../device/chario.c

Bug Summary

File:	obj-scan-build/../device/chario.c
Location:	line 1016, column 3
Description:	Value stored to 'count' is never read

Annotated Source Code

1	/*
2	* Mach Operating System
3	* Copyright (c) 1993-1988 Carnegie Mellon University
4	* All Rights Reserved.
5	*
6	* Permission to use, copy, modify and distribute this software and its
7	* documentation is hereby granted, provided that both the copyright
8	* notice and this permission notice appear in all copies of the
9	* software, derivative works or modified versions, and any portions
10	* thereof, and that both notices appear in supporting documentation.
11	*
12	* CARNEGIE MELLON ALLOWS FREE USE OF THIS SOFTWARE IN ITS "AS IS"
13	* CONDITION. CARNEGIE MELLON DISCLAIMS ANY LIABILITY OF ANY KIND FOR
14	* ANY DAMAGES WHATSOEVER RESULTING FROM THE USE OF THIS SOFTWARE.
15	*
16	* Carnegie Mellon requests users of this software to return to
17	*
18	* Software Distribution Coordinator or Software.Distribution@CS.CMU.EDU
19	* School of Computer Science
20	* Carnegie Mellon University
21	* Pittsburgh PA 15213-3890
22	*
23	* any improvements or extensions that they make and grant Carnegie Mellon
24	* the rights to redistribute these changes.
25	*/
26	/*
27	* Author: David B. Golub, Carnegie Mellon University
28	* Date: 8/88
29	*
30	* TTY io.
31	* Compatibility with old TTY device drivers.
32	*/
33
34	#include <mach/kern_return.h>
35	#include <mach/mig_errors.h>
36	#include <mach/vm_param.h>
37	#include <machine/machspl.h> /* spl definitions */
38
39	#include <ipc/ipc_port.h>
40
41	#include <kern/lock.h>
42	#include <kern/queue.h>
43
44	#include <vm/vm_map.h>
45	#include <vm/vm_kern.h>
46	#include <vm/vm_user.h>
47
48	#include <device/device_types.h>
49	#include <device/io_req.h>
50	#include <device/ds_routines.h>
51	#include <device/device_reply.user.h>
52
53	#include <device/tty.h>
54
55	/* If you change these, check that tty_outq_size and tty_inq_size
56	* is greater than largest tthiwat entry.
57	*/
58	short tthiwat[NSPEEDS18] =
59	{ 100,100,100,100,100,100,100,200,200,400,400,400,650,650,1300,2000,
60	2000,2000 };
61	short ttlowat[NSPEEDS18] =
62	{ 30, 30, 30, 30, 30, 30, 30, 50, 50,120,120,120,125,125, 125, 125,
63	125,125 };
64
65	/*
66	* forward declarations
67	*/
68	void queue_delayed_reply(
69	queue_t, io_req_t, boolean_t (*)(io_req_t));
70	void tty_output(struct tty *);
71	boolean_t char_open_done(io_req_t);
72	boolean_t char_read_done(io_req_t);
73	boolean_t char_write_done(io_req_t);
74
75	/*
76	* Fake 'line discipline' switch for the benefit of old code
77	* that wants to call through it.
78	*/
79	struct ldisc_switch linesw[] = {
80	{
81	char_read,
82	char_write,
83	ttyinput,
84	ttymodem,
85	tty_output
86	}
87	};
88
89	/*
90	* Sizes for input and output circular buffers.
91	*/
92	const int tty_inq_size = 4096; /* big nuf */
93	const int tty_outq_size = 2048; /* Must be bigger that tthiwat */
94	int pdma_default = 1; /* turn pseudo dma on by default */
95
96	/*
97	* compute pseudo-dma tables
98	*/
99
100	int pdma_timeouts[NSPEEDS18]; /* how many ticks in timeout */
101	int pdma_water_mark[NSPEEDS18];
102
103
104	void chario_init(void)
105	{
106	/* the basic idea with the timeouts is two allow enough
107	time for a character to show up if data is coming in at full data rate
108	plus a little slack. 2 ticks is considered slack
109	Below 300 baud we just glob a character at a time */
110	#define _PR(x)(0.20 * x) ((hz/x) + 2)
111
112	int i;
113
114	for (i = B00; i < B3007; i++)
115	pdma_timeouts[i] = 0;
116
117	pdma_timeouts[B3007] = _PR(30)(0.20 * 30);
118	pdma_timeouts[B6008] = _PR(60)(0.20 * 60);
119	pdma_timeouts[B12009] = _PR(120)(0.20 * 120);
120	pdma_timeouts[B180010] = _PR(180)(0.20 * 180);
121	pdma_timeouts[B240011] = _PR(240)(0.20 * 240);
122	pdma_timeouts[B480012] = _PR(480)(0.20 * 480);
123	pdma_timeouts[B960013] = _PR(960)(0.20 * 960);
124	pdma_timeouts[EXTA14] = _PR(1440)(0.20 * 1440); /* >14400 baud */
125	pdma_timeouts[EXTB15] = _PR(1920)(0.20 * 1920); /* >19200 baud */
126	pdma_timeouts[B5760016] = _PR(5760)(0.20 * 5760);
127	pdma_timeouts[B11520017] = _PR(11520)(0.20 * 11520);
128
129	for (i = B00; i < B3007; i++)
130	pdma_water_mark[i] = 0;
131
132	/* for the slow speeds, we try to buffer 0.02 of the baud rate
133	(20% of the character rate). For the faster lines,
134	we try to buffer 1/2 the input queue size */
135
136	#undef _PR
137	#define _PR(x)(0.20 * x) (0.20 * x)
138
139	pdma_water_mark[B3007] = _PR(120)(0.20 * 120);
140	pdma_water_mark[B6008] = _PR(120)(0.20 * 120);
141	pdma_water_mark[B12009] = _PR(120)(0.20 * 120);
142	pdma_water_mark[B180010] = _PR(180)(0.20 * 180);
143	pdma_water_mark[B240011] = _PR(240)(0.20 * 240);
144	pdma_water_mark[B480012] = _PR(480)(0.20 * 480);
145	i = tty_inq_size/2;
146	pdma_water_mark[B960013] = i;
147	pdma_water_mark[EXTA14] = i; /* >14400 baud */
148	pdma_water_mark[EXTB15] = i; /* >19200 baud */
149	pdma_water_mark[B5760016] = i;
150	pdma_water_mark[B11520017] = i;
151
152	return;
153	}
154
155	/*
156	* Open TTY, waiting for CARR_ON.
157	* No locks may be held.
158	* May run on any CPU.
159	*/
160	io_return_t char_open(
161	int dev,
162	struct tty * tp,
163	dev_mode_t mode,
164	io_req_t ior)
165	{
166	spl_t s;
167	io_return_t rc = D_SUCCESS0;
168
169	s = spltty();
170	simple_lock(&tp->t_lock);
171
172	tp->t_dev = dev;
173
174	if (tp->t_mctl)
175	(*tp->t_mctl)(tp, TM_DTR0x0002, DMSET0);
176
177	if (pdma_default)
178	tp->t_state \|= TS_MIN0x00004000;
179
180	if ((tp->t_state & TS_CARR_ON0x00000020) == 0) {
181	/*
182	* No carrier.
183	*/
184	if (mode & D_NODELAY0x4) {
185	tp->t_state \|= TS_ONDELAY0x00002000;
186	}
187	else {
188	/*
189	* Don`t return from open until carrier detected.
190	*/
191	tp->t_state \|= TS_WOPEN0x00000004;
192
193	ior->io_dev_ptr = (char *)tp;
194
195	queue_delayed_reply(&tp->t_delayed_open, ior, char_open_done);
196	rc = D_IO_QUEUED(-1);
197	goto out;
198	}
199	}
200	tp->t_state \|= TS_ISOPEN0x00000008;
201	if (tp->t_mctl)
202	(*tp->t_mctl)(tp, TM_RTS0x0004, DMBIS1);
203	out:
204	simple_unlock(&tp->t_lock);
205	splx(s);
206	return rc;
207	}
208
209	/*
210	* Retry wait for CARR_ON for open.
211	* No locks may be held.
212	* May run on any CPU.
213	*/
214	boolean_t char_open_done(
215	io_req_t ior)
216	{
217	struct tty tp = (struct tty )ior->io_dev_ptr;
218	spl_t s = spltty();
219
220	simple_lock(&tp->t_lock);
221	if ((tp->t_state & TS_ISOPEN0x00000008) == 0) {
222	queue_delayed_reply(&tp->t_delayed_open, ior, char_open_done);
223	simple_unlock(&tp->t_lock);
224	splx(s);
225	return FALSE((boolean_t) 0);
226	}
227
228	tp->t_state \|= TS_ISOPEN0x00000008;
229	tp->t_state &= ~TS_WOPEN0x00000004;
230
231	if (tp->t_mctl)
232	(*tp->t_mctl)(tp, TM_RTS0x0004, DMBIS1);
233
234	simple_unlock(&tp->t_lock);
235	splx(s);
236
237	ior->io_error = D_SUCCESS0;
238	(void) ds_open_done(ior);
239	return TRUE((boolean_t) 1);
240	}
241
242	boolean_t tty_close_open_reply(
243	io_req_t ior)
244	{
245	ior->io_error = D_DEVICE_DOWN2504;
246	(void) ds_open_done(ior);
247	return TRUE((boolean_t) 1);
248	}
249
250	/*
251	* Write to TTY.
252	* No locks may be held.
253	* Calls device start routine; must already be on master if
254	* device needs to run on master.
255	*/
256	io_return_t char_write(
257	struct tty * tp,
258	io_req_t ior)
259	{
260	spl_t s;
261	int count;
262	char *data;
263	vm_offset_t addr = 0;
264	io_return_t rc = D_SUCCESS0;
265
266	data = ior->io_dataio_un.data;
267	count = ior->io_count;
268	if (count == 0)
269	return rc;
270
271	if (!(ior->io_op & IO_INBAND0x00004000)) {
272	/*
273	* Copy out-of-line data into kernel address space.
274	* Since data is copied as page list, it will be
275	* accessible.
276	*/
277	vm_map_copy_t copy = (vm_map_copy_t) data;
278	kern_return_t kr;
279
280	kr = vm_map_copyout(device_io_map, &addr, copy);
281	if (kr != KERN_SUCCESS0)
282	return kr;
283	data = (char *) addr;
284	}
285
286	/*
287	* Check for tty operating.
288	*/
289	s = spltty();
290	simple_lock(&tp->t_lock);
291
292	if ((tp->t_state & TS_CARR_ON0x00000020) == 0) {
293
294	if ((tp->t_state & TS_ONDELAY0x00002000) == 0) {
295	/*
296	* No delayed writes - tell caller that device is down
297	*/
298	rc = D_IO_ERROR2500;
299	goto out;
300	}
301
302	if (ior->io_mode & D_NOWAIT0x8) {
303	rc = D_WOULD_BLOCK2501;
304	goto out;
305	}
306	}
307
308	/*
309	* Copy data into the output buffer.
310	* Report the amount not copied.
311	*/
312
313	ior->io_residual = b_to_q(data, count, &tp->t_outq);
314
315	/*
316	* Start hardware output.
317	*/
318
319	tp->t_state &= ~TS_TTSTOP0x00000100;
320	tty_output(tp);
321
322	if (tp->t_outq.c_cc > TTHIWAT(tp)tthiwat[(tp)->t_ospeed] \|\|
323	(tp->t_state & TS_CARR_ON0x00000020) == 0) {
324
325	/*
326	* Do not send reply until some characters have been sent.
327	*/
328	ior->io_dev_ptr = (char *)tp;
329	queue_delayed_reply(&tp->t_delayed_write, ior, char_write_done);
330
331	rc = D_IO_QUEUED(-1);
332	}
333	out:
334	simple_unlock(&tp->t_lock);
335	splx(s);
336
337	if (!(ior->io_op & IO_INBAND0x00004000))
338	(void) vm_deallocate(device_io_map, addr, ior->io_count);
339	return rc;
340	}
341
342	/*
343	* Retry wait for output queue emptied, for write.
344	* No locks may be held.
345	* May run on any CPU.
346	*/
347	boolean_t char_write_done(
348	io_req_t ior)
349	{
350	struct tty tp = (struct tty )ior->io_dev_ptr;
351	spl_t s = spltty();
352
353	simple_lock(&tp->t_lock);
354	if (tp->t_outq.c_cc > TTHIWAT(tp)tthiwat[(tp)->t_ospeed] \|\|
355	(tp->t_state & TS_CARR_ON0x00000020) == 0) {
356
357	queue_delayed_reply(&tp->t_delayed_write, ior, char_write_done);
358	simple_unlock(&tp->t_lock);
359	splx(s);
360	return FALSE((boolean_t) 0);
361	}
362	simple_unlock(&tp->t_lock);
363	splx(s);
364
365	if (IP_VALID(ior->io_reply_port)(((&(ior->io_reply_port)->ip_target.ipt_object) != ( (ipc_object_t) 0)) && ((&(ior->io_reply_port)-> ip_target.ipt_object) != ((ipc_object_t) -1)))) {
366	(void) (*((ior->io_op & IO_INBAND0x00004000) ?
367	ds_device_write_reply_inband :
368	ds_device_write_reply))(ior->io_reply_port,
369	ior->io_reply_port_type,
370	ior->io_error,
371	(int) (ior->io_total -
372	ior->io_residual));
373	}
374	mach_device_deallocate(ior->io_device);
375	return TRUE((boolean_t) 1);
376	}
377
378	boolean_t tty_close_write_reply(
379	io_req_t ior)
380	{
381	ior->io_residual = ior->io_count;
382	ior->io_error = D_DEVICE_DOWN2504;
383	(void) ds_write_done(ior);
384	return TRUE((boolean_t) 1);
385	}
386
387	/*
388	* Read from TTY.
389	* No locks may be held.
390	* May run on any CPU - does not talk to device driver.
391	*/
392	io_return_t char_read(
393	struct tty *tp,
394	io_req_t ior)
395	{
396	spl_t s;
397	kern_return_t rc;
398
399	/*
400	* Allocate memory for read buffer.
401	*/
402	rc = device_read_alloc(ior, (vm_size_t)ior->io_count);
403	if (rc != KERN_SUCCESS0)
404	return rc;
405
406	s = spltty();
407	simple_lock(&tp->t_lock);
408	if ((tp->t_state & TS_CARR_ON0x00000020) == 0) {
409
410	if ((tp->t_state & TS_ONDELAY0x00002000) == 0) {
411	/*
412	* No delayed writes - tell caller that device is down
413	*/
414	rc = D_IO_ERROR2500;
415	goto out;
416	}
417
418	if (ior->io_mode & D_NOWAIT0x8) {
419	rc = D_WOULD_BLOCK2501;
420	goto out;
421	}
422
423	}
424
425	if (tp->t_inq.c_cc <= 0 \|\|
426	(tp->t_state & TS_CARR_ON0x00000020) == 0) {
427
428	ior->io_dev_ptr = (char *)tp;
429	queue_delayed_reply(&tp->t_delayed_read, ior, char_read_done);
430	rc = D_IO_QUEUED(-1);
431	goto out;
432	}
433
434	ior->io_residual = ior->io_count - q_to_b(&tp->t_inq,
435	ior->io_dataio_un.data,
436	(int)ior->io_count);
437	if (tp->t_state & TS_RTS_DOWN0x00020000) {
438	(*tp->t_mctl)(tp, TM_RTS0x0004, DMBIS1);
439	tp->t_state &= ~TS_RTS_DOWN0x00020000;
440	}
441
442	out:
443	simple_unlock(&tp->t_lock);
444	splx(s);
445	return rc;
446	}
447
448	/*
449	* Retry wait for characters, for read.
450	* No locks may be held.
451	* May run on any CPU - does not talk to device driver.
452	*/
453	boolean_t char_read_done(
454	io_req_t ior)
455	{
456	struct tty tp = (struct tty )ior->io_dev_ptr;
457	spl_t s = spltty();
458
459	simple_lock(&tp->t_lock);
460
461	if (tp->t_inq.c_cc <= 0 \|\|
462	(tp->t_state & TS_CARR_ON0x00000020) == 0) {
463
464	queue_delayed_reply(&tp->t_delayed_read, ior, char_read_done);
465	simple_unlock(&tp->t_lock);
466	splx(s);
467	return FALSE((boolean_t) 0);
468	}
469
470	ior->io_residual = ior->io_count - q_to_b(&tp->t_inq,
471	ior->io_dataio_un.data,
472	(int)ior->io_count);
473	if (tp->t_state & TS_RTS_DOWN0x00020000) {
474	(*tp->t_mctl)(tp, TM_RTS0x0004, DMBIS1);
475	tp->t_state &= ~TS_RTS_DOWN0x00020000;
476	}
477
478	simple_unlock(&tp->t_lock);
479	splx(s);
480
481	(void) ds_read_done(ior);
482	return TRUE((boolean_t) 1);
483	}
484
485	boolean_t tty_close_read_reply(
486	io_req_t ior)
487	{
488	ior->io_residual = ior->io_count;
489	ior->io_error = D_DEVICE_DOWN2504;
490	(void) ds_read_done(ior);
491	return TRUE((boolean_t) 1);
492	}
493
494	/*
495	* Close the tty.
496	* Tty must be locked (at spltty).
497	* Iff modem control should run on master.
498	*/
499	void ttyclose(
500	struct tty *tp)
501	{
502	io_req_t ior;
503
504	/*
505	* Flush the read and write queues. Signal
506	* the open queue so that those waiting for open
507	* to complete will see that the tty is closed.
508	*/
509	while ((ior = (io_req_t)dequeue_head(&tp->t_delayed_read)) != 0) {
510	ior->io_done = tty_close_read_reply;
511	iodone(ior);
512	}
513	while ((ior = (io_req_t)dequeue_head(&tp->t_delayed_write)) != 0) {
514	ior->io_done = tty_close_write_reply;
515	iodone(ior);
516	}
517	while ((ior = (io_req_t)dequeue_head(&tp->t_delayed_open)) != 0) {
518	ior->io_done = tty_close_open_reply;
519	iodone(ior);
520	}
521
522	/* Close down modem */
523	if (tp->t_mctl) {
524	(*tp->t_mctl)(tp, TM_BRK0x0200\|TM_RTS0x0004, DMBIC2);
525	if ((tp->t_state&(TS_HUPCLS0x00000200\|TS_WOPEN0x00000004)) \|\| (tp->t_state&TS_ISOPEN0x00000008)==0)
526	(*tp->t_mctl)(tp, TM_HUP0x0000, DMSET0);
527	}
528
529	/* only save buffering bit, and carrier */
530	tp->t_state = tp->t_state & (TS_MIN0x00004000\|TS_CARR_ON0x00000020);
531	}
532
533	/*
534	* Port-death routine to clean up reply messages.
535	*/
536	boolean_t
537	tty_queue_clean(
538	queue_t q,
539	ipc_port_t port,
540	boolean_t (*routine)(io_req_t) )
541	{
542	io_req_t ior;
543
544	ior = (io_req_t)queue_first(q)((q)->next);
545	while (!queue_end(q, (queue_entry_t)ior)((q) == ((queue_entry_t)ior))) {
546	if (ior->io_reply_port == port) {
547	remqueue(q, (queue_entry_t)ior);
548	ior->io_done = routine;
549	iodone(ior);
550	return TRUE((boolean_t) 1);
551	}
552	ior = ior->io_next;
553	}
554	return FALSE((boolean_t) 0);
555	}
556
557	/*
558	* Handle port-death (dead reply port) for tty.
559	* No locks may be held.
560	* May run on any CPU.
561	*/
562	boolean_t
563	tty_portdeath(
564	struct tty * tp,
565	ipc_port_t port)
566	{
567	spl_t spl = spltty();
568	boolean_t result;
569
570	simple_lock(&tp->t_lock);
571
572	/*
573	* The queues may never have been initialized
574	*/
575	if (tp->t_delayed_read.next == 0) {
576	result = FALSE((boolean_t) 0);
577	}
578	else {
579	result =
580	tty_queue_clean(&tp->t_delayed_read, port,
581	tty_close_read_reply)
582	\|\| tty_queue_clean(&tp->t_delayed_write, port,
583	tty_close_write_reply)
584	\|\| tty_queue_clean(&tp->t_delayed_open, port,
585	tty_close_open_reply);
586	}
587	simple_unlock(&tp->t_lock);
588	splx(spl);
589
590	return result;
591	}
592
593	/*
594	* Get TTY status.
595	* No locks may be held.
596	* May run on any CPU.
597	*/
598	io_return_t tty_get_status(
599	struct tty *tp,
600	dev_flavor_t flavor,
601	int * data, /* pointer to OUT array */
602	natural_t count) / out */
603	{
604	spl_t s;
605
606	switch (flavor) {
607	case TTY_STATUS(dev_flavor_t)(('t'<<16) + 1):
608	{
609	struct tty_status *tsp =
610	(struct tty_status *) data;
611
612	if (*count < TTY_STATUS_COUNT(sizeof(struct tty_status)/sizeof(int)))
613	return (D_INVALID_OPERATION2505);
614
615	s = spltty();
616	simple_lock(&tp->t_lock);
617
618	tsp->tt_ispeed = tp->t_ispeed;
619	tsp->tt_ospeed = tp->t_ospeed;
620	tsp->tt_breakc = tp->t_breakc;
621	tsp->tt_flags = tp->t_flags;
622	if (tp->t_state & TS_HUPCLS0x00000200)
623	tsp->tt_flags \|= TF_HUPCLS0x00000040;
624
625	simple_unlock(&tp->t_lock);
626	splx(s);
627
628	*count = TTY_STATUS_COUNT(sizeof(struct tty_status)/sizeof(int));
629	break;
630
631	}
632	default:
633	return D_INVALID_OPERATION2505;
634	}
635	return D_SUCCESS0;
636	}
637
638	/*
639	* Set TTY status.
640	* No locks may be held.
641	* Calls device start or stop routines; must already be on master if
642	* device needs to run on master.
643	*/
644	io_return_t tty_set_status(
645	struct tty *tp,
646	dev_flavor_t flavor,
647	int * data,
648	natural_t count)
649	{
650	int s;
651
652	switch (flavor) {
653	case TTY_FLUSH(dev_flavor_t)(('t'<<16) + 3):
654	{
655	int flags;
656	if (count < TTY_FLUSH_COUNT(1))
657	return D_INVALID_OPERATION2505;
658
659	flags = *data;
660	if (flags == 0)
661	flags = D_READ0x1 \| D_WRITE0x2;
662
663	s = spltty();
664	simple_lock(&tp->t_lock);
665	tty_flush(tp, flags);
666	simple_unlock(&tp->t_lock);
667	splx(s);
668
669	break;
670	}
671	case TTY_STOP(dev_flavor_t)(('t'<<16) + 4):
672	/* stop output */
673	s = spltty();
674	simple_lock(&tp->t_lock);
675	if ((tp->t_state & TS_TTSTOP0x00000100) == 0) {
676	tp->t_state \|= TS_TTSTOP0x00000100;
677	(*tp->t_stop)(tp, 0);
678	}
679	simple_unlock(&tp->t_lock);
680	splx(s);
681	break;
682
683	case TTY_START(dev_flavor_t)(('t'<<16) + 5):
684	/* start output */
685	s = spltty();
686	simple_lock(&tp->t_lock);
687	if (tp->t_state & TS_TTSTOP0x00000100) {
688	tp->t_state &= ~TS_TTSTOP0x00000100;
689	tty_output(tp);
690	}
691	simple_unlock(&tp->t_lock);
692	splx(s);
693	break;
694
695	case TTY_STATUS(dev_flavor_t)(('t'<<16) + 1):
696	/* set special characters and speed */
697	{
698	struct tty_status *tsp;
699
700	if (count < TTY_STATUS_COUNT(sizeof(struct tty_status)/sizeof(int)))
701	return D_INVALID_OPERATION2505;
702
703	tsp = (struct tty_status *)data;
704
705	if (tsp->tt_ispeed < 0 \|\|
706	tsp->tt_ispeed >= NSPEEDS18 \|\|
707	tsp->tt_ospeed < 0 \|\|
708	tsp->tt_ospeed >= NSPEEDS18)
709	{
710	return D_INVALID_OPERATION2505;
711	}
712
713	s = spltty();
714	simple_lock(&tp->t_lock);
715
716	tp->t_ispeed = tsp->tt_ispeed;
717	tp->t_ospeed = tsp->tt_ospeed;
718	tp->t_breakc = tsp->tt_breakc;
719	tp->t_flags = tsp->tt_flags & ~TF_HUPCLS0x00000040;
720	if (tsp->tt_flags & TF_HUPCLS0x00000040)
721	tp->t_state \|= TS_HUPCLS0x00000200;
722
723	simple_unlock(&tp->t_lock);
724	splx(s);
725	break;
726	}
727	default:
728	return D_INVALID_OPERATION2505;
729	}
730	return D_SUCCESS0;
731	}
732
733
734	/*
735	* [internal]
736	* Queue IOR on reply queue, to wait for TTY operation.
737	* TTY must be locked (at spltty).
738	*/
739	void queue_delayed_reply(
740	queue_t qh,
741	io_req_t ior,
742	boolean_t (*io_done)(io_req_t) )
743	{
744	ior->io_done = io_done;
745	enqueue_tail(qh, (queue_entry_t)ior);
746	}
747
748	/*
749	* Retry delayed IO operations for TTY.
750	* TTY containing queue must be locked (at spltty).
751	*/
752	void tty_queue_completion(
753	queue_t qh)
754	{
755	io_req_t ior;
756
757	while ((ior = (io_req_t)dequeue_head(qh)) != 0) {
758	iodone(ior);
759	}
760	}
761
762	/*
763	* Set the default special characters.
764	* Since this routine is called whenever a tty has never been opened,
765	* we can initialize the queues here.
766	*/
767	void ttychars(
768	struct tty *tp)
769	{
770	if ((tp->t_flags & TS_INIT0x00000001) == 0) {
771	/*
772	* Initialize queues
773	*/
774	queue_init(&tp->t_delayed_open)((&tp->t_delayed_open)->next = (&tp->t_delayed_open )->prev = &tp->t_delayed_open);
775	queue_init(&tp->t_delayed_read)((&tp->t_delayed_read)->next = (&tp->t_delayed_read )->prev = &tp->t_delayed_read);
776	queue_init(&tp->t_delayed_write)((&tp->t_delayed_write)->next = (&tp->t_delayed_write )->prev = &tp->t_delayed_write);
777
778	/*
779	* Initialize character buffers
780	*/
781	cb_alloc(&tp->t_inq, tty_inq_size);
782
783	/* if we might do modem flow control */
784	if (tp->t_mctl && tp->t_inq.c_hog > 30)
785	tp->t_inq.c_hog -= 30;
786
787	cb_alloc(&tp->t_outq, tty_outq_size);
788
789	/*
790	* Mark initialized
791	*/
792	tp->t_state \|= TS_INIT0x00000001;
793	}
794
795	tp->t_breakc = 0;
796	}
797
798	/*
799	* Flush all TTY queues.
800	* Called at spltty, tty already locked.
801	* Calls device STOP routine; must already be on master if
802	* device needs to run on master.
803	*/
804	void tty_flush(
805	struct tty *tp,
806	int rw)
807	{
808	if (rw & D_READ0x1) {
809	cb_clear(&tp->t_inq);
810	tty_queue_completion(&tp->t_delayed_read);
811	}
812	if (rw & D_WRITE0x2) {
813	tp->t_state &= ~TS_TTSTOP0x00000100;
814	(*tp->t_stop)(tp, rw);
815	cb_clear(&tp->t_outq);
816	tty_queue_completion(&tp->t_delayed_write);
817	}
818	}
819
820	/*
821	* Restart character output after a delay timeout.
822	* Calls device start routine - must be on master CPU.
823	*
824	* Timeout routines are called only on master CPU.
825	* What if device runs on a different CPU?
826	*/
827	void ttrstrt(
828	struct tty *tp)
829	{
830	spl_t s;
831
832	s = spltty();
833	simple_lock(&tp->t_lock);
834
835	tp->t_state &= ~TS_TIMEOUT0x00000002;
836	ttstart (tp);
837
838	simple_unlock(&tp->t_lock);
839	splx(s);
840	}
841
842	/*
843	* Start output on the typewriter. It is used from the top half
844	* after some characters have been put on the output queue,
845	* from the interrupt routine to transmit the next
846	* character, and after a timeout has finished.
847	*
848	* Called at spltty, tty already locked.
849	* Must be on master CPU if device runs on master.
850	*/
851	void ttstart(tp)
852	struct tty *tp;
853	{
854	if ((tp->t_state & (TS_TIMEOUT0x00000002\|TS_TTSTOP0x00000100\|TS_BUSY0x00000040)) == 0) {
855	/*
856	* Start up the hardware again
857	*/
858	(*tp->t_start)(tp);
859
860	/*
861	* Wake up those waiting for write completion.
862	*/
863	if (tp->t_outq.c_cc <= TTLOWAT(tp)ttlowat[(tp)->t_ospeed])
864	tty_queue_completion(&tp->t_delayed_write);
865	}
866	}
867
868	/*
869	* Start character output, if the device is not busy or
870	* stopped or waiting for a timeout.
871	*
872	* Called at spltty, tty already locked.
873	* Must be on master CPU if device runs on master.
874	*/
875	void tty_output(
876	struct tty *tp)
877	{
878	if ((tp->t_state & (TS_TIMEOUT0x00000002\|TS_TTSTOP0x00000100\|TS_BUSY0x00000040)) == 0) {
879	/*
880	* Not busy. Start output.
881	*/
882	(*tp->t_start)(tp);
883
884	/*
885	* Wake up those waiting for write completion.
886	*/
887	if (tp->t_outq.c_cc <= TTLOWAT(tp)ttlowat[(tp)->t_ospeed])
888	tty_queue_completion(&tp->t_delayed_write);
889	}
890	}
891
892	/*
893	* Send any buffered recvd chars up to user
894	*/
895	void ttypush(
896	void * _tp)
897	{
898	struct tty *tp = _tp;
899	spl_t s = spltty();
900	int state;
901
902	simple_lock(&tp->t_lock);
903
904	/*
905	The pdma timeout has gone off.
906	If no character has been received since the timeout
907	was set, push any pending characters up.
908	If any characters were received in the last interval
909	then just reset the timeout and the character received bit.
910	*/
911
912	state = tp->t_state;
913
914	if (state & TS_MIN_TO0x00008000)
915	{
916	if (state & TS_MIN_TO_RCV0x00400000)
917	{ /* a character was received */
918	tp->t_state = state & ~TS_MIN_TO_RCV0x00400000;
919	timeout(ttypush,tp,pdma_timeouts[tp->t_ispeed]);
920	}
921	else
922	{
923	tp->t_state = state & ~TS_MIN_TO0x00008000;
924	if (tp->t_inq.c_cc) /* pending characters */
925	tty_queue_completion(&tp->t_delayed_read);
926	}
927	}
928	else
929	{
930	tp->t_state = state & ~TS_MIN_TO_RCV0x00400000;/* sanity */
931	}
932
933	simple_unlock(&tp->t_lock);
934	splx(s);
935	}
936
937	/*
938	* Put input character on input queue.
939	*
940	* Called at spltty, tty already locked.
941	*/
942	void ttyinput(
943	unsigned int c,
944	struct tty *tp)
945	{
946	if (tp->t_inq.c_cc >= tp->t_inq.c_hog) {
947	/*
948	* Do not want to overflow input queue
949	*/
950	if (tp->t_mctl) {
951	(*tp->t_mctl)(tp, TM_RTS0x0004, DMBIC2);
952	tp->t_state \|= TS_RTS_DOWN0x00020000;
953	}
954	tty_queue_completion(&tp->t_delayed_read);
955	return;
956
957	}
958
959	c &= 0xff;
960
961	(void) putc(c, &tp->t_inq);
962	if ((tp->t_state & TS_MIN0x00004000) == 0 \|\|
963	tp->t_inq.c_cc > pdma_water_mark[tp->t_ispeed])
964	{
965	/*
966	* No input buffering, or input minimum exceeded.
967	* Grab a request from input queue and queue it
968	* to io_done thread.
969	*/
970	if (tp->t_state & TS_MIN_TO0x00008000) {
971	tp->t_state &= ~(TS_MIN_TO0x00008000\|TS_MIN_TO_RCV0x00400000);
972	untimeout(ttypush, tp);
973	}
974	tty_queue_completion(&tp->t_delayed_read);
975	}
976	else {
977	/*
978	* Not enough characters.
979	* If no timeout is set, initiate the timeout
980	* Otherwise set the character received during timeout interval
981	* flag.
982	* One alternative approach would be just to reset the timeout
983	* into the future, but this involves making a timeout/untimeout
984	* call on every character.
985	*/
986	int ptime = pdma_timeouts[tp->t_ispeed];
987	if (ptime > 0)
988	{
989	if ((tp->t_state & TS_MIN_TO0x00008000) == 0)
990	{
991	tp->t_state \|= TS_MIN_TO0x00008000;
992	timeout(ttypush, tp, ptime);
993	}
994	else
995	{
996	tp->t_state \|= TS_MIN_TO_RCV0x00400000;
997	}
998	}
999	}
1000	}
1001
1002	/*
1003	* Put many characters on input queue.
1004	*
1005	* Called at spltty, tty already locked.
1006	*/
1007	void ttyinput_many(
1008	struct tty *tp,
1009	char *chars,
1010	int count)
1011	{
1012	/*
1013	* Do not want to overflow input queue
1014	*/
1015	if (tp->t_inq.c_cc < tp->t_inq.c_hog)
1016	count -= b_to_q( chars, count, &tp->t_inq);
	Value stored to 'count' is never read
1017
1018	tty_queue_completion(&tp->t_delayed_read);
1019	}
1020
1021
1022	/*
1023	* Handle modem control transition on a tty.
1024	* Flag indicates new state of carrier.
1025	* Returns FALSE if the line should be turned off.
1026	*
1027	* Called at spltty, tty already locked.
1028	*/
1029	boolean_t ttymodem(
1030	struct tty * tp,
1031	boolean_t carrier_up)
1032	{
1033	if ((tp->t_state&TS_WOPEN0x00000004) == 0 && (tp->t_flags & MDMBUF0x00000010)) {
1034	/*
1035	* Flow control by carrier. Carrier down stops
1036	* output; carrier up restarts output.
1037	*/
1038	if (carrier_up) {
1039	tp->t_state &= ~TS_TTSTOP0x00000100;
1040	tty_output(tp);
1041	}
1042	else if ((tp->t_state&TS_TTSTOP0x00000100) == 0) {
1043	tp->t_state \|= TS_TTSTOP0x00000100;
1044	(*tp->t_stop)(tp, 0);
1045	}
1046	}
1047	else if (carrier_up) {
1048	/*
1049	* Carrier now on.
1050	*/
1051	tp->t_state \|= TS_CARR_ON0x00000020;
1052	tt_open_wakeup(tp)(tty_queue_completion(&(tp)->t_delayed_open));
1053	}
1054	else {
1055	/*
1056	* Lost carrier.
1057	*/
1058	tp->t_state &= ~TS_CARR_ON0x00000020;
1059	if (tp->t_state & TS_ISOPEN0x00000008 &&
1060	(tp->t_flags & NOHANG0x00000020) == 0)
1061	{
1062	/*
1063	* Hang up TTY if carrier drops.
1064	* Need to alert users, somehow...
1065	*/
1066	tty_flush(tp, D_READ0x1\|D_WRITE0x2);
1067	return FALSE((boolean_t) 0);
1068	}
1069	}
1070	return TRUE((boolean_t) 1);
1071	}
1072
1073	/*
1074	* Similarly, handle transitions on the ClearToSend
1075	* signal. Nowadays, it is used by many modems as
1076	* a flow-control device: they turn it down to stop
1077	* us from sending more chars. We do the same with
1078	* the RequestToSend signal. [Yes, that is exactly
1079	* why those signals are defined in the standard.]
1080	*
1081	* Tty must be locked and on master.
1082	*/
1083	void
1084	tty_cts(
1085	struct tty * tp,
1086	boolean_t cts_up)
1087	{
1088	if (tp->t_state & TS_ISOPEN0x00000008){
1089	if (cts_up) {
1090	tp->t_state &= ~(TS_TTSTOP0x00000100\|TS_BUSY0x00000040);
1091	tty_output(tp);
1092	} else {
1093	tp->t_state \|= (TS_TTSTOP0x00000100\|TS_BUSY0x00000040);
1094	(*tp->t_stop)(tp, D_WRITE0x2);
1095	}
1096	}
1097	}