File: [local] / sys / dev / raidframe / rf_decluster.c (download)
Revision 1.1.1.1 (vendor branch), Tue Mar 4 16:09:46 2008 UTC (16 years, 6 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_decluster.c,v 1.5 2002/12/16 07:01:03 tdeval Exp $ */
/* $NetBSD: rf_decluster.c,v 1.5 2000/03/07 01:54:29 oster Exp $ */
/*
* Copyright (c) 1995 Carnegie-Mellon University.
* All rights reserved.
*
* Author: Mark Holland
*
* 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_decluster.c -- Code related to the declustered layout.
*
* Created 10-21-92 (MCH)
*
* Nov 93: Adding support for distributed sparing. This code is a little
* complex; the basic layout used is as follows:
* Let F = (v-1)/GCD(r,v-1). The spare space for each set of
* F consecutive fulltables is grouped together and placed after
* that set of tables.
* +-------------------------------+
* | F fulltables |
* | Spare Space |
* | F fulltables |
* | Spare Space |
* | ... |
* +-------------------------------+
*
*****************************************************************************/
#include "rf_types.h"
#include "rf_raid.h"
#include "rf_raidframe.h"
#include "rf_configure.h"
#include "rf_decluster.h"
#include "rf_debugMem.h"
#include "rf_utils.h"
#include "rf_alloclist.h"
#include "rf_general.h"
#include "rf_shutdown.h"
extern int rf_copyback_in_progress; /* Debug only. */
/* Found in rf_kintf.c */
int rf_GetSpareTableFromDaemon(RF_SparetWait_t *);
/* Configuration code. */
int
rf_ConfigureDeclustered(RF_ShutdownList_t **listp, RF_Raid_t *raidPtr,
RF_Config_t *cfgPtr)
{
RF_RaidLayout_t *layoutPtr = &(raidPtr->Layout);
int b, v, k, r, lambda; /* block design params */
int i, j;
RF_RowCol_t *first_avail_slot;
RF_StripeCount_t complete_FT_count, numCompleteFullTablesPerDisk;
RF_DeclusteredConfigInfo_t *info;
RF_StripeCount_t PUsPerDisk, spareRegionDepthInPUs,
numCompleteSpareRegionsPerDisk, extraPUsPerDisk;
RF_StripeCount_t totSparePUsPerDisk;
RF_SectorNum_t diskOffsetOfLastFullTableInSUs;
RF_SectorCount_t SpareSpaceInSUs;
char *cfgBuf = (char *) (cfgPtr->layoutSpecific);
RF_StripeNum_t l, SUID;
SUID = l = 0;
numCompleteSpareRegionsPerDisk = 0;
/* 1. Create layout specific structure. */
RF_MallocAndAdd(info, sizeof(RF_DeclusteredConfigInfo_t),
(RF_DeclusteredConfigInfo_t *), raidPtr->cleanupList);
if (info == NULL)
return (ENOMEM);
layoutPtr->layoutSpecificInfo = (void *) info;
info->SpareTable = NULL;
/* 2. Extract parameters from the config structure. */
if (layoutPtr->map->flags & RF_DISTRIBUTE_SPARE) {
bcopy(cfgBuf, info->sparemap_fname, RF_SPAREMAP_NAME_LEN);
}
cfgBuf += RF_SPAREMAP_NAME_LEN;
b = *((int *) cfgBuf);
cfgBuf += sizeof(int);
v = *((int *) cfgBuf);
cfgBuf += sizeof(int);
k = *((int *) cfgBuf);
cfgBuf += sizeof(int);
r = *((int *) cfgBuf);
cfgBuf += sizeof(int);
lambda = *((int *) cfgBuf);
cfgBuf += sizeof(int);
raidPtr->noRotate = *((int *) cfgBuf);
cfgBuf += sizeof(int);
/*
* The sparemaps are generated assuming that parity is rotated, so we
* issue a warning if both distributed sparing and no-rotate are on at
* the same time.
*/
if ((layoutPtr->map->flags & RF_DISTRIBUTE_SPARE) &&
raidPtr->noRotate) {
RF_ERRORMSG("Warning: distributed sparing specified without"
" parity rotation.\n");
}
if (raidPtr->numCol != v) {
RF_ERRORMSG2("RAID: config error: table element count (%d)"
" not equal to no. of cols (%d).\n", v, raidPtr->numCol);
return (EINVAL);
}
/* 3. Set up the values used in the mapping code. */
info->BlocksPerTable = b;
info->Lambda = lambda;
info->NumParityReps = info->groupSize = k;
/* b blks, k-1 SUs each. */
info->SUsPerTable = b * (k - 1) * layoutPtr->SUsPerPU;
info->SUsPerFullTable = k * info->SUsPerTable; /* rot k times */
info->PUsPerBlock = k - 1;
info->SUsPerBlock = info->PUsPerBlock * layoutPtr->SUsPerPU;
info->TableDepthInPUs = (b * k) / v;
/* k repetitions. */
info->FullTableDepthInPUs = info->TableDepthInPUs * k;
/* Used only in distributed sparing case. */
/* (v-1)/gcd fulltables. */
info->FullTablesPerSpareRegion = (v - 1) / rf_gcd(r, v - 1);
info->TablesPerSpareRegion = k * info->FullTablesPerSpareRegion;
info->SpareSpaceDepthPerRegionInSUs = (r * info->TablesPerSpareRegion /
(v - 1)) * layoutPtr->SUsPerPU;
/* Check to make sure the block design is sufficiently small. */
if ((raidPtr->Layout.map->flags & RF_DISTRIBUTE_SPARE)) {
if (info->FullTableDepthInPUs * layoutPtr->SUsPerPU +
info->SpareSpaceDepthPerRegionInSUs >
layoutPtr->stripeUnitsPerDisk) {
RF_ERRORMSG3("RAID: config error: Full Table depth"
" (%d) + Spare Space (%d) larger than disk size"
" (%d) (BD too big).\n",
(int) info->FullTableDepthInPUs,
(int) info->SpareSpaceDepthPerRegionInSUs,
(int) layoutPtr->stripeUnitsPerDisk);
return (EINVAL);
}
} else {
if (info->TableDepthInPUs * layoutPtr->SUsPerPU >
layoutPtr->stripeUnitsPerDisk) {
RF_ERRORMSG2("RAID: config error: Table depth (%d)"
" larger than disk size (%d) (BD too big).\n",
(int) (info->TableDepthInPUs * layoutPtr->SUsPerPU),
(int) layoutPtr->stripeUnitsPerDisk);
return (EINVAL);
}
}
/*
* Compute the size of each disk, and the number of tables in the last
* fulltable (which need not be complete).
*/
if (raidPtr->Layout.map->flags & RF_DISTRIBUTE_SPARE) {
PUsPerDisk = layoutPtr->stripeUnitsPerDisk /
layoutPtr->SUsPerPU;
spareRegionDepthInPUs =
(info->TablesPerSpareRegion * info->TableDepthInPUs +
(info->TablesPerSpareRegion * info->TableDepthInPUs) /
(v - 1));
info->SpareRegionDepthInSUs =
spareRegionDepthInPUs * layoutPtr->SUsPerPU;
numCompleteSpareRegionsPerDisk =
PUsPerDisk / spareRegionDepthInPUs;
info->NumCompleteSRs = numCompleteSpareRegionsPerDisk;
extraPUsPerDisk = PUsPerDisk % spareRegionDepthInPUs;
/*
* Assume conservatively that we need the full amount of spare
* space in one region in order to provide spares for the
* partial spare region at the end of the array. We set "i"
* to the number of tables in the partial spare region. This
* may actually include some fulltables.
*/
extraPUsPerDisk -= (info->SpareSpaceDepthPerRegionInSUs /
layoutPtr->SUsPerPU);
if (extraPUsPerDisk <= 0)
i = 0;
else
i = extraPUsPerDisk / info->TableDepthInPUs;
complete_FT_count = raidPtr->numRow *
(numCompleteSpareRegionsPerDisk *
(info->TablesPerSpareRegion / k) + i / k);
info->FullTableLimitSUID =
complete_FT_count * info->SUsPerFullTable;
info->ExtraTablesPerDisk = i % k;
/*
* Note that in the last spare region, the spare space is
* complete even though data/parity space is not.
*/
totSparePUsPerDisk = (numCompleteSpareRegionsPerDisk + 1) *
(info->SpareSpaceDepthPerRegionInSUs / layoutPtr->SUsPerPU);
info->TotSparePUsPerDisk = totSparePUsPerDisk;
layoutPtr->stripeUnitsPerDisk =
((complete_FT_count / raidPtr->numRow) *
info->FullTableDepthInPUs + /* data & parity space */
info->ExtraTablesPerDisk * info->TableDepthInPUs +
totSparePUsPerDisk /* spare space */
) * layoutPtr->SUsPerPU;
layoutPtr->dataStripeUnitsPerDisk =
(complete_FT_count * info->FullTableDepthInPUs +
info->ExtraTablesPerDisk * info->TableDepthInPUs) *
layoutPtr->SUsPerPU * (k - 1) / k;
} else {
/*
* Non-dist spare case: force each disk to contain an
* integral number of tables.
*/
layoutPtr->stripeUnitsPerDisk /=
(info->TableDepthInPUs * layoutPtr->SUsPerPU);
layoutPtr->stripeUnitsPerDisk *=
(info->TableDepthInPUs * layoutPtr->SUsPerPU);
/*
* Compute the number of tables in the last fulltable, which
* need not be complete.
*/
complete_FT_count =
((layoutPtr->stripeUnitsPerDisk / layoutPtr->SUsPerPU) /
info->FullTableDepthInPUs) * raidPtr->numRow;
info->FullTableLimitSUID =
complete_FT_count * info->SUsPerFullTable;
info->ExtraTablesPerDisk =
((layoutPtr->stripeUnitsPerDisk / layoutPtr->SUsPerPU) /
info->TableDepthInPUs) % k;
}
raidPtr->sectorsPerDisk = layoutPtr->stripeUnitsPerDisk *
layoutPtr->sectorsPerStripeUnit;
/*
* Find the disk offset of the stripe unit where the last fulltable
* starts.
*/
numCompleteFullTablesPerDisk = complete_FT_count / raidPtr->numRow;
diskOffsetOfLastFullTableInSUs = numCompleteFullTablesPerDisk *
info->FullTableDepthInPUs * layoutPtr->SUsPerPU;
if (raidPtr->Layout.map->flags & RF_DISTRIBUTE_SPARE) {
SpareSpaceInSUs = numCompleteSpareRegionsPerDisk *
info->SpareSpaceDepthPerRegionInSUs;
diskOffsetOfLastFullTableInSUs += SpareSpaceInSUs;
info->DiskOffsetOfLastSpareSpaceChunkInSUs =
diskOffsetOfLastFullTableInSUs + info->ExtraTablesPerDisk *
info->TableDepthInPUs * layoutPtr->SUsPerPU;
}
info->DiskOffsetOfLastFullTableInSUs = diskOffsetOfLastFullTableInSUs;
info->numCompleteFullTablesPerDisk = numCompleteFullTablesPerDisk;
/* 4. Create and initialize the lookup tables. */
info->LayoutTable = rf_make_2d_array(b, k, raidPtr->cleanupList);
if (info->LayoutTable == NULL)
return (ENOMEM);
info->OffsetTable = rf_make_2d_array(b, k, raidPtr->cleanupList);
if (info->OffsetTable == NULL)
return (ENOMEM);
info->BlockTable = rf_make_2d_array(info->TableDepthInPUs *
layoutPtr->SUsPerPU, raidPtr->numCol, raidPtr->cleanupList);
if (info->BlockTable == NULL)
return (ENOMEM);
first_avail_slot = rf_make_1d_array(v, NULL);
if (first_avail_slot == NULL)
return (ENOMEM);
for (i = 0; i < b; i++)
for (j = 0; j < k; j++)
info->LayoutTable[i][j] = *cfgBuf++;
/* Initialize the offset table. */
for (i = 0; i < b; i++)
for (j = 0; j < k; j++) {
info->OffsetTable[i][j] =
first_avail_slot[info->LayoutTable[i][j]];
first_avail_slot[info->LayoutTable[i][j]]++;
}
/* Initialize the block table. */
for (SUID = l = 0; l < layoutPtr->SUsPerPU; l++) {
for (i = 0; i < b; i++) {
for (j = 0; j < k; j++) {
info->BlockTable[(info->OffsetTable[i][j] *
layoutPtr->SUsPerPU) + l]
[info->LayoutTable[i][j]] = SUID;
}
SUID++;
}
}
rf_free_1d_array(first_avail_slot, v);
/* 5. Set up the remaining redundant-but-useful parameters. */
raidPtr->totalSectors = (k * complete_FT_count + raidPtr->numRow *
info->ExtraTablesPerDisk) * info->SUsPerTable *
layoutPtr->sectorsPerStripeUnit;
layoutPtr->numStripe = (raidPtr->totalSectors /
layoutPtr->sectorsPerStripeUnit) / (k - 1);
/*
* Strange evaluation order below to try and minimize overflow
* problems.
*/
layoutPtr->dataSectorsPerStripe =
(k - 1) * layoutPtr->sectorsPerStripeUnit;
layoutPtr->bytesPerStripeUnit = layoutPtr->sectorsPerStripeUnit <<
raidPtr->logBytesPerSector;
layoutPtr->numDataCol = k - 1;
layoutPtr->numParityCol = 1;
return (0);
}
/* Declustering with distributed sparing. */
void rf_ShutdownDeclusteredDS(RF_ThreadArg_t);
void
rf_ShutdownDeclusteredDS(RF_ThreadArg_t arg)
{
RF_DeclusteredConfigInfo_t *info;
RF_Raid_t *raidPtr;
raidPtr = (RF_Raid_t *) arg;
info =
(RF_DeclusteredConfigInfo_t *) raidPtr->Layout.layoutSpecificInfo;
if (info->SpareTable)
rf_FreeSpareTable(raidPtr);
}
int
rf_ConfigureDeclusteredDS(RF_ShutdownList_t **listp, RF_Raid_t *raidPtr,
RF_Config_t *cfgPtr)
{
int rc;
rc = rf_ConfigureDeclustered(listp, raidPtr, cfgPtr);
if (rc)
return (rc);
rc = rf_ShutdownCreate(listp, rf_ShutdownDeclusteredDS, raidPtr);
if (rc) {
RF_ERRORMSG1("Got %d adding shutdown event for"
" DeclusteredDS.\n", rc);
rf_ShutdownDeclusteredDS(raidPtr);
return (rc);
}
return (0);
}
void
rf_MapSectorDeclustered(RF_Raid_t *raidPtr, RF_RaidAddr_t raidSector,
RF_RowCol_t *row, RF_RowCol_t *col, RF_SectorNum_t *diskSector, int remap)
{
RF_RaidLayout_t *layoutPtr = &(raidPtr->Layout);
RF_DeclusteredConfigInfo_t *info =
(RF_DeclusteredConfigInfo_t *) layoutPtr->layoutSpecificInfo;
RF_StripeNum_t SUID = raidSector / layoutPtr->sectorsPerStripeUnit;
RF_StripeNum_t FullTableID, FullTableOffset, TableID, TableOffset;
RF_StripeNum_t BlockID, BlockOffset, RepIndex;
RF_StripeCount_t sus_per_fulltable = info->SUsPerFullTable;
RF_StripeCount_t fulltable_depth =
info->FullTableDepthInPUs * layoutPtr->SUsPerPU;
RF_StripeNum_t base_suid = 0, outSU, SpareRegion = 0, SpareSpace = 0;
rf_decluster_adjust_params(layoutPtr, &SUID, &sus_per_fulltable,
&fulltable_depth, &base_suid);
/* Fulltable ID within array (across rows). */
FullTableID = SUID / sus_per_fulltable;
if (raidPtr->numRow == 1)
*row = 0; /* Avoid a mod and a div in the common case. */
else {
*row = FullTableID % raidPtr->numRow;
/* Convert to fulltable ID on this disk. */
FullTableID /= raidPtr->numRow;
}
if (raidPtr->Layout.map->flags & RF_DISTRIBUTE_SPARE) {
SpareRegion = FullTableID / info->FullTablesPerSpareRegion;
SpareSpace = SpareRegion * info->SpareSpaceDepthPerRegionInSUs;
}
FullTableOffset = SUID % sus_per_fulltable;
TableID = FullTableOffset / info->SUsPerTable;
TableOffset = FullTableOffset - TableID * info->SUsPerTable;
BlockID = TableOffset / info->PUsPerBlock;
BlockOffset = TableOffset - BlockID * info->PUsPerBlock;
BlockID %= info->BlocksPerTable;
RepIndex = info->PUsPerBlock - TableID;
if (!raidPtr->noRotate)
BlockOffset += ((BlockOffset >= RepIndex) ? 1 : 0);
*col = info->LayoutTable[BlockID][BlockOffset];
/* Remap to distributed spare space if indicated. */
if (remap) {
RF_ASSERT(raidPtr->Disks[*row][*col].status ==
rf_ds_reconstructing ||
raidPtr->Disks[*row][*col].status == rf_ds_dist_spared ||
(rf_copyback_in_progress &&
raidPtr->Disks[*row][*col].status == rf_ds_optimal));
rf_remap_to_spare_space(layoutPtr, info, *row, FullTableID,
TableID, BlockID, (base_suid) ? 1 : 0, SpareRegion, col,
&outSU);
} else {
outSU = base_suid;
outSU += FullTableID * fulltable_depth;
/* Offset to start of FT. */
outSU += SpareSpace;
/* Skip rsvd spare space. */
outSU += TableID * info->TableDepthInPUs * layoutPtr->SUsPerPU;
/* Offset to start of table. */
outSU += info->OffsetTable[BlockID][BlockOffset] *
layoutPtr->SUsPerPU;
/* Offset to the PU. */
}
outSU += TableOffset / (info->BlocksPerTable * info->PUsPerBlock);
/* offs to the SU within a PU */
/*
* Convert SUs to sectors, and, if not aligned to SU boundary, add in
* offset to sector.
*/
*diskSector = outSU * layoutPtr->sectorsPerStripeUnit +
(raidSector % layoutPtr->sectorsPerStripeUnit);
RF_ASSERT(*col != -1);
}
/*
* Prototyping this inexplicably causes the compile of the layout table
* (rf_layout.c) to fail.
*/
void
rf_MapParityDeclustered(RF_Raid_t *raidPtr, RF_RaidAddr_t raidSector,
RF_RowCol_t *row, RF_RowCol_t *col, RF_SectorNum_t *diskSector, int remap)
{
RF_RaidLayout_t *layoutPtr = &(raidPtr->Layout);
RF_DeclusteredConfigInfo_t *info =
(RF_DeclusteredConfigInfo_t *) layoutPtr->layoutSpecificInfo;
RF_StripeNum_t SUID = raidSector / layoutPtr->sectorsPerStripeUnit;
RF_StripeNum_t FullTableID, FullTableOffset, TableID, TableOffset;
RF_StripeNum_t BlockID, BlockOffset, RepIndex;
RF_StripeCount_t sus_per_fulltable = info->SUsPerFullTable;
RF_StripeCount_t fulltable_depth =
info->FullTableDepthInPUs * layoutPtr->SUsPerPU;
RF_StripeNum_t base_suid = 0, outSU, SpareRegion = 0, SpareSpace = 0;
rf_decluster_adjust_params(layoutPtr, &SUID, &sus_per_fulltable,
&fulltable_depth, &base_suid);
/* Compute row & (possibly) spare space exactly as before. */
FullTableID = SUID / sus_per_fulltable;
if (raidPtr->numRow == 1)
*row = 0; /* Avoid a mod and a div in the common case. */
else {
*row = FullTableID % raidPtr->numRow;
/* Convert to fulltable ID on this disk. */
FullTableID /= raidPtr->numRow;
}
if ((raidPtr->Layout.map->flags & RF_DISTRIBUTE_SPARE)) {
SpareRegion = FullTableID / info->FullTablesPerSpareRegion;
SpareSpace = SpareRegion * info->SpareSpaceDepthPerRegionInSUs;
}
/* Compute BlockID and RepIndex exactly as before. */
FullTableOffset = SUID % sus_per_fulltable;
TableID = FullTableOffset / info->SUsPerTable;
TableOffset = FullTableOffset - TableID * info->SUsPerTable;
/*TableOffset = FullTableOffset % info->SUsPerTable;*/
/*BlockID = (TableOffset / info->PUsPerBlock) %
*info->BlocksPerTable;*/
BlockID = TableOffset / info->PUsPerBlock;
/*BlockOffset = TableOffset % info->PUsPerBlock;*/
BlockOffset = TableOffset - BlockID * info->PUsPerBlock;
BlockID %= info->BlocksPerTable;
/* The parity block is in the position indicated by RepIndex. */
RepIndex = (raidPtr->noRotate) ?
info->PUsPerBlock : info->PUsPerBlock - TableID;
*col = info->LayoutTable[BlockID][RepIndex];
if (remap) {
RF_ASSERT(raidPtr->Disks[*row][*col].status ==
rf_ds_reconstructing ||
raidPtr->Disks[*row][*col].status == rf_ds_dist_spared ||
(rf_copyback_in_progress &&
raidPtr->Disks[*row][*col].status == rf_ds_optimal));
rf_remap_to_spare_space(layoutPtr, info, *row, FullTableID,
TableID, BlockID, (base_suid) ? 1 : 0, SpareRegion, col,
&outSU);
} else {
/*
* Compute sector as before, except use RepIndex instead of
* BlockOffset.
*/
outSU = base_suid;
outSU += FullTableID * fulltable_depth;
outSU += SpareSpace; /* skip rsvd spare space */
outSU += TableID * info->TableDepthInPUs * layoutPtr->SUsPerPU;
outSU += info->OffsetTable[BlockID][RepIndex] *
layoutPtr->SUsPerPU;
}
outSU += TableOffset / (info->BlocksPerTable * info->PUsPerBlock);
*diskSector = outSU * layoutPtr->sectorsPerStripeUnit +
(raidSector % layoutPtr->sectorsPerStripeUnit);
RF_ASSERT(*col != -1);
}
/*
* Return an array of ints identifying the disks that comprise the stripe
* containing the indicated address.
* The caller must _never_ attempt to modify this array.
*/
void
rf_IdentifyStripeDeclustered(RF_Raid_t *raidPtr, RF_RaidAddr_t addr,
RF_RowCol_t **diskids, RF_RowCol_t *outRow)
{
RF_RaidLayout_t *layoutPtr = &(raidPtr->Layout);
RF_DeclusteredConfigInfo_t *info =
(RF_DeclusteredConfigInfo_t *) layoutPtr->layoutSpecificInfo;
RF_StripeCount_t sus_per_fulltable = info->SUsPerFullTable;
RF_StripeCount_t fulltable_depth =
info->FullTableDepthInPUs * layoutPtr->SUsPerPU;
RF_StripeNum_t base_suid = 0;
RF_StripeNum_t SUID = rf_RaidAddressToStripeUnitID(layoutPtr, addr);
RF_StripeNum_t stripeID, FullTableID;
int tableOffset;
rf_decluster_adjust_params(layoutPtr, &SUID, &sus_per_fulltable,
&fulltable_depth, &base_suid);
/* Fulltable ID within array (across rows). */
FullTableID = SUID / sus_per_fulltable;
*outRow = FullTableID % raidPtr->numRow;
/* Find stripe offset into array. */
stripeID = rf_StripeUnitIDToStripeID(layoutPtr, SUID);
/* Find offset into block design table. */
tableOffset = (stripeID % info->BlocksPerTable);
*diskids = info->LayoutTable[tableOffset];
}
/*
* This returns the default head-separation limit, measured in
* "required units for reconstruction". Each time a disk fetches
* a unit, it bumps a counter. The head-sep code prohibits any disk
* from getting more than headSepLimit counter values ahead of any
* other.
*
* We assume here that the number of floating recon buffers is already
* set. There are r stripes to be reconstructed in each table, and so
* if we have a total of B buffers, we can have at most B/r tables
* under recon at any one time. In each table, lambda units are required
* from each disk, so given B buffers, the head sep limit has to be
* (lambda*B)/r units. We subtract one to avoid weird boundary cases.
*
* For example, suppose we are given 50 buffers, r=19, and lambda=4 as in
* the 20.5 design. There are 19 stripes/table to be reconstructed, so
* we can have 50/19 tables concurrently under reconstruction, which means
* we can allow the fastest disk to get 50/19 tables ahead of the slower
* disk. There are lambda "required units" for each disk, so the fastest
* disk can get 4*50/19 = 10 counter values ahead of the slowest.
*
* If numBufsToAccumulate is not 1, we need to limit the head sep further
* because multiple bufs will be required for each stripe under recon.
*/
RF_HeadSepLimit_t
rf_GetDefaultHeadSepLimitDeclustered(RF_Raid_t *raidPtr)
{
RF_DeclusteredConfigInfo_t *info =
(RF_DeclusteredConfigInfo_t *) raidPtr->Layout.layoutSpecificInfo;
return (info->Lambda * raidPtr->numFloatingReconBufs /
info->TableDepthInPUs / rf_numBufsToAccumulate);
}
/*
* Return the default number of recon buffers to use. The value
* is somewhat arbitrary... It's intended to be large enough to
* allow for a reasonably large head-sep limit, but small enough
* that you don't use up all your system memory with buffers.
*/
int
rf_GetDefaultNumFloatingReconBuffersDeclustered(RF_Raid_t *raidPtr)
{
return (100 * rf_numBufsToAccumulate);
}
/*
* Sectors in the last fulltable of the array need to be handled
* specially since this fulltable can be incomplete. This function
* changes the values of certain params to handle this.
*
* The idea here is that MapSector et. al. figure out which disk the
* addressed unit lives on by computing the modulos of the unit number
* with the number of units per fulltable, table, etc. In the last
* fulltable, there are fewer units per fulltable, so we need to adjust
* the number of user data units per fulltable to reflect this.
*
* So, we (1) convert the fulltable size and depth parameters to
* the size of the partial fulltable at the end, (2) compute the
* disk sector offset where this fulltable starts, and (3) convert
* the users stripe unit number from an offset into the array to
* an offset into the last fulltable.
*/
void
rf_decluster_adjust_params(RF_RaidLayout_t *layoutPtr, RF_StripeNum_t *SUID,
RF_StripeCount_t *sus_per_fulltable, RF_StripeCount_t *fulltable_depth,
RF_StripeNum_t *base_suid)
{
RF_DeclusteredConfigInfo_t *info =
(RF_DeclusteredConfigInfo_t *) layoutPtr->layoutSpecificInfo;
if (*SUID >= info->FullTableLimitSUID) {
/* New full table size is size of last full table on disk. */
*sus_per_fulltable =
info->ExtraTablesPerDisk * info->SUsPerTable;
/* New full table depth is corresponding depth. */
*fulltable_depth =
info->ExtraTablesPerDisk * info->TableDepthInPUs *
layoutPtr->SUsPerPU;
/* Set up the new base offset. */
*base_suid = info->DiskOffsetOfLastFullTableInSUs;
/*
* Convert user's array address to an offset into the last
* fulltable.
*/
*SUID -= info->FullTableLimitSUID;
}
}
/*
* Map a stripe ID to a parity stripe ID.
* See comment above RaidAddressToParityStripeID in layout.c.
*/
void
rf_MapSIDToPSIDDeclustered(RF_RaidLayout_t *layoutPtr, RF_StripeNum_t stripeID,
RF_StripeNum_t *psID, RF_ReconUnitNum_t *which_ru)
{
RF_DeclusteredConfigInfo_t *info;
info = (RF_DeclusteredConfigInfo_t *) layoutPtr->layoutSpecificInfo;
*psID = (stripeID / (layoutPtr->SUsPerPU * info->BlocksPerTable)) *
info->BlocksPerTable + (stripeID % info->BlocksPerTable);
*which_ru = (stripeID % (info->BlocksPerTable * layoutPtr->SUsPerPU)) /
info->BlocksPerTable;
RF_ASSERT((*which_ru) < layoutPtr->SUsPerPU / layoutPtr->SUsPerRU);
}
/*
* Called from MapSector and MapParity to retarget an access at the spare unit.
* Modifies the "col" and "outSU" parameters only.
*/
void
rf_remap_to_spare_space(RF_RaidLayout_t *layoutPtr,
RF_DeclusteredConfigInfo_t *info, RF_RowCol_t row,
RF_StripeNum_t FullTableID, RF_StripeNum_t TableID, RF_SectorNum_t BlockID,
RF_StripeNum_t base_suid, RF_StripeNum_t SpareRegion, RF_RowCol_t *outCol,
RF_StripeNum_t *outSU)
{
RF_StripeNum_t ftID, spareTableStartSU, TableInSpareRegion,
lastSROffset, which_ft;
/*
* Note that FullTableID and hence SpareRegion may have gotten
* tweaked by rf_decluster_adjust_params. We detect this by
* noticing that base_suid is not 0.
*/
if (base_suid == 0) {
ftID = FullTableID;
} else {
/*
* There may be > 1.0 full tables in the last (i.e. partial)
* spare region. Find out which of these we are in.
*/
lastSROffset = info->NumCompleteSRs *
info->SpareRegionDepthInSUs;
which_ft =
(info->DiskOffsetOfLastFullTableInSUs - lastSROffset) /
(info->FullTableDepthInPUs * layoutPtr->SUsPerPU);
/* Compute the actual full table ID. */
ftID = info->DiskOffsetOfLastFullTableInSUs /
(info->FullTableDepthInPUs * layoutPtr->SUsPerPU) +
which_ft;
SpareRegion = info->NumCompleteSRs;
}
TableInSpareRegion = (ftID * info->NumParityReps + TableID) %
info->TablesPerSpareRegion;
*outCol = info->SpareTable[TableInSpareRegion][BlockID].spareDisk;
RF_ASSERT(*outCol != -1);
spareTableStartSU = (SpareRegion == info->NumCompleteSRs) ?
info->DiskOffsetOfLastFullTableInSUs + info->ExtraTablesPerDisk *
info->TableDepthInPUs * layoutPtr->SUsPerPU :
(SpareRegion + 1) * info->SpareRegionDepthInSUs -
info->SpareSpaceDepthPerRegionInSUs;
*outSU = spareTableStartSU +
info->SpareTable[TableInSpareRegion][BlockID].spareBlockOffsetInSUs;
if (*outSU >= layoutPtr->stripeUnitsPerDisk) {
printf("rf_remap_to_spare_space: invalid remapped disk SU"
" offset %ld.\n", (long) *outSU);
}
}
int
rf_InstallSpareTable(RF_Raid_t *raidPtr, RF_RowCol_t frow, RF_RowCol_t fcol)
{
RF_DeclusteredConfigInfo_t *info =
(RF_DeclusteredConfigInfo_t *) raidPtr->Layout.layoutSpecificInfo;
RF_SparetWait_t *req;
int retcode;
RF_Malloc(req, sizeof(*req), (RF_SparetWait_t *));
req->C = raidPtr->numCol;
req->G = raidPtr->Layout.numDataCol + raidPtr->Layout.numParityCol;
req->fcol = fcol;
req->SUsPerPU = raidPtr->Layout.SUsPerPU;
req->TablesPerSpareRegion = info->TablesPerSpareRegion;
req->BlocksPerTable = info->BlocksPerTable;
req->TableDepthInPUs = info->TableDepthInPUs;
req->SpareSpaceDepthPerRegionInSUs =
info->SpareSpaceDepthPerRegionInSUs;
retcode = rf_GetSpareTableFromDaemon(req);
RF_ASSERT(!retcode);
/* XXX -- Fix this to recover gracefully. -- XXX */
return (retcode);
}
/*
* Invoked via ioctl to install a spare table in the kernel.
*/
int
rf_SetSpareTable(RF_Raid_t *raidPtr, void *data)
{
RF_DeclusteredConfigInfo_t *info =
(RF_DeclusteredConfigInfo_t *) raidPtr->Layout.layoutSpecificInfo;
RF_SpareTableEntry_t **ptrs;
int i, retcode;
/*
* What we need to copyin is a 2-d array, so first copyin the user
* pointers to the rows in the table.
*/
RF_Malloc(ptrs, info->TablesPerSpareRegion *
sizeof(RF_SpareTableEntry_t *), (RF_SpareTableEntry_t **));
retcode = copyin((caddr_t) data, (caddr_t) ptrs,
info->TablesPerSpareRegion * sizeof(RF_SpareTableEntry_t *));
if (retcode)
return (retcode);
/* Now allocate kernel space for the row pointers. */
RF_Malloc(info->SpareTable, info->TablesPerSpareRegion *
sizeof(RF_SpareTableEntry_t *), (RF_SpareTableEntry_t **));
/*
* Now allocate kernel space for each row in the table, and copy it in
* from user space. */
for (i = 0; i < info->TablesPerSpareRegion; i++) {
RF_Malloc(info->SpareTable[i], info->BlocksPerTable *
sizeof(RF_SpareTableEntry_t), (RF_SpareTableEntry_t *));
retcode = copyin(ptrs[i], info->SpareTable[i],
info->BlocksPerTable * sizeof(RF_SpareTableEntry_t));
if (retcode) {
/* Blow off the memory we have allocated. */
info->SpareTable = NULL;
return (retcode);
}
}
/* Free up the temporary array we used. */
RF_Free(ptrs, info->TablesPerSpareRegion *
sizeof(RF_SpareTableEntry_t *));
return (0);
}
RF_ReconUnitCount_t
rf_GetNumSpareRUsDeclustered(RF_Raid_t *raidPtr)
{
RF_RaidLayout_t *layoutPtr = &raidPtr->Layout;
return (((RF_DeclusteredConfigInfo_t *)
layoutPtr->layoutSpecificInfo)->TotSparePUsPerDisk);
}
void
rf_FreeSpareTable(RF_Raid_t *raidPtr)
{
long i;
RF_RaidLayout_t *layoutPtr = &raidPtr->Layout;
RF_DeclusteredConfigInfo_t *info =
(RF_DeclusteredConfigInfo_t *) layoutPtr->layoutSpecificInfo;
RF_SpareTableEntry_t **table = info->SpareTable;
for (i = 0; i < info->TablesPerSpareRegion; i++) {
RF_Free(table[i], info->BlocksPerTable *
sizeof(RF_SpareTableEntry_t));
}
RF_Free(table, info->TablesPerSpareRegion *
sizeof(RF_SpareTableEntry_t *));
info->SpareTable = (RF_SpareTableEntry_t **) NULL;
}