/* $NetBSD: rf_fifo.c,v 1.3 1999/02/05 00:06:11 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_fifo.c -- prioritized fifo queue code. * There are only two priority levels: hi and lo. * * Aug 4, 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_fifo.h" #include "rf_debugMem.h" #include "rf_general.h" #include "rf_threadid.h" #include "rf_options.h" /* just malloc a header, zero it (via calloc), and return it */ /*ARGSUSED*/ void * rf_FifoCreate(sectPerDisk, clList, listp) RF_SectorCount_t sectPerDisk; RF_AllocListElem_t *clList; RF_ShutdownList_t **listp; { RF_FifoHeader_t *q; RF_CallocAndAdd(q, 1, sizeof(RF_FifoHeader_t), (RF_FifoHeader_t *), clList); q->hq_count = q->lq_count = 0; return ((void *) q); } void rf_FifoEnqueue(q_in, elem, priority) void *q_in; RF_DiskQueueData_t *elem; int priority; { RF_FifoHeader_t *q = (RF_FifoHeader_t *) q_in; RF_ASSERT(priority == RF_IO_NORMAL_PRIORITY || priority == RF_IO_LOW_PRIORITY); elem->next = NULL; if (priority == RF_IO_NORMAL_PRIORITY) { if (!q->hq_tail) { RF_ASSERT(q->hq_count == 0 && q->hq_head == NULL); q->hq_head = q->hq_tail = elem; } else { RF_ASSERT(q->hq_count != 0 && q->hq_head != NULL); q->hq_tail->next = elem; q->hq_tail = elem; } q->hq_count++; } else { RF_ASSERT(elem->next == NULL); if (rf_fifoDebug) { int tid; rf_get_threadid(tid); printf("[%d] fifo: ENQ lopri\n", tid); } if (!q->lq_tail) { RF_ASSERT(q->lq_count == 0 && q->lq_head == NULL); q->lq_head = q->lq_tail = elem; } else { RF_ASSERT(q->lq_count != 0 && q->lq_head != NULL); q->lq_tail->next = elem; q->lq_tail = elem; } q->lq_count++; } if ((q->hq_count + q->lq_count) != elem->queue->queueLength) { printf("Queue lengths differ!: %d %d %d\n", q->hq_count, q->lq_count, (int) elem->queue->queueLength); printf("%d %d %d %d\n", (int) elem->queue->numOutstanding, (int) elem->queue->maxOutstanding, (int) elem->queue->row, (int) elem->queue->col); } RF_ASSERT((q->hq_count + q->lq_count) == elem->queue->queueLength); } RF_DiskQueueData_t * rf_FifoDequeue(q_in) void *q_in; { RF_FifoHeader_t *q = (RF_FifoHeader_t *) q_in; RF_DiskQueueData_t *nd; RF_ASSERT(q); if (q->hq_head) { RF_ASSERT(q->hq_count != 0 && q->hq_tail != NULL); nd = q->hq_head; q->hq_head = q->hq_head->next; if (!q->hq_head) q->hq_tail = NULL; nd->next = NULL; q->hq_count--; } else if (q->lq_head) { RF_ASSERT(q->lq_count != 0 && q->lq_tail != NULL); nd = q->lq_head; q->lq_head = q->lq_head->next; if (!q->lq_head) q->lq_tail = NULL; nd->next = NULL; q->lq_count--; if (rf_fifoDebug) { int tid; rf_get_threadid(tid); printf("[%d] fifo: DEQ lopri %lx\n", tid, (long) nd); } } else { RF_ASSERT(q->hq_count == 0 && q->lq_count == 0 && q->hq_tail == NULL && q->lq_tail == NULL); nd = NULL; } return (nd); } /* This never gets used!! No loss (I hope) if we don't include it... GO */ #if !defined(__NetBSD__) && !defined(_KERNEL) static RF_DiskQueueData_t * n_in_q(headp, tailp, countp, n, deq) RF_DiskQueueData_t **headp; RF_DiskQueueData_t **tailp; int *countp; int n; int deq; { RF_DiskQueueData_t *r, *s; int i; for (s = NULL, i = n, r = *headp; r; s = r, r = r->next) { if (i == 0) break; i--; } RF_ASSERT(r != NULL); if (deq == 0) return (r); if (s) { s->next = r->next; } else { *headp = r->next; } if (*tailp == r) *tailp = s; (*countp)--; return (r); } #endif #if !defined(KERNEL) && RF_INCLUDE_QUEUE_RANDOM > 0 RF_DiskQueueData_t * rf_RandomPeek(q_in) void *q_in; { RF_FifoHeader_t *q = (RF_FifoHeader_t *) q_in; RF_DiskQueueData_t *req; int n; if (q->hq_head) { n = q->rval % q->hq_count; req = n_in_q(&q->hq_head, &q->hq_tail, &q->hq_count, n, 0); } else { RF_ASSERT(q->hq_count == 0); if (q->lq_head == NULL) { RF_ASSERT(q->lq_count == 0); return (NULL); } n = q->rval % q->lq_count; req = n_in_q(&q->lq_head, &q->lq_tail, &q->lq_count, n, 0); } RF_ASSERT((q->hq_count + q->lq_count) == req->queue->queueLength); RF_ASSERT(req != NULL); return (req); } RF_DiskQueueData_t * rf_RandomDequeue(q_in) void *q_in; { RF_FifoHeader_t *q = (RF_FifoHeader_t *) q_in; RF_DiskQueueData_t *req; int n; if (q->hq_head) { n = q->rval % q->hq_count; q->rval = (long) RF_STATIC_RANDOM(); req = n_in_q(&q->hq_head, &q->hq_tail, &q->hq_count, n, 1); } else { RF_ASSERT(q->hq_count == 0); if (q->lq_head == NULL) { RF_ASSERT(q->lq_count == 0); return (NULL); } n = q->rval % q->lq_count; q->rval = (long) RF_STATIC_RANDOM(); req = n_in_q(&q->lq_head, &q->lq_tail, &q->lq_count, n, 1); } RF_ASSERT((q->hq_count + q->lq_count) == (req->queue->queueLength - 1)); return (req); } #endif /* !KERNEL && RF_INCLUDE_QUEUE_RANDOM > 0 */ /* Return ptr to item at head of queue. Used to examine request * info without actually dequeueing the request. */ RF_DiskQueueData_t * rf_FifoPeek(void *q_in) { RF_DiskQueueData_t *headElement = NULL; RF_FifoHeader_t *q = (RF_FifoHeader_t *) q_in; RF_ASSERT(q); if (q->hq_head) headElement = q->hq_head; else if (q->lq_head) headElement = q->lq_head; return (headElement); } /* We sometimes need to promote a low priority access to a regular priority access. * Currently, this is only used when the user wants to write a stripe which is currently * under reconstruction. * This routine will promote all accesses tagged with the indicated parityStripeID from * the low priority queue to the end of the normal priority queue. * We assume the queue is locked upon entry. */ int rf_FifoPromote(q_in, parityStripeID, which_ru) void *q_in; RF_StripeNum_t parityStripeID; RF_ReconUnitNum_t which_ru; { RF_FifoHeader_t *q = (RF_FifoHeader_t *) q_in; RF_DiskQueueData_t *lp = q->lq_head, *pt = NULL; /* lp = lo-pri queue * pointer, pt = trailer */ int retval = 0; while (lp) { /* search for the indicated parity stripe in the low-pri queue */ if (lp->parityStripeID == parityStripeID && lp->which_ru == which_ru) { /* printf("FifoPromote: promoting access for psid * %ld\n",parityStripeID); */ if (pt) pt->next = lp->next; /* delete an entry other * than the first */ else q->lq_head = lp->next; /* delete the head entry */ if (!q->lq_head) q->lq_tail = NULL; /* we deleted the only * entry */ else if (lp == q->lq_tail) q->lq_tail = pt; /* we deleted the tail * entry */ lp->next = NULL; q->lq_count--; if (q->hq_tail) { q->hq_tail->next = lp; q->hq_tail = lp; } /* append to hi-priority queue */ else { q->hq_head = q->hq_tail = lp; } q->hq_count++; /* UpdateShortestSeekFinishTimeForced(lp->requestPtr, * lp->diskState); *//* deal with this later, if ever */ lp = (pt) ? pt->next : q->lq_head; /* reset low-pri pointer * and continue */ retval++; } else { pt = lp; lp = lp->next; } } /* sanity check. delete this if you ever put more than one entry in * the low-pri queue */ RF_ASSERT(retval == 0 || retval == 1); if (rf_fifoDebug) { int tid; rf_get_threadid(tid); printf("[%d] fifo: promote %d\n", tid, retval); } return (retval); }