File: [local] / sys / dev / raidframe / rf_dagffwr.c (download)
Revision 1.1.1.1 (vendor branch), Tue Mar 4 16:09:45 2008 UTC (16 years, 4 months ago) by nbrk
Branch: OPENBSD_4_2_BASE, MAIN
CVS Tags: jornada-partial-support-wip, HEAD Changes since 1.1: +0 -0 lines
Import of OpenBSD 4.2 release kernel tree with initial code to support
Jornada 720/728, StrongARM 1110-based handheld PC.
At this point kernel roots on NFS and boots into vfs_mountroot() and traps.
What is supported:
- glass console, Jornada framebuffer (jfb) works in 16bpp direct color mode
(needs some palette tweaks for non black/white/blue colors, i think)
- saic, SA11x0 interrupt controller (needs cleanup)
- sacom, SA11x0 UART (supported only as boot console for now)
- SA11x0 GPIO controller fully supported (but can't handle multiple interrupt
handlers on one gpio pin)
- sassp, SSP port on SA11x0 that attaches spibus
- Jornada microcontroller (jmcu) to control kbd, battery, etc throught
the SPI bus (wskbd attaches on jmcu, but not tested)
- tod functions seem work
- initial code for SA-1111 (chip companion) : this is TODO
Next important steps, i think:
- gpio and intc on sa1111
- pcmcia support for sa11x0 (and sa1111 help logic)
- REAL root on nfs when we have PCMCIA support (we may use any of supported pccard NICs)
- root on wd0! (using already supported PCMCIA-ATA)
|
/* $OpenBSD: rf_dagffwr.c,v 1.5 2002/12/16 07:01:03 tdeval Exp $ */
/* $NetBSD: rf_dagffwr.c,v 1.5 2000/01/07 03:40:58 oster Exp $ */
/*
* Copyright (c) 1995 Carnegie-Mellon University.
* All rights reserved.
*
* Author: Mark Holland, Daniel Stodolsky, William V. Courtright II
*
* Permission to use, copy, modify and distribute this software and
* its documentation is hereby granted, provided that both the copyright
* notice and this permission notice appear in all copies of the
* software, derivative works or modified versions, and any portions
* thereof, and that both notices appear in supporting documentation.
*
* CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
* CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND
* FOR ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
*
* Carnegie Mellon requests users of this software to return to
*
* Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
* School of Computer Science
* Carnegie Mellon University
* Pittsburgh PA 15213-3890
*
* any improvements or extensions that they make and grant Carnegie the
* rights to redistribute these changes.
*/
/*
* rf_dagff.c
*
* Code for creating fault-free DAGs.
*
*/
#include "rf_types.h"
#include "rf_raid.h"
#include "rf_dag.h"
#include "rf_dagutils.h"
#include "rf_dagfuncs.h"
#include "rf_debugMem.h"
#include "rf_dagffrd.h"
#include "rf_memchunk.h"
#include "rf_general.h"
#include "rf_dagffwr.h"
/*****************************************************************************
*
* General comments on DAG creation:
*
* All DAGs in this file use roll-away error recovery. Each DAG has a single
* commit node, usually called "Cmt." If an error occurs before the Cmt node
* is reached, the execution engine will halt forward execution and work
* backward through the graph, executing the undo functions. Assuming that
* each node in the graph prior to the Cmt node are undoable and atomic - or -
* does not make changes to permanent state, the graph will fail atomically.
* If an error occurs after the Cmt node executes, the engine will roll-forward
* through the graph, blindly executing nodes until it reaches the end.
* If a graph reaches the end, it is assumed to have completed successfully.
*
* A graph has only 1 Cmt node.
*
*****************************************************************************/
/*****************************************************************************
*
* The following wrappers map the standard DAG creation interface to the
* DAG creation routines. Additionally, these wrappers enable experimentation
* with new DAG structures by providing an extra level of indirection, allowing
* the DAG creation routines to be replaced at this single point.
*
*****************************************************************************/
void
rf_CreateNonRedundantWriteDAG(RF_Raid_t *raidPtr, RF_AccessStripeMap_t *asmap,
RF_DagHeader_t *dag_h, void *bp, RF_RaidAccessFlags_t flags,
RF_AllocListElem_t *allocList, RF_IoType_t type)
{
rf_CreateNonredundantDAG(raidPtr, asmap, dag_h, bp, flags, allocList,
RF_IO_TYPE_WRITE);
}
void
rf_CreateRAID0WriteDAG(RF_Raid_t *raidPtr, RF_AccessStripeMap_t *asmap,
RF_DagHeader_t *dag_h, void *bp, RF_RaidAccessFlags_t flags,
RF_AllocListElem_t *allocList, RF_IoType_t type)
{
rf_CreateNonredundantDAG(raidPtr, asmap, dag_h, bp, flags, allocList,
RF_IO_TYPE_WRITE);
}
void
rf_CreateSmallWriteDAG(RF_Raid_t *raidPtr, RF_AccessStripeMap_t *asmap,
RF_DagHeader_t *dag_h, void *bp, RF_RaidAccessFlags_t flags,
RF_AllocListElem_t *allocList)
{
/* "normal" rollaway. */
rf_CommonCreateSmallWriteDAG(raidPtr, asmap, dag_h, bp, flags,
allocList, &rf_xorFuncs, NULL);
}
void
rf_CreateLargeWriteDAG(RF_Raid_t *raidPtr, RF_AccessStripeMap_t *asmap,
RF_DagHeader_t *dag_h, void *bp, RF_RaidAccessFlags_t flags,
RF_AllocListElem_t *allocList)
{
/* "normal" rollaway. */
rf_CommonCreateLargeWriteDAG(raidPtr, asmap, dag_h, bp, flags,
allocList, 1, rf_RegularXorFunc, RF_TRUE);
}
/*****************************************************************************
*
* DAG creation code begins here.
*
*****************************************************************************/
/*****************************************************************************
*
* creates a DAG to perform a large-write operation:
*
* / Rod \ / Wnd \
* H -- block- Rod - Xor - Cmt - Wnd --- T
* \ Rod / \ Wnp /
* \[Wnq]/
*
* The XOR node also does the Q calculation in the P+Q architecture.
* All nodes that are before the commit node (Cmt) are assumed to be atomic
* and undoable - or - they make no changes to permanent state.
*
* Rod = read old data
* Cmt = commit node
* Wnp = write new parity
* Wnd = write new data
* Wnq = write new "q"
* [] denotes optional segments in the graph.
*
* Parameters: raidPtr - description of the physical array
* asmap - logical & physical addresses for this access
* bp - buffer ptr (holds write data)
* flags - general flags (e.g. disk locking)
* allocList - list of memory allocated in DAG creation
* nfaults - number of faults array can tolerate
* (equal to # redundancy units in stripe)
* redfuncs - list of redundancy generating functions
*
*****************************************************************************/
void
rf_CommonCreateLargeWriteDAG(RF_Raid_t *raidPtr, RF_AccessStripeMap_t *asmap,
RF_DagHeader_t *dag_h, void *bp, RF_RaidAccessFlags_t flags,
RF_AllocListElem_t *allocList, int nfaults, int (*redFunc) (RF_DagNode_t *),
int allowBufferRecycle)
{
RF_DagNode_t *nodes, *wndNodes, *rodNodes, *xorNode, *wnpNode;
RF_DagNode_t *wnqNode, *blockNode, *commitNode, *termNode;
int nWndNodes, nRodNodes, i, nodeNum, asmNum;
RF_AccessStripeMapHeader_t *new_asm_h[2];
RF_StripeNum_t parityStripeID;
char *sosBuffer, *eosBuffer;
RF_ReconUnitNum_t which_ru;
RF_RaidLayout_t *layoutPtr;
RF_PhysDiskAddr_t *pda;
layoutPtr = &(raidPtr->Layout);
parityStripeID = rf_RaidAddressToParityStripeID(layoutPtr,
asmap->raidAddress, &which_ru);
if (rf_dagDebug) {
printf("[Creating large-write DAG]\n");
}
dag_h->creator = "LargeWriteDAG";
dag_h->numCommitNodes = 1;
dag_h->numCommits = 0;
dag_h->numSuccedents = 1;
/* Alloc the nodes: Wnd, xor, commit, block, term, and Wnp. */
nWndNodes = asmap->numStripeUnitsAccessed;
RF_CallocAndAdd(nodes, nWndNodes + 4 + nfaults, sizeof(RF_DagNode_t),
(RF_DagNode_t *), allocList);
i = 0;
wndNodes = &nodes[i];
i += nWndNodes;
xorNode = &nodes[i];
i += 1;
wnpNode = &nodes[i];
i += 1;
blockNode = &nodes[i];
i += 1;
commitNode = &nodes[i];
i += 1;
termNode = &nodes[i];
i += 1;
if (nfaults == 2) {
wnqNode = &nodes[i];
i += 1;
} else {
wnqNode = NULL;
}
rf_MapUnaccessedPortionOfStripe(raidPtr, layoutPtr, asmap, dag_h,
new_asm_h, &nRodNodes, &sosBuffer, &eosBuffer, allocList);
if (nRodNodes > 0) {
RF_CallocAndAdd(rodNodes, nRodNodes, sizeof(RF_DagNode_t),
(RF_DagNode_t *), allocList);
} else {
rodNodes = NULL;
}
/* Begin node initialization. */
if (nRodNodes > 0) {
rf_InitNode(blockNode, rf_wait, RF_FALSE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, nRodNodes, 0, 0, 0, dag_h,
"Nil", allocList);
} else {
rf_InitNode(blockNode, rf_wait, RF_FALSE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, 1, 0, 0, 0, dag_h, "Nil",
allocList);
}
rf_InitNode(commitNode, rf_wait, RF_TRUE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, nWndNodes + nfaults, 1, 0, 0,
dag_h, "Cmt", allocList);
rf_InitNode(termNode, rf_wait, RF_FALSE, rf_TerminateFunc,
rf_TerminateUndoFunc, NULL, 0, nWndNodes + nfaults, 0, 0,
dag_h, "Trm", allocList);
/* Initialize the Rod nodes. */
for (nodeNum = asmNum = 0; asmNum < 2; asmNum++) {
if (new_asm_h[asmNum]) {
pda = new_asm_h[asmNum]->stripeMap->physInfo;
while (pda) {
rf_InitNode(&rodNodes[nodeNum], rf_wait,
RF_FALSE, rf_DiskReadFunc,
rf_DiskReadUndoFunc, rf_GenericWakeupFunc,
1, 1, 4, 0, dag_h, "Rod", allocList);
rodNodes[nodeNum].params[0].p = pda;
rodNodes[nodeNum].params[1].p = pda->bufPtr;
rodNodes[nodeNum].params[2].v = parityStripeID;
rodNodes[nodeNum].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, 0, which_ru);
nodeNum++;
pda = pda->next;
}
}
}
RF_ASSERT(nodeNum == nRodNodes);
/* Initialize the wnd nodes. */
pda = asmap->physInfo;
for (i = 0; i < nWndNodes; i++) {
rf_InitNode(&wndNodes[i], rf_wait, RF_FALSE, rf_DiskWriteFunc,
rf_DiskWriteUndoFunc, rf_GenericWakeupFunc, 1, 1, 4, 0,
dag_h, "Wnd", allocList);
RF_ASSERT(pda != NULL);
wndNodes[i].params[0].p = pda;
wndNodes[i].params[1].p = pda->bufPtr;
wndNodes[i].params[2].v = parityStripeID;
wndNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
pda = pda->next;
}
/* Initialize the redundancy node. */
if (nRodNodes > 0) {
rf_InitNode(xorNode, rf_wait, RF_FALSE, redFunc,
rf_NullNodeUndoFunc, NULL, 1, nRodNodes,
2 * (nWndNodes + nRodNodes) + 1, nfaults, dag_h,
"Xr ", allocList);
} else {
rf_InitNode(xorNode, rf_wait, RF_FALSE, redFunc,
rf_NullNodeUndoFunc, NULL, 1, 1,
2 * (nWndNodes + nRodNodes) + 1, nfaults, dag_h,
"Xr ", allocList);
}
xorNode->flags |= RF_DAGNODE_FLAG_YIELD;
for (i = 0; i < nWndNodes; i++) {
xorNode->params[2 * i + 0] =
wndNodes[i].params[0]; /* pda */
xorNode->params[2 * i + 1] =
wndNodes[i].params[1]; /* buf ptr */
}
for (i = 0; i < nRodNodes; i++) {
xorNode->params[2 * (nWndNodes + i) + 0] =
rodNodes[i].params[0]; /* pda */
xorNode->params[2 * (nWndNodes + i) + 1] =
rodNodes[i].params[1]; /* buf ptr */
}
/* Xor node needs to get at RAID information. */
xorNode->params[2 * (nWndNodes + nRodNodes)].p = raidPtr;
/*
* Look for an Rod node that reads a complete SU. If none, alloc
* a buffer to receive the parity info. Note that we can't use a
* new data buffer because it will not have gotten written when
* the xor occurs.
*/
if (allowBufferRecycle) {
for (i = 0; i < nRodNodes; i++) {
if (((RF_PhysDiskAddr_t *) rodNodes[i].params[0].p)
->numSector == raidPtr->Layout.sectorsPerStripeUnit)
break;
}
}
if ((!allowBufferRecycle) || (i == nRodNodes)) {
RF_CallocAndAdd(xorNode->results[0], 1,
rf_RaidAddressToByte(raidPtr,
raidPtr->Layout.sectorsPerStripeUnit),
(void *), allocList);
} else {
xorNode->results[0] = rodNodes[i].params[1].p;
}
/* Initialize the Wnp node. */
rf_InitNode(wnpNode, rf_wait, RF_FALSE, rf_DiskWriteFunc,
rf_DiskWriteUndoFunc, rf_GenericWakeupFunc, 1, 1, 4, 0,
dag_h, "Wnp", allocList);
wnpNode->params[0].p = asmap->parityInfo;
wnpNode->params[1].p = xorNode->results[0];
wnpNode->params[2].v = parityStripeID;
wnpNode->params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
/* parityInfo must describe entire parity unit. */
RF_ASSERT(asmap->parityInfo->next == NULL);
if (nfaults == 2) {
/*
* We never try to recycle a buffer for the Q calculation
* in addition to the parity. This would cause two buffers
* to get smashed during the P and Q calculation, guaranteeing
* one would be wrong.
*/
RF_CallocAndAdd(xorNode->results[1], 1,
rf_RaidAddressToByte(raidPtr,
raidPtr->Layout.sectorsPerStripeUnit),
(void *), allocList);
rf_InitNode(wnqNode, rf_wait, RF_FALSE, rf_DiskWriteFunc,
rf_DiskWriteUndoFunc, rf_GenericWakeupFunc, 1, 1, 4, 0,
dag_h, "Wnq", allocList);
wnqNode->params[0].p = asmap->qInfo;
wnqNode->params[1].p = xorNode->results[1];
wnqNode->params[2].v = parityStripeID;
wnqNode->params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
/* parityInfo must describe entire parity unit. */
RF_ASSERT(asmap->parityInfo->next == NULL);
}
/*
* Connect nodes to form graph.
*/
/* Connect dag header to block node. */
RF_ASSERT(blockNode->numAntecedents == 0);
dag_h->succedents[0] = blockNode;
if (nRodNodes > 0) {
/* Connect the block node to the Rod nodes. */
RF_ASSERT(blockNode->numSuccedents == nRodNodes);
RF_ASSERT(xorNode->numAntecedents == nRodNodes);
for (i = 0; i < nRodNodes; i++) {
RF_ASSERT(rodNodes[i].numAntecedents == 1);
blockNode->succedents[i] = &rodNodes[i];
rodNodes[i].antecedents[0] = blockNode;
rodNodes[i].antType[0] = rf_control;
/* Connect the Rod nodes to the Xor node. */
RF_ASSERT(rodNodes[i].numSuccedents == 1);
rodNodes[i].succedents[0] = xorNode;
xorNode->antecedents[i] = &rodNodes[i];
xorNode->antType[i] = rf_trueData;
}
} else {
/* Connect the block node to the Xor node. */
RF_ASSERT(blockNode->numSuccedents == 1);
RF_ASSERT(xorNode->numAntecedents == 1);
blockNode->succedents[0] = xorNode;
xorNode->antecedents[0] = blockNode;
xorNode->antType[0] = rf_control;
}
/* Connect the xor node to the 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;
/* Connect the commit node to the write nodes. */
RF_ASSERT(commitNode->numSuccedents == nWndNodes + nfaults);
for (i = 0; i < nWndNodes; i++) {
RF_ASSERT(wndNodes->numAntecedents == 1);
commitNode->succedents[i] = &wndNodes[i];
wndNodes[i].antecedents[0] = commitNode;
wndNodes[i].antType[0] = rf_control;
}
RF_ASSERT(wnpNode->numAntecedents == 1);
commitNode->succedents[nWndNodes] = wnpNode;
wnpNode->antecedents[0] = commitNode;
wnpNode->antType[0] = rf_trueData;
if (nfaults == 2) {
RF_ASSERT(wnqNode->numAntecedents == 1);
commitNode->succedents[nWndNodes + 1] = wnqNode;
wnqNode->antecedents[0] = commitNode;
wnqNode->antType[0] = rf_trueData;
}
/* Connect the write nodes to the term node. */
RF_ASSERT(termNode->numAntecedents == nWndNodes + nfaults);
RF_ASSERT(termNode->numSuccedents == 0);
for (i = 0; i < nWndNodes; i++) {
RF_ASSERT(wndNodes->numSuccedents == 1);
wndNodes[i].succedents[0] = termNode;
termNode->antecedents[i] = &wndNodes[i];
termNode->antType[i] = rf_control;
}
RF_ASSERT(wnpNode->numSuccedents == 1);
wnpNode->succedents[0] = termNode;
termNode->antecedents[nWndNodes] = wnpNode;
termNode->antType[nWndNodes] = rf_control;
if (nfaults == 2) {
RF_ASSERT(wnqNode->numSuccedents == 1);
wnqNode->succedents[0] = termNode;
termNode->antecedents[nWndNodes + 1] = wnqNode;
termNode->antType[nWndNodes + 1] = rf_control;
}
}
/*****************************************************************************
*
* Create a DAG to perform a small-write operation (either raid 5 or pq),
* which is as follows:
*
* Hdr -> Nil -> Rop -> Xor -> Cmt ----> Wnp [Unp] --> Trm
* \- Rod X / \----> Wnd [Und]-/
* [\- Rod X / \---> Wnd [Und]-/]
* [\- Roq -> Q / \--> Wnq [Unq]-/]
*
* Rop = read old parity
* Rod = read old data
* Roq = read old "q"
* Cmt = commit node
* Und = unlock data disk
* Unp = unlock parity disk
* Unq = unlock q disk
* Wnp = write new parity
* Wnd = write new data
* Wnq = write new "q"
* [ ] denotes optional segments in the graph.
*
* Parameters: raidPtr - description of the physical array
* asmap - logical & physical addresses for this access
* bp - buffer ptr (holds write data)
* flags - general flags (e.g. disk locking)
* allocList - list of memory allocated in DAG creation
* pfuncs - list of parity generating functions
* qfuncs - list of q generating functions
*
* A null qfuncs indicates single fault tolerant.
*****************************************************************************/
void
rf_CommonCreateSmallWriteDAG(RF_Raid_t *raidPtr, RF_AccessStripeMap_t *asmap,
RF_DagHeader_t *dag_h, void *bp, RF_RaidAccessFlags_t flags,
RF_AllocListElem_t *allocList, RF_RedFuncs_t *pfuncs, RF_RedFuncs_t *qfuncs)
{
RF_DagNode_t *readDataNodes, *readParityNodes, *readQNodes, *termNode;
RF_DagNode_t *unlockDataNodes, *unlockParityNodes, *unlockQNodes;
RF_DagNode_t *xorNodes, *qNodes, *blockNode, *commitNode, *nodes;
RF_DagNode_t *writeDataNodes, *writeParityNodes, *writeQNodes;
int i, j, nNodes, totalNumNodes, lu_flag;
RF_ReconUnitNum_t which_ru;
int (*func) (RF_DagNode_t *);
int (*undoFunc) (RF_DagNode_t *);
int (*qfunc) (RF_DagNode_t *);
int numDataNodes, numParityNodes;
RF_StripeNum_t parityStripeID;
RF_PhysDiskAddr_t *pda;
char *name, *qname;
long nfaults;
nfaults = qfuncs ? 2 : 1;
lu_flag = (rf_enableAtomicRMW) ? 1 : 0; /* Lock/unlock flag. */
parityStripeID = rf_RaidAddressToParityStripeID(&(raidPtr->Layout),
asmap->raidAddress, &which_ru);
pda = asmap->physInfo;
numDataNodes = asmap->numStripeUnitsAccessed;
numParityNodes = (asmap->parityInfo->next) ? 2 : 1;
if (rf_dagDebug) {
printf("[Creating small-write DAG]\n");
}
RF_ASSERT(numDataNodes > 0);
dag_h->creator = "SmallWriteDAG";
dag_h->numCommitNodes = 1;
dag_h->numCommits = 0;
dag_h->numSuccedents = 1;
/*
* DAG creation occurs in four steps:
* 1. Count the number of nodes in the DAG.
* 2. Create the nodes.
* 3. Initialize the nodes.
* 4. Connect the nodes.
*/
/*
* Step 1. Compute number of nodes in the graph.
*/
/*
* Number of nodes: a read and write for each data unit, a redundancy
* computation node for each parity node (nfaults * nparity), a read
* and write for each parity unit, a block and commit node (2), a
* terminate node if atomic RMW, an unlock node for each
* data/redundancy unit.
*/
totalNumNodes = (2 * numDataNodes) + (nfaults * numParityNodes)
+ (nfaults * 2 * numParityNodes) + 3;
if (lu_flag) {
totalNumNodes += (numDataNodes + (nfaults * numParityNodes));
}
/*
* Step 2. Create the nodes.
*/
RF_CallocAndAdd(nodes, totalNumNodes, sizeof(RF_DagNode_t),
(RF_DagNode_t *), allocList);
i = 0;
blockNode = &nodes[i];
i += 1;
commitNode = &nodes[i];
i += 1;
readDataNodes = &nodes[i];
i += numDataNodes;
readParityNodes = &nodes[i];
i += numParityNodes;
writeDataNodes = &nodes[i];
i += numDataNodes;
writeParityNodes = &nodes[i];
i += numParityNodes;
xorNodes = &nodes[i];
i += numParityNodes;
termNode = &nodes[i];
i += 1;
if (lu_flag) {
unlockDataNodes = &nodes[i];
i += numDataNodes;
unlockParityNodes = &nodes[i];
i += numParityNodes;
} else {
unlockDataNodes = unlockParityNodes = NULL;
}
if (nfaults == 2) {
readQNodes = &nodes[i];
i += numParityNodes;
writeQNodes = &nodes[i];
i += numParityNodes;
qNodes = &nodes[i];
i += numParityNodes;
if (lu_flag) {
unlockQNodes = &nodes[i];
i += numParityNodes;
} else {
unlockQNodes = NULL;
}
} else {
readQNodes = writeQNodes = qNodes = unlockQNodes = NULL;
}
RF_ASSERT(i == totalNumNodes);
/*
* Step 3. Initialize the nodes.
*/
/* Initialize block node (Nil). */
nNodes = numDataNodes + (nfaults * numParityNodes);
rf_InitNode(blockNode, rf_wait, RF_FALSE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, nNodes, 0, 0, 0, dag_h,
"Nil", allocList);
/* Initialize commit node (Cmt). */
rf_InitNode(commitNode, rf_wait, RF_TRUE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, nNodes, (nfaults * numParityNodes),
0, 0, dag_h, "Cmt", allocList);
/* Initialize terminate node (Trm). */
rf_InitNode(termNode, rf_wait, RF_FALSE, rf_TerminateFunc,
rf_TerminateUndoFunc, NULL, 0, nNodes, 0, 0, dag_h,
"Trm", allocList);
/* Initialize nodes which read old data (Rod). */
for (i = 0; i < numDataNodes; i++) {
rf_InitNode(&readDataNodes[i], rf_wait, RF_FALSE,
rf_DiskReadFunc, rf_DiskReadUndoFunc, rf_GenericWakeupFunc,
(nfaults * numParityNodes), 1, 4, 0, dag_h, "Rod",
allocList);
RF_ASSERT(pda != NULL);
/* Physical disk addr desc. */
readDataNodes[i].params[0].p = pda;
/* Buffer to hold old data. */
readDataNodes[i].params[1].p = rf_AllocBuffer(raidPtr,
dag_h, pda, allocList);
readDataNodes[i].params[2].v = parityStripeID;
readDataNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
lu_flag, 0, which_ru);
pda = pda->next;
for (j = 0; j < readDataNodes[i].numSuccedents; j++) {
readDataNodes[i].propList[j] = NULL;
}
}
/* Initialize nodes which read old parity (Rop). */
pda = asmap->parityInfo;
i = 0;
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(pda != NULL);
rf_InitNode(&readParityNodes[i], rf_wait, RF_FALSE,
rf_DiskReadFunc, rf_DiskReadUndoFunc, rf_GenericWakeupFunc,
numParityNodes, 1, 4, 0, dag_h, "Rop", allocList);
readParityNodes[i].params[0].p = pda;
/* Buffer to hold old parity. */
readParityNodes[i].params[1].p = rf_AllocBuffer(raidPtr,
dag_h, pda, allocList);
readParityNodes[i].params[2].v = parityStripeID;
readParityNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
lu_flag, 0, which_ru);
pda = pda->next;
for (j = 0; j < readParityNodes[i].numSuccedents; j++) {
readParityNodes[i].propList[0] = NULL;
}
}
/* Initialize nodes which read old Q (Roq). */
if (nfaults == 2) {
pda = asmap->qInfo;
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(pda != NULL);
rf_InitNode(&readQNodes[i], rf_wait, RF_FALSE,
rf_DiskReadFunc, rf_DiskReadUndoFunc,
rf_GenericWakeupFunc, numParityNodes,
1, 4, 0, dag_h, "Roq", allocList);
readQNodes[i].params[0].p = pda;
/* Buffer to hold old Q. */
readQNodes[i].params[1].p = rf_AllocBuffer(raidPtr,
dag_h, pda, allocList);
readQNodes[i].params[2].v = parityStripeID;
readQNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
lu_flag, 0, which_ru);
pda = pda->next;
for (j = 0; j < readQNodes[i].numSuccedents; j++) {
readQNodes[i].propList[0] = NULL;
}
}
}
/* Initialize nodes which write new data (Wnd). */
pda = asmap->physInfo;
for (i = 0; i < numDataNodes; i++) {
RF_ASSERT(pda != NULL);
rf_InitNode(&writeDataNodes[i], rf_wait, RF_FALSE,
rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h,
"Wnd", allocList);
/* Physical disk addr desc. */
writeDataNodes[i].params[0].p = pda;
/* Buffer holding new data to be written. */
writeDataNodes[i].params[1].p = pda->bufPtr;
writeDataNodes[i].params[2].v = parityStripeID;
writeDataNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
if (lu_flag) {
/* Initialize node to unlock the disk queue. */
rf_InitNode(&unlockDataNodes[i], rf_wait, RF_FALSE,
rf_DiskUnlockFunc, rf_DiskUnlockUndoFunc,
rf_GenericWakeupFunc, 1, 1, 2, 0, dag_h,
"Und", allocList);
/* Physical disk addr desc. */
unlockDataNodes[i].params[0].p = pda;
unlockDataNodes[i].params[1].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, lu_flag, which_ru);
}
pda = pda->next;
}
/*
* Initialize nodes which compute new parity and Q.
*/
/*
* We use the simple XOR func in the double-XOR case, and when
* we're accessing only a portion of one stripe unit.
* The distinction between the two is that the regular XOR func
* assumes that the targbuf is a full SU in size, and examines
* the pda associated with the buffer to decide where within
* the buffer to XOR the data, whereas the simple XOR func just
* XORs the data into the start of the buffer.
*/
if ((numParityNodes == 2) || ((numDataNodes == 1) &&
(asmap->totalSectorsAccessed <
raidPtr->Layout.sectorsPerStripeUnit))) {
func = pfuncs->simple;
undoFunc = rf_NullNodeUndoFunc;
name = pfuncs->SimpleName;
if (qfuncs) {
qfunc = qfuncs->simple;
qname = qfuncs->SimpleName;
} else {
qfunc = NULL;
qname = NULL;
}
} else {
func = pfuncs->regular;
undoFunc = rf_NullNodeUndoFunc;
name = pfuncs->RegularName;
if (qfuncs) {
qfunc = qfuncs->regular;
qname = qfuncs->RegularName;
} else {
qfunc = NULL;
qname = NULL;
}
}
/*
* Initialize the xor nodes: params are {pda,buf}.
* From {Rod,Wnd,Rop} nodes, and raidPtr.
*/
if (numParityNodes == 2) {
/* Double-xor case. */
for (i = 0; i < numParityNodes; i++) {
/* Note: no wakeup func for xor. */
rf_InitNode(&xorNodes[i], rf_wait, RF_FALSE, func,
undoFunc, NULL, 1, (numDataNodes + numParityNodes),
7, 1, dag_h, name, allocList);
xorNodes[i].flags |= RF_DAGNODE_FLAG_YIELD;
xorNodes[i].params[0] = readDataNodes[i].params[0];
xorNodes[i].params[1] = readDataNodes[i].params[1];
xorNodes[i].params[2] = readParityNodes[i].params[0];
xorNodes[i].params[3] = readParityNodes[i].params[1];
xorNodes[i].params[4] = writeDataNodes[i].params[0];
xorNodes[i].params[5] = writeDataNodes[i].params[1];
xorNodes[i].params[6].p = raidPtr;
/* Use old parity buf as target buf. */
xorNodes[i].results[0] = readParityNodes[i].params[1].p;
if (nfaults == 2) {
/* Note: no wakeup func for qor. */
rf_InitNode(&qNodes[i], rf_wait, RF_FALSE,
qfunc, undoFunc, NULL, 1,
(numDataNodes + numParityNodes), 7, 1,
dag_h, qname, allocList);
qNodes[i].params[0] =
readDataNodes[i].params[0];
qNodes[i].params[1] =
readDataNodes[i].params[1];
qNodes[i].params[2] = readQNodes[i].params[0];
qNodes[i].params[3] = readQNodes[i].params[1];
qNodes[i].params[4] =
writeDataNodes[i].params[0];
qNodes[i].params[5] =
writeDataNodes[i].params[1];
qNodes[i].params[6].p = raidPtr;
/* Use old Q buf as target buf. */
qNodes[i].results[0] =
readQNodes[i].params[1].p;
}
}
} else {
/* There is only one xor node in this case. */
rf_InitNode(&xorNodes[0], rf_wait, RF_FALSE, func, undoFunc,
NULL, 1, (numDataNodes + numParityNodes),
(2 * (numDataNodes + numDataNodes + 1) + 1), 1,
dag_h, name, allocList);
xorNodes[0].flags |= RF_DAGNODE_FLAG_YIELD;
for (i = 0; i < numDataNodes + 1; i++) {
/* Set up params related to Rod and Rop nodes. */
xorNodes[0].params[2 * i + 0] =
readDataNodes[i].params[0]; /* pda */
xorNodes[0].params[2 * i + 1] =
readDataNodes[i].params[1]; /* buffer ptr */
}
for (i = 0; i < numDataNodes; i++) {
/* Set up params related to Wnd and Wnp nodes. */
xorNodes[0].params[2 * (numDataNodes + 1 + i) + 0] =
writeDataNodes[i].params[0]; /* pda */
xorNodes[0].params[2 * (numDataNodes + 1 + i) + 1] =
writeDataNodes[i].params[1]; /* buffer ptr */
}
/* Xor node needs to get at RAID information. */
xorNodes[0].params[2 * (numDataNodes + numDataNodes + 1)].p =
raidPtr;
xorNodes[0].results[0] = readParityNodes[0].params[1].p;
if (nfaults == 2) {
rf_InitNode(&qNodes[0], rf_wait, RF_FALSE, qfunc,
undoFunc, NULL, 1, (numDataNodes + numParityNodes),
(2 * (numDataNodes + numDataNodes + 1) + 1), 1,
dag_h, qname, allocList);
for (i = 0; i < numDataNodes; i++) {
/* Set up params related to Rod. */
qNodes[0].params[2 * i + 0] =
readDataNodes[i].params[0]; /* pda */
qNodes[0].params[2 * i + 1] =
readDataNodes[i].params[1]; /* buffer ptr */
}
/* And read old q. */
qNodes[0].params[2 * numDataNodes + 0] =
readQNodes[0].params[0]; /* pda */
qNodes[0].params[2 * numDataNodes + 1] =
readQNodes[0].params[1]; /* buffer ptr */
for (i = 0; i < numDataNodes; i++) {
/* Set up params related to Wnd nodes. */
qNodes[0].params
[2 * (numDataNodes + 1 + i) + 0] =
/* pda */
writeDataNodes[i].params[0];
qNodes[0].params
[2 * (numDataNodes + 1 + i) + 1] =
/* buffer ptr */
writeDataNodes[i].params[1];
}
/* Xor node needs to get at RAID information. */
qNodes[0].params
[2 * (numDataNodes + numDataNodes + 1)].p = raidPtr;
qNodes[0].results[0] = readQNodes[0].params[1].p;
}
}
/* Initialize nodes which write new parity (Wnp). */
pda = asmap->parityInfo;
for (i = 0; i < numParityNodes; i++) {
rf_InitNode(&writeParityNodes[i], rf_wait, RF_FALSE,
rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h,
"Wnp", allocList);
RF_ASSERT(pda != NULL);
/* Param 1 (bufPtr) filled in by xor node. */
writeParityNodes[i].params[0].p = pda;
/* Buffer pointer for parity write operation. */
writeParityNodes[i].params[1].p = xorNodes[i].results[0];
writeParityNodes[i].params[2].v = parityStripeID;
writeParityNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
if (lu_flag) {
/* Initialize node to unlock the disk queue. */
rf_InitNode(&unlockParityNodes[i], rf_wait, RF_FALSE,
rf_DiskUnlockFunc, rf_DiskUnlockUndoFunc,
rf_GenericWakeupFunc, 1, 1, 2, 0, dag_h,
"Unp", allocList);
/* Physical disk addr desc. */
unlockParityNodes[i].params[0].p = pda;
unlockParityNodes[i].params[1].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, lu_flag, which_ru);
}
pda = pda->next;
}
/* Initialize nodes which write new Q (Wnq). */
if (nfaults == 2) {
pda = asmap->qInfo;
for (i = 0; i < numParityNodes; i++) {
rf_InitNode(&writeQNodes[i], rf_wait, RF_FALSE,
rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h,
"Wnq", allocList);
RF_ASSERT(pda != NULL);
/* Param 1 (bufPtr) filled in by xor node. */
writeQNodes[i].params[0].p = pda;
writeQNodes[i].params[1].p = qNodes[i].results[0];
/* Buffer pointer for parity write operation. */
writeQNodes[i].params[2].v = parityStripeID;
writeQNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, 0, which_ru);
if (lu_flag) {
/* Initialize node to unlock the disk queue. */
rf_InitNode(&unlockQNodes[i], rf_wait,
RF_FALSE, rf_DiskUnlockFunc,
rf_DiskUnlockUndoFunc,
rf_GenericWakeupFunc, 1, 1, 2, 0,
dag_h, "Unq", allocList);
/* Physical disk addr desc. */
unlockQNodes[i].params[0].p = pda;
unlockQNodes[i].params[1].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, lu_flag, which_ru);
}
pda = pda->next;
}
}
/*
* Step 4. Connect the nodes.
*/
/* Connect header to block node. */
dag_h->succedents[0] = blockNode;
/* Connect block node to read old data nodes. */
RF_ASSERT(blockNode->numSuccedents ==
(numDataNodes + (numParityNodes * nfaults)));
for (i = 0; i < numDataNodes; i++) {
blockNode->succedents[i] = &readDataNodes[i];
RF_ASSERT(readDataNodes[i].numAntecedents == 1);
readDataNodes[i].antecedents[0] = blockNode;
readDataNodes[i].antType[0] = rf_control;
}
/* Connect block node to read old parity nodes. */
for (i = 0; i < numParityNodes; i++) {
blockNode->succedents[numDataNodes + i] = &readParityNodes[i];
RF_ASSERT(readParityNodes[i].numAntecedents == 1);
readParityNodes[i].antecedents[0] = blockNode;
readParityNodes[i].antType[0] = rf_control;
}
/* Connect block node to read old Q nodes. */
if (nfaults == 2) {
for (i = 0; i < numParityNodes; i++) {
blockNode->succedents[numDataNodes + numParityNodes + i]
= &readQNodes[i];
RF_ASSERT(readQNodes[i].numAntecedents == 1);
readQNodes[i].antecedents[0] = blockNode;
readQNodes[i].antType[0] = rf_control;
}
}
/* Connect read old data nodes to xor nodes. */
for (i = 0; i < numDataNodes; i++) {
RF_ASSERT(readDataNodes[i].numSuccedents ==
(nfaults * numParityNodes));
for (j = 0; j < numParityNodes; j++) {
RF_ASSERT(xorNodes[j].numAntecedents ==
numDataNodes + numParityNodes);
readDataNodes[i].succedents[j] = &xorNodes[j];
xorNodes[j].antecedents[i] = &readDataNodes[i];
xorNodes[j].antType[i] = rf_trueData;
}
}
/* Connect read old data nodes to q nodes. */
if (nfaults == 2) {
for (i = 0; i < numDataNodes; i++) {
for (j = 0; j < numParityNodes; j++) {
RF_ASSERT(qNodes[j].numAntecedents ==
numDataNodes + numParityNodes);
readDataNodes[i].succedents[numParityNodes + j]
= &qNodes[j];
qNodes[j].antecedents[i] = &readDataNodes[i];
qNodes[j].antType[i] = rf_trueData;
}
}
}
/* Connect read old parity nodes to xor nodes. */
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(readParityNodes[i].numSuccedents == numParityNodes);
for (j = 0; j < numParityNodes; j++) {
readParityNodes[i].succedents[j] = &xorNodes[j];
xorNodes[j].antecedents[numDataNodes + i] =
&readParityNodes[i];
xorNodes[j].antType[numDataNodes + i] = rf_trueData;
}
}
/* Connect read old q nodes to q nodes. */
if (nfaults == 2) {
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(readParityNodes[i].numSuccedents ==
numParityNodes);
for (j = 0; j < numParityNodes; j++) {
readQNodes[i].succedents[j] = &qNodes[j];
qNodes[j].antecedents[numDataNodes + i] =
&readQNodes[i];
qNodes[j].antType[numDataNodes + i] =
rf_trueData;
}
}
}
/* Connect xor nodes to commit node. */
RF_ASSERT(commitNode->numAntecedents == (nfaults * numParityNodes));
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(xorNodes[i].numSuccedents == 1);
xorNodes[i].succedents[0] = commitNode;
commitNode->antecedents[i] = &xorNodes[i];
commitNode->antType[i] = rf_control;
}
/* Connect q nodes to commit node. */
if (nfaults == 2) {
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(qNodes[i].numSuccedents == 1);
qNodes[i].succedents[0] = commitNode;
commitNode->antecedents[i + numParityNodes] =
&qNodes[i];
commitNode->antType[i + numParityNodes] = rf_control;
}
}
/* Connect commit node to write nodes. */
RF_ASSERT(commitNode->numSuccedents ==
(numDataNodes + (nfaults * numParityNodes)));
for (i = 0; i < numDataNodes; i++) {
RF_ASSERT(writeDataNodes[i].numAntecedents == 1);
commitNode->succedents[i] = &writeDataNodes[i];
writeDataNodes[i].antecedents[0] = commitNode;
writeDataNodes[i].antType[0] = rf_trueData;
}
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(writeParityNodes[i].numAntecedents == 1);
commitNode->succedents[i + numDataNodes] = &writeParityNodes[i];
writeParityNodes[i].antecedents[0] = commitNode;
writeParityNodes[i].antType[0] = rf_trueData;
}
if (nfaults == 2) {
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(writeQNodes[i].numAntecedents == 1);
commitNode->succedents
[i + numDataNodes + numParityNodes] =
&writeQNodes[i];
writeQNodes[i].antecedents[0] = commitNode;
writeQNodes[i].antType[0] = rf_trueData;
}
}
RF_ASSERT(termNode->numAntecedents ==
(numDataNodes + (nfaults * numParityNodes)));
RF_ASSERT(termNode->numSuccedents == 0);
for (i = 0; i < numDataNodes; i++) {
if (lu_flag) {
/* Connect write new data nodes to unlock nodes. */
RF_ASSERT(writeDataNodes[i].numSuccedents == 1);
RF_ASSERT(unlockDataNodes[i].numAntecedents == 1);
writeDataNodes[i].succedents[0] = &unlockDataNodes[i];
unlockDataNodes[i].antecedents[0] = &writeDataNodes[i];
unlockDataNodes[i].antType[0] = rf_control;
/* Connect unlock nodes to term node. */
RF_ASSERT(unlockDataNodes[i].numSuccedents == 1);
unlockDataNodes[i].succedents[0] = termNode;
termNode->antecedents[i] = &unlockDataNodes[i];
termNode->antType[i] = rf_control;
} else {
/* Connect write new data nodes to term node. */
RF_ASSERT(writeDataNodes[i].numSuccedents == 1);
RF_ASSERT(termNode->numAntecedents ==
(numDataNodes + (nfaults * numParityNodes)));
writeDataNodes[i].succedents[0] = termNode;
termNode->antecedents[i] = &writeDataNodes[i];
termNode->antType[i] = rf_control;
}
}
for (i = 0; i < numParityNodes; i++) {
if (lu_flag) {
/* Connect write new parity nodes to unlock nodes. */
RF_ASSERT(writeParityNodes[i].numSuccedents == 1);
RF_ASSERT(unlockParityNodes[i].numAntecedents == 1);
writeParityNodes[i].succedents[0] =
&unlockParityNodes[i];
unlockParityNodes[i].antecedents[0] =
&writeParityNodes[i];
unlockParityNodes[i].antType[0] = rf_control;
/* Connect unlock nodes to term node. */
RF_ASSERT(unlockParityNodes[i].numSuccedents == 1);
unlockParityNodes[i].succedents[0] = termNode;
termNode->antecedents[numDataNodes + i] =
&unlockParityNodes[i];
termNode->antType[numDataNodes + i] = rf_control;
} else {
RF_ASSERT(writeParityNodes[i].numSuccedents == 1);
writeParityNodes[i].succedents[0] = termNode;
termNode->antecedents[numDataNodes + i] =
&writeParityNodes[i];
termNode->antType[numDataNodes + i] = rf_control;
}
}
if (nfaults == 2) {
for (i = 0; i < numParityNodes; i++) {
if (lu_flag) {
/* Connect write new Q nodes to unlock nodes. */
RF_ASSERT(writeQNodes[i].numSuccedents == 1);
RF_ASSERT(unlockQNodes[i].numAntecedents == 1);
writeQNodes[i].succedents[0] = &unlockQNodes[i];
unlockQNodes[i].antecedents[0] =
&writeQNodes[i];
unlockQNodes[i].antType[0] = rf_control;
/* Connect unlock nodes to unblock node. */
RF_ASSERT(unlockQNodes[i].numSuccedents == 1);
unlockQNodes[i].succedents[0] = termNode;
termNode->antecedents
[numDataNodes + numParityNodes + i] =
&unlockQNodes[i];
termNode->antType
[numDataNodes + numParityNodes + i] =
rf_control;
} else {
RF_ASSERT(writeQNodes[i].numSuccedents == 1);
writeQNodes[i].succedents[0] = termNode;
termNode->antecedents
[numDataNodes + numParityNodes + i] =
&writeQNodes[i];
termNode->antType
[numDataNodes + numParityNodes + i] =
rf_control;
}
}
}
}
/*****************************************************************************
* Create a write graph (fault-free or degraded) for RAID level 1.
*
* Hdr -> Commit -> Wpd -> Nil -> Trm
* -> Wsd ->
*
* The "Wpd" node writes data to the primary copy in the mirror pair.
* The "Wsd" node writes data to the secondary copy in the mirror pair.
*
* Parameters: raidPtr - description of the physical array
* asmap - logical & physical addresses for this access
* bp - buffer ptr (holds write data)
* flags - general flags (e.g. disk locking)
* allocList - list of memory allocated in DAG creation
*****************************************************************************/
void
rf_CreateRaidOneWriteDAG(RF_Raid_t *raidPtr, RF_AccessStripeMap_t *asmap,
RF_DagHeader_t *dag_h, void *bp, RF_RaidAccessFlags_t flags,
RF_AllocListElem_t *allocList)
{
RF_DagNode_t *unblockNode, *termNode, *commitNode;
RF_DagNode_t *nodes, *wndNode, *wmirNode;
int nWndNodes, nWmirNodes, i;
RF_ReconUnitNum_t which_ru;
RF_PhysDiskAddr_t *pda, *pdaP;
RF_StripeNum_t parityStripeID;
parityStripeID = rf_RaidAddressToParityStripeID(&(raidPtr->Layout),
asmap->raidAddress, &which_ru);
if (rf_dagDebug) {
printf("[Creating RAID level 1 write DAG]\n");
}
dag_h->creator = "RaidOneWriteDAG";
/* 2 implies access not SU aligned. */
nWmirNodes = (asmap->parityInfo->next) ? 2 : 1;
nWndNodes = (asmap->physInfo->next) ? 2 : 1;
/* Alloc the Wnd nodes and the Wmir node. */
if (asmap->numDataFailed == 1)
nWndNodes--;
if (asmap->numParityFailed == 1)
nWmirNodes--;
/*
* Total number of nodes = nWndNodes + nWmirNodes
* + (commit + unblock + terminator)
*/
RF_CallocAndAdd(nodes, nWndNodes + nWmirNodes + 3, sizeof(RF_DagNode_t),
(RF_DagNode_t *), allocList);
i = 0;
wndNode = &nodes[i];
i += nWndNodes;
wmirNode = &nodes[i];
i += nWmirNodes;
commitNode = &nodes[i];
i += 1;
unblockNode = &nodes[i];
i += 1;
termNode = &nodes[i];
i += 1;
RF_ASSERT(i == (nWndNodes + nWmirNodes + 3));
/* This dag can commit immediately. */
dag_h->numCommitNodes = 1;
dag_h->numCommits = 0;
dag_h->numSuccedents = 1;
/* Initialize the commit, unblock, and term nodes. */
rf_InitNode(commitNode, rf_wait, RF_TRUE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, (nWndNodes + nWmirNodes), 0, 0, 0,
dag_h, "Cmt", allocList);
rf_InitNode(unblockNode, rf_wait, RF_FALSE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, 1, (nWndNodes + nWmirNodes), 0, 0,
dag_h, "Nil", allocList);
rf_InitNode(termNode, rf_wait, RF_FALSE, rf_TerminateFunc,
rf_TerminateUndoFunc, NULL, 0, 1, 0, 0, dag_h, "Trm", allocList);
/* Initialize the wnd nodes. */
if (nWndNodes > 0) {
pda = asmap->physInfo;
for (i = 0; i < nWndNodes; i++) {
rf_InitNode(&wndNode[i], rf_wait, RF_FALSE,
rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h,
"Wpd", allocList);
RF_ASSERT(pda != NULL);
wndNode[i].params[0].p = pda;
wndNode[i].params[1].p = pda->bufPtr;
wndNode[i].params[2].v = parityStripeID;
wndNode[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, 0, which_ru);
pda = pda->next;
}
RF_ASSERT(pda == NULL);
}
/* Initialize the mirror nodes. */
if (nWmirNodes > 0) {
pda = asmap->physInfo;
pdaP = asmap->parityInfo;
for (i = 0; i < nWmirNodes; i++) {
rf_InitNode(&wmirNode[i], rf_wait, RF_FALSE,
rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h,
"Wsd", allocList);
RF_ASSERT(pda != NULL);
wmirNode[i].params[0].p = pdaP;
wmirNode[i].params[1].p = pda->bufPtr;
wmirNode[i].params[2].v = parityStripeID;
wmirNode[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, 0, which_ru);
pda = pda->next;
pdaP = pdaP->next;
}
RF_ASSERT(pda == NULL);
RF_ASSERT(pdaP == NULL);
}
/* Link the header node to the commit node. */
RF_ASSERT(dag_h->numSuccedents == 1);
RF_ASSERT(commitNode->numAntecedents == 0);
dag_h->succedents[0] = commitNode;
/* Link the commit node to the write nodes. */
RF_ASSERT(commitNode->numSuccedents == (nWndNodes + nWmirNodes));
for (i = 0; i < nWndNodes; i++) {
RF_ASSERT(wndNode[i].numAntecedents == 1);
commitNode->succedents[i] = &wndNode[i];
wndNode[i].antecedents[0] = commitNode;
wndNode[i].antType[0] = rf_control;
}
for (i = 0; i < nWmirNodes; i++) {
RF_ASSERT(wmirNode[i].numAntecedents == 1);
commitNode->succedents[i + nWndNodes] = &wmirNode[i];
wmirNode[i].antecedents[0] = commitNode;
wmirNode[i].antType[0] = rf_control;
}
/* Link the write nodes to the unblock node. */
RF_ASSERT(unblockNode->numAntecedents == (nWndNodes + nWmirNodes));
for (i = 0; i < nWndNodes; i++) {
RF_ASSERT(wndNode[i].numSuccedents == 1);
wndNode[i].succedents[0] = unblockNode;
unblockNode->antecedents[i] = &wndNode[i];
unblockNode->antType[i] = rf_control;
}
for (i = 0; i < nWmirNodes; i++) {
RF_ASSERT(wmirNode[i].numSuccedents == 1);
wmirNode[i].succedents[0] = unblockNode;
unblockNode->antecedents[i + nWndNodes] = &wmirNode[i];
unblockNode->antType[i + nWndNodes] = rf_control;
}
/* Link the unblock node to the 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;
}
/*
* DAGs that have no commit points.
*
* The following DAGs are used in forward and backward error recovery
* experiments.
* They are identical to the DAGs above this comment with the exception that
* the commit points have been removed.
*/
void
rf_CommonCreateLargeWriteDAGFwd(RF_Raid_t *raidPtr, RF_AccessStripeMap_t *asmap,
RF_DagHeader_t *dag_h, void *bp, RF_RaidAccessFlags_t flags,
RF_AllocListElem_t *allocList, int nfaults, int (*redFunc) (RF_DagNode_t *),
int allowBufferRecycle)
{
RF_DagNode_t *nodes, *wndNodes, *rodNodes, *xorNode, *wnpNode;
RF_DagNode_t *wnqNode, *blockNode, *syncNode, *termNode;
int nWndNodes, nRodNodes, i, nodeNum, asmNum;
RF_AccessStripeMapHeader_t *new_asm_h[2];
RF_StripeNum_t parityStripeID;
char *sosBuffer, *eosBuffer;
RF_ReconUnitNum_t which_ru;
RF_RaidLayout_t *layoutPtr;
RF_PhysDiskAddr_t *pda;
layoutPtr = &(raidPtr->Layout);
parityStripeID = rf_RaidAddressToParityStripeID(&(raidPtr->Layout),
asmap->raidAddress, &which_ru);
if (rf_dagDebug)
printf("[Creating large-write DAG]\n");
dag_h->creator = "LargeWriteDAGFwd";
dag_h->numCommitNodes = 0;
dag_h->numCommits = 0;
dag_h->numSuccedents = 1;
/* Alloc the nodes: Wnd, xor, commit, block, term, and Wnp. */
nWndNodes = asmap->numStripeUnitsAccessed;
RF_CallocAndAdd(nodes, nWndNodes + 4 + nfaults, sizeof(RF_DagNode_t),
(RF_DagNode_t *), allocList);
i = 0;
wndNodes = &nodes[i];
i += nWndNodes;
xorNode = &nodes[i];
i += 1;
wnpNode = &nodes[i];
i += 1;
blockNode = &nodes[i];
i += 1;
syncNode = &nodes[i];
i += 1;
termNode = &nodes[i];
i += 1;
if (nfaults == 2) {
wnqNode = &nodes[i];
i += 1;
} else {
wnqNode = NULL;
}
rf_MapUnaccessedPortionOfStripe(raidPtr, layoutPtr, asmap, dag_h,
new_asm_h, &nRodNodes, &sosBuffer, &eosBuffer, allocList);
if (nRodNodes > 0) {
RF_CallocAndAdd(rodNodes, nRodNodes, sizeof(RF_DagNode_t),
(RF_DagNode_t *), allocList);
} else {
rodNodes = NULL;
}
/* Begin node initialization. */
if (nRodNodes > 0) {
rf_InitNode(blockNode, rf_wait, RF_FALSE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, nRodNodes, 0, 0, 0, dag_h,
"Nil", allocList);
rf_InitNode(syncNode, rf_wait, RF_FALSE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, nWndNodes + 1, nRodNodes, 0, 0,
dag_h, "Nil", allocList);
} else {
rf_InitNode(blockNode, rf_wait, RF_FALSE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, 1, 0, 0, 0, dag_h, "Nil",
allocList);
rf_InitNode(syncNode, rf_wait, RF_FALSE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, nWndNodes + 1, 1, 0, 0, dag_h,
"Nil", allocList);
}
rf_InitNode(termNode, rf_wait, RF_FALSE, rf_TerminateFunc,
rf_TerminateUndoFunc, NULL, 0, nWndNodes + nfaults, 0, 0,
dag_h, "Trm", allocList);
/* Initialize the Rod nodes. */
for (nodeNum = asmNum = 0; asmNum < 2; asmNum++) {
if (new_asm_h[asmNum]) {
pda = new_asm_h[asmNum]->stripeMap->physInfo;
while (pda) {
rf_InitNode(&rodNodes[nodeNum], rf_wait,
RF_FALSE, rf_DiskReadFunc,
rf_DiskReadUndoFunc, rf_GenericWakeupFunc,
1, 1, 4, 0, dag_h, "Rod", allocList);
rodNodes[nodeNum].params[0].p = pda;
rodNodes[nodeNum].params[1].p = pda->bufPtr;
rodNodes[nodeNum].params[2].v = parityStripeID;
rodNodes[nodeNum].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, 0, which_ru);
nodeNum++;
pda = pda->next;
}
}
}
RF_ASSERT(nodeNum == nRodNodes);
/* Initialize the wnd nodes. */
pda = asmap->physInfo;
for (i = 0; i < nWndNodes; i++) {
rf_InitNode(&wndNodes[i], rf_wait, RF_FALSE, rf_DiskWriteFunc,
rf_DiskWriteUndoFunc, rf_GenericWakeupFunc, 1, 1, 4, 0,
dag_h, "Wnd", allocList);
RF_ASSERT(pda != NULL);
wndNodes[i].params[0].p = pda;
wndNodes[i].params[1].p = pda->bufPtr;
wndNodes[i].params[2].v = parityStripeID;
wndNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
pda = pda->next;
}
/* Initialize the redundancy node. */
rf_InitNode(xorNode, rf_wait, RF_FALSE, redFunc, rf_NullNodeUndoFunc,
NULL, 1, nfaults, 2 * (nWndNodes + nRodNodes) + 1, nfaults, dag_h,
"Xr ", allocList);
xorNode->flags |= RF_DAGNODE_FLAG_YIELD;
for (i = 0; i < nWndNodes; i++) {
xorNode->params[2 * i + 0] =
wndNodes[i].params[0]; /* pda */
xorNode->params[2 * i + 1] =
wndNodes[i].params[1]; /* buf ptr */
}
for (i = 0; i < nRodNodes; i++) {
xorNode->params[2 * (nWndNodes + i) + 0] =
rodNodes[i].params[0]; /* pda */
xorNode->params[2 * (nWndNodes + i) + 1] =
rodNodes[i].params[1]; /* buf ptr */
}
/* Xor node needs to get at RAID information. */
xorNode->params[2 * (nWndNodes + nRodNodes)].p = raidPtr;
/*
* Look for an Rod node that reads a complete SU. If none, alloc a
* buffer to receive the parity info. Note that we can't use a new
* data buffer because it will not have gotten written when the xor
* occurs.
*/
if (allowBufferRecycle) {
for (i = 0; i < nRodNodes; i++)
if (((RF_PhysDiskAddr_t *) rodNodes[i].params[0].p)
->numSector == raidPtr->Layout.sectorsPerStripeUnit)
break;
}
if ((!allowBufferRecycle) || (i == nRodNodes)) {
RF_CallocAndAdd(xorNode->results[0], 1,
rf_RaidAddressToByte(raidPtr,
raidPtr->Layout.sectorsPerStripeUnit),
(void *), allocList);
} else
xorNode->results[0] = rodNodes[i].params[1].p;
/* Initialize the Wnp node. */
rf_InitNode(wnpNode, rf_wait, RF_FALSE, rf_DiskWriteFunc,
rf_DiskWriteUndoFunc, rf_GenericWakeupFunc, 1, 1, 4, 0,
dag_h, "Wnp", allocList);
wnpNode->params[0].p = asmap->parityInfo;
wnpNode->params[1].p = xorNode->results[0];
wnpNode->params[2].v = parityStripeID;
wnpNode->params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
/* parityInfo must describe entire parity unit. */
RF_ASSERT(asmap->parityInfo->next == NULL);
if (nfaults == 2) {
/*
* Never try to recycle a buffer for the Q calcuation in
* addition to the parity. This would cause two buffers to
* get smashed during the P and Q calculation, guaranteeing
* one would be wrong.
*/
RF_CallocAndAdd(xorNode->results[1], 1,
rf_RaidAddressToByte(raidPtr,
raidPtr->Layout.sectorsPerStripeUnit),
(void *), allocList);
rf_InitNode(wnqNode, rf_wait, RF_FALSE, rf_DiskWriteFunc,
rf_DiskWriteUndoFunc, rf_GenericWakeupFunc, 1, 1, 4, 0,
dag_h, "Wnq", allocList);
wnqNode->params[0].p = asmap->qInfo;
wnqNode->params[1].p = xorNode->results[1];
wnqNode->params[2].v = parityStripeID;
wnqNode->params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
/* parityInfo must describe entire parity unit. */
RF_ASSERT(asmap->parityInfo->next == NULL);
}
/* Connect nodes to form graph. */
/* Connect dag header to block node. */
RF_ASSERT(blockNode->numAntecedents == 0);
dag_h->succedents[0] = blockNode;
if (nRodNodes > 0) {
/* Connect the block node to the Rod nodes. */
RF_ASSERT(blockNode->numSuccedents == nRodNodes);
RF_ASSERT(syncNode->numAntecedents == nRodNodes);
for (i = 0; i < nRodNodes; i++) {
RF_ASSERT(rodNodes[i].numAntecedents == 1);
blockNode->succedents[i] = &rodNodes[i];
rodNodes[i].antecedents[0] = blockNode;
rodNodes[i].antType[0] = rf_control;
/* Connect the Rod nodes to the Nil node. */
RF_ASSERT(rodNodes[i].numSuccedents == 1);
rodNodes[i].succedents[0] = syncNode;
syncNode->antecedents[i] = &rodNodes[i];
syncNode->antType[i] = rf_trueData;
}
} else {
/* Connect the block node to the Nil node. */
RF_ASSERT(blockNode->numSuccedents == 1);
RF_ASSERT(syncNode->numAntecedents == 1);
blockNode->succedents[0] = syncNode;
syncNode->antecedents[0] = blockNode;
syncNode->antType[0] = rf_control;
}
/* Connect the sync node to the Wnd nodes. */
RF_ASSERT(syncNode->numSuccedents == (1 + nWndNodes));
for (i = 0; i < nWndNodes; i++) {
RF_ASSERT(wndNodes->numAntecedents == 1);
syncNode->succedents[i] = &wndNodes[i];
wndNodes[i].antecedents[0] = syncNode;
wndNodes[i].antType[0] = rf_control;
}
/* Connect the sync node to the Xor node. */
RF_ASSERT(xorNode->numAntecedents == 1);
syncNode->succedents[nWndNodes] = xorNode;
xorNode->antecedents[0] = syncNode;
xorNode->antType[0] = rf_control;
/* Connect the xor node to the write parity node. */
RF_ASSERT(xorNode->numSuccedents == nfaults);
RF_ASSERT(wnpNode->numAntecedents == 1);
xorNode->succedents[0] = wnpNode;
wnpNode->antecedents[0] = xorNode;
wnpNode->antType[0] = rf_trueData;
if (nfaults == 2) {
RF_ASSERT(wnqNode->numAntecedents == 1);
xorNode->succedents[1] = wnqNode;
wnqNode->antecedents[0] = xorNode;
wnqNode->antType[0] = rf_trueData;
}
/* Connect the write nodes to the term node. */
RF_ASSERT(termNode->numAntecedents == nWndNodes + nfaults);
RF_ASSERT(termNode->numSuccedents == 0);
for (i = 0; i < nWndNodes; i++) {
RF_ASSERT(wndNodes->numSuccedents == 1);
wndNodes[i].succedents[0] = termNode;
termNode->antecedents[i] = &wndNodes[i];
termNode->antType[i] = rf_control;
}
RF_ASSERT(wnpNode->numSuccedents == 1);
wnpNode->succedents[0] = termNode;
termNode->antecedents[nWndNodes] = wnpNode;
termNode->antType[nWndNodes] = rf_control;
if (nfaults == 2) {
RF_ASSERT(wnqNode->numSuccedents == 1);
wnqNode->succedents[0] = termNode;
termNode->antecedents[nWndNodes + 1] = wnqNode;
termNode->antType[nWndNodes + 1] = rf_control;
}
}
/*****************************************************************************
*
* Create a DAG to perform a small-write operation (either raid 5 or pq),
* which is as follows:
*
* Hdr -> Nil -> Rop - Xor - Wnp [Unp] -- Trm
* \- Rod X- Wnd [Und] -------/
* [\- Rod X- Wnd [Und] ------/]
* [\- Roq - Q --> Wnq [Unq]-/]
*
* Rop = read old parity
* Rod = read old data
* Roq = read old "q"
* Cmt = commit node
* Und = unlock data disk
* Unp = unlock parity disk
* Unq = unlock q disk
* Wnp = write new parity
* Wnd = write new data
* Wnq = write new "q"
* [ ] denotes optional segments in the graph.
*
* Parameters: raidPtr - description of the physical array
* asmap - logical & physical addresses for this access
* bp - buffer ptr (holds write data)
* flags - general flags (e.g. disk locking)
* allocList - list of memory allocated in DAG creation
* pfuncs - list of parity generating functions
* qfuncs - list of q generating functions
*
* A null qfuncs indicates single fault tolerant.
*****************************************************************************/
void
rf_CommonCreateSmallWriteDAGFwd(RF_Raid_t *raidPtr, RF_AccessStripeMap_t *asmap,
RF_DagHeader_t *dag_h, void *bp, RF_RaidAccessFlags_t flags,
RF_AllocListElem_t *allocList, RF_RedFuncs_t *pfuncs, RF_RedFuncs_t *qfuncs)
{
RF_DagNode_t *readDataNodes, *readParityNodes, *readQNodes, *termNode;
RF_DagNode_t *unlockDataNodes, *unlockParityNodes, *unlockQNodes;
RF_DagNode_t *xorNodes, *qNodes, *blockNode, *nodes;
RF_DagNode_t *writeDataNodes, *writeParityNodes, *writeQNodes;
int i, j, nNodes, totalNumNodes, lu_flag;
RF_ReconUnitNum_t which_ru;
int (*func) (RF_DagNode_t *);
int (*undoFunc) (RF_DagNode_t *);
int (*qfunc) (RF_DagNode_t *);
int numDataNodes, numParityNodes;
RF_StripeNum_t parityStripeID;
RF_PhysDiskAddr_t *pda;
char *name, *qname;
long nfaults;
nfaults = qfuncs ? 2 : 1;
lu_flag = (rf_enableAtomicRMW) ? 1 : 0; /* Lock/unlock flag. */
parityStripeID = rf_RaidAddressToParityStripeID(&(raidPtr->Layout),
asmap->raidAddress, &which_ru);
pda = asmap->physInfo;
numDataNodes = asmap->numStripeUnitsAccessed;
numParityNodes = (asmap->parityInfo->next) ? 2 : 1;
if (rf_dagDebug)
printf("[Creating small-write DAG]\n");
RF_ASSERT(numDataNodes > 0);
dag_h->creator = "SmallWriteDAGFwd";
dag_h->numCommitNodes = 0;
dag_h->numCommits = 0;
dag_h->numSuccedents = 1;
qfunc = NULL;
qname = NULL;
/*
* DAG creation occurs in four steps:
* 1. Count the number of nodes in the DAG.
* 2. Create the nodes.
* 3. Initialize the nodes.
* 4. Connect the nodes.
*/
/* Step 1. Compute number of nodes in the graph. */
/*
* Number of nodes: a read and write for each data unit, a redundancy
* computation node for each parity node (nfaults * nparity), a read
* and write for each parity unit, a block node, a terminate node if
* atomic RMW, an unlock node for each data/redundancy unit.
*/
totalNumNodes = (2 * numDataNodes) + (nfaults * numParityNodes)
+ (nfaults * 2 * numParityNodes) + 2;
if (lu_flag)
totalNumNodes += (numDataNodes + (nfaults * numParityNodes));
/* Step 2. Create the nodes. */
RF_CallocAndAdd(nodes, totalNumNodes, sizeof(RF_DagNode_t),
(RF_DagNode_t *), allocList);
i = 0;
blockNode = &nodes[i];
i += 1;
readDataNodes = &nodes[i];
i += numDataNodes;
readParityNodes = &nodes[i];
i += numParityNodes;
writeDataNodes = &nodes[i];
i += numDataNodes;
writeParityNodes = &nodes[i];
i += numParityNodes;
xorNodes = &nodes[i];
i += numParityNodes;
termNode = &nodes[i];
i += 1;
if (lu_flag) {
unlockDataNodes = &nodes[i];
i += numDataNodes;
unlockParityNodes = &nodes[i];
i += numParityNodes;
} else {
unlockDataNodes = unlockParityNodes = NULL;
}
if (nfaults == 2) {
readQNodes = &nodes[i];
i += numParityNodes;
writeQNodes = &nodes[i];
i += numParityNodes;
qNodes = &nodes[i];
i += numParityNodes;
if (lu_flag) {
unlockQNodes = &nodes[i];
i += numParityNodes;
} else {
unlockQNodes = NULL;
}
} else {
readQNodes = writeQNodes = qNodes = unlockQNodes = NULL;
}
RF_ASSERT(i == totalNumNodes);
/* Step 3. Initialize the nodes. */
/* Initialize block node (Nil). */
nNodes = numDataNodes + (nfaults * numParityNodes);
rf_InitNode(blockNode, rf_wait, RF_FALSE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, nNodes, 0, 0, 0, dag_h,
"Nil", allocList);
/* Initialize terminate node (Trm). */
rf_InitNode(termNode, rf_wait, RF_FALSE, rf_TerminateFunc,
rf_TerminateUndoFunc, NULL, 0, nNodes, 0, 0, dag_h,
"Trm", allocList);
/* Initialize nodes which read old data (Rod). */
for (i = 0; i < numDataNodes; i++) {
rf_InitNode(&readDataNodes[i], rf_wait, RF_FALSE,
rf_DiskReadFunc, rf_DiskReadUndoFunc, rf_GenericWakeupFunc,
(numParityNodes * nfaults) + 1, 1, 4, 0, dag_h,
"Rod", allocList);
RF_ASSERT(pda != NULL);
/* Physical disk addr desc. */
readDataNodes[i].params[0].p = pda;
/* Buffer to hold old data. */
readDataNodes[i].params[1].p = rf_AllocBuffer(raidPtr, dag_h,
pda, allocList);
readDataNodes[i].params[2].v = parityStripeID;
readDataNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
lu_flag, 0, which_ru);
pda = pda->next;
for (j = 0; j < readDataNodes[i].numSuccedents; j++)
readDataNodes[i].propList[j] = NULL;
}
/* Initialize nodes which read old parity (Rop). */
pda = asmap->parityInfo;
i = 0;
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(pda != NULL);
rf_InitNode(&readParityNodes[i], rf_wait, RF_FALSE,
rf_DiskReadFunc, rf_DiskReadUndoFunc, rf_GenericWakeupFunc,
numParityNodes, 1, 4, 0, dag_h, "Rop", allocList);
readParityNodes[i].params[0].p = pda;
/* Buffer to hold old parity. */
readParityNodes[i].params[1].p = rf_AllocBuffer(raidPtr,
dag_h, pda, allocList);
readParityNodes[i].params[2].v = parityStripeID;
readParityNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
lu_flag, 0, which_ru);
for (j = 0; j < readParityNodes[i].numSuccedents; j++)
readParityNodes[i].propList[0] = NULL;
pda = pda->next;
}
/* Initialize nodes which read old Q (Roq). */
if (nfaults == 2) {
pda = asmap->qInfo;
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(pda != NULL);
rf_InitNode(&readQNodes[i], rf_wait, RF_FALSE,
rf_DiskReadFunc, rf_DiskReadUndoFunc,
rf_GenericWakeupFunc, numParityNodes, 1, 4, 0,
dag_h, "Roq", allocList);
readQNodes[i].params[0].p = pda;
/* Buffer to hold old Q. */
readQNodes[i].params[1].p = rf_AllocBuffer(raidPtr,
dag_h, pda, allocList);
readQNodes[i].params[2].v = parityStripeID;
readQNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
lu_flag, 0, which_ru);
for (j = 0; j < readQNodes[i].numSuccedents; j++)
readQNodes[i].propList[0] = NULL;
pda = pda->next;
}
}
/* Initialize nodes which write new data (Wnd). */
pda = asmap->physInfo;
for (i = 0; i < numDataNodes; i++) {
RF_ASSERT(pda != NULL);
rf_InitNode(&writeDataNodes[i], rf_wait, RF_FALSE,
rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
rf_GenericWakeupFunc, 1, 1, 4, 0,
dag_h, "Wnd", allocList);
/* Physical disk addr desc. */
writeDataNodes[i].params[0].p = pda;
/* Buffer holding new data to be written. */
writeDataNodes[i].params[1].p = pda->bufPtr;
writeDataNodes[i].params[2].v = parityStripeID;
writeDataNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
if (lu_flag) {
/* Initialize node to unlock the disk queue. */
rf_InitNode(&unlockDataNodes[i], rf_wait, RF_FALSE,
rf_DiskUnlockFunc, rf_DiskUnlockUndoFunc,
rf_GenericWakeupFunc, 1, 1, 2, 0, dag_h,
"Und", allocList);
/* Physical disk addr desc. */
unlockDataNodes[i].params[0].p = pda;
unlockDataNodes[i].params[1].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, lu_flag, which_ru);
}
pda = pda->next;
}
/* Initialize nodes which compute new parity and Q. */
/*
* Use the simple XOR func in the double-XOR case, and when
* accessing only a portion of one stripe unit. The distinction
* between the two is that the regular XOR func assumes that the
* targbuf is a full SU in size, and examines the pda associated with
* the buffer to decide where within the buffer to XOR the data,
* whereas the simple XOR func just XORs the data into the start of
* the buffer.
*/
if ((numParityNodes == 2) || ((numDataNodes == 1) &&
(asmap->totalSectorsAccessed <
raidPtr->Layout.sectorsPerStripeUnit))) {
func = pfuncs->simple;
undoFunc = rf_NullNodeUndoFunc;
name = pfuncs->SimpleName;
if (qfuncs) {
qfunc = qfuncs->simple;
qname = qfuncs->SimpleName;
}
} else {
func = pfuncs->regular;
undoFunc = rf_NullNodeUndoFunc;
name = pfuncs->RegularName;
if (qfuncs) {
qfunc = qfuncs->regular;
qname = qfuncs->RegularName;
}
}
/*
* Initialize the xor nodes: params are {pda,buf} from {Rod,Wnd,Rop}
* nodes, and raidPtr.
*/
if (numParityNodes == 2) { /* Double-xor case. */
for (i = 0; i < numParityNodes; i++) {
/* No wakeup func for xor. */
rf_InitNode(&xorNodes[i], rf_wait, RF_FALSE, func,
undoFunc, NULL, numParityNodes, numParityNodes +
numDataNodes, 7, 1, dag_h, name, allocList);
xorNodes[i].flags |= RF_DAGNODE_FLAG_YIELD;
xorNodes[i].params[0] = readDataNodes[i].params[0];
xorNodes[i].params[1] = readDataNodes[i].params[1];
xorNodes[i].params[2] = readParityNodes[i].params[0];
xorNodes[i].params[3] = readParityNodes[i].params[1];
xorNodes[i].params[4] = writeDataNodes[i].params[0];
xorNodes[i].params[5] = writeDataNodes[i].params[1];
xorNodes[i].params[6].p = raidPtr;
/* Use old parity buf as target buf. */
xorNodes[i].results[0] = readParityNodes[i].params[1].p;
if (nfaults == 2) {
/* No wakeup func for xor. */
rf_InitNode(&qNodes[i], rf_wait, RF_FALSE,
qfunc, undoFunc, NULL, numParityNodes,
numParityNodes + numDataNodes, 7, 1,
dag_h, qname, allocList);
qNodes[i].params[0] =
readDataNodes[i].params[0];
qNodes[i].params[1] =
readDataNodes[i].params[1];
qNodes[i].params[2] = readQNodes[i].params[0];
qNodes[i].params[3] = readQNodes[i].params[1];
qNodes[i].params[4] =
writeDataNodes[i].params[0];
qNodes[i].params[5] =
writeDataNodes[i].params[1];
qNodes[i].params[6].p = raidPtr;
/* Use old Q buf as target buf. */
qNodes[i].results[0] =
readQNodes[i].params[1].p;
}
}
} else {
/* There is only one xor node in this case. */
rf_InitNode(&xorNodes[0], rf_wait, RF_FALSE, func, undoFunc,
NULL, numParityNodes, numParityNodes + numDataNodes,
(2 * (numDataNodes + numDataNodes + 1) + 1), 1, dag_h,
name, allocList);
xorNodes[0].flags |= RF_DAGNODE_FLAG_YIELD;
for (i = 0; i < numDataNodes + 1; i++) {
/* Set up params related to Rod and Rop nodes. */
xorNodes[0].params[2 * i + 0] =
readDataNodes[i].params[0]; /* pda */
xorNodes[0].params[2 * i + 1] =
readDataNodes[i].params[1]; /* buffer pointer */
}
for (i = 0; i < numDataNodes; i++) {
/* Set up params related to Wnd and Wnp nodes. */
xorNodes[0].params[2 * (numDataNodes + 1 + i) + 0] =
writeDataNodes[i].params[0]; /* pda */
xorNodes[0].params[2 * (numDataNodes + 1 + i) + 1] =
writeDataNodes[i].params[1]; /* buffer pointer */
}
xorNodes[0].params[2 * (numDataNodes + numDataNodes + 1)].p =
raidPtr; /* xor node needs to get at RAID information */
xorNodes[0].results[0] = readParityNodes[0].params[1].p;
if (nfaults == 2) {
rf_InitNode(&qNodes[0], rf_wait, RF_FALSE, qfunc,
undoFunc, NULL, numParityNodes,
numParityNodes + numDataNodes,
(2 * (numDataNodes + numDataNodes + 1) + 1),
1, dag_h, qname, allocList);
for (i = 0; i < numDataNodes; i++) {
/* Set up params related to Rod. */
/* pda */
qNodes[0].params[2 * i + 0] =
readDataNodes[i].params[0];
/* buffer pointer */
qNodes[0].params[2 * i + 1] =
readDataNodes[i].params[1];
}
/* And read old q. */
qNodes[0].params[2 * numDataNodes + 0] =
readQNodes[0].params[0]; /* pda */
qNodes[0].params[2 * numDataNodes + 1] =
readQNodes[0].params[1]; /* buffer pointer */
for (i = 0; i < numDataNodes; i++) {
/* Set up params related to Wnd nodes. */
/* pda */
qNodes[0].params
[2 * (numDataNodes + 1 + i) + 0] =
writeDataNodes[i].params[0];
/* buffer pointer */
qNodes[0].params
[2 * (numDataNodes + 1 + i) + 1] =
writeDataNodes[i].params[1];
}
/* Xor node needs to get at RAID information. */
qNodes[0].params
[2 * (numDataNodes + numDataNodes + 1)].p =
raidPtr;
qNodes[0].results[0] = readQNodes[0].params[1].p;
}
}
/* Initialize nodes which write new parity (Wnp). */
pda = asmap->parityInfo;
for (i = 0; i < numParityNodes; i++) {
rf_InitNode(&writeParityNodes[i], rf_wait, RF_FALSE,
rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
rf_GenericWakeupFunc, 1, numParityNodes,
4, 0, dag_h, "Wnp", allocList);
RF_ASSERT(pda != NULL);
/* Param 1 (bufPtr) filled in by xor node. */
writeParityNodes[i].params[0].p = pda;
/* Buffer pointer for parity write operation. */
writeParityNodes[i].params[1].p = xorNodes[i].results[0];
writeParityNodes[i].params[2].v = parityStripeID;
writeParityNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY, 0, 0, which_ru);
if (lu_flag) {
/* Initialize node to unlock the disk queue. */
rf_InitNode(&unlockParityNodes[i], rf_wait, RF_FALSE,
rf_DiskUnlockFunc, rf_DiskUnlockUndoFunc,
rf_GenericWakeupFunc, 1, 1, 2, 0, dag_h,
"Unp", allocList);
unlockParityNodes[i].params[0].p =
pda; /* Physical disk addr desc. */
unlockParityNodes[i].params[1].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, lu_flag, which_ru);
}
pda = pda->next;
}
/* Initialize nodes which write new Q (Wnq). */
if (nfaults == 2) {
pda = asmap->qInfo;
for (i = 0; i < numParityNodes; i++) {
rf_InitNode(&writeQNodes[i], rf_wait, RF_FALSE,
rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
rf_GenericWakeupFunc, 1, numParityNodes,
4, 0, dag_h, "Wnq", allocList);
RF_ASSERT(pda != NULL);
/* Param 1 (bufPtr) filled in by xor node. */
writeQNodes[i].params[0].p = pda;
/* Buffer pointer for parity write operation. */
writeQNodes[i].params[1].p = qNodes[i].results[0];
writeQNodes[i].params[2].v = parityStripeID;
writeQNodes[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, 0, which_ru);
if (lu_flag) {
/* Initialize node to unlock the disk queue. */
rf_InitNode(&unlockQNodes[i], rf_wait,
RF_FALSE, rf_DiskUnlockFunc,
rf_DiskUnlockUndoFunc,
rf_GenericWakeupFunc, 1, 1, 2, 0,
dag_h, "Unq", allocList);
/* Physical disk addr desc. */
unlockQNodes[i].params[0].p = pda;
unlockQNodes[i].params[1].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, lu_flag, which_ru);
}
pda = pda->next;
}
}
/* Step 4. Connect the nodes. */
/* Connect header to block node. */
dag_h->succedents[0] = blockNode;
/* Connect block node to read old data nodes. */
RF_ASSERT(blockNode->numSuccedents ==
(numDataNodes + (numParityNodes * nfaults)));
for (i = 0; i < numDataNodes; i++) {
blockNode->succedents[i] = &readDataNodes[i];
RF_ASSERT(readDataNodes[i].numAntecedents == 1);
readDataNodes[i].antecedents[0] = blockNode;
readDataNodes[i].antType[0] = rf_control;
}
/* Connect block node to read old parity nodes. */
for (i = 0; i < numParityNodes; i++) {
blockNode->succedents[numDataNodes + i] = &readParityNodes[i];
RF_ASSERT(readParityNodes[i].numAntecedents == 1);
readParityNodes[i].antecedents[0] = blockNode;
readParityNodes[i].antType[0] = rf_control;
}
/* Connect block node to read old Q nodes. */
if (nfaults == 2)
for (i = 0; i < numParityNodes; i++) {
blockNode->succedents[numDataNodes +
numParityNodes + i] = &readQNodes[i];
RF_ASSERT(readQNodes[i].numAntecedents == 1);
readQNodes[i].antecedents[0] = blockNode;
readQNodes[i].antType[0] = rf_control;
}
/* Connect read old data nodes to write new data nodes. */
for (i = 0; i < numDataNodes; i++) {
RF_ASSERT(readDataNodes[i].numSuccedents ==
((nfaults * numParityNodes) + 1));
RF_ASSERT(writeDataNodes[i].numAntecedents == 1);
readDataNodes[i].succedents[0] = &writeDataNodes[i];
writeDataNodes[i].antecedents[0] = &readDataNodes[i];
writeDataNodes[i].antType[0] = rf_antiData;
}
/* Connect read old data nodes to xor nodes. */
for (i = 0; i < numDataNodes; i++) {
for (j = 0; j < numParityNodes; j++) {
RF_ASSERT(xorNodes[j].numAntecedents ==
numDataNodes + numParityNodes);
readDataNodes[i].succedents[1 + j] = &xorNodes[j];
xorNodes[j].antecedents[i] = &readDataNodes[i];
xorNodes[j].antType[i] = rf_trueData;
}
}
/* Connect read old data nodes to q nodes. */
if (nfaults == 2)
for (i = 0; i < numDataNodes; i++)
for (j = 0; j < numParityNodes; j++) {
RF_ASSERT(qNodes[j].numAntecedents ==
numDataNodes + numParityNodes);
readDataNodes[i].succedents
[1 + numParityNodes + j] = &qNodes[j];
qNodes[j].antecedents[i] = &readDataNodes[i];
qNodes[j].antType[i] = rf_trueData;
}
/* Connect read old parity nodes to xor nodes. */
for (i = 0; i < numParityNodes; i++) {
for (j = 0; j < numParityNodes; j++) {
RF_ASSERT(readParityNodes[i].numSuccedents ==
numParityNodes);
readParityNodes[i].succedents[j] = &xorNodes[j];
xorNodes[j].antecedents[numDataNodes + i] =
&readParityNodes[i];
xorNodes[j].antType[numDataNodes + i] = rf_trueData;
}
}
/* Connect read old q nodes to q nodes. */
if (nfaults == 2)
for (i = 0; i < numParityNodes; i++) {
for (j = 0; j < numParityNodes; j++) {
RF_ASSERT(readQNodes[i].numSuccedents ==
numParityNodes);
readQNodes[i].succedents[j] = &qNodes[j];
qNodes[j].antecedents[numDataNodes + i] =
&readQNodes[i];
qNodes[j].antType[numDataNodes + i] =
rf_trueData;
}
}
/* Connect xor nodes to the write new parity nodes. */
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(writeParityNodes[i].numAntecedents == numParityNodes);
for (j = 0; j < numParityNodes; j++) {
RF_ASSERT(xorNodes[j].numSuccedents == numParityNodes);
xorNodes[i].succedents[j] = &writeParityNodes[j];
writeParityNodes[j].antecedents[i] = &xorNodes[i];
writeParityNodes[j].antType[i] = rf_trueData;
}
}
/* Connect q nodes to the write new q nodes. */
if (nfaults == 2)
for (i = 0; i < numParityNodes; i++) {
RF_ASSERT(writeQNodes[i].numAntecedents ==
numParityNodes);
for (j = 0; j < numParityNodes; j++) {
RF_ASSERT(qNodes[j].numSuccedents == 1);
qNodes[i].succedents[j] = &writeQNodes[j];
writeQNodes[j].antecedents[i] = &qNodes[i];
writeQNodes[j].antType[i] = rf_trueData;
}
}
RF_ASSERT(termNode->numAntecedents ==
(numDataNodes + (nfaults * numParityNodes)));
RF_ASSERT(termNode->numSuccedents == 0);
for (i = 0; i < numDataNodes; i++) {
if (lu_flag) {
/* Connect write new data nodes to unlock nodes. */
RF_ASSERT(writeDataNodes[i].numSuccedents == 1);
RF_ASSERT(unlockDataNodes[i].numAntecedents == 1);
writeDataNodes[i].succedents[0] = &unlockDataNodes[i];
unlockDataNodes[i].antecedents[0] = &writeDataNodes[i];
unlockDataNodes[i].antType[0] = rf_control;
/* Connect unlock nodes to term nodes. */
RF_ASSERT(unlockDataNodes[i].numSuccedents == 1);
unlockDataNodes[i].succedents[0] = termNode;
termNode->antecedents[i] = &unlockDataNodes[i];
termNode->antType[i] = rf_control;
} else {
/* Connect write new data nodes to term node. */
RF_ASSERT(writeDataNodes[i].numSuccedents == 1);
RF_ASSERT(termNode->numAntecedents ==
(numDataNodes + (nfaults * numParityNodes)));
writeDataNodes[i].succedents[0] = termNode;
termNode->antecedents[i] = &writeDataNodes[i];
termNode->antType[i] = rf_control;
}
}
for (i = 0; i < numParityNodes; i++) {
if (lu_flag) {
/* Connect write new parity nodes to unlock nodes. */
RF_ASSERT(writeParityNodes[i].numSuccedents == 1);
RF_ASSERT(unlockParityNodes[i].numAntecedents == 1);
writeParityNodes[i].succedents[0] =
&unlockParityNodes[i];
unlockParityNodes[i].antecedents[0] =
&writeParityNodes[i];
unlockParityNodes[i].antType[0] = rf_control;
/* Connect unlock nodes to term node. */
RF_ASSERT(unlockParityNodes[i].numSuccedents == 1);
unlockParityNodes[i].succedents[0] = termNode;
termNode->antecedents[numDataNodes + i] =
&unlockParityNodes[i];
termNode->antType[numDataNodes + i] = rf_control;
} else {
RF_ASSERT(writeParityNodes[i].numSuccedents == 1);
writeParityNodes[i].succedents[0] = termNode;
termNode->antecedents[numDataNodes + i] =
&writeParityNodes[i];
termNode->antType[numDataNodes + i] = rf_control;
}
}
if (nfaults == 2)
for (i = 0; i < numParityNodes; i++) {
if (lu_flag) {
/* Connect write new Q nodes to unlock nodes. */
RF_ASSERT(writeQNodes[i].numSuccedents == 1);
RF_ASSERT(unlockQNodes[i].numAntecedents == 1);
writeQNodes[i].succedents[0] = &unlockQNodes[i];
unlockQNodes[i].antecedents[0] =
&writeQNodes[i];
unlockQNodes[i].antType[0] = rf_control;
/* Connect unlock nodes to unblock node. */
RF_ASSERT(unlockQNodes[i].numSuccedents == 1);
unlockQNodes[i].succedents[0] = termNode;
termNode->antecedents[numDataNodes +
numParityNodes + i] = &unlockQNodes[i];
termNode->antType[numDataNodes +
numParityNodes + i] = rf_control;
} else {
RF_ASSERT(writeQNodes[i].numSuccedents == 1);
writeQNodes[i].succedents[0] = termNode;
termNode->antecedents[numDataNodes +
numParityNodes + i] = &writeQNodes[i];
termNode->antType[numDataNodes +
numParityNodes + i] = rf_control;
}
}
}
/*****************************************************************************
* Create a write graph (fault-free or degraded) for RAID level 1.
*
* Hdr Nil -> Wpd -> Nil -> Trm
* Nil -> Wsd ->
*
* The "Wpd" node writes data to the primary copy in the mirror pair.
* The "Wsd" node writes data to the secondary copy in the mirror pair.
*
* Parameters: raidPtr - description of the physical array
* asmap - logical & physical addresses for this access
* bp - buffer ptr (holds write data)
* flags - general flags (e.g. disk locking)
* allocList - list of memory allocated in DAG creation
*****************************************************************************/
void
rf_CreateRaidOneWriteDAGFwd(RF_Raid_t *raidPtr, RF_AccessStripeMap_t *asmap,
RF_DagHeader_t *dag_h, void *bp, RF_RaidAccessFlags_t flags,
RF_AllocListElem_t *allocList)
{
RF_DagNode_t *blockNode, *unblockNode, *termNode;
RF_DagNode_t *nodes, *wndNode, *wmirNode;
int nWndNodes, nWmirNodes, i;
RF_ReconUnitNum_t which_ru;
RF_PhysDiskAddr_t *pda, *pdaP;
RF_StripeNum_t parityStripeID;
parityStripeID = rf_RaidAddressToParityStripeID(&(raidPtr->Layout),
asmap->raidAddress, &which_ru);
if (rf_dagDebug) {
printf("[Creating RAID level 1 write DAG]\n");
}
/* 2 implies access not SU aligned. */
nWmirNodes = (asmap->parityInfo->next) ? 2 : 1;
nWndNodes = (asmap->physInfo->next) ? 2 : 1;
/* Alloc the Wnd nodes and the Wmir node. */
if (asmap->numDataFailed == 1)
nWndNodes--;
if (asmap->numParityFailed == 1)
nWmirNodes--;
/*
* Total number of nodes = nWndNodes + nWmirNodes +
* (block + unblock + terminator)
*/
RF_CallocAndAdd(nodes, nWndNodes + nWmirNodes + 3,
sizeof(RF_DagNode_t), (RF_DagNode_t *), allocList);
i = 0;
wndNode = &nodes[i];
i += nWndNodes;
wmirNode = &nodes[i];
i += nWmirNodes;
blockNode = &nodes[i];
i += 1;
unblockNode = &nodes[i];
i += 1;
termNode = &nodes[i];
i += 1;
RF_ASSERT(i == (nWndNodes + nWmirNodes + 3));
/* This dag can commit immediately. */
dag_h->numCommitNodes = 0;
dag_h->numCommits = 0;
dag_h->numSuccedents = 1;
/* Initialize the unblock and term nodes. */
rf_InitNode(blockNode, rf_wait, RF_FALSE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, (nWndNodes + nWmirNodes),
0, 0, 0, dag_h, "Nil", allocList);
rf_InitNode(unblockNode, rf_wait, RF_FALSE, rf_NullNodeFunc,
rf_NullNodeUndoFunc, NULL, 1, (nWndNodes + nWmirNodes),
0, 0, dag_h, "Nil", allocList);
rf_InitNode(termNode, rf_wait, RF_FALSE, rf_TerminateFunc,
rf_TerminateUndoFunc, NULL, 0, 1, 0, 0, dag_h, "Trm", allocList);
/* Initialize the wnd nodes. */
if (nWndNodes > 0) {
pda = asmap->physInfo;
for (i = 0; i < nWndNodes; i++) {
rf_InitNode(&wndNode[i], rf_wait, RF_FALSE,
rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h,
"Wpd", allocList);
RF_ASSERT(pda != NULL);
wndNode[i].params[0].p = pda;
wndNode[i].params[1].p = pda->bufPtr;
wndNode[i].params[2].v = parityStripeID;
wndNode[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, 0, which_ru);
pda = pda->next;
}
RF_ASSERT(pda == NULL);
}
/* Initialize the mirror nodes. */
if (nWmirNodes > 0) {
pda = asmap->physInfo;
pdaP = asmap->parityInfo;
for (i = 0; i < nWmirNodes; i++) {
rf_InitNode(&wmirNode[i], rf_wait, RF_FALSE,
rf_DiskWriteFunc, rf_DiskWriteUndoFunc,
rf_GenericWakeupFunc, 1, 1, 4, 0, dag_h,
"Wsd", allocList);
RF_ASSERT(pda != NULL);
wmirNode[i].params[0].p = pdaP;
wmirNode[i].params[1].p = pda->bufPtr;
wmirNode[i].params[2].v = parityStripeID;
wmirNode[i].params[3].v =
RF_CREATE_PARAM3(RF_IO_NORMAL_PRIORITY,
0, 0, which_ru);
pda = pda->next;
pdaP = pdaP->next;
}
RF_ASSERT(pda == NULL);
RF_ASSERT(pdaP == NULL);
}
/* Link the header node to the block node. */
RF_ASSERT(dag_h->numSuccedents == 1);
RF_ASSERT(blockNode->numAntecedents == 0);
dag_h->succedents[0] = blockNode;
/* Link the block node to the write nodes. */
RF_ASSERT(blockNode->numSuccedents == (nWndNodes + nWmirNodes));
for (i = 0; i < nWndNodes; i++) {
RF_ASSERT(wndNode[i].numAntecedents == 1);
blockNode->succedents[i] = &wndNode[i];
wndNode[i].antecedents[0] = blockNode;
wndNode[i].antType[0] = rf_control;
}
for (i = 0; i < nWmirNodes; i++) {
RF_ASSERT(wmirNode[i].numAntecedents == 1);
blockNode->succedents[i + nWndNodes] = &wmirNode[i];
wmirNode[i].antecedents[0] = blockNode;
wmirNode[i].antType[0] = rf_control;
}
/* Link the write nodes to the unblock node. */
RF_ASSERT(unblockNode->numAntecedents == (nWndNodes + nWmirNodes));
for (i = 0; i < nWndNodes; i++) {
RF_ASSERT(wndNode[i].numSuccedents == 1);
wndNode[i].succedents[0] = unblockNode;
unblockNode->antecedents[i] = &wndNode[i];
unblockNode->antType[i] = rf_control;
}
for (i = 0; i < nWmirNodes; i++) {
RF_ASSERT(wmirNode[i].numSuccedents == 1);
wmirNode[i].succedents[0] = unblockNode;
unblockNode->antecedents[i + nWndNodes] = &wmirNode[i];
unblockNode->antType[i + nWndNodes] = rf_control;
}
/* Link the unblock node to the 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;
return;
}