->wakeFunc;
 1.3     oster 				wakeArg = item->common->wakeArg;
 1.3     oster 				FreeParityLogCommonData(item->common);
 1.3     oster 				FreeParityLogData(item);
 1.3     oster 				(wakeFunc) (wakeArg, 0);
 1.3     oster 			} else
 1.3     oster 				FreeParityLogData(item);
 1.3     oster 		}
 1.1     oster 	}
1.17       mrg 	rf_unlock_mutex2(raidPtr->regionInfo[regionID].mutex);
 1.3     oster 	if (rf_parityLogDebug)
 1.3     oster 		printf("[exiting ParityLogAppend]\n");
 1.3     oster 	return (0);
 1.3     oster }
 1.1     oster
 1.1     oster
1.10     perry void
 1.3     oster rf_EnableParityLogging(RF_Raid_t * raidPtr)
 1.3     oster {
 1.3     oster 	int     regionID;
 1.1     oster
 1.3     oster 	for (regionID = 0; regionID < rf_numParityRegions; regionID++) {
1.17       mrg 		rf_lock_mutex2(raidPtr->regionInfo[regionID].mutex);
 1.3     oster 		raidPtr->regionInfo[regionID].loggingEnabled = RF_TRUE;
1.17       mrg 		rf_unlock_mutex2(raidPtr->regionInfo[regionID].mutex);
 1.3     oster 	}
 1.3     oster 	if (rf_parityLogDebug)
 1.3     oster 		printf("[parity logging enabled]\n");
 1.1     oster }
 1.3     oster #endif				/* RF_INCLUDE_PARITYLOGGING > 0 */