Mercurial > illumos > onarm
view usr/src/cmd/fs.d/nfs/nfslog/readbuf.c @ 4:1a15d5aaf794
synchronized with onnv_86 (6202) in onnv-gate
| author | Koji Uno <koji.uno@sun.com> |
|---|---|
| date | Mon, 31 Aug 2009 14:38:03 +0900 |
| parents | c9caec207d52 |
| children |
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/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License, Version 1.0 only * (the "License"). You may not use this file except in compliance * with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END */ /* * Copyright 2005 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * nfs log - read buffer file and return structs in usable form */ #include <ctype.h> #include <stdio.h> #include <stdlib.h> #include <stddef.h> #include <string.h> #include <fcntl.h> #include <unistd.h> #include <signal.h> #include <sys/types.h> #include <sys/param.h> #include <sys/stat.h> #include <sys/utsname.h> #include <sys/mman.h> #include <strings.h> #include <errno.h> #include <syslog.h> #include <time.h> #include <limits.h> #include <libintl.h> #include <values.h> #include <search.h> #include <pwd.h> #include <netdb.h> #include <rpc/rpc.h> #include <netconfig.h> #include <netdir.h> #include <nfs/nfs_sec.h> #include <nfs/export.h> #include <rpc/auth.h> #include <rpc/svc.h> #include <rpc/xdr.h> #include <rpc/clnt.h> #include <nfs/nfs.h> #include <nfs/nfs_log.h> #include "nfslogd.h" #define MAX_LRS_READ_AHEAD 2048 #define MAX_RECS_TO_DELAY 32768 static int nfslog_init_buf(char *, struct nfslog_buf *, int *); static void nfslog_free_buf(struct nfslog_buf *, int); static struct nfslog_lr *nfslog_read_buffer(struct nfslog_buf *); static void free_lrp(struct nfslog_lr *); static struct nfslog_lr *remove_lrp_from_lb(struct nfslog_buf *, struct nfslog_lr *); static void insert_lrp_to_lb(struct nfslog_buf *, struct nfslog_lr *); static void nfslog_rewrite_bufheader(struct nfslog_buf *); /* * Treat the provided path name as an NFS log buffer file. * Allocate a data structure for its handling and initialize it. * *error contains the previous error condition encountered for * this object. This value can be used to avoid printing the last * error endlessly. * It will set *error appropriately after processing. */ struct nfslog_buf * nfslog_open_buf(char *bufpath, int *error) { struct nfslog_buf *lbp = NULL; if (bufpath == NULL) { *error = EINVAL; return (NULL); } if ((lbp = malloc(sizeof (struct nfslog_buf))) == NULL) { *error = ENOMEM; return (NULL); } bzero(lbp, sizeof (struct nfslog_buf)); if (nfslog_init_buf(bufpath, lbp, error)) { free(lbp); return (NULL); } return (lbp); } /* * Free the log buffer struct with all of its baggage and free the data struct */ void nfslog_close_buf(struct nfslog_buf *lbp, int close_quick) { nfslog_free_buf(lbp, close_quick); free(lbp); } /* * Set up the log buffer struct; simple things are opening and locking * the buffer file and then on to mmap()ing it for later use by the * XDR decode path. Make sure to read the buffer header before * returning so that we will be at the first true log record. * * *error contains the last error encountered on this object. It can * be used to avoid reporting the same error endlessly. It is reset * to the current error code on return. */ static int nfslog_init_buf(char *bufpath, struct nfslog_buf *lbp, int *error) { struct stat sb; int preverror = *error; lbp->next = lbp; lbp->prev = lbp; /* * set these values so that the free routine will know what to do */ lbp->mmap_addr = (intptr_t)MAP_FAILED; lbp->last_rec_id = MAXINT - 1; lbp->bh.bh_length = 0; lbp->bh_lrp = NULL; lbp->num_lrps = 0; lbp->lrps = NULL; lbp->last_record_offset = 0; lbp->prp = NULL; lbp->num_pr_queued = 0; lbp->bufpath = strdup(bufpath); if (lbp->bufpath == NULL) { *error = ENOMEM; if (preverror != *error) { syslog(LOG_ERR, gettext("Cannot strdup '%s': %s"), bufpath, strerror(*error)); } nfslog_free_buf(lbp, FALSE); return (*error); } if ((lbp->fd = open(bufpath, O_RDWR)) < 0) { *error = errno; if (preverror != *error) { syslog(LOG_ERR, gettext("Cannot open '%s': %s"), bufpath, strerror(*error)); } nfslog_free_buf(lbp, FALSE); return (*error); } /* * Lock the entire buffer file to prevent conflicting access. * We get a write lock because we want only 1 process to be * generating records from it. */ lbp->fl.l_type = F_WRLCK; lbp->fl.l_whence = SEEK_SET; /* beginning of file */ lbp->fl.l_start = (offset_t)0; lbp->fl.l_len = 0; /* entire file */ lbp->fl.l_sysid = 0; lbp->fl.l_pid = 0; if (fcntl(lbp->fd, F_SETLKW, &lbp->fl) == -1) { *error = errno; if (preverror != *error) { syslog(LOG_ERR, gettext("Cannot lock (%s): %s"), bufpath, strerror(*error)); } nfslog_free_buf(lbp, FALSE); return (*error); } if (fstat(lbp->fd, &sb)) { *error = errno; if (preverror != *error) { syslog(LOG_ERR, gettext("Cannot stat (%s): %s"), bufpath, strerror(*error)); } nfslog_free_buf(lbp, FALSE); return (*error); } lbp->filesize = sb.st_size; lbp->mmap_addr = (intptr_t)mmap(0, lbp->filesize, PROT_READ|PROT_WRITE, MAP_SHARED|MAP_NORESERVE, lbp->fd, 0); /* This is part of the duality of the use of either mmap()|read() */ if (lbp->mmap_addr == (intptr_t)MAP_FAILED) { lbp->next_rec = 0; } else { lbp->next_rec = lbp->mmap_addr; } /* Read the header */ if ((lbp->bh_lrp = nfslog_read_buffer(lbp)) == NULL) { *error = EIO; if (preverror != *error) { syslog(LOG_ERR, gettext( "error in reading file '%s': %s"), bufpath, strerror(EIO)); } nfslog_free_buf(lbp, FALSE); return (*error); } if (!xdr_nfslog_buffer_header(&lbp->bh_lrp->xdrs, &lbp->bh)) { *error = EIO; if (preverror != *error) { syslog(LOG_ERR, gettext( "error in reading file '%s': %s"), bufpath, strerror(*error)); } nfslog_free_buf(lbp, FALSE); return (*error); } /* * Set the pointer to the next record based on the buffer header. * 'lbp->bh.bh_offset' contains the offset of where to begin * processing relative to the buffer header. */ lbp->next_rec += lbp->bh.bh_offset; /* * If we are going to be using read() for file data, then we may * have to adjust the current file pointer to take into account * a starting point other than the beginning of the file. * If mmap is being used, this is taken care of as a side effect of * setting up the value of next_rec. */ if (lbp->mmap_addr == (intptr_t)MAP_FAILED && lbp->next_rec != 0) { (void) lseek(lbp->fd, lbp->next_rec, SEEK_SET); /* This is a special case of setting the last_record_offset */ lbp->last_record_offset = lbp->next_rec; } else { lbp->last_record_offset = lbp->next_rec - lbp->mmap_addr; } return (*error = 0); } /* * Free the nfslog buffer and its associated allocations */ static void nfslog_free_buf(struct nfslog_buf *lbp, int close_quick) { XDR xdrs; int error; caddr_t buffer; struct nfslog_lr *lrp, *lrp_next; struct processed_records *prp, *tprp; /* work to free the offset records and rewrite header */ if (lbp->prp) { if (lbp->last_record_offset == lbp->prp->start_offset) { /* adjust the offset for the entire buffer */ lbp->last_record_offset = lbp->prp->start_offset + lbp->prp->len; nfslog_rewrite_bufheader(lbp); } if (close_quick) return; prp = lbp->prp; do { tprp = prp->next; free(prp); prp = tprp; } while (lbp->prp != prp); } if (close_quick) return; /* Take care of the queue log records first */ if (lbp->lrps != NULL) { lrp = lbp->lrps; do { lrp_next = lrp->next; nfslog_free_logrecord(lrp, FALSE); lrp = lrp_next; } while (lrp != lbp->lrps); lbp->lrps = NULL; } /* The buffer header was decoded and needs to be freed */ if (lbp->bh.bh_length != 0) { buffer = (lbp->bh_lrp->buffer != NULL ? lbp->bh_lrp->buffer : (caddr_t)lbp->mmap_addr); xdrmem_create(&xdrs, buffer, lbp->bh_lrp->recsize, XDR_FREE); (void) xdr_nfslog_buffer_header(&xdrs, &lbp->bh); lbp->bh.bh_length = 0; } /* get rid of the bufheader lrp */ if (lbp->bh_lrp != NULL) { free_lrp(lbp->bh_lrp); lbp->bh_lrp = NULL; } /* Clean up for mmap() usage */ if (lbp->mmap_addr != (intptr_t)MAP_FAILED) { if (munmap((void *)lbp->mmap_addr, lbp->filesize)) { error = errno; syslog(LOG_ERR, gettext("munmap failed: %s: %s"), (lbp->bufpath != NULL ? lbp->bufpath : ""), strerror(error)); } lbp->mmap_addr = (intptr_t)MAP_FAILED; } /* Finally close the buffer file */ if (lbp->fd >= 0) { lbp->fl.l_type = F_UNLCK; if (fcntl(lbp->fd, F_SETLK, &lbp->fl) == -1) { error = errno; syslog(LOG_ERR, gettext("Cannot unlock file %s: %s"), (lbp->bufpath != NULL ? lbp->bufpath : ""), strerror(error)); } (void) close(lbp->fd); lbp->fd = -1; } if (lbp->bufpath != NULL) free(lbp->bufpath); } /* * We are reading a record from the log buffer file. Since we are reading * an XDR stream, we first have to read the first integer to determine * how much to read in whole for this record. Our preference is to use * mmap() but if failed initially we will be using read(). Need to be * careful about proper initialization of the log record both from a field * perspective and for XDR decoding. */ static struct nfslog_lr * nfslog_read_buffer(struct nfslog_buf *lbp) { XDR xdrs; unsigned int record_size; struct nfslog_lr *lrp; char *sizebuf, tbuf[16]; caddr_t buffer; offset_t next_rec; lrp = (struct nfslog_lr *)malloc(sizeof (*lrp)); bzero(lrp, sizeof (*lrp)); /* Check to see if mmap worked */ if (lbp->mmap_addr == (intptr_t)MAP_FAILED) { /* * EOF or other failure; we don't try to recover, just return */ if (read(lbp->fd, tbuf, BYTES_PER_XDR_UNIT) <= 0) { free_lrp(lrp); return (NULL); } sizebuf = tbuf; } else { /* EOF check for the mmap() case */ if (lbp->filesize <= lbp->next_rec - lbp->mmap_addr) { free_lrp(lrp); return (NULL); } sizebuf = (char *)(uintptr_t)lbp->next_rec; } /* We have to XDR the first int so we know how much is in this record */ xdrmem_create(&xdrs, sizebuf, sizeof (unsigned int), XDR_DECODE); if (!xdr_u_int(&xdrs, &record_size)) { free_lrp(lrp); return (NULL); } lrp->recsize = record_size; next_rec = lbp->next_rec + lrp->recsize; if (lbp->mmap_addr == (intptr_t)MAP_FAILED) { /* * Read() case - shouldn't be used very much. * Note: The 'buffer' field is used later on * to determine which method is being used mmap()|read() */ if (lbp->filesize < next_rec) { /* partial record from buffer */ syslog(LOG_ERR, gettext( "Last partial record in work buffer %s " "discarded\n"), lbp->bufpath); free_lrp(lrp); return (NULL); } if ((lrp->buffer = malloc(lrp->recsize)) == NULL) { free_lrp(lrp); return (NULL); } bcopy(sizebuf, lrp->buffer, BYTES_PER_XDR_UNIT); if (read(lbp->fd, &lrp->buffer[BYTES_PER_XDR_UNIT], lrp->recsize - BYTES_PER_XDR_UNIT) <= 0) { free_lrp(lrp); return (NULL); } } else if (lbp->filesize < next_rec - lbp->mmap_addr) { /* partial record from buffer */ syslog(LOG_ERR, gettext( "Last partial record in work buffer %s " "discarded\n"), lbp->bufpath); free_lrp(lrp); return (NULL); } /* other initializations */ lrp->next = lrp->prev = lrp; /* Keep track of the offset at which this record was read */ if (lbp->mmap_addr == (intptr_t)MAP_FAILED) lrp->f_offset = lbp->next_rec; else lrp->f_offset = lbp->next_rec - lbp->mmap_addr; /* This is the true address of the record */ lrp->record = lbp->next_rec; lrp->xdrargs = lrp->xdrres = NULL; lrp->lbp = lbp; /* Here is the logic for mmap() vs. read() */ buffer = (lrp->buffer != NULL ? lrp->buffer : (caddr_t)lrp->record); /* Setup for the 'real' XDR decode of the entire record */ xdrmem_create(&lrp->xdrs, buffer, lrp->recsize, XDR_DECODE); /* calculate the offset for the next record */ lbp->next_rec = next_rec; return (lrp); } /* * Simple removal of the log record from the log buffer queue. * Make sure to manage the count of records queued. */ static struct nfslog_lr * remove_lrp_from_lb(struct nfslog_buf *lbp, struct nfslog_lr *lrp) { if (lbp->lrps == lrp) { if (lbp->lrps == lbp->lrps->next) { lbp->lrps = NULL; } else { lbp->lrps = lrp->next; remque(lrp); } } else { remque(lrp); } lbp->num_lrps--; return (lrp); } /* * Insert a log record struct on the log buffer struct. The log buffer * has a pointer to the head of a queue of log records that have been * read from the buffer file but have not been processed yet because * the record id did not match the sequence desired for processing. * The insertion must be in the 'correct'/sorted order which adds * to the complexity of this function. */ static void insert_lrp_to_lb(struct nfslog_buf *lbp, struct nfslog_lr *lrp) { int ins_rec_id = lrp->log_record.re_header.rh_rec_id; struct nfslog_lr *curlrp; if (lbp->lrps == NULL) { /* that was easy */ lbp->lrps = lrp; } else { /* * Does this lrp go before the first on the list? * If so, do the insertion by hand since insque is not * as flexible when queueing an element to the head of * a list. */ if (ins_rec_id < lbp->lrps->log_record.re_header.rh_rec_id) { lrp->next = lbp->lrps; lrp->prev = lbp->lrps->prev; lbp->lrps->prev->next = lrp; lbp->lrps->prev = lrp; lbp->lrps = lrp; } else { /* * Search the queue for the correct insertion point. * Be careful about the insque so that the record * ends up in the right place. */ curlrp = lbp->lrps; do { if (ins_rec_id < curlrp->next->log_record.re_header.rh_rec_id) break; curlrp = curlrp->next; } while (curlrp != lbp->lrps); if (curlrp == lbp->lrps) insque(lrp, lbp->lrps->prev); else insque(lrp, curlrp); } } /* always keep track of how many we have */ lbp->num_lrps++; } /* * We are rewriting the buffer header at the start of the log buffer * for the sole purpose of resetting the bh_offset field. This is * supposed to represent the progress that the nfslogd daemon has made * in its processing of the log buffer file. * 'lbp->last_record_offset' contains the absolute offset of the end * of the last element processed. The on-disk buffer offset is relative * to the buffer header, therefore we subtract the length of the buffer * header from the absolute offset. */ static void nfslog_rewrite_bufheader(struct nfslog_buf *lbp) { XDR xdrs; nfslog_buffer_header bh; /* size big enough for buffer header encode */ #define XBUFSIZE 128 char buffer[XBUFSIZE]; unsigned int wsize; /* * if version 1 buffer is large and the current offset cannot be * represented, then don't update the offset in the buffer. */ if (lbp->bh.bh_flags & NFSLOG_BH_OFFSET_OVERFLOW) { /* No need to update the header - offset too big */ return; } /* * build the buffer header from the original that was saved * on initialization; note that the offset is taken from the * last record processed (the last offset that represents * all records processed without any holes in the processing) */ bh = lbp->bh; /* * if version 1 buffer is large and the current offset cannot be * represented in 32 bits, then save only the last valid offset * in the buffer and mark the flags to indicate that. */ if ((bh.bh_version > 1) || (lbp->last_record_offset - bh.bh_length < UINT32_MAX)) { bh.bh_offset = lbp->last_record_offset - bh.bh_length; } else { /* don't update the offset in the buffer */ bh.bh_flags |= NFSLOG_BH_OFFSET_OVERFLOW; lbp->bh.bh_flags = bh.bh_flags; syslog(LOG_ERR, gettext( "nfslog_rewrite_bufheader: %s: offset does not fit " "in a 32 bit field\n"), lbp->bufpath); } xdrmem_create(&xdrs, buffer, XBUFSIZE, XDR_ENCODE); if (!xdr_nfslog_buffer_header(&xdrs, &bh)) { syslog(LOG_ERR, gettext( "error in re-writing buffer file %s header\n"), lbp->bufpath); return; } wsize = xdr_getpos(&xdrs); if (lbp->mmap_addr == (intptr_t)MAP_FAILED) { /* go to the beginning of the file */ (void) lseek(lbp->fd, 0, SEEK_SET); (void) write(lbp->fd, buffer, wsize); (void) lseek(lbp->fd, lbp->next_rec, SEEK_SET); (void) fsync(lbp->fd); } else { bcopy(buffer, (void *)lbp->mmap_addr, wsize); (void) msync((void *)lbp->mmap_addr, wsize, MS_SYNC); } } /* * With the provided lrp, we will take and 'insert' the range that the * record covered in the buffer file into a list of processed ranges * for the buffer file. These ranges represent the records processed * but not 'marked' in the buffer header as being processed. * This insertion process is being done for two reasons. The first is that * we do not want to pay the performance penalty of re-writing the buffer header * for each record that we process. The second reason is that the records * may be processed out of order because of the unique ids. This will occur * if the kernel has written the records to the buffer file out of order. * The read routine will 'sort' them as the records are read. * * We do not want to re-write the buffer header such that a record is * represented and being processed when it has not been. In the case * that the nfslogd daemon restarts processing and the buffer header * has been re-written improperly, some records could be skipped. * We will be taking the conservative approach and only writing buffer * header offsets when the entire offset range has been processed. */ static void nfslog_ins_last_rec_processed(struct nfslog_lr *lrp) { struct processed_records *prp, *tp; /* init the data struct as if it were the only one */ prp = malloc(sizeof (*prp)); prp->next = prp->prev = prp; prp->start_offset = lrp->f_offset; prp->len = lrp->recsize; prp->num_recs = 1; /* always add since we know we are going to insert */ lrp->lbp->num_pr_queued++; /* Is this the first one? If so, take the easy way out */ if (lrp->lbp->prp == NULL) { lrp->lbp->prp = prp; } else { /* sort on insertion... */ tp = lrp->lbp->prp; do { if (prp->start_offset < tp->start_offset) break; tp = tp->next; } while (tp != lrp->lbp->prp); /* insert where appropriate (before the one we found */ insque(prp, tp->prev); /* * special case where the insertion was done at the * head of the list */ if (tp == lrp->lbp->prp && prp->start_offset < tp->start_offset) lrp->lbp->prp = prp; /* * now that the entry is in place, we need to see if it can * be combined with the previous or following entries. * combination is done by adding to the length. */ if (prp->start_offset == (prp->prev->start_offset + prp->prev->len)) { tp = prp->prev; remque(prp); tp->len += prp->len; tp->num_recs += prp->num_recs; free(prp); prp = tp; } if (prp->next->start_offset == (prp->start_offset + prp->len)) { prp->len += prp->next->len; prp->num_recs += prp->next->num_recs; tp = prp->next; remque(tp); free(tp); } } if (lrp->lbp->num_pr_queued > MAX_RECS_TO_DELAY) { prp = lrp->lbp->prp; if (lrp->lbp->last_record_offset == prp->start_offset) { /* adjust the offset for the entire buffer */ lrp->lbp->last_record_offset = prp->start_offset + prp->len; nfslog_rewrite_bufheader(lrp->lbp); tp = prp->next; if (tp != prp) remque(prp); else tp = NULL; lrp->lbp->prp = tp; lrp->lbp->num_pr_queued -= prp->num_recs; free(prp); } } } /* * nfslog_get_logrecord is responsible for retrieving the next log record * from the buffer file. This would normally be very straightforward but there * is the added complexity of attempting to order the requests coming out of * the buffer file. The fundamental problems is that the kernel nfs logging * functionality does not guarantee that the records were written to the file * in the order that the NFS server processed them. This can cause a problem * in the fh -> pathname mapping in the case were a lookup for a file comes * later in the buffer file than other operations on the lookup's target. * The fh mapping database will not have an entry and will therefore not * be able to map the fh to a name. * * So to solve this problem, the kernel nfs logging code tags each record * with a monotonically increasing id and is guaranteed to be allocated * in the order that the requests were processed. Realize however that * this processing guarantee is essentially for one thread on one client. * This id mechanism does not order all requests since it is only the * single client/single thread case that is most concerning to us here. * * This function will do the 'sorting' of the requests as they are * read from the buffer file. The sorting needs to take into account * that some ids may be missing (operations not logged but ids allocated) * and that the id field will eventually wrap over MAXINT. * * Complexity to solve the fh -> pathname mapping issue. */ struct nfslog_lr * nfslog_get_logrecord(struct nfslog_buf *lbp) { /* figure out what the next should be if the world were perfect */ unsigned int next_rec_id = lbp->last_rec_id + 1; struct nfslog_lr *lrp = NULL; /* * First we check the queued records on the log buffer struct * to see if the one we want is there. The records are sorted * on the record id during the insertions to the queue so that * this check is easy. */ if (lbp->lrps != NULL) { /* Does the first record match ? */ if (lbp->lrps->log_record.re_header.rh_rec_id == next_rec_id) { lrp = remove_lrp_from_lb(lbp, lbp->lrps); lbp->last_rec_id = lrp->log_record.re_header.rh_rec_id; } else { /* * Here we are checking for wrap of the record id * since it is an unsigned in. The idea is that * if there is a huge span between what we expect * and what is queued then we need to flush/empty * the queued records first. */ if (next_rec_id < lbp->lrps->log_record.re_header.rh_rec_id && ((lbp->lrps->log_record.re_header.rh_rec_id - next_rec_id) > (MAXINT / 2))) { lrp = remove_lrp_from_lb(lbp, lbp->lrps); lbp->last_rec_id = lrp->log_record.re_header.rh_rec_id; } } } /* * So the first queued record didn't match (or there were no queued * records to look at). Now we go to the buffer file looking for * the expected log record based on its id. We loop looking for * a matching records and save/queue the records that don't match. * Note that we will queue a maximum number to handle the case * of a missing record id or a queue that is very confused. We don't * want to consume too much memory. */ while (lrp == NULL) { /* Have we queued too many for this buffer? */ if (lbp->num_lrps >= MAX_LRS_READ_AHEAD) { lrp = remove_lrp_from_lb(lbp, lbp->lrps); lbp->last_rec_id = lrp->log_record.re_header.rh_rec_id; break; } /* * Get a record from the buffer file. If none are available, * this is probably and EOF condition (could be a read error * as well but that is masked. :-(). No records in the * file means that we need to pull any queued records * so that we don't miss any in the processing. */ if ((lrp = nfslog_read_buffer(lbp)) == NULL) { if (lbp->lrps != NULL) { lrp = remove_lrp_from_lb(lbp, lbp->lrps); lbp->last_rec_id = lrp->log_record.re_header.rh_rec_id; } else { return (NULL); /* it was really and EOF */ } } else { /* * Just read a record from the buffer file and now we * need to XDR the record header so that we can take * a look at the record id. */ if (!xdr_nfslog_request_record(&lrp->xdrs, &lrp->log_record)) { /* Free and return EOF/NULL on error */ nfslog_free_logrecord(lrp, FALSE); return (NULL); } /* * If the new record is less than or matches the * expected record id, then we return this record */ if (lrp->log_record.re_header.rh_rec_id <= next_rec_id) { lbp->last_rec_id = lrp->log_record.re_header.rh_rec_id; } else { /* * This is not the one we were looking * for; queue it for later processing * (queueing sorts on record id) */ insert_lrp_to_lb(lbp, lrp); lrp = NULL; } } } return (lrp); } /* * Free the log record provided. * This is complex because the associated XDR streams also need to be freed * since allocation could have occured during the DECODE phase. The record * header, args and results need to be XDR_FREEd. The xdr funtions will * be provided if a free needs to be done. * * Note that caller tells us if the record being freed was processed. * If so, then the buffer header should be updated. Updating the buffer * header keeps track of where the nfslogd daemon left off in its processing * if it is unable to complete the entire file. */ void nfslog_free_logrecord(struct nfslog_lr *lrp, bool_t processing_complete) { caddr_t buffer; nfslog_request_record *reqrec; if (processing_complete) { nfslog_ins_last_rec_processed(lrp); } reqrec = &lrp->log_record; buffer = (lrp->buffer != NULL ? lrp->buffer : (caddr_t)lrp->record); xdrmem_create(&lrp->xdrs, buffer, lrp->recsize, XDR_FREE); (void) xdr_nfslog_request_record(&lrp->xdrs, reqrec); if (lrp->xdrargs != NULL && reqrec->re_rpc_arg) (*lrp->xdrargs)(&lrp->xdrs, reqrec->re_rpc_arg); if (reqrec->re_rpc_arg) free(reqrec->re_rpc_arg); if (lrp->xdrres != NULL && reqrec->re_rpc_res) (*lrp->xdrres)(&lrp->xdrs, reqrec->re_rpc_res); if (reqrec->re_rpc_res) free(reqrec->re_rpc_res); free_lrp(lrp); } static void free_lrp(struct nfslog_lr *lrp) { if (lrp->buffer != NULL) free(lrp->buffer); free(lrp); } /* * Utility function used elsewhere */ void nfslog_opaque_print_buf(void *buf, int len, char *outbuf, int *outbufoffsetp, int maxoffset) { int i, j; uint_t *ip; uchar_t *u_buf = (uchar_t *)buf; int outbufoffset = *outbufoffsetp; outbufoffset += sprintf(&outbuf[outbufoffset], " \""); if (len <= sizeof (int)) { for (j = 0; (j < len) && (outbufoffset < maxoffset); j++, u_buf++) outbufoffset += sprintf(&outbuf[outbufoffset], "%02x", *u_buf); return; } /* More than 4 bytes, print with spaces in integer offsets */ j = (int)((uintptr_t)buf % sizeof (int)); i = 0; if (j > 0) { i = sizeof (int) - j; for (; (j < sizeof (int)) && (outbufoffset < maxoffset); j++, u_buf++) outbufoffset += sprintf(&outbuf[outbufoffset], "%02x", *u_buf); } /* LINTED */ ip = (uint_t *)u_buf; for (; ((i + sizeof (int)) <= len) && (outbufoffset < maxoffset); i += sizeof (int), ip++) { outbufoffset += sprintf(&outbuf[outbufoffset], " %08x", *ip); } if (i < len) { /* Last element not int */ u_buf = (uchar_t *)ip; if (i > j) /* not first element */ outbufoffset += sprintf(&outbuf[outbufoffset], " "); for (; (i < len) && (outbufoffset < maxoffset); i++, u_buf++) { outbufoffset += sprintf(&outbuf[outbufoffset], "%02x", *u_buf); } } if (outbufoffset < maxoffset) outbufoffset += sprintf(&outbuf[outbufoffset], "\""); *outbufoffsetp = outbufoffset; }