/* $OpenBSD: rf_sstf.c,v 1.3 2000/01/11 18:02:23 peter Exp $ */ /* $NetBSD: rf_sstf.c,v 1.4 2000/01/08 23:45:05 oster Exp $ */ /* * Copyright (c) 1995 Carnegie-Mellon University. * All rights reserved. * * Author: Jim Zelenka * * 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. */ /******************************************************************************* * * sstf.c -- prioritized shortest seek time first disk queueing code * ******************************************************************************/ #include "rf_alloclist.h" #include "rf_stripelocks.h" #include "rf_layout.h" #include "rf_diskqueue.h" #include "rf_sstf.h" #include "rf_debugMem.h" #include "rf_general.h" #include "rf_options.h" #include "rf_raid.h" #include "rf_types.h" #define DIR_LEFT 1 #define DIR_RIGHT 2 #define DIR_EITHER 3 #define SNUM_DIFF(_a_,_b_) (((_a_)>(_b_))?((_a_)-(_b_)):((_b_)-(_a_))) #define QSUM(_sstfq_) (((_sstfq_)->lopri.qlen)+((_sstfq_)->left.qlen)+((_sstfq_)->right.qlen)) static void do_sstf_ord_q(RF_DiskQueueData_t **, RF_DiskQueueData_t **, RF_DiskQueueData_t *); static RF_DiskQueueData_t * closest_to_arm(RF_SstfQ_t *, RF_SectorNum_t, int *, int); static void do_dequeue(RF_SstfQ_t *, RF_DiskQueueData_t *); static void do_sstf_ord_q(queuep, tailp, req) RF_DiskQueueData_t **queuep; RF_DiskQueueData_t **tailp; RF_DiskQueueData_t *req; { RF_DiskQueueData_t *r, *s; if (*queuep == NULL) { *queuep = req; *tailp = req; req->next = NULL; req->prev = NULL; return; } if (req->sectorOffset <= (*queuep)->sectorOffset) { req->next = *queuep; req->prev = NULL; (*queuep)->prev = req; *queuep = req; return; } if (req->sectorOffset > (*tailp)->sectorOffset) { /* optimization */ r = NULL; s = *tailp; goto q_at_end; } for (s = NULL, r = *queuep; r; s = r, r = r->next) { if (r->sectorOffset >= req->sectorOffset) { /* insert after s, before r */ RF_ASSERT(s); req->next = r; r->prev = req; s->next = req; req->prev = s; return; } } q_at_end: /* insert after s, at end of queue */ RF_ASSERT(r == NULL); RF_ASSERT(s); RF_ASSERT(s == (*tailp)); req->next = NULL; req->prev = s; s->next = req; *tailp = req; } /* for removing from head-of-queue */ #define DO_HEAD_DEQ(_r_,_q_) { \ _r_ = (_q_)->queue; \ RF_ASSERT((_r_) != NULL); \ (_q_)->queue = (_r_)->next; \ (_q_)->qlen--; \ if ((_q_)->qlen == 0) { \ RF_ASSERT((_r_) == (_q_)->qtail); \ RF_ASSERT((_q_)->queue == NULL); \ (_q_)->qtail = NULL; \ } \ else { \ RF_ASSERT((_q_)->queue->prev == (_r_)); \ (_q_)->queue->prev = NULL; \ } \ } /* for removing from end-of-queue */ #define DO_TAIL_DEQ(_r_,_q_) { \ _r_ = (_q_)->qtail; \ RF_ASSERT((_r_) != NULL); \ (_q_)->qtail = (_r_)->prev; \ (_q_)->qlen--; \ if ((_q_)->qlen == 0) { \ RF_ASSERT((_r_) == (_q_)->queue); \ RF_ASSERT((_q_)->qtail == NULL); \ (_q_)->queue = NULL; \ } \ else { \ RF_ASSERT((_q_)->qtail->next == (_r_)); \ (_q_)->qtail->next = NULL; \ } \ } #define DO_BEST_DEQ(_l_,_r_,_q_) { \ if (SNUM_DIFF((_q_)->queue->sectorOffset,_l_) \ < SNUM_DIFF((_q_)->qtail->sectorOffset,_l_)) \ { \ DO_HEAD_DEQ(_r_,_q_); \ } \ else { \ DO_TAIL_DEQ(_r_,_q_); \ } \ } static RF_DiskQueueData_t * closest_to_arm(queue, arm_pos, dir, allow_reverse) RF_SstfQ_t *queue; RF_SectorNum_t arm_pos; int *dir; int allow_reverse; { RF_SectorNum_t best_pos_l = 0, this_pos_l = 0, last_pos = 0; RF_SectorNum_t best_pos_r = 0, this_pos_r = 0; RF_DiskQueueData_t *r, *best_l, *best_r; best_r = best_l = NULL; for (r = queue->queue; r; r = r->next) { if (r->sectorOffset < arm_pos) { if (best_l == NULL) { best_l = r; last_pos = best_pos_l = this_pos_l; } else { this_pos_l = arm_pos - r->sectorOffset; if (this_pos_l < best_pos_l) { best_l = r; last_pos = best_pos_l = this_pos_l; } else { last_pos = this_pos_l; } } } else { if (best_r == NULL) { best_r = r; last_pos = best_pos_r = this_pos_r; } else { this_pos_r = r->sectorOffset - arm_pos; if (this_pos_r < best_pos_r) { best_r = r; last_pos = best_pos_r = this_pos_r; } else { last_pos = this_pos_r; } if (this_pos_r > last_pos) { /* getting farther away */ break; } } } } if ((best_r == NULL) && (best_l == NULL)) return (NULL); if ((*dir == DIR_RIGHT) && best_r) return (best_r); if ((*dir == DIR_LEFT) && best_l) return (best_l); if (*dir == DIR_EITHER) { if (best_l == NULL) return (best_r); if (best_r == NULL) return (best_l); if (best_pos_r < best_pos_l) return (best_r); else return (best_l); } /* * Nothing in the direction we want to go. Reverse or * reset the arm. We know we have an I/O in the other * direction. */ if (allow_reverse) { if (*dir == DIR_RIGHT) { *dir = DIR_LEFT; return (best_l); } else { *dir = DIR_RIGHT; return (best_r); } } /* * Reset (beginning of queue). */ RF_ASSERT(*dir == DIR_RIGHT); return (queue->queue); } void * rf_SstfCreate(sect_per_disk, cl_list, listp) RF_SectorCount_t sect_per_disk; RF_AllocListElem_t *cl_list; RF_ShutdownList_t **listp; { RF_Sstf_t *sstfq; RF_CallocAndAdd(sstfq, 1, sizeof(RF_Sstf_t), (RF_Sstf_t *), cl_list); sstfq->dir = DIR_EITHER; sstfq->allow_reverse = 1; return ((void *) sstfq); } void * rf_ScanCreate(sect_per_disk, cl_list, listp) RF_SectorCount_t sect_per_disk; RF_AllocListElem_t *cl_list; RF_ShutdownList_t **listp; { RF_Sstf_t *scanq; RF_CallocAndAdd(scanq, 1, sizeof(RF_Sstf_t), (RF_Sstf_t *), cl_list); scanq->dir = DIR_RIGHT; scanq->allow_reverse = 1; return ((void *) scanq); } void * rf_CscanCreate(sect_per_disk, cl_list, listp) RF_SectorCount_t sect_per_disk; RF_AllocListElem_t *cl_list; RF_ShutdownList_t **listp; { RF_Sstf_t *cscanq; RF_CallocAndAdd(cscanq, 1, sizeof(RF_Sstf_t), (RF_Sstf_t *), cl_list); cscanq->dir = DIR_RIGHT; return ((void *) cscanq); } void rf_SstfEnqueue(qptr, req, priority) void *qptr; RF_DiskQueueData_t *req; int priority; { RF_Sstf_t *sstfq; sstfq = (RF_Sstf_t *) qptr; if (priority == RF_IO_LOW_PRIORITY) { if (rf_sstfDebug || rf_scanDebug || rf_cscanDebug) { RF_DiskQueue_t *dq; dq = (RF_DiskQueue_t *) req->queue; printf("raid%d: ENQ lopri %d,%d queues are %d,%d,%d\n", req->raidPtr->raidid, dq->row, dq->col, sstfq->left.qlen, sstfq->right.qlen, sstfq->lopri.qlen); } do_sstf_ord_q(&sstfq->lopri.queue, &sstfq->lopri.qtail, req); sstfq->lopri.qlen++; } else { if (req->sectorOffset < sstfq->last_sector) { do_sstf_ord_q(&sstfq->left.queue, &sstfq->left.qtail, req); sstfq->left.qlen++; } else { do_sstf_ord_q(&sstfq->right.queue, &sstfq->right.qtail, req); sstfq->right.qlen++; } } } static void do_dequeue(queue, req) RF_SstfQ_t *queue; RF_DiskQueueData_t *req; { RF_DiskQueueData_t *req2; if (rf_sstfDebug || rf_scanDebug || rf_cscanDebug) { printf("raid%d: do_dequeue\n", req->raidPtr->raidid); } if (req == queue->queue) { DO_HEAD_DEQ(req2, queue); RF_ASSERT(req2 == req); } else if (req == queue->qtail) { DO_TAIL_DEQ(req2, queue); RF_ASSERT(req2 == req); } else { /* dequeue from middle of list */ RF_ASSERT(req->next); RF_ASSERT(req->prev); queue->qlen--; req->next->prev = req->prev; req->prev->next = req->next; req->next = req->prev = NULL; } } RF_DiskQueueData_t * rf_SstfDequeue(qptr) void *qptr; { RF_DiskQueueData_t *req = NULL; RF_Sstf_t *sstfq; sstfq = (RF_Sstf_t *) qptr; if (rf_sstfDebug) { RF_DiskQueue_t *dq; dq = (RF_DiskQueue_t *) req->queue; RF_ASSERT(QSUM(sstfq) == dq->queueLength); printf("raid%d: sstf: Dequeue %d,%d queues are %d,%d,%d\n", req->raidPtr->raidid, dq->row, dq->col, sstfq->left.qlen, sstfq->right.qlen, sstfq->lopri.qlen); } if (sstfq->left.queue == NULL) { RF_ASSERT(sstfq->left.qlen == 0); if (sstfq->right.queue == NULL) { RF_ASSERT(sstfq->right.qlen == 0); if (sstfq->lopri.queue == NULL) { RF_ASSERT(sstfq->lopri.qlen == 0); return (NULL); } if (rf_sstfDebug) { printf("raid%d: sstf: check for close lopri", req->raidPtr->raidid); } req = closest_to_arm(&sstfq->lopri, sstfq->last_sector, &sstfq->dir, sstfq->allow_reverse); if (rf_sstfDebug) { printf("raid%d: sstf: closest_to_arm said %lx", req->raidPtr->raidid, (long) req); } if (req == NULL) return (NULL); do_dequeue(&sstfq->lopri, req); } else { DO_BEST_DEQ(sstfq->last_sector, req, &sstfq->right); } } else { if (sstfq->right.queue == NULL) { RF_ASSERT(sstfq->right.qlen == 0); DO_BEST_DEQ(sstfq->last_sector, req, &sstfq->left); } else { if (SNUM_DIFF(sstfq->last_sector, sstfq->right.queue->sectorOffset) < SNUM_DIFF(sstfq->last_sector, sstfq->left.qtail->sectorOffset)) { DO_HEAD_DEQ(req, &sstfq->right); } else { DO_TAIL_DEQ(req, &sstfq->left); } } } RF_ASSERT(req); sstfq->last_sector = req->sectorOffset; return (req); } RF_DiskQueueData_t * rf_ScanDequeue(qptr) void *qptr; { RF_DiskQueueData_t *req = NULL; RF_Sstf_t *scanq; scanq = (RF_Sstf_t *) qptr; if (rf_scanDebug) { RF_DiskQueue_t *dq; dq = (RF_DiskQueue_t *) req->queue; RF_ASSERT(QSUM(scanq) == dq->queueLength); printf("raid%d: scan: Dequeue %d,%d queues are %d,%d,%d\n", req->raidPtr->raidid, dq->row, dq->col, scanq->left.qlen, scanq->right.qlen, scanq->lopri.qlen); } if (scanq->left.queue == NULL) { RF_ASSERT(scanq->left.qlen == 0); if (scanq->right.queue == NULL) { RF_ASSERT(scanq->right.qlen == 0); if (scanq->lopri.queue == NULL) { RF_ASSERT(scanq->lopri.qlen == 0); return (NULL); } req = closest_to_arm(&scanq->lopri, scanq->last_sector, &scanq->dir, scanq->allow_reverse); if (req == NULL) return (NULL); do_dequeue(&scanq->lopri, req); } else { scanq->dir = DIR_RIGHT; DO_HEAD_DEQ(req, &scanq->right); } } else if (scanq->right.queue == NULL) { RF_ASSERT(scanq->right.qlen == 0); RF_ASSERT(scanq->left.queue); scanq->dir = DIR_LEFT; DO_TAIL_DEQ(req, &scanq->left); } else { RF_ASSERT(scanq->right.queue); RF_ASSERT(scanq->left.queue); if (scanq->dir == DIR_RIGHT) { DO_HEAD_DEQ(req, &scanq->right); } else { DO_TAIL_DEQ(req, &scanq->left); } } RF_ASSERT(req); scanq->last_sector = req->sectorOffset; return (req); } RF_DiskQueueData_t * rf_CscanDequeue(qptr) void *qptr; { RF_DiskQueueData_t *req = NULL; RF_Sstf_t *cscanq; cscanq = (RF_Sstf_t *) qptr; RF_ASSERT(cscanq->dir == DIR_RIGHT); if (rf_cscanDebug) { RF_DiskQueue_t *dq; dq = (RF_DiskQueue_t *) req->queue; RF_ASSERT(QSUM(cscanq) == dq->queueLength); printf("raid%d: scan: Dequeue %d,%d queues are %d,%d,%d\n", req->raidPtr->raidid, dq->row, dq->col, cscanq->left.qlen, cscanq->right.qlen, cscanq->lopri.qlen); } if (cscanq->right.queue) { DO_HEAD_DEQ(req, &cscanq->right); } else { RF_ASSERT(cscanq->right.qlen == 0); if (cscanq->left.queue == NULL) { RF_ASSERT(cscanq->left.qlen == 0); if (cscanq->lopri.queue == NULL) { RF_ASSERT(cscanq->lopri.qlen == 0); return (NULL); } req = closest_to_arm(&cscanq->lopri, cscanq->last_sector, &cscanq->dir, cscanq->allow_reverse); if (req == NULL) return (NULL); do_dequeue(&cscanq->lopri, req); } else { /* * There's I/Os to the left of the arm. Swing * on back (swap queues). */ cscanq->right = cscanq->left; cscanq->left.qlen = 0; cscanq->left.queue = cscanq->left.qtail = NULL; DO_HEAD_DEQ(req, &cscanq->right); } } RF_ASSERT(req); cscanq->last_sector = req->sectorOffset; return (req); } RF_DiskQueueData_t * rf_SstfPeek(qptr) void *qptr; { RF_DiskQueueData_t *req; RF_Sstf_t *sstfq; sstfq = (RF_Sstf_t *) qptr; if ((sstfq->left.queue == NULL) && (sstfq->right.queue == NULL)) { req = closest_to_arm(&sstfq->lopri, sstfq->last_sector, &sstfq->dir, sstfq->allow_reverse); } else { if (sstfq->left.queue == NULL) req = sstfq->right.queue; else { if (sstfq->right.queue == NULL) req = sstfq->left.queue; else { if (SNUM_DIFF(sstfq->last_sector, sstfq->right.queue->sectorOffset) < SNUM_DIFF(sstfq->last_sector, sstfq->left.qtail->sectorOffset)) { req = sstfq->right.queue; } else { req = sstfq->left.qtail; } } } } if (req == NULL) { RF_ASSERT(QSUM(sstfq) == 0); } return (req); } RF_DiskQueueData_t * rf_ScanPeek(qptr) void *qptr; { RF_DiskQueueData_t *req; RF_Sstf_t *scanq; int dir; scanq = (RF_Sstf_t *) qptr; dir = scanq->dir; if (scanq->left.queue == NULL) { RF_ASSERT(scanq->left.qlen == 0); if (scanq->right.queue == NULL) { RF_ASSERT(scanq->right.qlen == 0); if (scanq->lopri.queue == NULL) { RF_ASSERT(scanq->lopri.qlen == 0); return (NULL); } req = closest_to_arm(&scanq->lopri, scanq->last_sector, &dir, scanq->allow_reverse); } else { req = scanq->right.queue; } } else if (scanq->right.queue == NULL) { RF_ASSERT(scanq->right.qlen == 0); RF_ASSERT(scanq->left.queue); req = scanq->left.qtail; } else { RF_ASSERT(scanq->right.queue); RF_ASSERT(scanq->left.queue); if (scanq->dir == DIR_RIGHT) { req = scanq->right.queue; } else { req = scanq->left.qtail; } } if (req == NULL) { RF_ASSERT(QSUM(scanq) == 0); } return (req); } RF_DiskQueueData_t * rf_CscanPeek(qptr) void *qptr; { RF_DiskQueueData_t *req; RF_Sstf_t *cscanq; cscanq = (RF_Sstf_t *) qptr; RF_ASSERT(cscanq->dir == DIR_RIGHT); if (cscanq->right.queue) { req = cscanq->right.queue; } else { RF_ASSERT(cscanq->right.qlen == 0); if (cscanq->left.queue == NULL) { RF_ASSERT(cscanq->left.qlen == 0); if (cscanq->lopri.queue == NULL) { RF_ASSERT(cscanq->lopri.qlen == 0); return (NULL); } req = closest_to_arm(&cscanq->lopri, cscanq->last_sector, &cscanq->dir, cscanq->allow_reverse); } else { /* * There's I/Os to the left of the arm. We'll end * up swinging on back. */ req = cscanq->left.queue; } } if (req == NULL) { RF_ASSERT(QSUM(cscanq) == 0); } return (req); } int rf_SstfPromote(qptr, parityStripeID, which_ru) void *qptr; RF_StripeNum_t parityStripeID; RF_ReconUnitNum_t which_ru; { RF_DiskQueueData_t *r, *next; RF_Sstf_t *sstfq; int n; sstfq = (RF_Sstf_t *) qptr; n = 0; if (rf_sstfDebug || rf_scanDebug || rf_cscanDebug) { printf("raid%d: promote %ld %d queues are %d,%d,%d\n", r->raidPtr->raidid, (long) parityStripeID, (int) which_ru, sstfq->left.qlen, sstfq->right.qlen, sstfq->lopri.qlen); } for (r = sstfq->lopri.queue; r; r = next) { next = r->next; if (rf_sstfDebug || rf_scanDebug || rf_cscanDebug) { printf("raid%d: check promote %lx\n", r->raidPtr->raidid, (long) r); } if ((r->parityStripeID == parityStripeID) && (r->which_ru == which_ru)) { do_dequeue(&sstfq->lopri, r); rf_SstfEnqueue(qptr, r, RF_IO_NORMAL_PRIORITY); n++; } } if (rf_sstfDebug || rf_scanDebug || rf_cscanDebug) { printf("raid%d: promoted %d matching I/Os queues are %d,%d,%d\n", r->raidPtr->raidid, n, sstfq->left.qlen, sstfq->right.qlen, sstfq->lopri.qlen); } return (n); }