710948de69
world. This should be considered highly experimental. Approved-by: re
845 lines
30 KiB
C
845 lines
30 KiB
C
/* $FreeBSD$ */
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/* $NetBSD: rf_dagdegwr.c,v 1.6 2001/01/26 04:05:08 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: Mark Holland, Daniel Stodolsky, William V. Courtright II
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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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* rf_dagdegwr.c
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*
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* code for creating degraded write DAGs
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*
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*/
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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_dagutils.h>
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#include <dev/raidframe/rf_dagfuncs.h>
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#include <dev/raidframe/rf_debugMem.h>
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#include <dev/raidframe/rf_memchunk.h>
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#include <dev/raidframe/rf_general.h>
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#include <dev/raidframe/rf_dagdegwr.h>
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/******************************************************************************
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*
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* General comments on DAG creation:
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*
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* All DAGs in this file use roll-away error recovery. Each DAG has a single
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* commit node, usually called "Cmt." If an error occurs before the Cmt node
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* is reached, the execution engine will halt forward execution and work
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* backward through the graph, executing the undo functions. Assuming that
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* each node in the graph prior to the Cmt node are undoable and atomic - or -
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* does not make changes to permanent state, the graph will fail atomically.
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* If an error occurs after the Cmt node executes, the engine will roll-forward
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* through the graph, blindly executing nodes until it reaches the end.
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* If a graph reaches the end, it is assumed to have completed successfully.
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*
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* A graph has only 1 Cmt node.
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*
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*/
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/******************************************************************************
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*
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* The following wrappers map the standard DAG creation interface to the
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* DAG creation routines. Additionally, these wrappers enable experimentation
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* with new DAG structures by providing an extra level of indirection, allowing
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* the DAG creation routines to be replaced at this single point.
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*/
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static
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RF_CREATE_DAG_FUNC_DECL(rf_CreateSimpleDegradedWriteDAG)
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{
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rf_CommonCreateSimpleDegradedWriteDAG(raidPtr, asmap, dag_h, bp,
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flags, allocList, 1, rf_RecoveryXorFunc, RF_TRUE);
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}
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void
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rf_CreateDegradedWriteDAG(raidPtr, asmap, dag_h, bp, flags, allocList)
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RF_Raid_t *raidPtr;
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RF_AccessStripeMap_t *asmap;
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RF_DagHeader_t *dag_h;
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void *bp;
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RF_RaidAccessFlags_t flags;
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RF_AllocListElem_t *allocList;
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{
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RF_RaidLayout_t *layoutPtr = &(raidPtr->Layout);
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RF_PhysDiskAddr_t *failedPDA = asmap->failedPDAs[0];
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RF_ASSERT(asmap->numDataFailed == 1);
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dag_h->creator = "DegradedWriteDAG";
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/* if the access writes only a portion of the failed unit, and also
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* writes some portion of at least one surviving unit, we create two
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* DAGs, one for the failed component and one for the non-failed
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* component, and do them sequentially. Note that the fact that we're
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* accessing only a portion of the failed unit indicates that the
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* access either starts or ends in the failed unit, and hence we need
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* create only two dags. This is inefficient in that the same data or
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* parity can get read and written twice using this structure. I need
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* to fix this to do the access all at once. */
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RF_ASSERT(!(asmap->numStripeUnitsAccessed != 1 && failedPDA->numSector != layoutPtr->sectorsPerStripeUnit));
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rf_CreateSimpleDegradedWriteDAG(raidPtr, asmap, dag_h, bp, flags, allocList);
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}
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/******************************************************************************
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*
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* DAG creation code begins here
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*/
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/******************************************************************************
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*
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* CommonCreateSimpleDegradedWriteDAG -- creates a DAG to do a degraded-mode
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* write, which is as follows
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*
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* / {Wnq} --\
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* hdr -> blockNode -> Rod -> Xor -> Cmt -> Wnp ----> unblock -> term
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* \ {Rod} / \ Wnd ---/
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* \ {Wnd} -/
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*
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* commit nodes: Xor, Wnd
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*
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* IMPORTANT:
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* This DAG generator does not work for double-degraded archs since it does not
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* generate Q
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*
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* This dag is essentially identical to the large-write dag, except that the
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* write to the failed data unit is suppressed.
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*
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* IMPORTANT: this dag does not work in the case where the access writes only
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* a portion of the failed unit, and also writes some portion of at least one
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* surviving SU. this case is handled in CreateDegradedWriteDAG above.
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*
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* The block & unblock nodes are leftovers from a previous version. They
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* do nothing, but I haven't deleted them because it would be a tremendous
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* effort to put them back in.
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*
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* This dag is used whenever a one of the data units in a write has failed.
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* If it is the parity unit that failed, the nonredundant write dag (below)
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* is used.
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*****************************************************************************/
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void
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rf_CommonCreateSimpleDegradedWriteDAG(raidPtr, asmap, dag_h, bp, flags,
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allocList, nfaults, redFunc, allowBufferRecycle)
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RF_Raid_t *raidPtr;
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RF_AccessStripeMap_t *asmap;
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RF_DagHeader_t *dag_h;
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void *bp;
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RF_RaidAccessFlags_t flags;
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RF_AllocListElem_t *allocList;
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int nfaults;
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int (*redFunc) (RF_DagNode_t *);
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int allowBufferRecycle;
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{
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int nNodes, nRrdNodes, nWndNodes, nXorBufs, i, j, paramNum,
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rdnodesFaked;
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RF_DagNode_t *blockNode, *unblockNode, *wnpNode, *wnqNode, *termNode;
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RF_DagNode_t *nodes, *wndNodes, *rrdNodes, *xorNode, *commitNode;
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RF_SectorCount_t sectorsPerSU;
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RF_ReconUnitNum_t which_ru;
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char *xorTargetBuf = NULL; /* the target buffer for the XOR
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* operation */
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char *overlappingPDAs;/* a temporary array of flags */
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RF_AccessStripeMapHeader_t *new_asm_h[2];
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RF_PhysDiskAddr_t *pda, *parityPDA;
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RF_StripeNum_t parityStripeID;
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RF_PhysDiskAddr_t *failedPDA;
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RF_RaidLayout_t *layoutPtr;
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layoutPtr = &(raidPtr->Layout);
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parityStripeID = rf_RaidAddressToParityStripeID(layoutPtr, asmap->raidAddress,
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&which_ru);
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sectorsPerSU = layoutPtr->sectorsPerStripeUnit;
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/* failedPDA points to the pda within the asm that targets the failed
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* disk */
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failedPDA = asmap->failedPDAs[0];
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if (rf_dagDebug)
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printf("[Creating degraded-write DAG]\n");
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RF_ASSERT(asmap->numDataFailed == 1);
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dag_h->creator = "SimpleDegradedWriteDAG";
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/*
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* Generate two ASMs identifying the surviving data
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* we need in order to recover the lost data.
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*/
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/* overlappingPDAs array must be zero'd */
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RF_Calloc(overlappingPDAs, asmap->numStripeUnitsAccessed, sizeof(char), (char *));
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rf_GenerateFailedAccessASMs(raidPtr, asmap, failedPDA, dag_h, new_asm_h,
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&nXorBufs, NULL, overlappingPDAs, allocList);
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/* create all the nodes at once */
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nWndNodes = asmap->numStripeUnitsAccessed - 1; /* no access is
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* generated for the
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* failed pda */
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nRrdNodes = ((new_asm_h[0]) ? new_asm_h[0]->stripeMap->numStripeUnitsAccessed : 0) +
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((new_asm_h[1]) ? new_asm_h[1]->stripeMap->numStripeUnitsAccessed : 0);
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/*
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* XXX
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*
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* There's a bug with a complete stripe overwrite- that means 0 reads
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* of old data, and the rest of the DAG generation code doesn't like
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* that. A release is coming, and I don't wanna risk breaking a critical
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* DAG generator, so here's what I'm gonna do- if there's no read nodes,
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* I'm gonna fake there being a read node, and I'm gonna swap in a
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* no-op node in its place (to make all the link-up code happy).
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* This should be fixed at some point. --jimz
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*/
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if (nRrdNodes == 0) {
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nRrdNodes = 1;
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rdnodesFaked = 1;
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} else {
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rdnodesFaked = 0;
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}
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/* lock, unlock, xor, Wnd, Rrd, W(nfaults) */
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nNodes = 5 + nfaults + nWndNodes + nRrdNodes;
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RF_CallocAndAdd(nodes, nNodes, sizeof(RF_DagNode_t),
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(RF_DagNode_t *), allocList);
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i = 0;
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blockNode = &nodes[i];
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i += 1;
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commitNode = &nodes[i];
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i += 1;
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unblockNode = &nodes[i];
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i += 1;
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termNode = &nodes[i];
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i += 1;
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xorNode = &nodes[i];
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i += 1;
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wnpNode = &nodes[i];
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i += 1;
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wndNodes = &nodes[i];
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i += nWndNodes;
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rrdNodes = &nodes[i];
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i += nRrdNodes;
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if (nfaults == 2) {
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wnqNode = &nodes[i];
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i += 1;
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} else {
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wnqNode = NULL;
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}
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RF_ASSERT(i == nNodes);
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/* this dag can not commit until all rrd and xor Nodes have completed */
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dag_h->numCommitNodes = 1;
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dag_h->numCommits = 0;
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dag_h->numSuccedents = 1;
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RF_ASSERT(nRrdNodes > 0);
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rf_InitNode(blockNode, rf_wait, RF_FALSE, rf_NullNodeFunc, rf_NullNodeUndoFunc,
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NULL, nRrdNodes, 0, 0, 0, dag_h, "Nil", allocList);
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rf_InitNode(commitNode, rf_wait, RF_TRUE, rf_NullNodeFunc, rf_NullNodeUndoFunc,
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NULL, nWndNodes + nfaults, 1, 0, 0, dag_h, "Cmt", allocList);
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rf_InitNode(unblockNode, rf_wait, RF_FALSE, rf_NullNodeFunc, rf_NullNodeUndoFunc,
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NULL, 1, nWndNodes + nfaults, 0, 0, dag_h, "Nil", allocList);
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rf_InitNode(termNode, rf_wait, RF_FALSE, rf_TerminateFunc, rf_TerminateUndoFunc,
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NULL, 0, 1, 0, 0, dag_h, "Trm", allocList);
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rf_InitNode(xorNode, rf_wait, RF_FALSE, redFunc, rf_NullNodeUndoFunc, NULL, 1,
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nRrdNodes, 2 * nXorBufs + 2, nfaults, dag_h, "Xrc", allocList);
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/*
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* Fill in the Rrd nodes. If any of the rrd buffers are the same size as
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* the failed buffer, save a pointer to it so we can use it as the target
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* of the XOR. The pdas in the rrd nodes have been range-restricted, so if
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* a buffer is the same size as the failed buffer, it must also be at the
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* same alignment within the SU.
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*/
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i = 0;
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if (new_asm_h[0]) {
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for (i = 0, pda = new_asm_h[0]->stripeMap->physInfo;
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i < new_asm_h[0]->stripeMap->numStripeUnitsAccessed;
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i++, pda = pda->next) {
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rf_InitNode(&rrdNodes[i], rf_wait, RF_FALSE, rf_DiskReadFunc, rf_DiskReadUndoFunc,
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rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h, "Rrd", allocList);
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RF_ASSERT(pda);
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rrdNodes[i].params[0].p = pda;
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rrdNodes[i].params[1].p = pda->bufPtr;
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rrdNodes[i].params[2].v = parityStripeID;
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rrdNodes[i].params[3].v = RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
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}
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}
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/* i now equals the number of stripe units accessed in new_asm_h[0] */
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if (new_asm_h[1]) {
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for (j = 0, pda = new_asm_h[1]->stripeMap->physInfo;
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j < new_asm_h[1]->stripeMap->numStripeUnitsAccessed;
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j++, pda = pda->next) {
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rf_InitNode(&rrdNodes[i + j], rf_wait, RF_FALSE, rf_DiskReadFunc, rf_DiskReadUndoFunc,
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rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h, "Rrd", allocList);
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RF_ASSERT(pda);
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rrdNodes[i + j].params[0].p = pda;
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rrdNodes[i + j].params[1].p = pda->bufPtr;
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rrdNodes[i + j].params[2].v = parityStripeID;
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rrdNodes[i + j].params[3].v = RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
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if (allowBufferRecycle && (pda->numSector == failedPDA->numSector))
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xorTargetBuf = pda->bufPtr;
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}
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}
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if (rdnodesFaked) {
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/*
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* This is where we'll init that fake noop read node
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* (XXX should the wakeup func be different?)
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*/
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rf_InitNode(&rrdNodes[0], rf_wait, RF_FALSE, rf_NullNodeFunc, rf_NullNodeUndoFunc,
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NULL, 1, 1, 0, 0, dag_h, "RrN", allocList);
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}
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/*
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* Make a PDA for the parity unit. The parity PDA should start at
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* the same offset into the SU as the failed PDA.
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*/
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/* Danner comment: I don't think this copy is really necessary. We are
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* in one of two cases here. (1) The entire failed unit is written.
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* Then asmap->parityInfo will describe the entire parity. (2) We are
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* only writing a subset of the failed unit and nothing else. Then the
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* asmap->parityInfo describes the failed unit and the copy can also
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* be avoided. */
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RF_MallocAndAdd(parityPDA, sizeof(RF_PhysDiskAddr_t), (RF_PhysDiskAddr_t *), allocList);
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parityPDA->row = asmap->parityInfo->row;
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parityPDA->col = asmap->parityInfo->col;
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parityPDA->startSector = ((asmap->parityInfo->startSector / sectorsPerSU)
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* sectorsPerSU) + (failedPDA->startSector % sectorsPerSU);
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parityPDA->numSector = failedPDA->numSector;
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if (!xorTargetBuf) {
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RF_CallocAndAdd(xorTargetBuf, 1,
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rf_RaidAddressToByte(raidPtr, failedPDA->numSector), (char *), allocList);
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}
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/* init the Wnp node */
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rf_InitNode(wnpNode, rf_wait, RF_FALSE, rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
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rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h, "Wnp", allocList);
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wnpNode->params[0].p = parityPDA;
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wnpNode->params[1].p = xorTargetBuf;
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wnpNode->params[2].v = parityStripeID;
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wnpNode->params[3].v = RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
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/* fill in the Wnq Node */
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if (nfaults == 2) {
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{
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RF_MallocAndAdd(parityPDA, sizeof(RF_PhysDiskAddr_t),
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(RF_PhysDiskAddr_t *), allocList);
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parityPDA->row = asmap->qInfo->row;
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parityPDA->col = asmap->qInfo->col;
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parityPDA->startSector = ((asmap->qInfo->startSector / sectorsPerSU)
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* sectorsPerSU) + (failedPDA->startSector % sectorsPerSU);
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parityPDA->numSector = failedPDA->numSector;
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rf_InitNode(wnqNode, rf_wait, RF_FALSE, rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
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rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h, "Wnq", allocList);
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wnqNode->params[0].p = parityPDA;
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RF_CallocAndAdd(xorNode->results[1], 1,
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rf_RaidAddressToByte(raidPtr, failedPDA->numSector), (char *), allocList);
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wnqNode->params[1].p = xorNode->results[1];
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wnqNode->params[2].v = parityStripeID;
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wnqNode->params[3].v = RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
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}
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}
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/* fill in the Wnd nodes */
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for (pda = asmap->physInfo, i = 0; i < nWndNodes; i++, pda = pda->next) {
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if (pda == failedPDA) {
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i--;
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continue;
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}
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rf_InitNode(&wndNodes[i], rf_wait, RF_FALSE, rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
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rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h, "Wnd", allocList);
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RF_ASSERT(pda);
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wndNodes[i].params[0].p = pda;
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wndNodes[i].params[1].p = pda->bufPtr;
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wndNodes[i].params[2].v = parityStripeID;
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wndNodes[i].params[3].v = RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
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}
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/* fill in the results of the xor node */
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xorNode->results[0] = xorTargetBuf;
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/* fill in the params of the xor node */
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paramNum = 0;
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if (rdnodesFaked == 0) {
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for (i = 0; i < nRrdNodes; i++) {
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/* all the Rrd nodes need to be xored together */
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xorNode->params[paramNum++] = rrdNodes[i].params[0];
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xorNode->params[paramNum++] = rrdNodes[i].params[1];
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}
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}
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for (i = 0; i < nWndNodes; i++) {
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/* any Wnd nodes that overlap the failed access need to be
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* xored in */
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if (overlappingPDAs[i]) {
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RF_MallocAndAdd(pda, sizeof(RF_PhysDiskAddr_t), (RF_PhysDiskAddr_t *), allocList);
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bcopy((char *) wndNodes[i].params[0].p, (char *) pda, sizeof(RF_PhysDiskAddr_t));
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rf_RangeRestrictPDA(raidPtr, failedPDA, pda, RF_RESTRICT_DOBUFFER, 0);
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xorNode->params[paramNum++].p = pda;
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xorNode->params[paramNum++].p = pda->bufPtr;
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}
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}
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RF_Free(overlappingPDAs, asmap->numStripeUnitsAccessed * sizeof(char));
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/*
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* Install the failed PDA into the xor param list so that the
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* new data gets xor'd in.
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*/
|
|
xorNode->params[paramNum++].p = failedPDA;
|
|
xorNode->params[paramNum++].p = failedPDA->bufPtr;
|
|
|
|
/*
|
|
* The last 2 params to the recovery xor node are always the failed
|
|
* PDA and the raidPtr. install the failedPDA even though we have just
|
|
* done so above. This allows us to use the same XOR function for both
|
|
* degraded reads and degraded writes.
|
|
*/
|
|
xorNode->params[paramNum++].p = failedPDA;
|
|
xorNode->params[paramNum++].p = raidPtr;
|
|
RF_ASSERT(paramNum == 2 * nXorBufs + 2);
|
|
|
|
/*
|
|
* Code to link nodes begins here
|
|
*/
|
|
|
|
/* link header to block node */
|
|
RF_ASSERT(blockNode->numAntecedents == 0);
|
|
dag_h->succedents[0] = blockNode;
|
|
|
|
/* link block node to rd nodes */
|
|
RF_ASSERT(blockNode->numSuccedents == nRrdNodes);
|
|
for (i = 0; i < nRrdNodes; i++) {
|
|
RF_ASSERT(rrdNodes[i].numAntecedents == 1);
|
|
blockNode->succedents[i] = &rrdNodes[i];
|
|
rrdNodes[i].antecedents[0] = blockNode;
|
|
rrdNodes[i].antType[0] = rf_control;
|
|
}
|
|
|
|
/* link read nodes to xor node */
|
|
RF_ASSERT(xorNode->numAntecedents == nRrdNodes);
|
|
for (i = 0; i < nRrdNodes; i++) {
|
|
RF_ASSERT(rrdNodes[i].numSuccedents == 1);
|
|
rrdNodes[i].succedents[0] = xorNode;
|
|
xorNode->antecedents[i] = &rrdNodes[i];
|
|
xorNode->antType[i] = rf_trueData;
|
|
}
|
|
|
|
/* link xor node to commit node */
|
|
RF_ASSERT(xorNode->numSuccedents == 1);
|
|
RF_ASSERT(commitNode->numAntecedents == 1);
|
|
xorNode->succedents[0] = commitNode;
|
|
commitNode->antecedents[0] = xorNode;
|
|
commitNode->antType[0] = rf_control;
|
|
|
|
/* link commit node to wnd nodes */
|
|
RF_ASSERT(commitNode->numSuccedents == nfaults + nWndNodes);
|
|
for (i = 0; i < nWndNodes; i++) {
|
|
RF_ASSERT(wndNodes[i].numAntecedents == 1);
|
|
commitNode->succedents[i] = &wndNodes[i];
|
|
wndNodes[i].antecedents[0] = commitNode;
|
|
wndNodes[i].antType[0] = rf_control;
|
|
}
|
|
|
|
/* link the commit node to wnp, wnq nodes */
|
|
RF_ASSERT(wnpNode->numAntecedents == 1);
|
|
commitNode->succedents[nWndNodes] = wnpNode;
|
|
wnpNode->antecedents[0] = commitNode;
|
|
wnpNode->antType[0] = rf_control;
|
|
if (nfaults == 2) {
|
|
RF_ASSERT(wnqNode->numAntecedents == 1);
|
|
commitNode->succedents[nWndNodes + 1] = wnqNode;
|
|
wnqNode->antecedents[0] = commitNode;
|
|
wnqNode->antType[0] = rf_control;
|
|
}
|
|
/* link write new data nodes to unblock node */
|
|
RF_ASSERT(unblockNode->numAntecedents == (nWndNodes + nfaults));
|
|
for (i = 0; i < nWndNodes; i++) {
|
|
RF_ASSERT(wndNodes[i].numSuccedents == 1);
|
|
wndNodes[i].succedents[0] = unblockNode;
|
|
unblockNode->antecedents[i] = &wndNodes[i];
|
|
unblockNode->antType[i] = rf_control;
|
|
}
|
|
|
|
/* link write new parity node to unblock node */
|
|
RF_ASSERT(wnpNode->numSuccedents == 1);
|
|
wnpNode->succedents[0] = unblockNode;
|
|
unblockNode->antecedents[nWndNodes] = wnpNode;
|
|
unblockNode->antType[nWndNodes] = rf_control;
|
|
|
|
/* link write new q node to unblock node */
|
|
if (nfaults == 2) {
|
|
RF_ASSERT(wnqNode->numSuccedents == 1);
|
|
wnqNode->succedents[0] = unblockNode;
|
|
unblockNode->antecedents[nWndNodes + 1] = wnqNode;
|
|
unblockNode->antType[nWndNodes + 1] = rf_control;
|
|
}
|
|
/* link unblock node to term node */
|
|
RF_ASSERT(unblockNode->numSuccedents == 1);
|
|
RF_ASSERT(termNode->numAntecedents == 1);
|
|
RF_ASSERT(termNode->numSuccedents == 0);
|
|
unblockNode->succedents[0] = termNode;
|
|
termNode->antecedents[0] = unblockNode;
|
|
termNode->antType[0] = rf_control;
|
|
}
|
|
#define CONS_PDA(if,start,num) \
|
|
pda_p->row = asmap->if->row; pda_p->col = asmap->if->col; \
|
|
pda_p->startSector = ((asmap->if->startSector / secPerSU) * secPerSU) + start; \
|
|
pda_p->numSector = num; \
|
|
pda_p->next = NULL; \
|
|
RF_MallocAndAdd(pda_p->bufPtr,rf_RaidAddressToByte(raidPtr,num),(char *), allocList)
|
|
#if (RF_INCLUDE_PQ > 0) || (RF_INCLUDE_EVENODD > 0)
|
|
void
|
|
rf_WriteGenerateFailedAccessASMs(
|
|
RF_Raid_t * raidPtr,
|
|
RF_AccessStripeMap_t * asmap,
|
|
RF_PhysDiskAddr_t ** pdap,
|
|
int *nNodep,
|
|
RF_PhysDiskAddr_t ** pqpdap,
|
|
int *nPQNodep,
|
|
RF_AllocListElem_t * allocList)
|
|
{
|
|
RF_RaidLayout_t *layoutPtr = &(raidPtr->Layout);
|
|
int PDAPerDisk, i;
|
|
RF_SectorCount_t secPerSU = layoutPtr->sectorsPerStripeUnit;
|
|
int numDataCol = layoutPtr->numDataCol;
|
|
int state;
|
|
unsigned napdas;
|
|
RF_SectorNum_t fone_start, fone_end, ftwo_start = 0, ftwo_end;
|
|
RF_PhysDiskAddr_t *fone = asmap->failedPDAs[0], *ftwo = asmap->failedPDAs[1];
|
|
RF_PhysDiskAddr_t *pda_p;
|
|
RF_RaidAddr_t sosAddr;
|
|
|
|
/* determine how many pda's we will have to generate per unaccess
|
|
* stripe. If there is only one failed data unit, it is one; if two,
|
|
* possibly two, depending wether they overlap. */
|
|
|
|
fone_start = rf_StripeUnitOffset(layoutPtr, fone->startSector);
|
|
fone_end = fone_start + fone->numSector;
|
|
|
|
if (asmap->numDataFailed == 1) {
|
|
PDAPerDisk = 1;
|
|
state = 1;
|
|
RF_MallocAndAdd(*pqpdap, 2 * sizeof(RF_PhysDiskAddr_t), (RF_PhysDiskAddr_t *), allocList);
|
|
pda_p = *pqpdap;
|
|
/* build p */
|
|
CONS_PDA(parityInfo, fone_start, fone->numSector);
|
|
pda_p->type = RF_PDA_TYPE_PARITY;
|
|
pda_p++;
|
|
/* build q */
|
|
CONS_PDA(qInfo, fone_start, fone->numSector);
|
|
pda_p->type = RF_PDA_TYPE_Q;
|
|
} else {
|
|
ftwo_start = rf_StripeUnitOffset(layoutPtr, ftwo->startSector);
|
|
ftwo_end = ftwo_start + ftwo->numSector;
|
|
if (fone->numSector + ftwo->numSector > secPerSU) {
|
|
PDAPerDisk = 1;
|
|
state = 2;
|
|
RF_MallocAndAdd(*pqpdap, 2 * sizeof(RF_PhysDiskAddr_t), (RF_PhysDiskAddr_t *), allocList);
|
|
pda_p = *pqpdap;
|
|
CONS_PDA(parityInfo, 0, secPerSU);
|
|
pda_p->type = RF_PDA_TYPE_PARITY;
|
|
pda_p++;
|
|
CONS_PDA(qInfo, 0, secPerSU);
|
|
pda_p->type = RF_PDA_TYPE_Q;
|
|
} else {
|
|
PDAPerDisk = 2;
|
|
state = 3;
|
|
/* four of them, fone, then ftwo */
|
|
RF_MallocAndAdd(*pqpdap, 4 * sizeof(RF_PhysDiskAddr_t), (RF_PhysDiskAddr_t *), allocList);
|
|
pda_p = *pqpdap;
|
|
CONS_PDA(parityInfo, fone_start, fone->numSector);
|
|
pda_p->type = RF_PDA_TYPE_PARITY;
|
|
pda_p++;
|
|
CONS_PDA(qInfo, fone_start, fone->numSector);
|
|
pda_p->type = RF_PDA_TYPE_Q;
|
|
pda_p++;
|
|
CONS_PDA(parityInfo, ftwo_start, ftwo->numSector);
|
|
pda_p->type = RF_PDA_TYPE_PARITY;
|
|
pda_p++;
|
|
CONS_PDA(qInfo, ftwo_start, ftwo->numSector);
|
|
pda_p->type = RF_PDA_TYPE_Q;
|
|
}
|
|
}
|
|
/* figure out number of nonaccessed pda */
|
|
napdas = PDAPerDisk * (numDataCol - 2);
|
|
*nPQNodep = PDAPerDisk;
|
|
|
|
*nNodep = napdas;
|
|
if (napdas == 0)
|
|
return; /* short circuit */
|
|
|
|
/* allocate up our list of pda's */
|
|
|
|
RF_CallocAndAdd(pda_p, napdas, sizeof(RF_PhysDiskAddr_t), (RF_PhysDiskAddr_t *), allocList);
|
|
*pdap = pda_p;
|
|
|
|
/* linkem together */
|
|
for (i = 0; i < (napdas - 1); i++)
|
|
pda_p[i].next = pda_p + (i + 1);
|
|
|
|
sosAddr = rf_RaidAddressOfPrevStripeBoundary(layoutPtr, asmap->raidAddress);
|
|
for (i = 0; i < numDataCol; i++) {
|
|
if ((pda_p - (*pdap)) == napdas)
|
|
continue;
|
|
pda_p->type = RF_PDA_TYPE_DATA;
|
|
pda_p->raidAddress = sosAddr + (i * secPerSU);
|
|
(raidPtr->Layout.map->MapSector) (raidPtr, pda_p->raidAddress, &(pda_p->row), &(pda_p->col), &(pda_p->startSector), 0);
|
|
/* skip over dead disks */
|
|
if (RF_DEAD_DISK(raidPtr->Disks[pda_p->row][pda_p->col].status))
|
|
continue;
|
|
switch (state) {
|
|
case 1: /* fone */
|
|
pda_p->numSector = fone->numSector;
|
|
pda_p->raidAddress += fone_start;
|
|
pda_p->startSector += fone_start;
|
|
RF_MallocAndAdd(pda_p->bufPtr, rf_RaidAddressToByte(raidPtr, pda_p->numSector), (char *), allocList);
|
|
break;
|
|
case 2: /* full stripe */
|
|
pda_p->numSector = secPerSU;
|
|
RF_MallocAndAdd(pda_p->bufPtr, rf_RaidAddressToByte(raidPtr, secPerSU), (char *), allocList);
|
|
break;
|
|
case 3: /* two slabs */
|
|
pda_p->numSector = fone->numSector;
|
|
pda_p->raidAddress += fone_start;
|
|
pda_p->startSector += fone_start;
|
|
RF_MallocAndAdd(pda_p->bufPtr, rf_RaidAddressToByte(raidPtr, pda_p->numSector), (char *), allocList);
|
|
pda_p++;
|
|
pda_p->type = RF_PDA_TYPE_DATA;
|
|
pda_p->raidAddress = sosAddr + (i * secPerSU);
|
|
(raidPtr->Layout.map->MapSector) (raidPtr, pda_p->raidAddress, &(pda_p->row), &(pda_p->col), &(pda_p->startSector), 0);
|
|
pda_p->numSector = ftwo->numSector;
|
|
pda_p->raidAddress += ftwo_start;
|
|
pda_p->startSector += ftwo_start;
|
|
RF_MallocAndAdd(pda_p->bufPtr, rf_RaidAddressToByte(raidPtr, pda_p->numSector), (char *), allocList);
|
|
break;
|
|
default:
|
|
RF_PANIC();
|
|
}
|
|
pda_p++;
|
|
}
|
|
|
|
RF_ASSERT(pda_p - *pdap == napdas);
|
|
return;
|
|
}
|
|
#define DISK_NODE_PDA(node) ((node)->params[0].p)
|
|
|
|
#define DISK_NODE_PARAMS(_node_,_p_) \
|
|
(_node_).params[0].p = _p_ ; \
|
|
(_node_).params[1].p = (_p_)->bufPtr; \
|
|
(_node_).params[2].v = parityStripeID; \
|
|
(_node_).params[3].v = RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru)
|
|
|
|
void
|
|
rf_DoubleDegSmallWrite(
|
|
RF_Raid_t * raidPtr,
|
|
RF_AccessStripeMap_t * asmap,
|
|
RF_DagHeader_t * dag_h,
|
|
void *bp,
|
|
RF_RaidAccessFlags_t flags,
|
|
RF_AllocListElem_t * allocList,
|
|
char *redundantReadNodeName,
|
|
char *redundantWriteNodeName,
|
|
char *recoveryNodeName,
|
|
int (*recovFunc) (RF_DagNode_t *))
|
|
{
|
|
RF_RaidLayout_t *layoutPtr = &(raidPtr->Layout);
|
|
RF_DagNode_t *nodes, *wudNodes, *rrdNodes, *recoveryNode, *blockNode,
|
|
*unblockNode, *rpNodes, *rqNodes, *wpNodes, *wqNodes, *termNode;
|
|
RF_PhysDiskAddr_t *pda, *pqPDAs;
|
|
RF_PhysDiskAddr_t *npdas;
|
|
int nWriteNodes, nNodes, nReadNodes, nRrdNodes, nWudNodes, i;
|
|
RF_ReconUnitNum_t which_ru;
|
|
int nPQNodes;
|
|
RF_StripeNum_t parityStripeID = rf_RaidAddressToParityStripeID(layoutPtr, asmap->raidAddress, &which_ru);
|
|
|
|
/* simple small write case - First part looks like a reconstruct-read
|
|
* of the failed data units. Then a write of all data units not
|
|
* failed. */
|
|
|
|
|
|
/* Hdr | ------Block- / / \ Rrd Rrd ... Rrd Rp Rq \ \
|
|
* / -------PQ----- / \ \ Wud Wp WQ \ | /
|
|
* --Unblock- | T
|
|
*
|
|
* Rrd = read recovery data (potentially none) Wud = write user data
|
|
* (not incl. failed disks) Wp = Write P (could be two) Wq = Write Q
|
|
* (could be two)
|
|
*
|
|
*/
|
|
|
|
rf_WriteGenerateFailedAccessASMs(raidPtr, asmap, &npdas, &nRrdNodes, &pqPDAs, &nPQNodes, allocList);
|
|
|
|
RF_ASSERT(asmap->numDataFailed == 1);
|
|
|
|
nWudNodes = asmap->numStripeUnitsAccessed - (asmap->numDataFailed);
|
|
nReadNodes = nRrdNodes + 2 * nPQNodes;
|
|
nWriteNodes = nWudNodes + 2 * nPQNodes;
|
|
nNodes = 4 + nReadNodes + nWriteNodes;
|
|
|
|
RF_CallocAndAdd(nodes, nNodes, sizeof(RF_DagNode_t), (RF_DagNode_t *), allocList);
|
|
blockNode = nodes;
|
|
unblockNode = blockNode + 1;
|
|
termNode = unblockNode + 1;
|
|
recoveryNode = termNode + 1;
|
|
rrdNodes = recoveryNode + 1;
|
|
rpNodes = rrdNodes + nRrdNodes;
|
|
rqNodes = rpNodes + nPQNodes;
|
|
wudNodes = rqNodes + nPQNodes;
|
|
wpNodes = wudNodes + nWudNodes;
|
|
wqNodes = wpNodes + nPQNodes;
|
|
|
|
dag_h->creator = "PQ_DDSimpleSmallWrite";
|
|
dag_h->numSuccedents = 1;
|
|
dag_h->succedents[0] = blockNode;
|
|
rf_InitNode(termNode, rf_wait, RF_FALSE, rf_TerminateFunc, rf_TerminateUndoFunc, NULL, 0, 1, 0, 0, dag_h, "Trm", allocList);
|
|
termNode->antecedents[0] = unblockNode;
|
|
termNode->antType[0] = rf_control;
|
|
|
|
/* init the block and unblock nodes */
|
|
/* The block node has all the read nodes as successors */
|
|
rf_InitNode(blockNode, rf_wait, RF_FALSE, rf_NullNodeFunc, rf_NullNodeUndoFunc, NULL, nReadNodes, 0, 0, 0, dag_h, "Nil", allocList);
|
|
for (i = 0; i < nReadNodes; i++)
|
|
blockNode->succedents[i] = rrdNodes + i;
|
|
|
|
/* The unblock node has all the writes as successors */
|
|
rf_InitNode(unblockNode, rf_wait, RF_FALSE, rf_NullNodeFunc, rf_NullNodeUndoFunc, NULL, 1, nWriteNodes, 0, 0, dag_h, "Nil", allocList);
|
|
for (i = 0; i < nWriteNodes; i++) {
|
|
unblockNode->antecedents[i] = wudNodes + i;
|
|
unblockNode->antType[i] = rf_control;
|
|
}
|
|
unblockNode->succedents[0] = termNode;
|
|
|
|
#define INIT_READ_NODE(node,name) \
|
|
rf_InitNode(node, rf_wait, RF_FALSE, rf_DiskReadFunc, rf_DiskReadUndoFunc, rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h, name, allocList); \
|
|
(node)->succedents[0] = recoveryNode; \
|
|
(node)->antecedents[0] = blockNode; \
|
|
(node)->antType[0] = rf_control;
|
|
|
|
/* build the read nodes */
|
|
pda = npdas;
|
|
for (i = 0; i < nRrdNodes; i++, pda = pda->next) {
|
|
INIT_READ_NODE(rrdNodes + i, "rrd");
|
|
DISK_NODE_PARAMS(rrdNodes[i], pda);
|
|
}
|
|
|
|
/* read redundancy pdas */
|
|
pda = pqPDAs;
|
|
INIT_READ_NODE(rpNodes, "Rp");
|
|
RF_ASSERT(pda);
|
|
DISK_NODE_PARAMS(rpNodes[0], pda);
|
|
pda++;
|
|
INIT_READ_NODE(rqNodes, redundantReadNodeName);
|
|
RF_ASSERT(pda);
|
|
DISK_NODE_PARAMS(rqNodes[0], pda);
|
|
if (nPQNodes == 2) {
|
|
pda++;
|
|
INIT_READ_NODE(rpNodes + 1, "Rp");
|
|
RF_ASSERT(pda);
|
|
DISK_NODE_PARAMS(rpNodes[1], pda);
|
|
pda++;
|
|
INIT_READ_NODE(rqNodes + 1, redundantReadNodeName);
|
|
RF_ASSERT(pda);
|
|
DISK_NODE_PARAMS(rqNodes[1], pda);
|
|
}
|
|
/* the recovery node has all reads as precedessors and all writes as
|
|
* successors. It generates a result for every write P or write Q
|
|
* node. As parameters, it takes a pda per read and a pda per stripe
|
|
* of user data written. It also takes as the last params the raidPtr
|
|
* and asm. For results, it takes PDA for P & Q. */
|
|
|
|
|
|
rf_InitNode(recoveryNode, rf_wait, RF_FALSE, recovFunc, rf_NullNodeUndoFunc, NULL,
|
|
nWriteNodes, /* succesors */
|
|
nReadNodes, /* preds */
|
|
nReadNodes + nWudNodes + 3, /* params */
|
|
2 * nPQNodes, /* results */
|
|
dag_h, recoveryNodeName, allocList);
|
|
|
|
|
|
|
|
for (i = 0; i < nReadNodes; i++) {
|
|
recoveryNode->antecedents[i] = rrdNodes + i;
|
|
recoveryNode->antType[i] = rf_control;
|
|
recoveryNode->params[i].p = DISK_NODE_PDA(rrdNodes + i);
|
|
}
|
|
for (i = 0; i < nWudNodes; i++) {
|
|
recoveryNode->succedents[i] = wudNodes + i;
|
|
}
|
|
recoveryNode->params[nReadNodes + nWudNodes].p = asmap->failedPDAs[0];
|
|
recoveryNode->params[nReadNodes + nWudNodes + 1].p = raidPtr;
|
|
recoveryNode->params[nReadNodes + nWudNodes + 2].p = asmap;
|
|
|
|
for (; i < nWriteNodes; i++)
|
|
recoveryNode->succedents[i] = wudNodes + i;
|
|
|
|
pda = pqPDAs;
|
|
recoveryNode->results[0] = pda;
|
|
pda++;
|
|
recoveryNode->results[1] = pda;
|
|
if (nPQNodes == 2) {
|
|
pda++;
|
|
recoveryNode->results[2] = pda;
|
|
pda++;
|
|
recoveryNode->results[3] = pda;
|
|
}
|
|
/* fill writes */
|
|
#define INIT_WRITE_NODE(node,name) \
|
|
rf_InitNode(node, rf_wait, RF_FALSE, rf_DiskWriteFunc, rf_DiskWriteUndoFunc, rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h, name, allocList); \
|
|
(node)->succedents[0] = unblockNode; \
|
|
(node)->antecedents[0] = recoveryNode; \
|
|
(node)->antType[0] = rf_control;
|
|
|
|
pda = asmap->physInfo;
|
|
for (i = 0; i < nWudNodes; i++) {
|
|
INIT_WRITE_NODE(wudNodes + i, "Wd");
|
|
DISK_NODE_PARAMS(wudNodes[i], pda);
|
|
recoveryNode->params[nReadNodes + i].p = DISK_NODE_PDA(wudNodes + i);
|
|
pda = pda->next;
|
|
}
|
|
/* write redundancy pdas */
|
|
pda = pqPDAs;
|
|
INIT_WRITE_NODE(wpNodes, "Wp");
|
|
RF_ASSERT(pda);
|
|
DISK_NODE_PARAMS(wpNodes[0], pda);
|
|
pda++;
|
|
INIT_WRITE_NODE(wqNodes, "Wq");
|
|
RF_ASSERT(pda);
|
|
DISK_NODE_PARAMS(wqNodes[0], pda);
|
|
if (nPQNodes == 2) {
|
|
pda++;
|
|
INIT_WRITE_NODE(wpNodes + 1, "Wp");
|
|
RF_ASSERT(pda);
|
|
DISK_NODE_PARAMS(wpNodes[1], pda);
|
|
pda++;
|
|
INIT_WRITE_NODE(wqNodes + 1, "Wq");
|
|
RF_ASSERT(pda);
|
|
DISK_NODE_PARAMS(wqNodes[1], pda);
|
|
}
|
|
}
|
|
#endif /* (RF_INCLUDE_PQ > 0) || (RF_INCLUDE_EVENODD > 0) */
|