/* $OpenBSD: rf_cvscan.c,v 1.4 2000/01/07 14:50:20 peter Exp $ */ /* $NetBSD: rf_cvscan.c,v 1.5 1999/08/13 03:41:53 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. */ /******************************************************************************* * * cvscan.c -- prioritized cvscan disk queueing code. * * Nov 9, 1994, adapted from raidSim version (MCH) * ******************************************************************************/ #include "rf_types.h" #include "rf_alloclist.h" #include "rf_stripelocks.h" #include "rf_layout.h" #include "rf_diskqueue.h" #include "rf_cvscan.h" #include "rf_debugMem.h" #include "rf_general.h" #define DO_CHECK_STATE(_hdr_) CheckCvscanState((_hdr_), __FILE__, __LINE__) #define pri_ok(p) ( ((p) == RF_IO_NORMAL_PRIORITY) || ((p) == RF_IO_LOW_PRIORITY)) static void CheckCvscanState(RF_CvscanHeader_t * hdr, char *file, int line) { long i, key; RF_DiskQueueData_t *tmp; if (hdr->left != (RF_DiskQueueData_t *) NULL) RF_ASSERT(hdr->left->sectorOffset < hdr->cur_block); for (key = hdr->cur_block, i = 0, tmp = hdr->left; tmp != (RF_DiskQueueData_t *) NULL; key = tmp->sectorOffset, i++, tmp = tmp->next) RF_ASSERT(tmp->sectorOffset <= key && tmp->priority == hdr->nxt_priority && pri_ok(tmp->priority)); RF_ASSERT(i == hdr->left_cnt); for (key = hdr->cur_block, i = 0, tmp = hdr->right; tmp != (RF_DiskQueueData_t *) NULL; key = tmp->sectorOffset, i++, tmp = tmp->next) { RF_ASSERT(key <= tmp->sectorOffset); RF_ASSERT(tmp->priority == hdr->nxt_priority); RF_ASSERT(pri_ok(tmp->priority)); } RF_ASSERT(i == hdr->right_cnt); for (key = hdr->nxt_priority - 1, tmp = hdr->burner; tmp != (RF_DiskQueueData_t *) NULL; key = tmp->priority, tmp = tmp->next) { RF_ASSERT(tmp); RF_ASSERT(hdr); RF_ASSERT(pri_ok(tmp->priority)); RF_ASSERT(key >= tmp->priority); RF_ASSERT(tmp->priority < hdr->nxt_priority); } } static void PriorityInsert(RF_DiskQueueData_t ** list_ptr, RF_DiskQueueData_t * req) { /* * insert block pointed to by req in to list whose first * entry is * pointed to by the pointer that list_ptr points to * ie., list_ptr * is a grandparent of the first entry */ for (; (*list_ptr) != (RF_DiskQueueData_t *) NULL && (*list_ptr)->priority > req->priority; list_ptr = &((*list_ptr)->next)) { } req->next = (*list_ptr); (*list_ptr) = req; } static void ReqInsert(RF_DiskQueueData_t ** list_ptr, RF_DiskQueueData_t * req, RF_CvscanArmDir_t order) { /* * insert block pointed to by req in to list whose first * entry is * pointed to by the pointer that list_ptr points to * ie., list_ptr * is a grandparent of the first entry */ for (; (*list_ptr) != (RF_DiskQueueData_t *) NULL && ((order == rf_cvscan_RIGHT && (*list_ptr)->sectorOffset <= req->sectorOffset) || (order == rf_cvscan_LEFT && (*list_ptr)->sectorOffset > req->sectorOffset)); list_ptr = &((*list_ptr)->next)) { } req->next = (*list_ptr); (*list_ptr) = req; } static RF_DiskQueueData_t * ReqDequeue(RF_DiskQueueData_t ** list_ptr) { RF_DiskQueueData_t *ret = (*list_ptr); if ((*list_ptr) != (RF_DiskQueueData_t *) NULL) { (*list_ptr) = (*list_ptr)->next; } return (ret); } static void ReBalance(RF_CvscanHeader_t * hdr) { /* DO_CHECK_STATE(hdr); */ while (hdr->right != (RF_DiskQueueData_t *) NULL && hdr->right->sectorOffset < hdr->cur_block) { hdr->right_cnt--; hdr->left_cnt++; ReqInsert(&hdr->left, ReqDequeue(&hdr->right), rf_cvscan_LEFT); } /* DO_CHECK_STATE(hdr); */ } static void Transfer(RF_DiskQueueData_t ** to_list_ptr, RF_DiskQueueData_t ** from_list_ptr) { RF_DiskQueueData_t *gp; for (gp = (*from_list_ptr); gp != (RF_DiskQueueData_t *) NULL;) { RF_DiskQueueData_t *p = gp->next; PriorityInsert(to_list_ptr, gp); gp = p; } (*from_list_ptr) = (RF_DiskQueueData_t *) NULL; } static void RealEnqueue(RF_CvscanHeader_t * hdr, RF_DiskQueueData_t * req) { RF_ASSERT(req->priority == RF_IO_NORMAL_PRIORITY || req->priority == RF_IO_LOW_PRIORITY); DO_CHECK_STATE(hdr); if (hdr->left_cnt == 0 && hdr->right_cnt == 0) { hdr->nxt_priority = req->priority; } if (req->priority > hdr->nxt_priority) { /* ** dump all other outstanding requests on the back burner */ Transfer(&hdr->burner, &hdr->left); Transfer(&hdr->burner, &hdr->right); hdr->left_cnt = 0; hdr->right_cnt = 0; hdr->nxt_priority = req->priority; } if (req->priority < hdr->nxt_priority) { /* ** yet another low priority task! */ PriorityInsert(&hdr->burner, req); } else { if (req->sectorOffset < hdr->cur_block) { /* this request is to the left of the current arms */ ReqInsert(&hdr->left, req, rf_cvscan_LEFT); hdr->left_cnt++; } else { /* this request is to the right of the current arms */ ReqInsert(&hdr->right, req, rf_cvscan_RIGHT); hdr->right_cnt++; } } DO_CHECK_STATE(hdr); } void rf_CvscanEnqueue(void *q_in, RF_DiskQueueData_t * elem, int priority) { RF_CvscanHeader_t *hdr = (RF_CvscanHeader_t *) q_in; RealEnqueue(hdr, elem /* req */ ); } RF_DiskQueueData_t * rf_CvscanDequeue(void *q_in) { RF_CvscanHeader_t *hdr = (RF_CvscanHeader_t *) q_in; long range, i, sum_dist_left, sum_dist_right; RF_DiskQueueData_t *ret; RF_DiskQueueData_t *tmp; DO_CHECK_STATE(hdr); if (hdr->left_cnt == 0 && hdr->right_cnt == 0) return ((RF_DiskQueueData_t *) NULL); range = RF_MIN(hdr->range_for_avg, RF_MIN(hdr->left_cnt, hdr->right_cnt)); for (i = 0, tmp = hdr->left, sum_dist_left = ((hdr->direction == rf_cvscan_RIGHT) ? range * hdr->change_penalty : 0); tmp != (RF_DiskQueueData_t *) NULL && i < range; tmp = tmp->next, i++) { sum_dist_left += hdr->cur_block - tmp->sectorOffset; } for (i = 0, tmp = hdr->right, sum_dist_right = ((hdr->direction == rf_cvscan_LEFT) ? range * hdr->change_penalty : 0); tmp != (RF_DiskQueueData_t *) NULL && i < range; tmp = tmp->next, i++) { sum_dist_right += tmp->sectorOffset - hdr->cur_block; } if (hdr->right_cnt == 0 || sum_dist_left < sum_dist_right) { hdr->direction = rf_cvscan_LEFT; hdr->cur_block = hdr->left->sectorOffset + hdr->left->numSector; hdr->left_cnt = RF_MAX(hdr->left_cnt - 1, 0); tmp = hdr->left; ret = (ReqDequeue(&hdr->left)) /*->parent*/ ; } else { hdr->direction = rf_cvscan_RIGHT; hdr->cur_block = hdr->right->sectorOffset + hdr->right->numSector; hdr->right_cnt = RF_MAX(hdr->right_cnt - 1, 0); tmp = hdr->right; ret = (ReqDequeue(&hdr->right)) /*->parent*/ ; } ReBalance(hdr); if (hdr->left_cnt == 0 && hdr->right_cnt == 0 && hdr->burner != (RF_DiskQueueData_t *) NULL) { /* ** restore low priority requests for next dequeue */ RF_DiskQueueData_t *burner = hdr->burner; hdr->nxt_priority = burner->priority; while (burner != (RF_DiskQueueData_t *) NULL && burner->priority == hdr->nxt_priority) { RF_DiskQueueData_t *next = burner->next; RealEnqueue(hdr, burner); burner = next; } hdr->burner = burner; } DO_CHECK_STATE(hdr); return (ret); } RF_DiskQueueData_t * rf_CvscanPeek(void *q_in) { RF_CvscanHeader_t *hdr = (RF_CvscanHeader_t *) q_in; long range, i, sum_dist_left, sum_dist_right; RF_DiskQueueData_t *tmp, *headElement; DO_CHECK_STATE(hdr); if (hdr->left_cnt == 0 && hdr->right_cnt == 0) headElement = NULL; else { range = RF_MIN(hdr->range_for_avg, RF_MIN(hdr->left_cnt, hdr->right_cnt)); for (i = 0, tmp = hdr->left, sum_dist_left = ((hdr->direction == rf_cvscan_RIGHT) ? range * hdr->change_penalty : 0); tmp != (RF_DiskQueueData_t *) NULL && i < range; tmp = tmp->next, i++) { sum_dist_left += hdr->cur_block - tmp->sectorOffset; } for (i = 0, tmp = hdr->right, sum_dist_right = ((hdr->direction == rf_cvscan_LEFT) ? range * hdr->change_penalty : 0); tmp != (RF_DiskQueueData_t *) NULL && i < range; tmp = tmp->next, i++) { sum_dist_right += tmp->sectorOffset - hdr->cur_block; } if (hdr->right_cnt == 0 || sum_dist_left < sum_dist_right) headElement = hdr->left; else headElement = hdr->right; } return (headElement); } /* ** CVSCAN( 1, 0 ) is Shortest Seek Time First (SSTF) ** lowest average response time ** CVSCAN( 1, infinity ) is SCAN ** lowest response time standard deviation */ int rf_CvscanConfigure() { return (0); } void * rf_CvscanCreate(RF_SectorCount_t sectPerDisk, RF_AllocListElem_t * clList, RF_ShutdownList_t ** listp) { RF_CvscanHeader_t *hdr; long range = 2; /* Currently no mechanism to change these */ long penalty = sectPerDisk / 5; RF_MallocAndAdd(hdr, sizeof(RF_CvscanHeader_t), (RF_CvscanHeader_t *), clList); bzero((char *) hdr, sizeof(RF_CvscanHeader_t)); hdr->range_for_avg = RF_MAX(range, 1); hdr->change_penalty = RF_MAX(penalty, 0); hdr->direction = rf_cvscan_RIGHT; hdr->cur_block = 0; hdr->left_cnt = hdr->right_cnt = 0; hdr->left = hdr->right = (RF_DiskQueueData_t *) NULL; hdr->burner = (RF_DiskQueueData_t *) NULL; DO_CHECK_STATE(hdr); return ((void *) hdr); } #if (defined(__NetBSD__) || defined(__OpenBSD__)) && defined(_KERNEL) /* PrintCvscanQueue is not used, so we ignore it... */ #else static void PrintCvscanQueue(RF_CvscanHeader_t * hdr) { RF_DiskQueueData_t *tmp; printf("CVSCAN(%d,%d) at %d going %s\n", (int) hdr->range_for_avg, (int) hdr->change_penalty, (int) hdr->cur_block, (hdr->direction == rf_cvscan_LEFT) ? "LEFT" : "RIGHT"); printf("\tLeft(%d): ", hdr->left_cnt); for (tmp = hdr->left; tmp != (RF_DiskQueueData_t *) NULL; tmp = tmp->next) printf("(%d,%ld,%d) ", (int) tmp->sectorOffset, (long) (tmp->sectorOffset + tmp->numSector), tmp->priority); printf("\n"); printf("\tRight(%d): ", hdr->right_cnt); for (tmp = hdr->right; tmp != (RF_DiskQueueData_t *) NULL; tmp = tmp->next) printf("(%d,%ld,%d) ", (int) tmp->sectorOffset, (long) (tmp->sectorOffset + tmp->numSector), tmp->priority); printf("\n"); printf("\tBurner: "); for (tmp = hdr->burner; tmp != (RF_DiskQueueData_t *) NULL; tmp = tmp->next) printf("(%d,%ld,%d) ", (int) tmp->sectorOffset, (long) (tmp->sectorOffset + tmp->numSector), tmp->priority); printf("\n"); } #endif /* promotes reconstruction accesses for the given stripeID to normal priority. * returns 1 if an access was found and zero otherwise. Normally, we should * only have one or zero entries in the burner queue, so execution time should * be short. */ int rf_CvscanPromote(void *q_in, RF_StripeNum_t parityStripeID, RF_ReconUnitNum_t which_ru) { RF_CvscanHeader_t *hdr = (RF_CvscanHeader_t *) q_in; RF_DiskQueueData_t *trailer = NULL, *tmp = hdr->burner, *tlist = NULL; int retval = 0; DO_CHECK_STATE(hdr); while (tmp) { /* handle entries at the front of the list */ if (tmp->parityStripeID == parityStripeID && tmp->which_ru == which_ru) { hdr->burner = tmp->next; tmp->priority = RF_IO_NORMAL_PRIORITY; tmp->next = tlist; tlist = tmp; tmp = hdr->burner; } else break; } if (tmp) { trailer = tmp; tmp = tmp->next; } while (tmp) { /* handle entries on the rest of the list */ if (tmp->parityStripeID == parityStripeID && tmp->which_ru == which_ru) { trailer->next = tmp->next; tmp->priority = RF_IO_NORMAL_PRIORITY; tmp->next = tlist; tlist = tmp; /* insert on a temp queue */ tmp = trailer->next; } else { trailer = tmp; tmp = tmp->next; } } while (tlist) { retval++; tmp = tlist->next; RealEnqueue(hdr, tlist); tlist = tmp; } RF_ASSERT(retval == 0 || retval == 1); DO_CHECK_STATE((RF_CvscanHeader_t *) q_in); return (retval); }