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world. This should be considered highly experimental. Approved-by: re
976 lines
38 KiB
C
976 lines
38 KiB
C
/* $FreeBSD$ */
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/* $NetBSD: rf_evenodd_dagfuncs.c,v 1.7 2001/01/26 03:50:53 oster Exp $ */
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/*
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* Copyright (c) 1995 Carnegie-Mellon University.
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* All rights reserved.
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*
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* Author: ChangMing Wu
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*
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* Permission to use, copy, modify and distribute this software and
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* its documentation is hereby granted, provided that both the copyright
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* notice and this permission notice appear in all copies of the
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* software, derivative works or modified versions, and any portions
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* thereof, and that both notices appear in supporting documentation.
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*
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* CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
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* CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND
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* FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
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*
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* Carnegie Mellon requests users of this software to return to
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*
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* Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
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* School of Computer Science
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* Carnegie Mellon University
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* Pittsburgh PA 15213-3890
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*
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* any improvements or extensions that they make and grant Carnegie the
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* rights to redistribute these changes.
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*/
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/*
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* Code for RAID-EVENODD architecture.
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*/
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#include <dev/raidframe/rf_archs.h>
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#if RF_INCLUDE_EVENODD > 0
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#include <dev/raidframe/rf_types.h>
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#include <dev/raidframe/rf_raid.h>
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#include <dev/raidframe/rf_dag.h>
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#include <dev/raidframe/rf_dagffrd.h>
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#include <dev/raidframe/rf_dagffwr.h>
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#include <dev/raidframe/rf_dagdegrd.h>
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#include <dev/raidframe/rf_dagdegwr.h>
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#include <dev/raidframe/rf_dagutils.h>
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#include <dev/raidframe/rf_dagfuncs.h>
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#include <dev/raidframe/rf_etimer.h>
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#include <dev/raidframe/rf_general.h>
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#include <dev/raidframe/rf_configure.h>
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#include <dev/raidframe/rf_parityscan.h>
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#include <dev/raidframe/rf_evenodd.h>
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#include <dev/raidframe/rf_evenodd_dagfuncs.h>
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/* These redundant functions are for small write */
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RF_RedFuncs_t rf_EOSmallWritePFuncs = {rf_RegularXorFunc, "Regular Old-New P", rf_SimpleXorFunc, "Simple Old-New P"};
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RF_RedFuncs_t rf_EOSmallWriteEFuncs = {rf_RegularONEFunc, "Regular Old-New E", rf_SimpleONEFunc, "Regular Old-New E"};
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/* These redundant functions are for degraded read */
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RF_RedFuncs_t rf_eoPRecoveryFuncs = {rf_RecoveryXorFunc, "Recovery Xr", rf_RecoveryXorFunc, "Recovery Xr"};
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RF_RedFuncs_t rf_eoERecoveryFuncs = {rf_RecoveryEFunc, "Recovery E Func", rf_RecoveryEFunc, "Recovery E Func"};
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/**********************************************************************************************
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* the following encoding node functions is used in EO_000_CreateLargeWriteDAG
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**********************************************************************************************/
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int
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rf_RegularPEFunc(node)
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RF_DagNode_t *node;
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{
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rf_RegularESubroutine(node, node->results[1]);
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rf_RegularXorFunc(node);/* does the wakeup here! */
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#if 1
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return (0); /* XXX This was missing... GO */
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#endif
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}
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/************************************************************************************************
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* For EO_001_CreateSmallWriteDAG, there are (i)RegularONEFunc() and (ii)SimpleONEFunc() to
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* be used. The previous case is when write access at least sectors of full stripe unit.
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* The later function is used when the write access two stripe units but with total sectors
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* less than sectors per SU. In this case, the access of parity and 'E' are shown as disconnected
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* areas in their stripe unit and parity write and 'E' write are both devided into two distinct
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* writes( totally four). This simple old-new write and regular old-new write happen as in RAID-5
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************************************************************************************************/
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/* Algorithm:
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1. Store the difference of old data and new data in the Rod buffer.
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2. then encode this buffer into the buffer which already have old 'E' information inside it,
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the result can be shown to be the new 'E' information.
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3. xor the Wnd buffer into the difference buffer to recover the original old data.
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Here we have another alternative: to allocate a temporary buffer for storing the difference of
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old data and new data, then encode temp buf into old 'E' buf to form new 'E', but this approach
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take the same speed as the previous, and need more memory.
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*/
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int
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rf_RegularONEFunc(node)
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RF_DagNode_t *node;
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{
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RF_Raid_t *raidPtr = (RF_Raid_t *) node->params[node->numParams - 1].p;
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RF_RaidLayout_t *layoutPtr = (RF_RaidLayout_t *) & raidPtr->Layout;
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int EpdaIndex = (node->numParams - 1) / 2 - 1; /* the parameter of node
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* where you can find
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* e-pda */
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int i, k, retcode = 0;
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int suoffset, length;
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RF_RowCol_t scol;
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char *srcbuf, *destbuf;
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RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec;
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RF_Etimer_t timer;
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RF_PhysDiskAddr_t *pda, *EPDA = (RF_PhysDiskAddr_t *) node->params[EpdaIndex].p;
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int ESUOffset = rf_StripeUnitOffset(layoutPtr, EPDA->startSector); /* generally zero */
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RF_ASSERT(EPDA->type == RF_PDA_TYPE_Q);
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RF_ASSERT(ESUOffset == 0);
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RF_ETIMER_START(timer);
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/* Xor the Wnd buffer into Rod buffer, the difference of old data and
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* new data is stored in Rod buffer */
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for (k = 0; k < EpdaIndex; k += 2) {
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length = rf_RaidAddressToByte(raidPtr, ((RF_PhysDiskAddr_t *) node->params[k].p)->numSector);
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retcode = rf_bxor(node->params[k + EpdaIndex + 3].p, node->params[k + 1].p, length, node->dagHdr->bp);
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}
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/* Start to encoding the buffer storing the difference of old data and
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* new data into 'E' buffer */
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for (i = 0; i < EpdaIndex; i += 2)
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if (node->params[i + 1].p != node->results[0]) { /* results[0] is buf ptr
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* of E */
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pda = (RF_PhysDiskAddr_t *) node->params[i].p;
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srcbuf = (char *) node->params[i + 1].p;
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scol = rf_EUCol(layoutPtr, pda->raidAddress);
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suoffset = rf_StripeUnitOffset(layoutPtr, pda->startSector);
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destbuf = ((char *) node->results[0]) + rf_RaidAddressToByte(raidPtr, suoffset);
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rf_e_encToBuf(raidPtr, scol, srcbuf, RF_EO_MATRIX_DIM - 2, destbuf, pda->numSector);
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}
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/* Recover the original old data to be used by parity encoding
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* function in XorNode */
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for (k = 0; k < EpdaIndex; k += 2) {
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length = rf_RaidAddressToByte(raidPtr, ((RF_PhysDiskAddr_t *) node->params[k].p)->numSector);
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retcode = rf_bxor(node->params[k + EpdaIndex + 3].p, node->params[k + 1].p, length, node->dagHdr->bp);
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}
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RF_ETIMER_STOP(timer);
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RF_ETIMER_EVAL(timer);
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tracerec->q_us += RF_ETIMER_VAL_US(timer);
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rf_GenericWakeupFunc(node, 0);
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#if 1
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return (0); /* XXX this was missing.. GO */
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#endif
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}
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int
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rf_SimpleONEFunc(node)
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RF_DagNode_t *node;
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{
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RF_Raid_t *raidPtr = (RF_Raid_t *) node->params[node->numParams - 1].p;
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RF_RaidLayout_t *layoutPtr = (RF_RaidLayout_t *) & raidPtr->Layout;
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RF_PhysDiskAddr_t *pda = (RF_PhysDiskAddr_t *) node->params[0].p;
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int retcode = 0;
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char *srcbuf, *destbuf;
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RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec;
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int length;
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RF_RowCol_t scol;
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RF_Etimer_t timer;
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RF_ASSERT(((RF_PhysDiskAddr_t *) node->params[2].p)->type == RF_PDA_TYPE_Q);
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if (node->dagHdr->status == rf_enable) {
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RF_ETIMER_START(timer);
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length = rf_RaidAddressToByte(raidPtr, ((RF_PhysDiskAddr_t *) node->params[4].p)->numSector); /* this is a pda of
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* writeDataNodes */
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/* bxor to buffer of readDataNodes */
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retcode = rf_bxor(node->params[5].p, node->params[1].p, length, node->dagHdr->bp);
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/* find out the corresponding colume in encoding matrix for
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* write colume to be encoded into redundant disk 'E' */
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scol = rf_EUCol(layoutPtr, pda->raidAddress);
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srcbuf = node->params[1].p;
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destbuf = node->params[3].p;
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/* Start encoding process */
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rf_e_encToBuf(raidPtr, scol, srcbuf, RF_EO_MATRIX_DIM - 2, destbuf, pda->numSector);
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rf_bxor(node->params[5].p, node->params[1].p, length, node->dagHdr->bp);
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RF_ETIMER_STOP(timer);
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RF_ETIMER_EVAL(timer);
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tracerec->q_us += RF_ETIMER_VAL_US(timer);
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}
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return (rf_GenericWakeupFunc(node, retcode)); /* call wake func
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* explicitly since no
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* I/O in this node */
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}
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/****** called by rf_RegularPEFunc(node) and rf_RegularEFunc(node) in f.f. large write ********/
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void
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rf_RegularESubroutine(node, ebuf)
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RF_DagNode_t *node;
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char *ebuf;
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{
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RF_Raid_t *raidPtr = (RF_Raid_t *) node->params[node->numParams - 1].p;
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RF_RaidLayout_t *layoutPtr = (RF_RaidLayout_t *) & raidPtr->Layout;
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RF_PhysDiskAddr_t *pda;
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int i, suoffset;
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RF_RowCol_t scol;
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char *srcbuf, *destbuf;
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RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec;
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RF_Etimer_t timer;
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RF_ETIMER_START(timer);
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for (i = 0; i < node->numParams - 2; i += 2) {
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RF_ASSERT(node->params[i + 1].p != ebuf);
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pda = (RF_PhysDiskAddr_t *) node->params[i].p;
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suoffset = rf_StripeUnitOffset(layoutPtr, pda->startSector);
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scol = rf_EUCol(layoutPtr, pda->raidAddress);
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srcbuf = (char *) node->params[i + 1].p;
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destbuf = ebuf + rf_RaidAddressToByte(raidPtr, suoffset);
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rf_e_encToBuf(raidPtr, scol, srcbuf, RF_EO_MATRIX_DIM - 2, destbuf, pda->numSector);
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}
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RF_ETIMER_STOP(timer);
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RF_ETIMER_EVAL(timer);
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tracerec->xor_us += RF_ETIMER_VAL_US(timer);
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}
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/*******************************************************************************************
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* Used in EO_001_CreateLargeWriteDAG
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******************************************************************************************/
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int
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rf_RegularEFunc(node)
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RF_DagNode_t *node;
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{
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rf_RegularESubroutine(node, node->results[0]);
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rf_GenericWakeupFunc(node, 0);
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#if 1
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return (0); /* XXX this was missing?.. GO */
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#endif
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}
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/*******************************************************************************************
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* This degraded function allow only two case:
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* 1. when write access the full failed stripe unit, then the access can be more than
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* one tripe units.
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* 2. when write access only part of the failed SU, we assume accesses of more than
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* one stripe unit is not allowed so that the write can be dealt with like a
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* large write.
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* The following function is based on these assumptions. So except in the second case,
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* it looks the same as a large write encodeing function. But this is not exactly the
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* normal way for doing a degraded write, since raidframe have to break cases of access
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* other than the above two into smaller accesses. We may have to change
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* DegrESubroutin in the future.
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*******************************************************************************************/
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void
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rf_DegrESubroutine(node, ebuf)
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RF_DagNode_t *node;
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char *ebuf;
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{
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RF_Raid_t *raidPtr = (RF_Raid_t *) node->params[node->numParams - 1].p;
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RF_RaidLayout_t *layoutPtr = (RF_RaidLayout_t *) & raidPtr->Layout;
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RF_PhysDiskAddr_t *failedPDA = (RF_PhysDiskAddr_t *) node->params[node->numParams - 2].p;
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RF_PhysDiskAddr_t *pda;
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int i, suoffset, failedSUOffset = rf_StripeUnitOffset(layoutPtr, failedPDA->startSector);
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RF_RowCol_t scol;
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char *srcbuf, *destbuf;
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RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec;
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RF_Etimer_t timer;
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RF_ETIMER_START(timer);
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for (i = 0; i < node->numParams - 2; i += 2) {
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RF_ASSERT(node->params[i + 1].p != ebuf);
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pda = (RF_PhysDiskAddr_t *) node->params[i].p;
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suoffset = rf_StripeUnitOffset(layoutPtr, pda->startSector);
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scol = rf_EUCol(layoutPtr, pda->raidAddress);
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srcbuf = (char *) node->params[i + 1].p;
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destbuf = ebuf + rf_RaidAddressToByte(raidPtr, suoffset - failedSUOffset);
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rf_e_encToBuf(raidPtr, scol, srcbuf, RF_EO_MATRIX_DIM - 2, destbuf, pda->numSector);
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}
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RF_ETIMER_STOP(timer);
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RF_ETIMER_EVAL(timer);
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tracerec->q_us += RF_ETIMER_VAL_US(timer);
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}
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/**************************************************************************************
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* This function is used in case where one data disk failed and both redundant disks
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* alive. It is used in the EO_100_CreateWriteDAG. Note: if there is another disk
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* failed in the stripe but not accessed at this time, then we should, instead, use
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* the rf_EOWriteDoubleRecoveryFunc().
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**************************************************************************************/
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int
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rf_Degraded_100_EOFunc(node)
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RF_DagNode_t *node;
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{
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rf_DegrESubroutine(node, node->results[1]);
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rf_RecoveryXorFunc(node); /* does the wakeup here! */
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#if 1
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return (0); /* XXX this was missing... SHould these be
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* void functions??? GO */
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#endif
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}
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/**************************************************************************************
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* This function is to encode one sector in one of the data disks to the E disk.
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* However, in evenodd this function can also be used as decoding function to recover
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* data from dead disk in the case of parity failure and a single data failure.
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**************************************************************************************/
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void
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rf_e_EncOneSect(
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RF_RowCol_t srcLogicCol,
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char *srcSecbuf,
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RF_RowCol_t destLogicCol,
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char *destSecbuf,
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int bytesPerSector)
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{
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int S_index; /* index of the EU in the src col which need
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* be Xored into all EUs in a dest sector */
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int numRowInEncMatix = (RF_EO_MATRIX_DIM) - 1;
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RF_RowCol_t j, indexInDest, /* row index of an encoding unit in
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* the destination colume of encoding
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* matrix */
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indexInSrc; /* row index of an encoding unit in the source
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* colume used for recovery */
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int bytesPerEU = bytesPerSector / numRowInEncMatix;
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#if RF_EO_MATRIX_DIM > 17
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int shortsPerEU = bytesPerEU / sizeof(short);
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short *destShortBuf, *srcShortBuf1, *srcShortBuf2;
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short temp1;
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#elif RF_EO_MATRIX_DIM == 17
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int longsPerEU = bytesPerEU / sizeof(long);
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long *destLongBuf, *srcLongBuf1, *srcLongBuf2;
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long temp1;
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#endif
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#if RF_EO_MATRIX_DIM > 17
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RF_ASSERT(sizeof(short) == 2 || sizeof(short) == 1);
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RF_ASSERT(bytesPerEU % sizeof(short) == 0);
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#elif RF_EO_MATRIX_DIM == 17
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RF_ASSERT(sizeof(long) == 8 || sizeof(long) == 4);
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RF_ASSERT(bytesPerEU % sizeof(long) == 0);
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#endif
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S_index = rf_EO_Mod((RF_EO_MATRIX_DIM - 1 + destLogicCol - srcLogicCol), RF_EO_MATRIX_DIM);
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#if RF_EO_MATRIX_DIM > 17
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srcShortBuf1 = (short *) (srcSecbuf + S_index * bytesPerEU);
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#elif RF_EO_MATRIX_DIM == 17
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srcLongBuf1 = (long *) (srcSecbuf + S_index * bytesPerEU);
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#endif
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for (indexInDest = 0; indexInDest < numRowInEncMatix; indexInDest++) {
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indexInSrc = rf_EO_Mod((indexInDest + destLogicCol - srcLogicCol), RF_EO_MATRIX_DIM);
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#if RF_EO_MATRIX_DIM > 17
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destShortBuf = (short *) (destSecbuf + indexInDest * bytesPerEU);
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srcShortBuf2 = (short *) (srcSecbuf + indexInSrc * bytesPerEU);
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for (j = 0; j < shortsPerEU; j++) {
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temp1 = destShortBuf[j] ^ srcShortBuf1[j];
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/* note: S_index won't be at the end row for any src
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* col! */
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if (indexInSrc != RF_EO_MATRIX_DIM - 1)
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destShortBuf[j] = (srcShortBuf2[j]) ^ temp1;
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/* if indexInSrc is at the end row, ie.
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* RF_EO_MATRIX_DIM -1, then all elements are zero! */
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else
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destShortBuf[j] = temp1;
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}
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#elif RF_EO_MATRIX_DIM == 17
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destLongBuf = (long *) (destSecbuf + indexInDest * bytesPerEU);
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srcLongBuf2 = (long *) (srcSecbuf + indexInSrc * bytesPerEU);
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for (j = 0; j < longsPerEU; j++) {
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temp1 = destLongBuf[j] ^ srcLongBuf1[j];
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if (indexInSrc != RF_EO_MATRIX_DIM - 1)
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destLongBuf[j] = (srcLongBuf2[j]) ^ temp1;
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else
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destLongBuf[j] = temp1;
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}
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#endif
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}
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}
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void
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rf_e_encToBuf(
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RF_Raid_t * raidPtr,
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RF_RowCol_t srcLogicCol,
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char *srcbuf,
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RF_RowCol_t destLogicCol,
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char *destbuf,
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int numSector)
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{
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int i, bytesPerSector = rf_RaidAddressToByte(raidPtr, 1);
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for (i = 0; i < numSector; i++) {
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rf_e_EncOneSect(srcLogicCol, srcbuf, destLogicCol, destbuf, bytesPerSector);
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srcbuf += bytesPerSector;
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destbuf += bytesPerSector;
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}
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}
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/**************************************************************************************
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* when parity die and one data die, We use second redundant information, 'E',
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* to recover the data in dead disk. This function is used in the recovery node of
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* for EO_110_CreateReadDAG
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**************************************************************************************/
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int
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rf_RecoveryEFunc(node)
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RF_DagNode_t *node;
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{
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RF_Raid_t *raidPtr = (RF_Raid_t *) node->params[node->numParams - 1].p;
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RF_RaidLayout_t *layoutPtr = (RF_RaidLayout_t *) & raidPtr->Layout;
|
|
RF_PhysDiskAddr_t *failedPDA = (RF_PhysDiskAddr_t *) node->params[node->numParams - 2].p;
|
|
RF_RowCol_t scol, /* source logical column */
|
|
fcol = rf_EUCol(layoutPtr, failedPDA->raidAddress); /* logical column of
|
|
* failed SU */
|
|
int i;
|
|
RF_PhysDiskAddr_t *pda;
|
|
int suoffset, failedSUOffset = rf_StripeUnitOffset(layoutPtr, failedPDA->startSector);
|
|
char *srcbuf, *destbuf;
|
|
RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec;
|
|
RF_Etimer_t timer;
|
|
|
|
bzero((char *) node->results[0], rf_RaidAddressToByte(raidPtr, failedPDA->numSector));
|
|
if (node->dagHdr->status == rf_enable) {
|
|
RF_ETIMER_START(timer);
|
|
for (i = 0; i < node->numParams - 2; i += 2)
|
|
if (node->params[i + 1].p != node->results[0]) {
|
|
pda = (RF_PhysDiskAddr_t *) node->params[i].p;
|
|
if (i == node->numParams - 4)
|
|
scol = RF_EO_MATRIX_DIM - 2; /* the colume of
|
|
* redundant E */
|
|
else
|
|
scol = rf_EUCol(layoutPtr, pda->raidAddress);
|
|
srcbuf = (char *) node->params[i + 1].p;
|
|
suoffset = rf_StripeUnitOffset(layoutPtr, pda->startSector);
|
|
destbuf = ((char *) node->results[0]) + rf_RaidAddressToByte(raidPtr, suoffset - failedSUOffset);
|
|
rf_e_encToBuf(raidPtr, scol, srcbuf, fcol, destbuf, pda->numSector);
|
|
}
|
|
RF_ETIMER_STOP(timer);
|
|
RF_ETIMER_EVAL(timer);
|
|
tracerec->xor_us += RF_ETIMER_VAL_US(timer);
|
|
}
|
|
return (rf_GenericWakeupFunc(node, 0)); /* node execute successfully */
|
|
}
|
|
/**************************************************************************************
|
|
* This function is used in the case where one data and the parity have filed.
|
|
* (in EO_110_CreateWriteDAG )
|
|
**************************************************************************************/
|
|
int
|
|
rf_EO_DegradedWriteEFunc(RF_DagNode_t * node)
|
|
{
|
|
rf_DegrESubroutine(node, node->results[0]);
|
|
rf_GenericWakeupFunc(node, 0);
|
|
#if 1
|
|
return (0); /* XXX Yet another one!! GO */
|
|
#endif
|
|
}
|
|
|
|
|
|
|
|
/**************************************************************************************
|
|
* THE FUNCTION IS FOR DOUBLE DEGRADED READ AND WRITE CASES
|
|
**************************************************************************************/
|
|
|
|
void
|
|
rf_doubleEOdecode(
|
|
RF_Raid_t * raidPtr,
|
|
char **rrdbuf,
|
|
char **dest,
|
|
RF_RowCol_t * fcol,
|
|
char *pbuf,
|
|
char *ebuf)
|
|
{
|
|
RF_RaidLayout_t *layoutPtr = (RF_RaidLayout_t *) & (raidPtr->Layout);
|
|
int i, j, k, f1, f2, row;
|
|
int rrdrow, erow, count = 0;
|
|
int bytesPerSector = rf_RaidAddressToByte(raidPtr, 1);
|
|
int numRowInEncMatix = (RF_EO_MATRIX_DIM) - 1;
|
|
#if 0
|
|
int pcol = (RF_EO_MATRIX_DIM) - 1;
|
|
#endif
|
|
int ecol = (RF_EO_MATRIX_DIM) - 2;
|
|
int bytesPerEU = bytesPerSector / numRowInEncMatix;
|
|
int numDataCol = layoutPtr->numDataCol;
|
|
#if RF_EO_MATRIX_DIM > 17
|
|
int shortsPerEU = bytesPerEU / sizeof(short);
|
|
short *rrdbuf_current, *pbuf_current, *ebuf_current;
|
|
short *dest_smaller, *dest_smaller_current, *dest_larger, *dest_larger_current;
|
|
short *temp;
|
|
short *P;
|
|
|
|
RF_ASSERT(bytesPerEU % sizeof(short) == 0);
|
|
RF_Malloc(P, bytesPerEU, (short *));
|
|
RF_Malloc(temp, bytesPerEU, (short *));
|
|
#elif RF_EO_MATRIX_DIM == 17
|
|
int longsPerEU = bytesPerEU / sizeof(long);
|
|
long *rrdbuf_current, *pbuf_current, *ebuf_current;
|
|
long *dest_smaller, *dest_smaller_current, *dest_larger, *dest_larger_current;
|
|
long *temp;
|
|
long *P;
|
|
|
|
RF_ASSERT(bytesPerEU % sizeof(long) == 0);
|
|
RF_Malloc(P, bytesPerEU, (long *));
|
|
RF_Malloc(temp, bytesPerEU, (long *));
|
|
#endif
|
|
RF_ASSERT(*((long *) dest[0]) == 0);
|
|
RF_ASSERT(*((long *) dest[1]) == 0);
|
|
bzero((char *) P, bytesPerEU);
|
|
bzero((char *) temp, bytesPerEU);
|
|
RF_ASSERT(*P == 0);
|
|
/* calculate the 'P' parameter, which, not parity, is the Xor of all
|
|
* elements in the last two column, ie. 'E' and 'parity' colume, see
|
|
* the Ref. paper by Blaum, et al 1993 */
|
|
for (i = 0; i < numRowInEncMatix; i++)
|
|
for (k = 0; k < longsPerEU; k++) {
|
|
#if RF_EO_MATRIX_DIM > 17
|
|
ebuf_current = ((short *) ebuf) + i * shortsPerEU + k;
|
|
pbuf_current = ((short *) pbuf) + i * shortsPerEU + k;
|
|
#elif RF_EO_MATRIX_DIM == 17
|
|
ebuf_current = ((long *) ebuf) + i * longsPerEU + k;
|
|
pbuf_current = ((long *) pbuf) + i * longsPerEU + k;
|
|
#endif
|
|
P[k] ^= *ebuf_current;
|
|
P[k] ^= *pbuf_current;
|
|
}
|
|
RF_ASSERT(fcol[0] != fcol[1]);
|
|
if (fcol[0] < fcol[1]) {
|
|
#if RF_EO_MATRIX_DIM > 17
|
|
dest_smaller = (short *) (dest[0]);
|
|
dest_larger = (short *) (dest[1]);
|
|
#elif RF_EO_MATRIX_DIM == 17
|
|
dest_smaller = (long *) (dest[0]);
|
|
dest_larger = (long *) (dest[1]);
|
|
#endif
|
|
f1 = fcol[0];
|
|
f2 = fcol[1];
|
|
} else {
|
|
#if RF_EO_MATRIX_DIM > 17
|
|
dest_smaller = (short *) (dest[1]);
|
|
dest_larger = (short *) (dest[0]);
|
|
#elif RF_EO_MATRIX_DIM == 17
|
|
dest_smaller = (long *) (dest[1]);
|
|
dest_larger = (long *) (dest[0]);
|
|
#endif
|
|
f1 = fcol[1];
|
|
f2 = fcol[0];
|
|
}
|
|
row = (RF_EO_MATRIX_DIM) - 1;
|
|
while ((row = rf_EO_Mod((row + f1 - f2), RF_EO_MATRIX_DIM)) != ((RF_EO_MATRIX_DIM) - 1)) {
|
|
#if RF_EO_MATRIX_DIM > 17
|
|
dest_larger_current = dest_larger + row * shortsPerEU;
|
|
dest_smaller_current = dest_smaller + row * shortsPerEU;
|
|
#elif RF_EO_MATRIX_DIM == 17
|
|
dest_larger_current = dest_larger + row * longsPerEU;
|
|
dest_smaller_current = dest_smaller + row * longsPerEU;
|
|
#endif
|
|
/** Do the diagonal recovery. Initially, temp[k] = (failed 1),
|
|
which is the failed data in the colume which has smaller col index. **/
|
|
/* step 1: ^(SUM of nonfailed in-diagonal A(rrdrow,0..m-3)) */
|
|
for (j = 0; j < numDataCol; j++) {
|
|
if (j == f1 || j == f2)
|
|
continue;
|
|
rrdrow = rf_EO_Mod((row + f2 - j), RF_EO_MATRIX_DIM);
|
|
if (rrdrow != (RF_EO_MATRIX_DIM) - 1) {
|
|
#if RF_EO_MATRIX_DIM > 17
|
|
rrdbuf_current = (short *) (rrdbuf[j]) + rrdrow * shortsPerEU;
|
|
for (k = 0; k < shortsPerEU; k++)
|
|
temp[k] ^= *(rrdbuf_current + k);
|
|
#elif RF_EO_MATRIX_DIM == 17
|
|
rrdbuf_current = (long *) (rrdbuf[j]) + rrdrow * longsPerEU;
|
|
for (k = 0; k < longsPerEU; k++)
|
|
temp[k] ^= *(rrdbuf_current + k);
|
|
#endif
|
|
}
|
|
}
|
|
/* step 2: ^E(erow,m-2), If erow is at the buttom row, don't
|
|
* Xor into it E(erow,m-2) = (principle diagonal) ^ (failed
|
|
* 1) ^ (failed 2) ^ ( SUM of nonfailed in-diagonal
|
|
* A(rrdrow,0..m-3) ) After this step, temp[k] = (principle
|
|
* diagonal) ^ (failed 2) */
|
|
|
|
erow = rf_EO_Mod((row + f2 - ecol), (RF_EO_MATRIX_DIM));
|
|
if (erow != (RF_EO_MATRIX_DIM) - 1) {
|
|
#if RF_EO_MATRIX_DIM > 17
|
|
ebuf_current = (short *) ebuf + shortsPerEU * erow;
|
|
for (k = 0; k < shortsPerEU; k++)
|
|
temp[k] ^= *(ebuf_current + k);
|
|
#elif RF_EO_MATRIX_DIM == 17
|
|
ebuf_current = (long *) ebuf + longsPerEU * erow;
|
|
for (k = 0; k < longsPerEU; k++)
|
|
temp[k] ^= *(ebuf_current + k);
|
|
#endif
|
|
}
|
|
/* step 3: ^P to obtain the failed data (failed 2). P can be
|
|
* proved to be actually (principle diagonal) After this
|
|
* step, temp[k] = (failed 2), the failed data to be recovered */
|
|
#if RF_EO_MATRIX_DIM > 17
|
|
for (k = 0; k < shortsPerEU; k++)
|
|
temp[k] ^= P[k];
|
|
/* Put the data to the destination buffer */
|
|
for (k = 0; k < shortsPerEU; k++)
|
|
dest_larger_current[k] = temp[k];
|
|
#elif RF_EO_MATRIX_DIM == 17
|
|
for (k = 0; k < longsPerEU; k++)
|
|
temp[k] ^= P[k];
|
|
/* Put the data to the destination buffer */
|
|
for (k = 0; k < longsPerEU; k++)
|
|
dest_larger_current[k] = temp[k];
|
|
#endif
|
|
|
|
/** THE FOLLOWING DO THE HORIZONTAL XOR **/
|
|
/* step 1: ^(SUM of A(row,0..m-3)), ie. all nonfailed data
|
|
* columes */
|
|
for (j = 0; j < numDataCol; j++) {
|
|
if (j == f1 || j == f2)
|
|
continue;
|
|
#if RF_EO_MATRIX_DIM > 17
|
|
rrdbuf_current = (short *) (rrdbuf[j]) + row * shortsPerEU;
|
|
for (k = 0; k < shortsPerEU; k++)
|
|
temp[k] ^= *(rrdbuf_current + k);
|
|
#elif RF_EO_MATRIX_DIM == 17
|
|
rrdbuf_current = (long *) (rrdbuf[j]) + row * longsPerEU;
|
|
for (k = 0; k < longsPerEU; k++)
|
|
temp[k] ^= *(rrdbuf_current + k);
|
|
#endif
|
|
}
|
|
/* step 2: ^A(row,m-1) */
|
|
/* step 3: Put the data to the destination buffer */
|
|
#if RF_EO_MATRIX_DIM > 17
|
|
pbuf_current = (short *) pbuf + shortsPerEU * row;
|
|
for (k = 0; k < shortsPerEU; k++)
|
|
temp[k] ^= *(pbuf_current + k);
|
|
for (k = 0; k < shortsPerEU; k++)
|
|
dest_smaller_current[k] = temp[k];
|
|
#elif RF_EO_MATRIX_DIM == 17
|
|
pbuf_current = (long *) pbuf + longsPerEU * row;
|
|
for (k = 0; k < longsPerEU; k++)
|
|
temp[k] ^= *(pbuf_current + k);
|
|
for (k = 0; k < longsPerEU; k++)
|
|
dest_smaller_current[k] = temp[k];
|
|
#endif
|
|
count++;
|
|
}
|
|
/* Check if all Encoding Unit in the data buffer have been decoded,
|
|
* according EvenOdd theory, if "RF_EO_MATRIX_DIM" is a prime number,
|
|
* this algorithm will covered all buffer */
|
|
RF_ASSERT(count == numRowInEncMatix);
|
|
RF_Free((char *) P, bytesPerEU);
|
|
RF_Free((char *) temp, bytesPerEU);
|
|
}
|
|
|
|
|
|
/***************************************************************************************
|
|
* This function is called by double degragded read
|
|
* EO_200_CreateReadDAG
|
|
*
|
|
***************************************************************************************/
|
|
int
|
|
rf_EvenOddDoubleRecoveryFunc(node)
|
|
RF_DagNode_t *node;
|
|
{
|
|
int ndataParam = 0;
|
|
int np = node->numParams;
|
|
RF_AccessStripeMap_t *asmap = (RF_AccessStripeMap_t *) node->params[np - 1].p;
|
|
RF_Raid_t *raidPtr = (RF_Raid_t *) node->params[np - 2].p;
|
|
RF_RaidLayout_t *layoutPtr = (RF_RaidLayout_t *) & (raidPtr->Layout);
|
|
int i, prm, sector, nresults = node->numResults;
|
|
RF_SectorCount_t secPerSU = layoutPtr->sectorsPerStripeUnit;
|
|
unsigned sosAddr;
|
|
int two = 0, mallc_one = 0, mallc_two = 0; /* flags to indicate if
|
|
* memory is allocated */
|
|
int bytesPerSector = rf_RaidAddressToByte(raidPtr, 1);
|
|
RF_PhysDiskAddr_t *ppda, *ppda2, *epda, *epda2, *pda, *pda0, *pda1,
|
|
npda;
|
|
RF_RowCol_t fcol[2], fsuoff[2], fsuend[2], numDataCol = layoutPtr->numDataCol;
|
|
char **buf, *ebuf, *pbuf, *dest[2];
|
|
long *suoff = NULL, *suend = NULL, *prmToCol = NULL, psuoff, esuoff;
|
|
RF_SectorNum_t startSector, endSector;
|
|
RF_Etimer_t timer;
|
|
RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec;
|
|
|
|
RF_ETIMER_START(timer);
|
|
|
|
/* Find out the number of parameters which are pdas for data
|
|
* information */
|
|
for (i = 0; i <= np; i++)
|
|
if (((RF_PhysDiskAddr_t *) node->params[i].p)->type != RF_PDA_TYPE_DATA) {
|
|
ndataParam = i;
|
|
break;
|
|
}
|
|
RF_Malloc(buf, numDataCol * sizeof(char *), (char **));
|
|
if (ndataParam != 0) {
|
|
RF_Malloc(suoff, ndataParam * sizeof(long), (long *));
|
|
RF_Malloc(suend, ndataParam * sizeof(long), (long *));
|
|
RF_Malloc(prmToCol, ndataParam * sizeof(long), (long *));
|
|
}
|
|
if (asmap->failedPDAs[1] &&
|
|
(asmap->failedPDAs[1]->numSector + asmap->failedPDAs[0]->numSector < secPerSU)) {
|
|
RF_ASSERT(0); /* currently, no support for this situation */
|
|
ppda = node->params[np - 6].p;
|
|
ppda2 = node->params[np - 5].p;
|
|
RF_ASSERT(ppda2->type == RF_PDA_TYPE_PARITY);
|
|
epda = node->params[np - 4].p;
|
|
epda2 = node->params[np - 3].p;
|
|
RF_ASSERT(epda2->type == RF_PDA_TYPE_Q);
|
|
two = 1;
|
|
} else {
|
|
ppda = node->params[np - 4].p;
|
|
epda = node->params[np - 3].p;
|
|
psuoff = rf_StripeUnitOffset(layoutPtr, ppda->startSector);
|
|
esuoff = rf_StripeUnitOffset(layoutPtr, epda->startSector);
|
|
RF_ASSERT(psuoff == esuoff);
|
|
}
|
|
/*
|
|
the followings have three goals:
|
|
1. determine the startSector to begin decoding and endSector to end decoding.
|
|
2. determine the colume numbers of the two failed disks.
|
|
3. determine the offset and end offset of the access within each failed stripe unit.
|
|
*/
|
|
if (nresults == 1) {
|
|
/* find the startSector to begin decoding */
|
|
pda = node->results[0];
|
|
bzero(pda->bufPtr, bytesPerSector * pda->numSector);
|
|
fsuoff[0] = rf_StripeUnitOffset(layoutPtr, pda->startSector);
|
|
fsuend[0] = fsuoff[0] + pda->numSector;
|
|
startSector = fsuoff[0];
|
|
endSector = fsuend[0];
|
|
|
|
/* find out the column of failed disk being accessed */
|
|
fcol[0] = rf_EUCol(layoutPtr, pda->raidAddress);
|
|
|
|
/* find out the other failed colume not accessed */
|
|
sosAddr = rf_RaidAddressOfPrevStripeBoundary(layoutPtr, asmap->raidAddress);
|
|
for (i = 0; i < numDataCol; i++) {
|
|
npda.raidAddress = sosAddr + (i * secPerSU);
|
|
(raidPtr->Layout.map->MapSector) (raidPtr, npda.raidAddress, &(npda.row), &(npda.col), &(npda.startSector), 0);
|
|
/* skip over dead disks */
|
|
if (RF_DEAD_DISK(raidPtr->Disks[npda.row][npda.col].status))
|
|
if (i != fcol[0])
|
|
break;
|
|
}
|
|
RF_ASSERT(i < numDataCol);
|
|
fcol[1] = i;
|
|
} else {
|
|
RF_ASSERT(nresults == 2);
|
|
pda0 = node->results[0];
|
|
bzero(pda0->bufPtr, bytesPerSector * pda0->numSector);
|
|
pda1 = node->results[1];
|
|
bzero(pda1->bufPtr, bytesPerSector * pda1->numSector);
|
|
/* determine the failed colume numbers of the two failed
|
|
* disks. */
|
|
fcol[0] = rf_EUCol(layoutPtr, pda0->raidAddress);
|
|
fcol[1] = rf_EUCol(layoutPtr, pda1->raidAddress);
|
|
/* determine the offset and end offset of the access within
|
|
* each failed stripe unit. */
|
|
fsuoff[0] = rf_StripeUnitOffset(layoutPtr, pda0->startSector);
|
|
fsuend[0] = fsuoff[0] + pda0->numSector;
|
|
fsuoff[1] = rf_StripeUnitOffset(layoutPtr, pda1->startSector);
|
|
fsuend[1] = fsuoff[1] + pda1->numSector;
|
|
/* determine the startSector to begin decoding */
|
|
startSector = RF_MIN(pda0->startSector, pda1->startSector);
|
|
/* determine the endSector to end decoding */
|
|
endSector = RF_MAX(fsuend[0], fsuend[1]);
|
|
}
|
|
/*
|
|
assign the beginning sector and the end sector for each parameter
|
|
find out the corresponding colume # for each parameter
|
|
*/
|
|
for (prm = 0; prm < ndataParam; prm++) {
|
|
pda = node->params[prm].p;
|
|
suoff[prm] = rf_StripeUnitOffset(layoutPtr, pda->startSector);
|
|
suend[prm] = suoff[prm] + pda->numSector;
|
|
prmToCol[prm] = rf_EUCol(layoutPtr, pda->raidAddress);
|
|
}
|
|
/* 'sector' is the sector for the current decoding algorithm. For each
|
|
* sector in the failed SU, find out the corresponding parameters that
|
|
* cover the current sector and that are needed for decoding of this
|
|
* sector in failed SU. 2. Find out if sector is in the shadow of any
|
|
* accessed failed SU. If not, malloc a temporary space of a sector in
|
|
* size. */
|
|
for (sector = startSector; sector < endSector; sector++) {
|
|
if (nresults == 2)
|
|
if (!(fsuoff[0] <= sector && sector < fsuend[0]) && !(fsuoff[1] <= sector && sector < fsuend[1]))
|
|
continue;
|
|
for (prm = 0; prm < ndataParam; prm++)
|
|
if (suoff[prm] <= sector && sector < suend[prm])
|
|
buf[(prmToCol[prm])] = ((RF_PhysDiskAddr_t *) node->params[prm].p)->bufPtr +
|
|
rf_RaidAddressToByte(raidPtr, sector - suoff[prm]);
|
|
/* find out if sector is in the shadow of any accessed failed
|
|
* SU. If yes, assign dest[0], dest[1] to point at suitable
|
|
* position of the buffer corresponding to failed SUs. if no,
|
|
* malloc a temporary space of a sector in size for
|
|
* destination of decoding. */
|
|
RF_ASSERT(nresults == 1 || nresults == 2);
|
|
if (nresults == 1) {
|
|
dest[0] = ((RF_PhysDiskAddr_t *) node->results[0])->bufPtr + rf_RaidAddressToByte(raidPtr, sector - fsuoff[0]);
|
|
/* Always malloc temp buffer to dest[1] */
|
|
RF_Malloc(dest[1], bytesPerSector, (char *));
|
|
bzero(dest[1], bytesPerSector);
|
|
mallc_two = 1;
|
|
} else {
|
|
if (fsuoff[0] <= sector && sector < fsuend[0])
|
|
dest[0] = ((RF_PhysDiskAddr_t *) node->results[0])->bufPtr + rf_RaidAddressToByte(raidPtr, sector - fsuoff[0]);
|
|
else {
|
|
RF_Malloc(dest[0], bytesPerSector, (char *));
|
|
bzero(dest[0], bytesPerSector);
|
|
mallc_one = 1;
|
|
}
|
|
if (fsuoff[1] <= sector && sector < fsuend[1])
|
|
dest[1] = ((RF_PhysDiskAddr_t *) node->results[1])->bufPtr + rf_RaidAddressToByte(raidPtr, sector - fsuoff[1]);
|
|
else {
|
|
RF_Malloc(dest[1], bytesPerSector, (char *));
|
|
bzero(dest[1], bytesPerSector);
|
|
mallc_two = 1;
|
|
}
|
|
RF_ASSERT(mallc_one == 0 || mallc_two == 0);
|
|
}
|
|
pbuf = ppda->bufPtr + rf_RaidAddressToByte(raidPtr, sector - psuoff);
|
|
ebuf = epda->bufPtr + rf_RaidAddressToByte(raidPtr, sector - esuoff);
|
|
/*
|
|
* After finish finding all needed sectors, call doubleEOdecode function for decoding
|
|
* one sector to destination.
|
|
*/
|
|
rf_doubleEOdecode(raidPtr, buf, dest, fcol, pbuf, ebuf);
|
|
/* free all allocated memory, and mark flag to indicate no
|
|
* memory is being allocated */
|
|
if (mallc_one == 1)
|
|
RF_Free(dest[0], bytesPerSector);
|
|
if (mallc_two == 1)
|
|
RF_Free(dest[1], bytesPerSector);
|
|
mallc_one = mallc_two = 0;
|
|
}
|
|
RF_Free(buf, numDataCol * sizeof(char *));
|
|
if (ndataParam != 0) {
|
|
RF_Free(suoff, ndataParam * sizeof(long));
|
|
RF_Free(suend, ndataParam * sizeof(long));
|
|
RF_Free(prmToCol, ndataParam * sizeof(long));
|
|
}
|
|
RF_ETIMER_STOP(timer);
|
|
RF_ETIMER_EVAL(timer);
|
|
if (tracerec) {
|
|
tracerec->q_us += RF_ETIMER_VAL_US(timer);
|
|
}
|
|
rf_GenericWakeupFunc(node, 0);
|
|
#if 1
|
|
return (0); /* XXX is this even close!!?!?!!? GO */
|
|
#endif
|
|
}
|
|
|
|
|
|
/* currently, only access of one of the two failed SU is allowed in this function.
|
|
* also, asmap->numStripeUnitsAccessed is limited to be one, the RaidFrame will break large access into
|
|
* many accesses of single stripe unit.
|
|
*/
|
|
|
|
int
|
|
rf_EOWriteDoubleRecoveryFunc(node)
|
|
RF_DagNode_t *node;
|
|
{
|
|
int np = node->numParams;
|
|
RF_AccessStripeMap_t *asmap = (RF_AccessStripeMap_t *) node->params[np - 1].p;
|
|
RF_Raid_t *raidPtr = (RF_Raid_t *) node->params[np - 2].p;
|
|
RF_RaidLayout_t *layoutPtr = (RF_RaidLayout_t *) & (raidPtr->Layout);
|
|
RF_SectorNum_t sector;
|
|
RF_RowCol_t col, scol;
|
|
int prm, i, j;
|
|
RF_SectorCount_t secPerSU = layoutPtr->sectorsPerStripeUnit;
|
|
unsigned sosAddr;
|
|
unsigned bytesPerSector = rf_RaidAddressToByte(raidPtr, 1);
|
|
RF_int64 numbytes;
|
|
RF_SectorNum_t startSector, endSector;
|
|
RF_PhysDiskAddr_t *ppda, *epda, *pda, *fpda, npda;
|
|
RF_RowCol_t fcol[2], numDataCol = layoutPtr->numDataCol;
|
|
char **buf; /* buf[0], buf[1], buf[2], ...etc. point to
|
|
* buffer storing data read from col0, col1,
|
|
* col2 */
|
|
char *ebuf, *pbuf, *dest[2], *olddata[2];
|
|
RF_Etimer_t timer;
|
|
RF_AccTraceEntry_t *tracerec = node->dagHdr->tracerec;
|
|
|
|
RF_ASSERT(asmap->numDataFailed == 1); /* currently only support this
|
|
* case, the other failed SU
|
|
* is not being accessed */
|
|
RF_ETIMER_START(timer);
|
|
RF_Malloc(buf, numDataCol * sizeof(char *), (char **));
|
|
|
|
ppda = node->results[0];/* Instead of being buffers, node->results[0]
|
|
* and [1] are Ppda and Epda */
|
|
epda = node->results[1];
|
|
fpda = asmap->failedPDAs[0];
|
|
|
|
/* First, recovery the failed old SU using EvenOdd double decoding */
|
|
/* determine the startSector and endSector for decoding */
|
|
startSector = rf_StripeUnitOffset(layoutPtr, fpda->startSector);
|
|
endSector = startSector + fpda->numSector;
|
|
/* Assign buf[col] pointers to point to each non-failed colume and
|
|
* initialize the pbuf and ebuf to point at the beginning of each
|
|
* source buffers and destination buffers */
|
|
for (prm = 0; prm < numDataCol - 2; prm++) {
|
|
pda = (RF_PhysDiskAddr_t *) node->params[prm].p;
|
|
col = rf_EUCol(layoutPtr, pda->raidAddress);
|
|
buf[col] = pda->bufPtr;
|
|
}
|
|
/* pbuf and ebuf: they will change values as double recovery decoding
|
|
* goes on */
|
|
pbuf = ppda->bufPtr;
|
|
ebuf = epda->bufPtr;
|
|
/* find out the logical colume numbers in the encoding matrix of the
|
|
* two failed columes */
|
|
fcol[0] = rf_EUCol(layoutPtr, fpda->raidAddress);
|
|
|
|
/* find out the other failed colume not accessed this time */
|
|
sosAddr = rf_RaidAddressOfPrevStripeBoundary(layoutPtr, asmap->raidAddress);
|
|
for (i = 0; i < numDataCol; i++) {
|
|
npda.raidAddress = sosAddr + (i * secPerSU);
|
|
(raidPtr->Layout.map->MapSector) (raidPtr, npda.raidAddress, &(npda.row), &(npda.col), &(npda.startSector), 0);
|
|
/* skip over dead disks */
|
|
if (RF_DEAD_DISK(raidPtr->Disks[npda.row][npda.col].status))
|
|
if (i != fcol[0])
|
|
break;
|
|
}
|
|
RF_ASSERT(i < numDataCol);
|
|
fcol[1] = i;
|
|
/* assign temporary space to put recovered failed SU */
|
|
numbytes = fpda->numSector * bytesPerSector;
|
|
RF_Malloc(olddata[0], numbytes, (char *));
|
|
RF_Malloc(olddata[1], numbytes, (char *));
|
|
dest[0] = olddata[0];
|
|
dest[1] = olddata[1];
|
|
bzero(olddata[0], numbytes);
|
|
bzero(olddata[1], numbytes);
|
|
/* Begin the recovery decoding, initially buf[j], ebuf, pbuf, dest[j]
|
|
* have already pointed at the beginning of each source buffers and
|
|
* destination buffers */
|
|
for (sector = startSector, i = 0; sector < endSector; sector++, i++) {
|
|
rf_doubleEOdecode(raidPtr, buf, dest, fcol, pbuf, ebuf);
|
|
for (j = 0; j < numDataCol; j++)
|
|
if ((j != fcol[0]) && (j != fcol[1]))
|
|
buf[j] += bytesPerSector;
|
|
dest[0] += bytesPerSector;
|
|
dest[1] += bytesPerSector;
|
|
ebuf += bytesPerSector;
|
|
pbuf += bytesPerSector;
|
|
}
|
|
/* after recovery, the buffer pointed by olddata[0] is the old failed
|
|
* data. With new writing data and this old data, use small write to
|
|
* calculate the new redundant informations */
|
|
/* node->params[ 0, ... PDAPerDisk * (numDataCol - 2)-1 ] are Pdas of
|
|
* Rrd; params[ PDAPerDisk*(numDataCol - 2), ... PDAPerDisk*numDataCol
|
|
* -1 ] are Pdas of Rp, ( Rp2 ), Re, ( Re2 ) ; params[
|
|
* PDAPerDisk*numDataCol, ... PDAPerDisk*numDataCol
|
|
* +asmap->numStripeUnitsAccessed -asmap->numDataFailed-1] are Pdas of
|
|
* wudNodes; For current implementation, we assume the simplest case:
|
|
* asmap->numStripeUnitsAccessed == 1 and asmap->numDataFailed == 1
|
|
* ie. PDAPerDisk = 1 then node->params[numDataCol] must be the new
|
|
* data to be writen to the failed disk. We first bxor the new data
|
|
* into the old recovered data, then do the same things as small
|
|
* write. */
|
|
|
|
rf_bxor(((RF_PhysDiskAddr_t *) node->params[numDataCol].p)->bufPtr, olddata[0], numbytes, node->dagHdr->bp);
|
|
/* do new 'E' calculation */
|
|
/* find out the corresponding colume in encoding matrix for write
|
|
* colume to be encoded into redundant disk 'E' */
|
|
scol = rf_EUCol(layoutPtr, fpda->raidAddress);
|
|
/* olddata[0] now is source buffer pointer; epda->bufPtr is the dest
|
|
* buffer pointer */
|
|
rf_e_encToBuf(raidPtr, scol, olddata[0], RF_EO_MATRIX_DIM - 2, epda->bufPtr, fpda->numSector);
|
|
|
|
/* do new 'P' calculation */
|
|
rf_bxor(olddata[0], ppda->bufPtr, numbytes, node->dagHdr->bp);
|
|
/* Free the allocated buffer */
|
|
RF_Free(olddata[0], numbytes);
|
|
RF_Free(olddata[1], numbytes);
|
|
RF_Free(buf, numDataCol * sizeof(char *));
|
|
|
|
RF_ETIMER_STOP(timer);
|
|
RF_ETIMER_EVAL(timer);
|
|
if (tracerec) {
|
|
tracerec->q_us += RF_ETIMER_VAL_US(timer);
|
|
}
|
|
rf_GenericWakeupFunc(node, 0);
|
|
return (0);
|
|
}
|
|
#endif /* RF_INCLUDE_EVENODD > 0 */
|