Bug Summary

File:rx/rx_rdwr.c
Location:line 418, column 7
Description:Access to field 'prev' results in a dereference of a null pointer

Annotated Source Code

1 /*
2 * Copyright 2000, International Business Machines Corporation and others.
3 * All Rights Reserved.
4 *
5 * This software has been released under the terms of the IBM Public
6 * License. For details, see the LICENSE file in the top-level source
7 * directory or online at http://www.openafs.org/dl/license10.html
8 */
9
10#include <afsconfig.h>
11#include <afs/param.h>
12
13#ifdef KERNEL1
14# ifndef UKERNEL1
15# ifdef RX_KERNEL_TRACE
16# include "rx_kcommon.h"
17# endif
18# if defined(AFS_DARWIN_ENV) || defined(AFS_XBSD_ENV)
19# include "afs/sysincludes.h"
20# else
21# include "h/types.h"
22# include "h/time.h"
23# include "h/stat.h"
24# if defined(AFS_AIX_ENV) || defined(AFS_AUX_ENV) || defined(AFS_SUN5_ENV)
25# include "h/systm.h"
26# endif
27# ifdef AFS_OSF_ENV
28# include <net/net_globals.h>
29# endif /* AFS_OSF_ENV */
30# ifdef AFS_LINUX20_ENV
31# include "h/socket.h"
32# endif
33# include "netinet/in.h"
34# if defined(AFS_SGI_ENV)
35# include "afs/sysincludes.h"
36# endif
37# endif
38# include "afs/afs_args.h"
39# if (defined(AFS_AUX_ENV) || defined(AFS_AIX_ENV))
40# include "h/systm.h"
41# endif
42# else /* !UKERNEL */
43# include "afs/sysincludes.h"
44# endif /* !UKERNEL */
45
46# ifdef RXDEBUG
47# undef RXDEBUG /* turn off debugging */
48# endif /* RXDEBUG */
49
50# include "afs/afs_osi.h"
51# include "rx_kmutex.h"
52# include "rx/rx_kernel.h"
53# include "afs/lock.h"
54#else /* KERNEL */
55# include <roken.h>
56#endif /* KERNEL */
57
58#include "rx.h"
59#include "rx_clock.h"
60#include "rx_queue.h"
61#include "rx_globals.h"
62
63#ifdef RX_LOCKS_DB
64/* rxdb_fileID is used to identify the lock location, along with line#. */
65static int rxdb_fileID = RXDB_FILE_RX_RDWR4;
66#endif /* RX_LOCKS_DB */
67/* rxi_ReadProc -- internal version.
68 *
69 * LOCKS USED -- called at netpri
70 */
71int
72rxi_ReadProc(struct rx_call *call, char *bufusr_buf,
73 int nbytes)
74{
75 struct rx_packet *cp = call->currentPacket;
76 struct rx_packet *rp;
77 int requestCount;
78 unsigned int t;
79
80/* XXXX took out clock_NewTime from here. Was it needed? */
81 requestCount = nbytes;
82
83 /* Free any packets from the last call to ReadvProc/WritevProc */
84 if (queue_IsNotEmpty(&call->iovq)(((struct rx_queue *)(&call->iovq))->next != ((struct
rx_queue *)(&call->iovq)))) {
85#ifdef RXDEBUG_PACKET
86 call->iovqc -=
87#endif /* RXDEBUG_PACKET */
88 rxi_FreePackets(0, &call->iovq);
89 }
90
91 do {
92 if (call->nLeft == 0) {
93 /* Get next packet */
94 MUTEX_ENTER(&call->lock)do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 94);}while(0);
95 for (;;) {
96 if (call->error || (call->mode != RX_MODE_RECEIVING2)) {
97 if (call->error) {
98 call->mode = RX_MODE_ERROR3;
99 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 99);}while(0);
100 return 0;
101 }
102 if (call->mode == RX_MODE_SENDING1) {
103 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 103);}while(0);
104 rxi_FlushWrite(call);
105 MUTEX_ENTER(&call->lock)do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 105);}while(0);
106 continue;
107 }
108 }
109 if (queue_IsNotEmpty(&call->rq)(((struct rx_queue *)(&call->rq))->next != ((struct
rx_queue *)(&call->rq)))) {
110 /* Check that next packet available is next in sequence */
111 rp = queue_First(&call->rq, rx_packet)((struct rx_packet *)((struct rx_queue *)(&call->rq))->
next);
112 if (rp->header.seq == call->rnext) {
113 afs_int32 error;
114 struct rx_connection *conn = call->conn;
115 queue_Remove(rp)(((((struct rx_queue *)(rp))->prev->next=((struct rx_queue
*)(rp))->next)->prev=((struct rx_queue *)(rp))->prev
), ((struct rx_queue *)(rp))->next = 0);
116#ifdef RX_TRACK_PACKETS
117 rp->flags &= ~RX_PKTFLAG_RQ;
118#endif
119#ifdef RXDEBUG_PACKET
120 call->rqc--;
121#endif /* RXDEBUG_PACKET */
122
123 /* RXS_CheckPacket called to undo RXS_PreparePacket's
124 * work. It may reduce the length of the packet by up
125 * to conn->maxTrailerSize, to reflect the length of the
126 * data + the header. */
127 if ((error =
128 RXS_CheckPacket(conn->securityObject, call,((conn->securityObject && (conn->securityObject
->ops->op_CheckPacket)) ? (*(conn->securityObject)->
ops->op_CheckPacket)(conn->securityObject,call,rp) : 0)
129 rp)((conn->securityObject && (conn->securityObject
->ops->op_CheckPacket)) ? (*(conn->securityObject)->
ops->op_CheckPacket)(conn->securityObject,call,rp) : 0))) {
130 /* Used to merely shut down the call, but now we
131 * shut down the whole connection since this may
132 * indicate an attempt to hijack it */
133
134 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 134);}while(0);
135 rxi_ConnectionError(conn, error);
136 MUTEX_ENTER(&conn->conn_data_lock)do{if (!(pthread_mutex_lock(&conn->conn_data_lock) == 0
)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c", 136
);}while(0);
137 rp = rxi_SendConnectionAbort(conn, rp, 0, 0);
138 MUTEX_EXIT(&conn->conn_data_lock)do{if (!(pthread_mutex_unlock(&conn->conn_data_lock) ==
0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 138);}while(0);
139 rxi_FreePacket(rp);
140
141 return 0;
142 }
143 call->rnext++;
144 cp = call->currentPacket = rp;
145#ifdef RX_TRACK_PACKETS
146 call->currentPacket->flags |= RX_PKTFLAG_CP;
147#endif
148 call->curvec = 1; /* 0th vec is always header */
149 /* begin at the beginning [ more or less ], continue
150 * on until the end, then stop. */
151 call->curpos =
152 (char *)cp->wirevec[1].iov_base +
153 call->conn->securityHeaderSize;
154 call->curlen =
155 cp->wirevec[1].iov_len -
156 call->conn->securityHeaderSize;
157
158 /* Notice that this code works correctly if the data
159 * size is 0 (which it may be--no reply arguments from
160 * server, for example). This relies heavily on the
161 * fact that the code below immediately frees the packet
162 * (no yields, etc.). If it didn't, this would be a
163 * problem because a value of zero for call->nLeft
164 * normally means that there is no read packet */
165 call->nLeft = cp->length;
166 hadd32(call->bytesRcvd, cp->length)((void)((((call->bytesRcvd).low ^ (int)(cp->length)) &
0x80000000) ? (((((call->bytesRcvd).low + (int)(cp->length
)) & 0x80000000) == 0) && (call->bytesRcvd).high
++) : (((call->bytesRcvd).low & (int)(cp->length) &
0x80000000) && (call->bytesRcvd).high++)), (call->
bytesRcvd).low += (int)(cp->length));
167
168 /* Send a hard ack for every rxi_HardAckRate+1 packets
169 * consumed. Otherwise schedule an event to send
170 * the hard ack later on.
171 */
172 call->nHardAcks++;
173 if (!(call->flags & RX_CALL_RECEIVE_DONE32)) {
174 if (call->nHardAcks > (u_short) rxi_HardAckRate) {
175 rxevent_Cancel(call->delayedAckEvent, call,do { if (call->delayedAckEvent) { rxevent_Cancel_1(call->
delayedAckEvent, call, 0); call->delayedAckEvent = ((void *
)0); } } while(0)
176 RX_CALL_REFCOUNT_DELAY)do { if (call->delayedAckEvent) { rxevent_Cancel_1(call->
delayedAckEvent, call, 0); call->delayedAckEvent = ((void *
)0); } } while(0);
177 rxi_SendAck(call, 0, 0, RX_ACK_DELAY8, 0);
178 } else {
179 struct clock when, now;
180 clock_GetTime(&now)do { struct timeval tv; gettimeofday(&tv, ((void *)0)); (
&now)->sec = (afs_int32)tv.tv_sec; (&now)->usec
= (afs_int32)tv.tv_usec; } while(0);
181 when = now;
182 /* Delay to consolidate ack packets */
183 clock_Add(&when, &rx_hardAckDelay)do { (&when)->sec += (&rx_hardAckDelay)->sec; if
(((&when)->usec += (&rx_hardAckDelay)->usec) >=
1000000) { (&when)->usec -= 1000000; (&when)->
sec++; } } while(0);
184 if (!call->delayedAckEvent
185 || clock_Gt(&call->delayedAckEvent->((&call->delayedAckEvent-> eventTime)->sec>(&
when)->sec || ((&call->delayedAckEvent-> eventTime
)->sec==(&when)->sec && (&call->delayedAckEvent
-> eventTime)->usec>(&when)->usec))
186 eventTime, &when)((&call->delayedAckEvent-> eventTime)->sec>(&
when)->sec || ((&call->delayedAckEvent-> eventTime
)->sec==(&when)->sec && (&call->delayedAckEvent
-> eventTime)->usec>(&when)->usec))) {
187 rxevent_Cancel(call->delayedAckEvent,do { if (call->delayedAckEvent) { rxevent_Cancel_1(call->
delayedAckEvent, call, 0); call->delayedAckEvent = ((void *
)0); } } while(0)
188 call,do { if (call->delayedAckEvent) { rxevent_Cancel_1(call->
delayedAckEvent, call, 0); call->delayedAckEvent = ((void *
)0); } } while(0)
189 RX_CALL_REFCOUNT_DELAY)do { if (call->delayedAckEvent) { rxevent_Cancel_1(call->
delayedAckEvent, call, 0); call->delayedAckEvent = ((void *
)0); } } while(0);
190 MUTEX_ENTER(&rx_refcnt_mutex)do{if (!(pthread_mutex_lock(&rx_refcnt_mutex) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 190);}while(0);
191 CALL_HOLD(call, RX_CALL_REFCOUNT_DELAY)call->refCount++;
192 MUTEX_EXIT(&rx_refcnt_mutex)do{if (!(pthread_mutex_unlock(&rx_refcnt_mutex) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 192);}while(0);
193 call->delayedAckEvent =
194 rxevent_PostNow(&when, &now,
195 rxi_SendDelayedAck, call,
196 0);
197 }
198 }
199 }
200 break;
201 }
202 }
203
204 /*
205 * If we reach this point either we have no packets in the
206 * receive queue or the next packet in the queue is not the
207 * one we are looking for. There is nothing else for us to
208 * do but wait for another packet to arrive.
209 */
210
211 /* Are there ever going to be any more packets? */
212 if (call->flags & RX_CALL_RECEIVE_DONE32) {
213 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 213);}while(0);
214 return requestCount - nbytes;
215 }
216 /* Wait for in-sequence packet */
217 call->flags |= RX_CALL_READER_WAIT1;
218 clock_NewTime();
219 call->startWait = clock_Sec()(time(((void *)0)));
220 while (call->flags & RX_CALL_READER_WAIT1) {
221#ifdef RX_ENABLE_LOCKS1
222 CV_WAIT(&call->cv_rq, &call->lock){ int isGlockOwner = (pthread_self() == afs_global_owner); if
(isGlockOwner) { do { do { if (!(pthread_self() == afs_global_owner
)) { osi_Panic("afs global lock not held"); } } while(0); memset
(&afs_global_owner, 0, sizeof(pthread_t)); do{if (!(pthread_mutex_unlock
(&afs_global_lock) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 222);}while(0); } while(0); } pthread_cond_wait(&call->
cv_rq,&call->lock); if (isGlockOwner) { do{if (!(pthread_mutex_unlock
(&call->lock) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 222);}while(0); do { do{if (!(pthread_mutex_lock(&afs_global_lock
) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 222);}while(0); afs_global_owner = pthread_self(); } while(
0); do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 222);}while(0); } };
223#else
224 osi_rxSleep(&call->rq)(((afs_iclSetp) && (afs_iclSetp->states & 2)) ?
afs_icl_Event2(afs_iclSetp, (701087897L), (1<<24)+((4)
<<18)+((7)<<12), (long)("/home/wollman/openafs/src/rx/rx_rdwr.c"
), (long)(224)) : 0); afs_osi_Sleep(&call->rq);
225#endif
226 }
227 cp = call->currentPacket;
228
229 call->startWait = 0;
230#ifdef RX_ENABLE_LOCKS1
231 if (call->error) {
232 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 232);}while(0);
233 return 0;
234 }
235#endif /* RX_ENABLE_LOCKS */
236 }
237 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 237);}while(0);
238 } else
239 /* osi_Assert(cp); */
240 /* MTUXXX this should be replaced by some error-recovery code before shipping */
241 /* yes, the following block is allowed to be the ELSE clause (or not) */
242 /* It's possible for call->nLeft to be smaller than any particular
243 * iov_len. Usually, recvmsg doesn't change the iov_len, since it
244 * reflects the size of the buffer. We have to keep track of the
245 * number of bytes read in the length field of the packet struct. On
246 * the final portion of a received packet, it's almost certain that
247 * call->nLeft will be smaller than the final buffer. */
248 while (nbytes && cp) {
249 t = MIN((int)call->curlen, nbytes)((((int)call->curlen)<(nbytes))?((int)call->curlen):
(nbytes));
250 t = MIN(t, (int)call->nLeft)(((t)<((int)call->nLeft))?(t):((int)call->nLeft));
251 memcpy(bufusr_buf, call->curpos, t);
252 bufusr_buf += t;
253 nbytes -= t;
254 call->curpos += t;
255 call->curlen -= t;
256 call->nLeft -= t;
257
258 if (!call->nLeft) {
259 /* out of packet. Get another one. */
260#ifdef RX_TRACK_PACKETS
261 call->currentPacket->flags &= ~RX_PKTFLAG_CP;
262#endif
263 rxi_FreePacket(cp);
264 cp = call->currentPacket = (struct rx_packet *)0;
265 } else if (!call->curlen) {
266 /* need to get another struct iov */
267 if (++call->curvec >= cp->niovecs) {
268 /* current packet is exhausted, get ready for another */
269 /* don't worry about curvec and stuff, they get set somewhere else */
270#ifdef RX_TRACK_PACKETS
271 call->currentPacket->flags &= ~RX_PKTFLAG_CP;
272#endif
273 rxi_FreePacket(cp);
274 cp = call->currentPacket = (struct rx_packet *)0;
275 call->nLeft = 0;
276 } else {
277 call->curpos =
278 (char *)cp->wirevec[call->curvec].iov_base;
279 call->curlen = cp->wirevec[call->curvec].iov_len;
280 }
281 }
282 }
283 if (!nbytes) {
284 /* user buffer is full, return */
285 return requestCount;
286 }
287
288 } while (nbytes);
289
290 return requestCount;
291}
292
293int
294rx_ReadProc(struct rx_call *call, char *bufusr_buf, int nbytes)
295{
296 int bytes;
297 int tcurlen;
298 int tnLeft;
299 char *tcurpos;
300 SPLVAR;
301
302 /* Free any packets from the last call to ReadvProc/WritevProc */
303 if (!queue_IsEmpty(&call->iovq)(((struct rx_queue *)(&call->iovq))->next == ((struct
rx_queue *)(&call->iovq)))) {
304#ifdef RXDEBUG_PACKET
305 call->iovqc -=
306#endif /* RXDEBUG_PACKET */
307 rxi_FreePackets(0, &call->iovq);
308 }
309
310 /*
311 * Most common case, all of the data is in the current iovec.
312 * We are relying on nLeft being zero unless the call is in receive mode.
313 */
314 tcurlen = call->curlen;
315 tnLeft = call->nLeft;
316 if (!call->error && tcurlen > nbytes && tnLeft > nbytes) {
317 tcurpos = call->curpos;
318 memcpy(bufusr_buf, tcurpos, nbytes);
319
320 call->curpos = tcurpos + nbytes;
321 call->curlen = tcurlen - nbytes;
322 call->nLeft = tnLeft - nbytes;
323
324 if (!call->nLeft && call->currentPacket != NULL((void *)0)) {
325 /* out of packet. Get another one. */
326 rxi_FreePacket(call->currentPacket);
327 call->currentPacket = (struct rx_packet *)0;
328 }
329 return nbytes;
330 }
331
332 NETPRI;
333 bytes = rxi_ReadProc(call, bufusr_buf, nbytes);
334 USERPRI;
335 return bytes;
336}
337
338/* Optimization for unmarshalling 32 bit integers */
339int
340rx_ReadProc32(struct rx_call *call, afs_int32 * value)
341{
342 int bytes;
343 int tcurlen;
344 int tnLeft;
345 char *tcurpos;
346 SPLVAR;
347
348 /* Free any packets from the last call to ReadvProc/WritevProc */
349 if (!queue_IsEmpty(&call->iovq)(((struct rx_queue *)(&call->iovq))->next == ((struct
rx_queue *)(&call->iovq)))) {
350#ifdef RXDEBUG_PACKET
351 call->iovqc -=
352#endif /* RXDEBUG_PACKET */
353 rxi_FreePackets(0, &call->iovq);
354 }
355
356 /*
357 * Most common case, all of the data is in the current iovec.
358 * We are relying on nLeft being zero unless the call is in receive mode.
359 */
360 tcurlen = call->curlen;
361 tnLeft = call->nLeft;
362 if (!call->error && tcurlen >= sizeof(afs_int32)
363 && tnLeft >= sizeof(afs_int32)) {
364 tcurpos = call->curpos;
365
366 memcpy((char *)value, tcurpos, sizeof(afs_int32));
367
368 call->curpos = tcurpos + sizeof(afs_int32);
369 call->curlen = (u_short)(tcurlen - sizeof(afs_int32));
370 call->nLeft = (u_short)(tnLeft - sizeof(afs_int32));
371 if (!call->nLeft && call->currentPacket != NULL((void *)0)) {
372 /* out of packet. Get another one. */
373 rxi_FreePacket(call->currentPacket);
374 call->currentPacket = (struct rx_packet *)0;
375 }
376 return sizeof(afs_int32);
377 }
378
379 NETPRI;
380 bytes = rxi_ReadProc(call, (char *)value, sizeof(afs_int32));
381 USERPRI;
382
383 return bytes;
384}
385
386/* rxi_FillReadVec
387 *
388 * Uses packets in the receive queue to fill in as much of the
389 * current iovec as possible. Does not block if it runs out
390 * of packets to complete the iovec. Return true if an ack packet
391 * was sent, otherwise return false */
392int
393rxi_FillReadVec(struct rx_call *call, afs_uint32 serial)
394{
395 int didConsume = 0;
396 int didHardAck = 0;
397 unsigned int t;
398 struct rx_packet *rp;
399 struct rx_packet *curp;
400 struct iovec *call_iov;
401 struct iovec *cur_iov = NULL((void *)0);
402
403 curp = call->currentPacket;
404 if (curp) {
1
Taking false branch
405 cur_iov = &curp->wirevec[call->curvec];
406 }
407 call_iov = &call->iov[call->iovNext];
408
409 while (!call->error && call->iovNBytes && call->iovNext < call->iovMax) {
2
Loop condition is true. Entering loop body
8
Loop condition is true. Entering loop body
410 if (call->nLeft == 0) {
3
Taking true branch
9
Taking true branch
411 /* Get next packet */
412 if (queue_IsNotEmpty(&call->rq)(((struct rx_queue *)(&call->rq))->next != ((struct
rx_queue *)(&call->rq)))) {
4
Taking true branch
10
Taking true branch
413 /* Check that next packet available is next in sequence */
414 rp = queue_First(&call->rq, rx_packet)((struct rx_packet *)((struct rx_queue *)(&call->rq))->
next);
415 if (rp->header.seq == call->rnext) {
5
Taking true branch
11
Taking true branch
416 afs_int32 error;
417 struct rx_connection *conn = call->conn;
418 queue_Remove(rp)(((((struct rx_queue *)(rp))->prev->next=((struct rx_queue
*)(rp))->next)->prev=((struct rx_queue *)(rp))->prev
), ((struct rx_queue *)(rp))->next = 0);
12
Within the expansion of the macro 'queue_Remove':
a
Access to field 'prev' results in a dereference of a null pointer
419#ifdef RX_TRACK_PACKETS
420 rp->flags &= ~RX_PKTFLAG_RQ;
421#endif
422#ifdef RXDEBUG_PACKET
423 call->rqc--;
424#endif /* RXDEBUG_PACKET */
425
426 /* RXS_CheckPacket called to undo RXS_PreparePacket's
427 * work. It may reduce the length of the packet by up
428 * to conn->maxTrailerSize, to reflect the length of the
429 * data + the header. */
430 if ((error =
6
Taking false branch
431 RXS_CheckPacket(conn->securityObject, call, rp)((conn->securityObject && (conn->securityObject
->ops->op_CheckPacket)) ? (*(conn->securityObject)->
ops->op_CheckPacket)(conn->securityObject,call,rp) : 0))) {
432 /* Used to merely shut down the call, but now we
433 * shut down the whole connection since this may
434 * indicate an attempt to hijack it */
435
436 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 436);}while(0);
437 rxi_ConnectionError(conn, error);
438 MUTEX_ENTER(&conn->conn_data_lock)do{if (!(pthread_mutex_lock(&conn->conn_data_lock) == 0
)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c", 438
);}while(0);
439 rp = rxi_SendConnectionAbort(conn, rp, 0, 0);
440 MUTEX_EXIT(&conn->conn_data_lock)do{if (!(pthread_mutex_unlock(&conn->conn_data_lock) ==
0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 440);}while(0);
441 rxi_FreePacket(rp);
442 MUTEX_ENTER(&call->lock)do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 442);}while(0);
443
444 return 1;
445 }
446 call->rnext++;
447 curp = call->currentPacket = rp;
448#ifdef RX_TRACK_PACKETS
449 call->currentPacket->flags |= RX_PKTFLAG_CP;
450#endif
451 call->curvec = 1; /* 0th vec is always header */
452 cur_iov = &curp->wirevec[1];
453 /* begin at the beginning [ more or less ], continue
454 * on until the end, then stop. */
455 call->curpos =
456 (char *)curp->wirevec[1].iov_base +
457 call->conn->securityHeaderSize;
458 call->curlen =
459 curp->wirevec[1].iov_len -
460 call->conn->securityHeaderSize;
461
462 /* Notice that this code works correctly if the data
463 * size is 0 (which it may be--no reply arguments from
464 * server, for example). This relies heavily on the
465 * fact that the code below immediately frees the packet
466 * (no yields, etc.). If it didn't, this would be a
467 * problem because a value of zero for call->nLeft
468 * normally means that there is no read packet */
469 call->nLeft = curp->length;
470 hadd32(call->bytesRcvd, curp->length)((void)((((call->bytesRcvd).low ^ (int)(curp->length)) &
0x80000000) ? (((((call->bytesRcvd).low + (int)(curp->
length)) & 0x80000000) == 0) && (call->bytesRcvd
).high++) : (((call->bytesRcvd).low & (int)(curp->length
) & 0x80000000) && (call->bytesRcvd).high++)),
(call->bytesRcvd).low += (int)(curp->length));
471
472 /* Send a hard ack for every rxi_HardAckRate+1 packets
473 * consumed. Otherwise schedule an event to send
474 * the hard ack later on.
475 */
476 call->nHardAcks++;
477 didConsume = 1;
478 continue;
7
 Execution continues on line 409
479 }
480 }
481 break;
482 }
483
484 /* It's possible for call->nLeft to be smaller than any particular
485 * iov_len. Usually, recvmsg doesn't change the iov_len, since it
486 * reflects the size of the buffer. We have to keep track of the
487 * number of bytes read in the length field of the packet struct. On
488 * the final portion of a received packet, it's almost certain that
489 * call->nLeft will be smaller than the final buffer. */
490 while (call->iovNBytes && call->iovNext < call->iovMax && curp) {
491
492 t = MIN((int)call->curlen, call->iovNBytes)((((int)call->curlen)<(call->iovNBytes))?((int)call->
curlen):(call->iovNBytes));
493 t = MIN(t, (int)call->nLeft)(((t)<((int)call->nLeft))?(t):((int)call->nLeft));
494 call_iov->iov_base = call->curpos;
495 call_iov->iov_len = t;
496 call_iov++;
497 call->iovNext++;
498 call->iovNBytes -= t;
499 call->curpos += t;
500 call->curlen -= t;
501 call->nLeft -= t;
502
503 if (!call->nLeft) {
504 /* out of packet. Get another one. */
505#ifdef RX_TRACK_PACKETS
506 curp->flags &= ~RX_PKTFLAG_CP;
507 curp->flags |= RX_PKTFLAG_IOVQ;
508#endif
509 queue_Append(&call->iovq, curp)(((((struct rx_queue *)(curp))->prev=((struct rx_queue *)(
&call->iovq))->prev)->next=((struct rx_queue *)(
curp)))->next=((struct rx_queue *)(&call->iovq)), (
(struct rx_queue *)(&call->iovq))->prev=((struct rx_queue
*)(curp)));
510#ifdef RXDEBUG_PACKET
511 call->iovqc++;
512#endif /* RXDEBUG_PACKET */
513 curp = call->currentPacket = (struct rx_packet *)0;
514 } else if (!call->curlen) {
515 /* need to get another struct iov */
516 if (++call->curvec >= curp->niovecs) {
517 /* current packet is exhausted, get ready for another */
518 /* don't worry about curvec and stuff, they get set somewhere else */
519#ifdef RX_TRACK_PACKETS
520 curp->flags &= ~RX_PKTFLAG_CP;
521 curp->flags |= RX_PKTFLAG_IOVQ;
522#endif
523 queue_Append(&call->iovq, curp)(((((struct rx_queue *)(curp))->prev=((struct rx_queue *)(
&call->iovq))->prev)->next=((struct rx_queue *)(
curp)))->next=((struct rx_queue *)(&call->iovq)), (
(struct rx_queue *)(&call->iovq))->prev=((struct rx_queue
*)(curp)));
524#ifdef RXDEBUG_PACKET
525 call->iovqc++;
526#endif /* RXDEBUG_PACKET */
527 curp = call->currentPacket = (struct rx_packet *)0;
528 call->nLeft = 0;
529 } else {
530 cur_iov++;
531 call->curpos = (char *)cur_iov->iov_base;
532 call->curlen = cur_iov->iov_len;
533 }
534 }
535 }
536 }
537
538 /* If we consumed any packets then check whether we need to
539 * send a hard ack. */
540 if (didConsume && (!(call->flags & RX_CALL_RECEIVE_DONE32))) {
541 if (call->nHardAcks > (u_short) rxi_HardAckRate) {
542 rxevent_Cancel(call->delayedAckEvent, call,do { if (call->delayedAckEvent) { rxevent_Cancel_1(call->
delayedAckEvent, call, 0); call->delayedAckEvent = ((void *
)0); } } while(0)
543 RX_CALL_REFCOUNT_DELAY)do { if (call->delayedAckEvent) { rxevent_Cancel_1(call->
delayedAckEvent, call, 0); call->delayedAckEvent = ((void *
)0); } } while(0);
544 rxi_SendAck(call, 0, serial, RX_ACK_DELAY8, 0);
545 didHardAck = 1;
546 } else {
547 struct clock when, now;
548 clock_GetTime(&now)do { struct timeval tv; gettimeofday(&tv, ((void *)0)); (
&now)->sec = (afs_int32)tv.tv_sec; (&now)->usec
= (afs_int32)tv.tv_usec; } while(0);
549 when = now;
550 /* Delay to consolidate ack packets */
551 clock_Add(&when, &rx_hardAckDelay)do { (&when)->sec += (&rx_hardAckDelay)->sec; if
(((&when)->usec += (&rx_hardAckDelay)->usec) >=
1000000) { (&when)->usec -= 1000000; (&when)->
sec++; } } while(0);
552 if (!call->delayedAckEvent
553 || clock_Gt(&call->delayedAckEvent->eventTime, &when)((&call->delayedAckEvent->eventTime)->sec>(&
when)->sec || ((&call->delayedAckEvent->eventTime
)->sec==(&when)->sec && (&call->delayedAckEvent
->eventTime)->usec>(&when)->usec))) {
554 rxevent_Cancel(call->delayedAckEvent, call,do { if (call->delayedAckEvent) { rxevent_Cancel_1(call->
delayedAckEvent, call, 0); call->delayedAckEvent = ((void *
)0); } } while(0)
555 RX_CALL_REFCOUNT_DELAY)do { if (call->delayedAckEvent) { rxevent_Cancel_1(call->
delayedAckEvent, call, 0); call->delayedAckEvent = ((void *
)0); } } while(0);
556 MUTEX_ENTER(&rx_refcnt_mutex)do{if (!(pthread_mutex_lock(&rx_refcnt_mutex) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 556);}while(0);
557 CALL_HOLD(call, RX_CALL_REFCOUNT_DELAY)call->refCount++;
558 MUTEX_EXIT(&rx_refcnt_mutex)do{if (!(pthread_mutex_unlock(&rx_refcnt_mutex) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 558);}while(0);
559 call->delayedAckEvent =
560 rxevent_PostNow(&when, &now, rxi_SendDelayedAck, call, 0);
561 }
562 }
563 }
564 return didHardAck;
565}
566
567
568/* rxi_ReadvProc -- internal version.
569 *
570 * Fills in an iovec with pointers to the packet buffers. All packets
571 * except the last packet (new current packet) are moved to the iovq
572 * while the application is processing the data.
573 *
574 * LOCKS USED -- called at netpri.
575 */
576int
577rxi_ReadvProc(struct rx_call *call, struct iovec *iov, int *nio, int maxio,
578 int nbytes)
579{
580 int bytes;
581
582 /* Free any packets from the last call to ReadvProc/WritevProc */
583 if (queue_IsNotEmpty(&call->iovq)(((struct rx_queue *)(&call->iovq))->next != ((struct
rx_queue *)(&call->iovq)))) {
584#ifdef RXDEBUG_PACKET
585 call->iovqc -=
586#endif /* RXDEBUG_PACKET */
587 rxi_FreePackets(0, &call->iovq);
588 }
589
590 if (call->mode == RX_MODE_SENDING1) {
591 rxi_FlushWrite(call);
592 }
593
594 MUTEX_ENTER(&call->lock)do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 594);}while(0);
595 if (call->error)
596 goto error;
597
598 /* Get whatever data is currently available in the receive queue.
599 * If rxi_FillReadVec sends an ack packet then it is possible
600 * that we will receive more data while we drop the call lock
601 * to send the packet. Set the RX_CALL_IOVEC_WAIT flag
602 * here to avoid a race with the receive thread if we send
603 * hard acks in rxi_FillReadVec. */
604 call->flags |= RX_CALL_IOVEC_WAIT16384;
605 call->iovNBytes = nbytes;
606 call->iovMax = maxio;
607 call->iovNext = 0;
608 call->iov = iov;
609 rxi_FillReadVec(call, 0);
610
611 /* if we need more data then sleep until the receive thread has
612 * filled in the rest. */
613 if (!call->error && call->iovNBytes && call->iovNext < call->iovMax
614 && !(call->flags & RX_CALL_RECEIVE_DONE32)) {
615 call->flags |= RX_CALL_READER_WAIT1;
616 clock_NewTime();
617 call->startWait = clock_Sec()(time(((void *)0)));
618 while (call->flags & RX_CALL_READER_WAIT1) {
619#ifdef RX_ENABLE_LOCKS1
620 CV_WAIT(&call->cv_rq, &call->lock){ int isGlockOwner = (pthread_self() == afs_global_owner); if
(isGlockOwner) { do { do { if (!(pthread_self() == afs_global_owner
)) { osi_Panic("afs global lock not held"); } } while(0); memset
(&afs_global_owner, 0, sizeof(pthread_t)); do{if (!(pthread_mutex_unlock
(&afs_global_lock) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 620);}while(0); } while(0); } pthread_cond_wait(&call->
cv_rq,&call->lock); if (isGlockOwner) { do{if (!(pthread_mutex_unlock
(&call->lock) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 620);}while(0); do { do{if (!(pthread_mutex_lock(&afs_global_lock
) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 620);}while(0); afs_global_owner = pthread_self(); } while(
0); do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 620);}while(0); } };
621#else
622 osi_rxSleep(&call->rq)(((afs_iclSetp) && (afs_iclSetp->states & 2)) ?
afs_icl_Event2(afs_iclSetp, (701087897L), (1<<24)+((4)
<<18)+((7)<<12), (long)("/home/wollman/openafs/src/rx/rx_rdwr.c"
), (long)(622)) : 0); afs_osi_Sleep(&call->rq);
623#endif
624 }
625 call->startWait = 0;
626 }
627 call->flags &= ~RX_CALL_IOVEC_WAIT16384;
628
629 if (call->error)
630 goto error;
631
632 call->iov = NULL((void *)0);
633 *nio = call->iovNext;
634 bytes = nbytes - call->iovNBytes;
635 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 635);}while(0);
636 return bytes;
637
638 error:
639 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 639);}while(0);
640 call->mode = RX_MODE_ERROR3;
641 return 0;
642}
643
644int
645rx_ReadvProc(struct rx_call *call, struct iovec *iov, int *nio, int maxio,
646 int nbytes)
647{
648 int bytes;
649 SPLVAR;
650
651 NETPRI;
652 bytes = rxi_ReadvProc(call, iov, nio, maxio, nbytes);
653 USERPRI;
654 return bytes;
655}
656
657/* rxi_WriteProc -- internal version.
658 *
659 * LOCKS USED -- called at netpri
660 */
661
662int
663rxi_WriteProc(struct rx_call *call, char *bufusr_buf,
664 int nbytes)
665{
666 struct rx_connection *conn = call->conn;
667 struct rx_packet *cp = call->currentPacket;
668 unsigned int t;
669 int requestCount = nbytes;
670
671 /* Free any packets from the last call to ReadvProc/WritevProc */
672 if (queue_IsNotEmpty(&call->iovq)(((struct rx_queue *)(&call->iovq))->next != ((struct
rx_queue *)(&call->iovq)))) {
673#ifdef RXDEBUG_PACKET
674 call->iovqc -=
675#endif /* RXDEBUG_PACKET */
676 rxi_FreePackets(0, &call->iovq);
677 }
678
679 if (call->mode != RX_MODE_SENDING1) {
680 if ((conn->type == RX_SERVER_CONNECTION1)
681 && (call->mode == RX_MODE_RECEIVING2)) {
682 call->mode = RX_MODE_SENDING1;
683 if (cp) {
684#ifdef RX_TRACK_PACKETS
685 cp->flags &= ~RX_PKTFLAG_CP;
686#endif
687 rxi_FreePacket(cp);
688 cp = call->currentPacket = (struct rx_packet *)0;
689 call->nLeft = 0;
690 call->nFree = 0;
691 }
692 } else {
693 return 0;
694 }
695 }
696
697 /* Loop condition is checked at end, so that a write of 0 bytes
698 * will force a packet to be created--specially for the case where
699 * there are 0 bytes on the stream, but we must send a packet
700 * anyway. */
701 do {
702 if (call->nFree == 0) {
703 MUTEX_ENTER(&call->lock)do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 703);}while(0);
704 cp = call->currentPacket;
705 if (call->error)
706 call->mode = RX_MODE_ERROR3;
707 if (!call->error && cp) {
708 /* Clear the current packet now so that if
709 * we are forced to wait and drop the lock
710 * the packet we are planning on using
711 * cannot be freed.
712 */
713#ifdef RX_TRACK_PACKETS
714 cp->flags &= ~RX_PKTFLAG_CP;
715#endif
716 call->currentPacket = (struct rx_packet *)0;
717 clock_NewTime(); /* Bogus: need new time package */
718 /* The 0, below, specifies that it is not the last packet:
719 * there will be others. PrepareSendPacket may
720 * alter the packet length by up to
721 * conn->securityMaxTrailerSize */
722 hadd32(call->bytesSent, cp->length)((void)((((call->bytesSent).low ^ (int)(cp->length)) &
0x80000000) ? (((((call->bytesSent).low + (int)(cp->length
)) & 0x80000000) == 0) && (call->bytesSent).high
++) : (((call->bytesSent).low & (int)(cp->length) &
0x80000000) && (call->bytesSent).high++)), (call->
bytesSent).low += (int)(cp->length));
723 rxi_PrepareSendPacket(call, cp, 0);
724#ifdef AFS_GLOBAL_RXLOCK_KERNEL
725 /* PrepareSendPacket drops the call lock */
726 rxi_WaitforTQBusy(call);
727#endif /* AFS_GLOBAL_RXLOCK_KERNEL */
728#ifdef RX_TRACK_PACKETS
729 cp->flags |= RX_PKTFLAG_TQ;
730#endif
731 queue_Append(&call->tq, cp)(((((struct rx_queue *)(cp))->prev=((struct rx_queue *)(&
call->tq))->prev)->next=((struct rx_queue *)(cp)))->
next=((struct rx_queue *)(&call->tq)), ((struct rx_queue
*)(&call->tq))->prev=((struct rx_queue *)(cp)));
732#ifdef RXDEBUG_PACKET
733 call->tqc++;
734#endif /* RXDEBUG_PACKET */
735 cp = (struct rx_packet *)0;
736 /* If the call is in recovery, let it exhaust its current
737 * retransmit queue before forcing it to send new packets
738 */
739 if (!(call->flags & (RX_CALL_FAST_RECOVER2048))) {
740 rxi_Start(call, 0);
741 }
742 } else if (cp) {
743#ifdef RX_TRACK_PACKETS
744 cp->flags &= ~RX_PKTFLAG_CP;
745#endif
746 rxi_FreePacket(cp);
747 cp = call->currentPacket = (struct rx_packet *)0;
748 }
749 /* Wait for transmit window to open up */
750 while (!call->error
751 && call->tnext + 1 > call->tfirst + (2 * call->twind)) {
752 clock_NewTime();
753 call->startWait = clock_Sec()(time(((void *)0)));
754
755#ifdef RX_ENABLE_LOCKS1
756 CV_WAIT(&call->cv_twind, &call->lock){ int isGlockOwner = (pthread_self() == afs_global_owner); if
(isGlockOwner) { do { do { if (!(pthread_self() == afs_global_owner
)) { osi_Panic("afs global lock not held"); } } while(0); memset
(&afs_global_owner, 0, sizeof(pthread_t)); do{if (!(pthread_mutex_unlock
(&afs_global_lock) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 756);}while(0); } while(0); } pthread_cond_wait(&call->
cv_twind,&call->lock); if (isGlockOwner) { do{if (!(pthread_mutex_unlock
(&call->lock) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 756);}while(0); do { do{if (!(pthread_mutex_lock(&afs_global_lock
) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 756);}while(0); afs_global_owner = pthread_self(); } while(
0); do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 756);}while(0); } };
757#else
758 call->flags |= RX_CALL_WAIT_WINDOW_ALLOC2;
759 osi_rxSleep(&call->twind)(((afs_iclSetp) && (afs_iclSetp->states & 2)) ?
afs_icl_Event2(afs_iclSetp, (701087897L), (1<<24)+((4)
<<18)+((7)<<12), (long)("/home/wollman/openafs/src/rx/rx_rdwr.c"
), (long)(759)) : 0); afs_osi_Sleep(&call->twind);
760#endif
761
762 call->startWait = 0;
763#ifdef RX_ENABLE_LOCKS1
764 if (call->error) {
765 call->mode = RX_MODE_ERROR3;
766 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 766);}while(0);
767 return 0;
768 }
769#endif /* RX_ENABLE_LOCKS */
770 }
771 if ((cp = rxi_AllocSendPacket(call, nbytes))) {
772#ifdef RX_TRACK_PACKETS
773 cp->flags |= RX_PKTFLAG_CP;
774#endif
775 call->currentPacket = cp;
776 call->nFree = cp->length;
777 call->curvec = 1; /* 0th vec is always header */
778 /* begin at the beginning [ more or less ], continue
779 * on until the end, then stop. */
780 call->curpos =
781 (char *)cp->wirevec[1].iov_base +
782 call->conn->securityHeaderSize;
783 call->curlen =
784 cp->wirevec[1].iov_len - call->conn->securityHeaderSize;
785 }
786 if (call->error) {
787 call->mode = RX_MODE_ERROR3;
788 if (cp) {
789#ifdef RX_TRACK_PACKETS
790 cp->flags &= ~RX_PKTFLAG_CP;
791#endif
792 rxi_FreePacket(cp);
793 call->currentPacket = NULL((void *)0);
794 }
795 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 795);}while(0);
796 return 0;
797 }
798 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 798);}while(0);
799 }
800
801 if (cp && (int)call->nFree < nbytes) {
802 /* Try to extend the current buffer */
803 int len, mud;
804 len = cp->length;
805 mud = rx_MaxUserDataSize(call)((call)->MTU - sizeof (struct rx_header) - (call)->conn
->securityHeaderSize - (call)->conn->securityMaxTrailerSize
);
806 if (mud > len) {
807 int want;
808 want = MIN(nbytes - (int)call->nFree, mud - len)(((nbytes - (int)call->nFree)<(mud - len))?(nbytes - (int
)call->nFree):(mud - len));
809 rxi_AllocDataBuf(cp, want, RX_PACKET_CLASS_SEND_CBUF4);
810 if (cp->length > (unsigned)mud)
811 cp->length = mud;
812 call->nFree += (cp->length - len);
813 }
814 }
815
816 /* If the remaining bytes fit in the buffer, then store them
817 * and return. Don't ship a buffer that's full immediately to
818 * the peer--we don't know if it's the last buffer yet */
819
820 if (!cp) {
821 call->nFree = 0;
822 }
823
824 while (nbytes && call->nFree) {
825
826 t = MIN((int)call->curlen, nbytes)((((int)call->curlen)<(nbytes))?((int)call->curlen):
(nbytes));
827 t = MIN((int)call->nFree, t)((((int)call->nFree)<(t))?((int)call->nFree):(t));
828 memcpy(call->curpos, bufusr_buf, t);
829 bufusr_buf += t;
830 nbytes -= t;
831 call->curpos += t;
832 call->curlen -= (u_short)t;
833 call->nFree -= (u_short)t;
834
835 if (!call->curlen) {
836 /* need to get another struct iov */
837 if (++call->curvec >= cp->niovecs) {
838 /* current packet is full, extend or send it */
839 call->nFree = 0;
840 } else {
841 call->curpos = (char *)cp->wirevec[call->curvec].iov_base;
842 call->curlen = cp->wirevec[call->curvec].iov_len;
843 }
844 }
845 } /* while bytes to send and room to send them */
846
847 /* might be out of space now */
848 if (!nbytes) {
849 return requestCount;
850 } else; /* more data to send, so get another packet and keep going */
851 } while (nbytes);
852
853 return requestCount - nbytes;
854}
855
856int
857rx_WriteProc(struct rx_call *call, char *bufusr_buf, int nbytes)
858{
859 int bytes;
860 int tcurlen;
861 int tnFree;
862 char *tcurpos;
863 SPLVAR;
864
865 /* Free any packets from the last call to ReadvProc/WritevProc */
866 if (queue_IsNotEmpty(&call->iovq)(((struct rx_queue *)(&call->iovq))->next != ((struct
rx_queue *)(&call->iovq)))) {
867#ifdef RXDEBUG_PACKET
868 call->iovqc -=
869#endif /* RXDEBUG_PACKET */
870 rxi_FreePackets(0, &call->iovq);
871 }
872
873 /*
874 * Most common case: all of the data fits in the current iovec.
875 * We are relying on nFree being zero unless the call is in send mode.
876 */
877 tcurlen = (int)call->curlen;
878 tnFree = (int)call->nFree;
879 if (!call->error && tcurlen >= nbytes && tnFree >= nbytes) {
880 tcurpos = call->curpos;
881
882 memcpy(tcurpos, bufusr_buf, nbytes);
883 call->curpos = tcurpos + nbytes;
884 call->curlen = (u_short)(tcurlen - nbytes);
885 call->nFree = (u_short)(tnFree - nbytes);
886 return nbytes;
887 }
888
889 NETPRI;
890 bytes = rxi_WriteProc(call, bufusr_buf, nbytes);
891 USERPRI;
892 return bytes;
893}
894
895/* Optimization for marshalling 32 bit arguments */
896int
897rx_WriteProc32(struct rx_call *call, afs_int32 * value)
898{
899 int bytes;
900 int tcurlen;
901 int tnFree;
902 char *tcurpos;
903 SPLVAR;
904
905 if (queue_IsNotEmpty(&call->iovq)(((struct rx_queue *)(&call->iovq))->next != ((struct
rx_queue *)(&call->iovq)))) {
906#ifdef RXDEBUG_PACKET
907 call->iovqc -=
908#endif /* RXDEBUG_PACKET */
909 rxi_FreePackets(0, &call->iovq);
910 }
911
912 /*
913 * Most common case: all of the data fits in the current iovec.
914 * We are relying on nFree being zero unless the call is in send mode.
915 */
916 tcurlen = call->curlen;
917 tnFree = call->nFree;
918 if (!call->error && tcurlen >= sizeof(afs_int32)
919 && tnFree >= sizeof(afs_int32)) {
920 tcurpos = call->curpos;
921
922 if (!((size_t)tcurpos & (sizeof(afs_int32) - 1))) {
923 *((afs_int32 *) (tcurpos)) = *value;
924 } else {
925 memcpy(tcurpos, (char *)value, sizeof(afs_int32));
926 }
927 call->curpos = tcurpos + sizeof(afs_int32);
928 call->curlen = (u_short)(tcurlen - sizeof(afs_int32));
929 call->nFree = (u_short)(tnFree - sizeof(afs_int32));
930 return sizeof(afs_int32);
931 }
932
933 NETPRI;
934 bytes = rxi_WriteProc(call, (char *)value, sizeof(afs_int32));
935 USERPRI;
936 return bytes;
937}
938
939/* rxi_WritevAlloc -- internal version.
940 *
941 * Fill in an iovec to point to data in packet buffers. The application
942 * calls rxi_WritevProc when the buffers are full.
943 *
944 * LOCKS USED -- called at netpri.
945 */
946
947static int
948rxi_WritevAlloc(struct rx_call *call, struct iovec *iov, int *nio, int maxio,
949 int nbytes)
950{
951 struct rx_connection *conn = call->conn;
952 struct rx_packet *cp = call->currentPacket;
953 int requestCount;
954 int nextio;
955 /* Temporary values, real work is done in rxi_WritevProc */
956 int tnFree;
957 unsigned int tcurvec;
958 char *tcurpos;
959 int tcurlen;
960
961 requestCount = nbytes;
962 nextio = 0;
963
964 /* Free any packets from the last call to ReadvProc/WritevProc */
965 if (queue_IsNotEmpty(&call->iovq)(((struct rx_queue *)(&call->iovq))->next != ((struct
rx_queue *)(&call->iovq)))) {
966#ifdef RXDEBUG_PACKET
967 call->iovqc -=
968#endif /* RXDEBUG_PACKET */
969 rxi_FreePackets(0, &call->iovq);
970 }
971
972 if (call->mode != RX_MODE_SENDING1) {
973 if ((conn->type == RX_SERVER_CONNECTION1)
974 && (call->mode == RX_MODE_RECEIVING2)) {
975 call->mode = RX_MODE_SENDING1;
976 if (cp) {
977#ifdef RX_TRACK_PACKETS
978 cp->flags &= ~RX_PKTFLAG_CP;
979#endif
980 rxi_FreePacket(cp);
981 cp = call->currentPacket = (struct rx_packet *)0;
982 call->nLeft = 0;
983 call->nFree = 0;
984 }
985 } else {
986 return 0;
987 }
988 }
989
990 /* Set up the iovec to point to data in packet buffers. */
991 tnFree = call->nFree;
992 tcurvec = call->curvec;
993 tcurpos = call->curpos;
994 tcurlen = call->curlen;
995 do {
996 int t;
997
998 if (tnFree == 0) {
999 /* current packet is full, allocate a new one */
1000 MUTEX_ENTER(&call->lock)do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 1000);}while(0);
1001 cp = rxi_AllocSendPacket(call, nbytes);
1002 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 1002);}while(0);
1003 if (cp == NULL((void *)0)) {
1004 /* out of space, return what we have */
1005 *nio = nextio;
1006 return requestCount - nbytes;
1007 }
1008#ifdef RX_TRACK_PACKETS
1009 cp->flags |= RX_PKTFLAG_IOVQ;
1010#endif
1011 queue_Append(&call->iovq, cp)(((((struct rx_queue *)(cp))->prev=((struct rx_queue *)(&
call->iovq))->prev)->next=((struct rx_queue *)(cp)))
->next=((struct rx_queue *)(&call->iovq)), ((struct
rx_queue *)(&call->iovq))->prev=((struct rx_queue *
)(cp)));
1012#ifdef RXDEBUG_PACKET
1013 call->iovqc++;
1014#endif /* RXDEBUG_PACKET */
1015 tnFree = cp->length;
1016 tcurvec = 1;
1017 tcurpos =
1018 (char *)cp->wirevec[1].iov_base +
1019 call->conn->securityHeaderSize;
1020 tcurlen = cp->wirevec[1].iov_len - call->conn->securityHeaderSize;
1021 }
1022
1023 if (tnFree < nbytes) {
1024 /* try to extend the current packet */
1025 int len, mud;
1026 len = cp->length;
1027 mud = rx_MaxUserDataSize(call)((call)->MTU - sizeof (struct rx_header) - (call)->conn
->securityHeaderSize - (call)->conn->securityMaxTrailerSize
);
1028 if (mud > len) {
1029 int want;
1030 want = MIN(nbytes - tnFree, mud - len)(((nbytes - tnFree)<(mud - len))?(nbytes - tnFree):(mud - len
));
1031 rxi_AllocDataBuf(cp, want, RX_PACKET_CLASS_SEND_CBUF4);
1032 if (cp->length > (unsigned)mud)
1033 cp->length = mud;
1034 tnFree += (cp->length - len);
1035 if (cp == call->currentPacket) {
1036 call->nFree += (cp->length - len);
1037 }
1038 }
1039 }
1040
1041 /* fill in the next entry in the iovec */
1042 t = MIN(tcurlen, nbytes)(((tcurlen)<(nbytes))?(tcurlen):(nbytes));
1043 t = MIN(tnFree, t)(((tnFree)<(t))?(tnFree):(t));
1044 iov[nextio].iov_base = tcurpos;
1045 iov[nextio].iov_len = t;
1046 nbytes -= t;
1047 tcurpos += t;
1048 tcurlen -= t;
1049 tnFree -= t;
1050 nextio++;
1051
1052 if (!tcurlen) {
1053 /* need to get another struct iov */
1054 if (++tcurvec >= cp->niovecs) {
1055 /* current packet is full, extend it or move on to next packet */
1056 tnFree = 0;
1057 } else {
1058 tcurpos = (char *)cp->wirevec[tcurvec].iov_base;
1059 tcurlen = cp->wirevec[tcurvec].iov_len;
1060 }
1061 }
1062 } while (nbytes && nextio < maxio);
1063 *nio = nextio;
1064 return requestCount - nbytes;
1065}
1066
1067int
1068rx_WritevAlloc(struct rx_call *call, struct iovec *iov, int *nio, int maxio,
1069 int nbytes)
1070{
1071 int bytes;
1072 SPLVAR;
1073
1074 NETPRI;
1075 bytes = rxi_WritevAlloc(call, iov, nio, maxio, nbytes);
1076 USERPRI;
1077 return bytes;
1078}
1079
1080/* rxi_WritevProc -- internal version.
1081 *
1082 * Send buffers allocated in rxi_WritevAlloc.
1083 *
1084 * LOCKS USED -- called at netpri.
1085 */
1086int
1087rxi_WritevProc(struct rx_call *call, struct iovec *iov, int nio, int nbytes)
1088{
1089 struct rx_packet *cp = NULL((void *)0);
1090#ifdef RX_TRACK_PACKETS
1091 struct rx_packet *p, *np;
1092#endif
1093 int nextio;
1094 int requestCount;
1095 struct rx_queue tmpq;
1096#ifdef RXDEBUG_PACKET
1097 u_short tmpqc;
1098#endif
1099
1100 requestCount = nbytes;
1101 nextio = 0;
1102
1103 MUTEX_ENTER(&call->lock)do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 1103);}while(0);
1104 if (call->error) {
1105 call->mode = RX_MODE_ERROR3;
1106 } else if (call->mode != RX_MODE_SENDING1) {
1107 call->error = RX_PROTOCOL_ERROR(-5);
1108 }
1109#ifdef AFS_GLOBAL_RXLOCK_KERNEL
1110 rxi_WaitforTQBusy(call);
1111#endif /* AFS_GLOBAL_RXLOCK_KERNEL */
1112 cp = call->currentPacket;
1113
1114 if (call->error) {
1115 call->mode = RX_MODE_ERROR3;
1116 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 1116);}while(0);
1117 if (cp) {
1118#ifdef RX_TRACK_PACKETS
1119 cp->flags &= ~RX_PKTFLAG_CP;
1120 cp->flags |= RX_PKTFLAG_IOVQ;
1121#endif
1122 queue_Prepend(&call->iovq, cp)(((((struct rx_queue *)(cp))->next=((struct rx_queue *)(&
call->iovq))->next)->prev=((struct rx_queue *)(cp)))
->prev=((struct rx_queue *)(&call->iovq)), ((struct
rx_queue *)(&call->iovq))->next=((struct rx_queue *
)(cp)));
1123#ifdef RXDEBUG_PACKET
1124 call->iovqc++;
1125#endif /* RXDEBUG_PACKET */
1126 call->currentPacket = (struct rx_packet *)0;
1127 }
1128#ifdef RXDEBUG_PACKET
1129 call->iovqc -=
1130#endif /* RXDEBUG_PACKET */
1131 rxi_FreePackets(0, &call->iovq);
1132 return 0;
1133 }
1134
1135 /* Loop through the I/O vector adjusting packet pointers.
1136 * Place full packets back onto the iovq once they are ready
1137 * to send. Set RX_PROTOCOL_ERROR if any problems are found in
1138 * the iovec. We put the loop condition at the end to ensure that
1139 * a zero length write will push a short packet. */
1140 nextio = 0;
1141 queue_Init(&tmpq)(((struct rx_queue *)(&tmpq)))->prev = (((struct rx_queue
*)(&tmpq)))->next = (((struct rx_queue *)(&tmpq))
);
1142#ifdef RXDEBUG_PACKET
1143 tmpqc = 0;
1144#endif /* RXDEBUG_PACKET */
1145 do {
1146 if (call->nFree == 0 && cp) {
1147 clock_NewTime(); /* Bogus: need new time package */
1148 /* The 0, below, specifies that it is not the last packet:
1149 * there will be others. PrepareSendPacket may
1150 * alter the packet length by up to
1151 * conn->securityMaxTrailerSize */
1152 hadd32(call->bytesSent, cp->length)((void)((((call->bytesSent).low ^ (int)(cp->length)) &
0x80000000) ? (((((call->bytesSent).low + (int)(cp->length
)) & 0x80000000) == 0) && (call->bytesSent).high
++) : (((call->bytesSent).low & (int)(cp->length) &
0x80000000) && (call->bytesSent).high++)), (call->
bytesSent).low += (int)(cp->length));
1153 rxi_PrepareSendPacket(call, cp, 0);
1154#ifdef AFS_GLOBAL_RXLOCK_KERNEL
1155 /* PrepareSendPacket drops the call lock */
1156 rxi_WaitforTQBusy(call);
1157#endif /* AFS_GLOBAL_RXLOCK_KERNEL */
1158 queue_Append(&tmpq, cp)(((((struct rx_queue *)(cp))->prev=((struct rx_queue *)(&
tmpq))->prev)->next=((struct rx_queue *)(cp)))->next
=((struct rx_queue *)(&tmpq)), ((struct rx_queue *)(&
tmpq))->prev=((struct rx_queue *)(cp)));
1159#ifdef RXDEBUG_PACKET
1160 tmpqc++;
1161#endif /* RXDEBUG_PACKET */
1162 cp = call->currentPacket = (struct rx_packet *)0;
1163
1164 /* The head of the iovq is now the current packet */
1165 if (nbytes) {
1166 if (queue_IsEmpty(&call->iovq)(((struct rx_queue *)(&call->iovq))->next == ((struct
rx_queue *)(&call->iovq)))) {
1167 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 1167);}while(0);
1168 call->error = RX_PROTOCOL_ERROR(-5);
1169#ifdef RXDEBUG_PACKET
1170 tmpqc -=
1171#endif /* RXDEBUG_PACKET */
1172 rxi_FreePackets(0, &tmpq);
1173 return 0;
1174 }
1175 cp = queue_First(&call->iovq, rx_packet)((struct rx_packet *)((struct rx_queue *)(&call->iovq)
)->next);
1176 queue_Remove(cp)(((((struct rx_queue *)(cp))->prev->next=((struct rx_queue
*)(cp))->next)->prev=((struct rx_queue *)(cp))->prev
), ((struct rx_queue *)(cp))->next = 0);
1177#ifdef RX_TRACK_PACKETS
1178 cp->flags &= ~RX_PKTFLAG_IOVQ;
1179#endif
1180#ifdef RXDEBUG_PACKET
1181 call->iovqc--;
1182#endif /* RXDEBUG_PACKET */
1183#ifdef RX_TRACK_PACKETS
1184 cp->flags |= RX_PKTFLAG_CP;
1185#endif
1186 call->currentPacket = cp;
1187 call->nFree = cp->length;
1188 call->curvec = 1;
1189 call->curpos =
1190 (char *)cp->wirevec[1].iov_base +
1191 call->conn->securityHeaderSize;
1192 call->curlen =
1193 cp->wirevec[1].iov_len - call->conn->securityHeaderSize;
1194 }
1195 }
1196
1197 if (nbytes) {
1198 /* The next iovec should point to the current position */
1199 if (iov[nextio].iov_base != call->curpos
1200 || iov[nextio].iov_len > (int)call->curlen) {
1201 call->error = RX_PROTOCOL_ERROR(-5);
1202 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 1202);}while(0);
1203 if (cp) {
1204#ifdef RX_TRACK_PACKETS
1205 cp->flags &= ~RX_PKTFLAG_CP;
1206#endif
1207 queue_Prepend(&tmpq, cp)(((((struct rx_queue *)(cp))->next=((struct rx_queue *)(&
tmpq))->next)->prev=((struct rx_queue *)(cp)))->prev
=((struct rx_queue *)(&tmpq)), ((struct rx_queue *)(&
tmpq))->next=((struct rx_queue *)(cp)));
1208#ifdef RXDEBUG_PACKET
1209 tmpqc++;
1210#endif /* RXDEBUG_PACKET */
1211 cp = call->currentPacket = (struct rx_packet *)0;
1212 }
1213#ifdef RXDEBUG_PACKET
1214 tmpqc -=
1215#endif /* RXDEBUG_PACKET */
1216 rxi_FreePackets(0, &tmpq);
1217 return 0;
1218 }
1219 nbytes -= iov[nextio].iov_len;
1220 call->curpos += iov[nextio].iov_len;
1221 call->curlen -= iov[nextio].iov_len;
1222 call->nFree -= iov[nextio].iov_len;
1223 nextio++;
1224 if (call->curlen == 0) {
1225 if (++call->curvec > cp->niovecs) {
1226 call->nFree = 0;
1227 } else {
1228 call->curpos = (char *)cp->wirevec[call->curvec].iov_base;
1229 call->curlen = cp->wirevec[call->curvec].iov_len;
1230 }
1231 }
1232 }
1233 } while (nbytes && nextio < nio);
1234
1235 /* Move the packets from the temporary queue onto the transmit queue.
1236 * We may end up with more than call->twind packets on the queue. */
1237
1238#ifdef RX_TRACK_PACKETS
1239 for (queue_Scan(&tmpq, p, np, rx_packet)(p) = ((struct rx_packet *)((struct rx_queue *)(&tmpq))->
next), np = ((struct rx_packet *)((struct rx_queue *)(p))->
next); !(((struct rx_queue *)(&tmpq)) == ((struct rx_queue
*)(p))); (p) = (np), np = ((struct rx_packet *)((struct rx_queue
*)(p))->next))
1240 {
1241 p->flags |= RX_PKTFLAG_TQ;
1242 }
1243#endif
1244
1245 if (call->error)
1246 call->mode = RX_MODE_ERROR3;
1247
1248 queue_SpliceAppend(&call->tq, &tmpq)if ((((struct rx_queue *)(((struct rx_queue *)(&tmpq))))->
next == ((struct rx_queue *)(((struct rx_queue *)(&tmpq))
)))); else ((((((struct rx_queue *)(&tmpq))->prev->
next=((struct rx_queue *)(&call->tq)))->prev->next
=((struct rx_queue *)(&tmpq))->next)->prev=((struct
rx_queue *)(&call->tq))->prev, ((struct rx_queue *
)(&call->tq))->prev=((struct rx_queue *)(&tmpq)
)->prev), (((struct rx_queue *)(((struct rx_queue *)(&
tmpq)))))->prev = (((struct rx_queue *)(((struct rx_queue *
)(&tmpq)))))->next = (((struct rx_queue *)(((struct rx_queue
*)(&tmpq))))));
1249
1250 /* If the call is in recovery, let it exhaust its current retransmit
1251 * queue before forcing it to send new packets
1252 */
1253 if (!(call->flags & RX_CALL_FAST_RECOVER2048)) {
1254 rxi_Start(call, 0);
1255 }
1256
1257 /* Wait for the length of the transmit queue to fall below call->twind */
1258 while (!call->error && call->tnext + 1 > call->tfirst + (2 * call->twind)) {
1259 clock_NewTime();
1260 call->startWait = clock_Sec()(time(((void *)0)));
1261#ifdef RX_ENABLE_LOCKS1
1262 CV_WAIT(&call->cv_twind, &call->lock){ int isGlockOwner = (pthread_self() == afs_global_owner); if
(isGlockOwner) { do { do { if (!(pthread_self() == afs_global_owner
)) { osi_Panic("afs global lock not held"); } } while(0); memset
(&afs_global_owner, 0, sizeof(pthread_t)); do{if (!(pthread_mutex_unlock
(&afs_global_lock) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 1262);}while(0); } while(0); } pthread_cond_wait(&call->
cv_twind,&call->lock); if (isGlockOwner) { do{if (!(pthread_mutex_unlock
(&call->lock) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 1262);}while(0); do { do{if (!(pthread_mutex_lock(&afs_global_lock
) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 1262);}while(0); afs_global_owner = pthread_self(); } while
(0); do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 1262);}while(0); }
};
1263#else
1264 call->flags |= RX_CALL_WAIT_WINDOW_ALLOC2;
1265 osi_rxSleep(&call->twind)(((afs_iclSetp) && (afs_iclSetp->states & 2)) ?
afs_icl_Event2(afs_iclSetp, (701087897L), (1<<24)+((4)
<<18)+((7)<<12), (long)("/home/wollman/openafs/src/rx/rx_rdwr.c"
), (long)(1265)) : 0); afs_osi_Sleep(&call->twind);
1266#endif
1267 call->startWait = 0;
1268 }
1269
1270 /* cp is no longer valid since we may have given up the lock */
1271 cp = call->currentPacket;
1272
1273 if (call->error) {
1274 call->mode = RX_MODE_ERROR3;
1275 call->currentPacket = NULL((void *)0);
1276 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 1276);}while(0);
1277 if (cp) {
1278#ifdef RX_TRACK_PACKETS
1279 cp->flags &= ~RX_PKTFLAG_CP;
1280#endif
1281 rxi_FreePacket(cp);
1282 }
1283 return 0;
1284 }
1285 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 1285);}while(0);
1286
1287 return requestCount - nbytes;
1288}
1289
1290int
1291rx_WritevProc(struct rx_call *call, struct iovec *iov, int nio, int nbytes)
1292{
1293 int bytes;
1294 SPLVAR;
1295
1296 NETPRI;
1297 bytes = rxi_WritevProc(call, iov, nio, nbytes);
1298 USERPRI;
1299 return bytes;
1300}
1301
1302/* Flush any buffered data to the stream, switch to read mode
1303 * (clients) or to EOF mode (servers)
1304 *
1305 * LOCKS HELD: called at netpri.
1306 */
1307void
1308rxi_FlushWrite(struct rx_call *call)
1309{
1310 struct rx_packet *cp = NULL((void *)0);
1311
1312 /* Free any packets from the last call to ReadvProc/WritevProc */
1313 if (queue_IsNotEmpty(&call->iovq)(((struct rx_queue *)(&call->iovq))->next != ((struct
rx_queue *)(&call->iovq)))) {
1314#ifdef RXDEBUG_PACKET
1315 call->iovqc -=
1316#endif /* RXDEBUG_PACKET */
1317 rxi_FreePackets(0, &call->iovq);
1318 }
1319
1320 if (call->mode == RX_MODE_SENDING1) {
1321
1322 call->mode =
1323 (call->conn->type ==
1324 RX_CLIENT_CONNECTION0 ? RX_MODE_RECEIVING2 : RX_MODE_EOF4);
1325
1326#ifdef RX_KERNEL_TRACE
1327 {
1328 int glockOwner = ISAFS_GLOCK()(pthread_self() == afs_global_owner);
1329 if (!glockOwner)
1330 AFS_GLOCK()do { do{if (!(pthread_mutex_lock(&afs_global_lock) == 0))
AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c", 1330
);}while(0); afs_global_owner = pthread_self(); } while(0);
1331 afs_Trace3(afs_iclSetp, CM_TRACE_WASHERE, ICL_TYPE_STRING,(((afs_iclSetp) && (afs_iclSetp->states & 2)) ?
afs_icl_Event3(afs_iclSetp, (701087902L), (1<<24)+((4)
<<18)+((7)<<12)+((2)<<6), (long)("/home/wollman/openafs/src/rx/rx_rdwr.c"
), (long)(1332), (long)(call)) : 0)
1332 __FILE__, ICL_TYPE_INT32, __LINE__, ICL_TYPE_POINTER,(((afs_iclSetp) && (afs_iclSetp->states & 2)) ?
afs_icl_Event3(afs_iclSetp, (701087902L), (1<<24)+((4)
<<18)+((7)<<12)+((2)<<6), (long)("/home/wollman/openafs/src/rx/rx_rdwr.c"
), (long)(1332), (long)(call)) : 0)
1333 call)(((afs_iclSetp) && (afs_iclSetp->states & 2)) ?
afs_icl_Event3(afs_iclSetp, (701087902L), (1<<24)+((4)
<<18)+((7)<<12)+((2)<<6), (long)("/home/wollman/openafs/src/rx/rx_rdwr.c"
), (long)(1332), (long)(call)) : 0);
1334 if (!glockOwner)
1335 AFS_GUNLOCK()do { do { if (!(pthread_self() == afs_global_owner)) { osi_Panic
("afs global lock not held"); } } while(0); memset(&afs_global_owner
, 0, sizeof(pthread_t)); do{if (!(pthread_mutex_unlock(&afs_global_lock
) == 0)) AssertionFailed("/home/wollman/openafs/src/rx/rx_rdwr.c"
, 1335);}while(0); } while(0);
1336 }
1337#endif
1338
1339 MUTEX_ENTER(&call->lock)do{if (!(pthread_mutex_lock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 1339);}while(0);
1340 if (call->error)
1341 call->mode = RX_MODE_ERROR3;
1342
1343 cp = call->currentPacket;
1344
1345 if (cp) {
1346 /* cp->length is only supposed to be the user's data */
1347 /* cp->length was already set to (then-current)
1348 * MaxUserDataSize or less. */
1349#ifdef RX_TRACK_PACKETS
1350 cp->flags &= ~RX_PKTFLAG_CP;
1351#endif
1352 cp->length -= call->nFree;
1353 call->currentPacket = (struct rx_packet *)0;
1354 call->nFree = 0;
1355 } else {
1356 cp = rxi_AllocSendPacket(call, 0);
1357 if (!cp) {
1358 /* Mode can no longer be MODE_SENDING */
1359 return;
1360 }
1361 cp->length = 0;
1362 cp->niovecs = 2; /* header + space for rxkad stuff */
1363 call->nFree = 0;
1364 }
1365
1366 /* The 1 specifies that this is the last packet */
1367 hadd32(call->bytesSent, cp->length)((void)((((call->bytesSent).low ^ (int)(cp->length)) &
0x80000000) ? (((((call->bytesSent).low + (int)(cp->length
)) & 0x80000000) == 0) && (call->bytesSent).high
++) : (((call->bytesSent).low & (int)(cp->length) &
0x80000000) && (call->bytesSent).high++)), (call->
bytesSent).low += (int)(cp->length));
1368 rxi_PrepareSendPacket(call, cp, 1);
1369#ifdef AFS_GLOBAL_RXLOCK_KERNEL
1370 /* PrepareSendPacket drops the call lock */
1371 rxi_WaitforTQBusy(call);
1372#endif /* AFS_GLOBAL_RXLOCK_KERNEL */
1373#ifdef RX_TRACK_PACKETS
1374 cp->flags |= RX_PKTFLAG_TQ;
1375#endif
1376 queue_Append(&call->tq, cp)(((((struct rx_queue *)(cp))->prev=((struct rx_queue *)(&
call->tq))->prev)->next=((struct rx_queue *)(cp)))->
next=((struct rx_queue *)(&call->tq)), ((struct rx_queue
*)(&call->tq))->prev=((struct rx_queue *)(cp)));
1377#ifdef RXDEBUG_PACKET
1378 call->tqc++;
1379#endif /* RXDEBUG_PACKET */
1380
1381 /* If the call is in recovery, let it exhaust its current retransmit
1382 * queue before forcing it to send new packets
1383 */
1384 if (!(call->flags & RX_CALL_FAST_RECOVER2048)) {
1385 rxi_Start(call, 0);
1386 }
1387 MUTEX_EXIT(&call->lock)do{if (!(pthread_mutex_unlock(&call->lock) == 0)) AssertionFailed
("/home/wollman/openafs/src/rx/rx_rdwr.c", 1387);}while(0);
1388 }
1389}
1390
1391/* Flush any buffered data to the stream, switch to read mode
1392 * (clients) or to EOF mode (servers) */
1393void
1394rx_FlushWrite(struct rx_call *call)
1395{
1396 SPLVAR;
1397 NETPRI;
1398 rxi_FlushWrite(call);
1399 USERPRI;
1400}