/usr/src/sys/dev/usb/uaudio.c

Bug Summary

File:	dev/usb/uaudio.c
Warning:	line 3598, column 2 Value stored to 'nframes' is never read

Annotated Source Code

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clang -cc1 -cc1 -triple amd64-unknown-openbsd7.4 -analyze -disable-free -clear-ast-before-backend -disable-llvm-verifier -discard-value-names -main-file-name uaudio.c -analyzer-checker=core -analyzer-checker=apiModeling -analyzer-checker=unix -analyzer-checker=deadcode -analyzer-checker=security.insecureAPI.UncheckedReturn -analyzer-checker=security.insecureAPI.getpw -analyzer-checker=security.insecureAPI.gets -analyzer-checker=security.insecureAPI.mktemp -analyzer-checker=security.insecureAPI.mkstemp -analyzer-checker=security.insecureAPI.vfork -analyzer-checker=nullability.NullPassedToNonnull -analyzer-checker=nullability.NullReturnedFromNonnull -analyzer-output plist -w -setup-static-analyzer -mrelocation-model static -mframe-pointer=all -relaxed-aliasing -ffp-contract=on -fno-rounding-math -mconstructor-aliases -ffreestanding -mcmodel=kernel -target-cpu x86-64 -target-feature +retpoline-indirect-calls -target-feature +retpoline-indirect-branches -target-feature -sse2 -target-feature -sse -target-feature -3dnow -target-feature -mmx -target-feature +save-args -target-feature +retpoline-external-thunk -disable-red-zone -no-implicit-float -tune-cpu generic -debugger-tuning=gdb -fcoverage-compilation-dir=/usr/src/sys/arch/amd64/compile/GENERIC.MP/obj -nostdsysteminc -nobuiltininc -resource-dir /usr/local/llvm16/lib/clang/16 -I /usr/src/sys -I /usr/src/sys/arch/amd64/compile/GENERIC.MP/obj -I /usr/src/sys/arch -I /usr/src/sys/dev/pci/drm/include -I /usr/src/sys/dev/pci/drm/include/uapi -I /usr/src/sys/dev/pci/drm/amd/include/asic_reg -I /usr/src/sys/dev/pci/drm/amd/include -I /usr/src/sys/dev/pci/drm/amd/amdgpu -I /usr/src/sys/dev/pci/drm/amd/display -I /usr/src/sys/dev/pci/drm/amd/display/include -I /usr/src/sys/dev/pci/drm/amd/display/dc -I /usr/src/sys/dev/pci/drm/amd/display/amdgpu_dm -I /usr/src/sys/dev/pci/drm/amd/pm/inc -I /usr/src/sys/dev/pci/drm/amd/pm/legacy-dpm -I /usr/src/sys/dev/pci/drm/amd/pm/swsmu -I /usr/src/sys/dev/pci/drm/amd/pm/swsmu/inc -I /usr/src/sys/dev/pci/drm/amd/pm/swsmu/smu11 -I /usr/src/sys/dev/pci/drm/amd/pm/swsmu/smu12 -I /usr/src/sys/dev/pci/drm/amd/pm/swsmu/smu13 -I /usr/src/sys/dev/pci/drm/amd/pm/powerplay/inc -I /usr/src/sys/dev/pci/drm/amd/pm/powerplay/hwmgr -I /usr/src/sys/dev/pci/drm/amd/pm/powerplay/smumgr -I /usr/src/sys/dev/pci/drm/amd/pm/swsmu/inc -I /usr/src/sys/dev/pci/drm/amd/pm/swsmu/inc/pmfw_if -I /usr/src/sys/dev/pci/drm/amd/display/dc/inc -I /usr/src/sys/dev/pci/drm/amd/display/dc/inc/hw -I /usr/src/sys/dev/pci/drm/amd/display/dc/clk_mgr -I /usr/src/sys/dev/pci/drm/amd/display/modules/inc -I /usr/src/sys/dev/pci/drm/amd/display/modules/hdcp -I /usr/src/sys/dev/pci/drm/amd/display/dmub/inc -I /usr/src/sys/dev/pci/drm/i915 -D DDB -D DIAGNOSTIC -D KTRACE -D ACCOUNTING -D KMEMSTATS -D PTRACE -D POOL_DEBUG -D CRYPTO -D SYSVMSG -D SYSVSEM -D SYSVSHM -D UVM_SWAP_ENCRYPT -D FFS -D FFS2 -D FFS_SOFTUPDATES -D UFS_DIRHASH -D QUOTA -D EXT2FS -D MFS -D NFSCLIENT -D NFSSERVER -D CD9660 -D UDF -D MSDOSFS -D FIFO -D FUSE -D SOCKET_SPLICE -D TCP_ECN -D TCP_SIGNATURE -D INET6 -D IPSEC -D PPP_BSDCOMP -D PPP_DEFLATE -D PIPEX -D MROUTING -D MPLS -D BOOT_CONFIG -D USER_PCICONF -D APERTURE -D MTRR -D NTFS -D SUSPEND -D HIBERNATE -D PCIVERBOSE -D USBVERBOSE -D WSDISPLAY_COMPAT_USL -D WSDISPLAY_COMPAT_RAWKBD -D WSDISPLAY_DEFAULTSCREENS=6 -D X86EMU -D ONEWIREVERBOSE -D MULTIPROCESSOR -D MAXUSERS=80 -D _KERNEL -O2 -Wno-pointer-sign -Wno-address-of-packed-member -Wno-constant-conversion -Wno-unused-but-set-variable -Wno-gnu-folding-constant -fdebug-compilation-dir=/usr/src/sys/arch/amd64/compile/GENERIC.MP/obj -ferror-limit 19 -fwrapv -D_RET_PROTECTOR -ret-protector -fcf-protection=branch -fgnuc-version=4.2.1 -vectorize-loops -vectorize-slp -fno-builtin-malloc -fno-builtin-calloc -fno-builtin-realloc -fno-builtin-valloc -fno-builtin-free -fno-builtin-strdup -fno-builtin-strndup -analyzer-output=html -faddrsig -o /home/ben/Projects/scan/2024-01-11-110808-61670-1 -x c /usr/src/sys/dev/usb/uaudio.c

1	/* $OpenBSD: uaudio.c,v 1.174 2023/12/10 06:32:14 ratchov Exp $ */
2	/*
3	* Copyright (c) 2018 Alexandre Ratchov <alex@caoua.org>
4	*
5	* Permission to use, copy, modify, and distribute this software for any
6	* purpose with or without fee is hereby granted, provided that the above
7	* copyright notice and this permission notice appear in all copies.
8	*
9	* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
10	* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
11	* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
12	* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
13	* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
14	* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
15	* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
16	*/
17	/*
18	* The USB Audio Class (UAC) defines what is an audio device and how
19	* to use it. There are two versions of the UAC: v1.0 and v2.0. They
20	* are not compatible with each other but they are close enough to
21	* attempt to have the same driver for both.
22	*
23	*/
24	#include <sys/param.h>
25	#include <sys/types.h>
26	#include <sys/device.h>
27	#include <sys/errno.h>
28	#include <sys/fcntl.h>
29	#include <sys/malloc.h>
30	#include <sys/systm.h>
31	#include <sys/time.h>
32	#include <sys/audioio.h>
33	#include <machine/bus.h>
34	#include <dev/audio_if.h>
35	#include <dev/usb/usb.h>
36	#include <dev/usb/usbdi.h>
37	#include <dev/usb/usbdivar.h>
38	#include <dev/usb/usb_mem.h>
39
40	#ifdef UAUDIO_DEBUG
41	#define DPRINTF(...)do {} while(0) \
42	do { \
43	if (uaudio_debug) \
44	printf(__VA_ARGS__); \
45	} while (0)
46	#else
47	#define DPRINTF(...)do {} while(0) do {} while(0)
48	#endif
49
50	#define DEVNAME(sc)((sc)->dev.dv_xname) ((sc)->dev.dv_xname)
51
52	/*
53	* Isochronous endpoint usage (XXX: these belong to dev/usb/usb.h).
54	*/
55	#define UE_ISO_USAGE0x30 0x30
56	#define UE_ISO_USAGE_DATA0x00 0x00
57	#define UE_ISO_USAGE_FEEDBACK0x10 0x10
58	#define UE_ISO_USAGE_IMPL0x20 0x20
59	#define UE_GET_ISO_USAGE(a)((a) & 0x30) ((a) & UE_ISO_USAGE0x30)
60
61	/*
62	* Max length of unit names
63	*/
64	#define UAUDIO_NAMEMAX16 MAX_AUDIO_DEV_LEN16
65
66	/*
67	* USB audio class versions
68	*/
69	#define UAUDIO_V10x100 0x100
70	#define UAUDIO_V20x200 0x200
71
72	/*
73	* AC class-specific descriptor interface sub-type
74	*/
75	#define UAUDIO_AC_HEADER0x1 0x1
76	#define UAUDIO_AC_INPUT0x2 0x2
77	#define UAUDIO_AC_OUTPUT0x3 0x3
78	#define UAUDIO_AC_MIXER0x4 0x4
79	#define UAUDIO_AC_SELECTOR0x5 0x5
80	#define UAUDIO_AC_FEATURE0x6 0x6
81	#define UAUDIO_AC_EFFECT0x7 0x7
82	#define UAUDIO_AC_PROCESSING0x8 0x8
83	#define UAUDIO_AC_EXTENSION0x9 0x9
84	#define UAUDIO_AC_CLKSRC0xa 0xa
85	#define UAUDIO_AC_CLKSEL0xb 0xb
86	#define UAUDIO_AC_CLKMULT0xc 0xc
87	#define UAUDIO_AC_RATECONV0xd 0xd
88
89	/*
90	* AS class-specific interface sub-types
91	*/
92	#define UAUDIO_AS_GENERAL0x1 0x1
93	#define UAUDIO_AS_FORMAT0x2 0x2
94
95	/*
96	* AS class-specific endpoint sub-type
97	*/
98	#define UAUDIO_EP_GENERAL0x1 0x1
99
100	/*
101	* UAC v1 formats, wFormatTag is an enum
102	*/
103	#define UAUDIO_V1_FMT_PCM0x1 0x1
104	#define UAUDIO_V1_FMT_PCM80x2 0x2
105	#define UAUDIO_V1_FMT_FLOAT0x3 0x3
106	#define UAUDIO_V1_FMT_ALAW0x4 0x4
107	#define UAUDIO_V1_FMT_MULAW0x5 0x5
108
109	/*
110	* UAC v2 formats, bmFormats is a bitmap
111	*/
112	#define UAUDIO_V2_FMT_PCM0x01 0x01
113	#define UAUDIO_V2_FMT_PCM80x02 0x02
114	#define UAUDIO_V2_FMT_FLOAT0x04 0x04
115	#define UAUDIO_V2_FMT_ALAW0x08 0x08
116	#define UAUDIO_V2_FMT_MULAW0x10 0x10
117
118	/*
119	* AC requests
120	*/
121	#define UAUDIO_V1_REQ_SET_CUR0x01 0x01
122	#define UAUDIO_V1_REQ_SET_MIN0x02 0x02
123	#define UAUDIO_V1_REQ_SET_MAX0x03 0x03
124	#define UAUDIO_V1_REQ_SET_RES0x04 0x04
125	#define UAUDIO_V1_REQ_GET_CUR0x81 0x81
126	#define UAUDIO_V1_REQ_GET_MIN0x82 0x82
127	#define UAUDIO_V1_REQ_GET_MAX0x83 0x83
128	#define UAUDIO_V1_REQ_GET_RES0x84 0x84
129	#define UAUDIO_V2_REQ_CUR1 1
130	#define UAUDIO_V2_REQ_RANGES2 2
131
132	/*
133	* AC request "selector control"
134	*/
135	#define UAUDIO_V2_REQSEL_CLKFREQ1 1
136	#define UAUDIO_V2_REQSEL_CLKSEL1 1
137
138	/*
139	* AS class-specific endpoint attributes
140	*/
141	#define UAUDIO_EP_FREQCTL0x01 0x01
142
143	/*
144	* AC feature control selectors (aka wValue in the request)
145	*/
146	#define UAUDIO_REQSEL_MUTE0x01 0x01
147	#define UAUDIO_REQSEL_VOLUME0x02 0x02
148	#define UAUDIO_REQSEL_BASS0x03 0x03
149	#define UAUDIO_REQSEL_MID0x04 0x04
150	#define UAUDIO_REQSEL_TREBLE0x05 0x05
151	#define UAUDIO_REQSEL_EQ0x06 0x06
152	#define UAUDIO_REQSEL_AGC0x07 0x07
153	#define UAUDIO_REQSEL_DELAY0x08 0x08
154	#define UAUDIO_REQSEL_BASSBOOST0x09 0x09
155	#define UAUDIO_REQSEL_LOUDNESS0x0a 0x0a
156	#define UAUDIO_REQSEL_GAIN0x0b 0x0b
157	#define UAUDIO_REQSEL_GAINPAD0x0c 0x0c
158	#define UAUDIO_REQSEL_PHASEINV0x0d 0x0d
159
160	/*
161	* Endpoint (UAC v1) or clock-source unit (UAC v2) sample rate control
162	*/
163	#define UAUDIO_REQSEL_RATE0x01 0x01
164
165	/*
166	* Samples-per-frame are fractions. UAC v2.0 requires the denominator to
167	* be multiple of 2^16, as used in the sync pipe. On the other hand, to
168	* represent sample-per-frame of all rates we support, we need the
169	* denominator to be such that (rate / 1000) can be represented exactly,
170	* 80 works. So we use the least common multiplier of both.
171	*/
172	#define UAUDIO_SPF_DIV327680 327680
173
174	/*
175	* names of DAC and ADC unit names
176	*/
177	#define UAUDIO_NAME_PLAY"dac" "dac"
178	#define UAUDIO_NAME_REC"record" "record"
179
180	/*
181	* read/write pointers for secure sequential access of binary data,
182	* ex. usb descriptors, tables and alike. Bytes are read using the
183	* read pointer up to the write pointer.
184	*/
185	struct uaudio_blob {
186	unsigned char rptr, wptr;
187	};
188
189	/*
190	* Ranges of integer values used to represent controls values and
191	* sample frequencies.
192	*/
193	struct uaudio_ranges {
194	unsigned int nval;
195	struct uaudio_ranges_el {
196	struct uaudio_ranges_el *next;
197	int min, max, res;
198	} *el;
199	};
200
201	struct uaudio_softc {
202	struct device dev;
203	struct usbd_device *udev;
204	int version;
205
206	/*
207	* UAC exposes the device as a circuit of units. Input and
208	* output jacks are known as terminal units, others are
209	* processing units. The purpose of this driver is to give
210	* them reasonable names and expose them as mixer(1)
211	* controls. Control names are derived from the type of the
212	* unit and its role in the circuit.
213	*
214	* UAC v2.0 exposes also the clock circuitry using units, so
215	* selecting the sample rate also involves units usage.
216	*/
217	struct uaudio_unit {
218	struct uaudio_unit unit_next, src_next, *dst_next;
219	struct uaudio_unit src_list, dst_list;
220	char name[UAUDIO_NAMEMAX16];
221	unsigned int nch;
222	int type, id;
223
224	/* terminal or clock type */
225	unsigned int term;
226
227	/* clock source, if a terminal or selector */
228	struct uaudio_unit *clock;
229
230	/* sample rates, if this is a clock source */
231	struct uaudio_ranges rates;
232
233	/* mixer(4) bits */
234	#define UAUDIO_CLASS_OUT0 0
235	#define UAUDIO_CLASS_IN1 1
236	#define UAUDIO_CLASS_COUNT2 2
237	int mixer_class;
238	struct uaudio_mixent {
239	struct uaudio_mixent *next;
240	char *fname;
241	#define UAUDIO_MIX_SW0 0
242	#define UAUDIO_MIX_NUM1 1
243	#define UAUDIO_MIX_ENUM2 2
244	int type;
245	int chan;
246	int req_sel;
247	struct uaudio_ranges ranges;
248	} *mixent_list;
249	} *unit_list;
250
251	/*
252	* Current clock, UAC v2.0 only
253	*/
254	struct uaudio_unit *clock;
255
256	/*
257	* Number of input and output terminals
258	*/
259	unsigned int nin, nout;
260
261	/*
262	* When unique names are needed, they are generated using a
263	* base string suffixed with a number. Ex. "spkr5". The
264	* following structure is used to keep track of strings we
265	* allocated.
266	*/
267	struct uaudio_name {
268	struct uaudio_name *next;
269	char *templ;
270	unsigned int unit;
271	} *names;
272
273	/*
274	* Audio streaming (AS) alternate settings, i.e. stream format
275	* and USB-related parameters to use it.
276	*/
277	struct uaudio_alt {
278	struct uaudio_alt *next;
279	int ifnum, altnum;
280	int mode; /* one of AUMODE_{RECORD,PLAY} */
281	int data_addr; /* data endpoint address */
282	int sync_addr; /* feedback endpoint address */
283	int maxpkt; /* max supported bytes per frame */
284	int fps; /* USB (micro-)frames per second */
285	int bps, bits, nch; /* audio encoding */
286	int v1_rates; /* if UAC 1.0, bitmap of rates */
287	} *alts;
288
289	/*
290	* Audio parameters: play and record stream formats usable
291	* together.
292	*/
293	struct uaudio_params {
294	struct uaudio_params *next;
295	struct uaudio_alt palt, ralt;
296	int v1_rates;
297	} params_list, params;
298
299	/*
300	* One direction audio stream, aka "DMA" in progress
301	*/
302	struct uaudio_stream {
303	#define UAUDIO_NXFERS_MIN2 2
304	#define UAUDIO_NXFERS_MAX8 8
305	struct uaudio_xfer {
306	struct usbd_xfer *usb_xfer;
307	unsigned char *buf;
308	uint16_t *sizes;
309	unsigned int size; /* bytes requested */
310	unsigned int nframes; /* frames requested */
311	} data_xfers[UAUDIO_NXFERS_MAX8], sync_xfers[UAUDIO_NXFERS_MAX8];
312
313	/*
314	* We don't use all the data_xfers[] entries because
315	* we can't schedule too many frames in the usb
316	* controller.
317	*/
318	unsigned int nxfers;
319
320	unsigned int spf_remain; /* frac sample left */
321	unsigned int spf; /* avg samples per frame */
322	unsigned int spf_min, spf_max; /* allowed boundaries */
323
324	/*
325	* The max frame size we'll need (which may be lower
326	* than the maxpkt the usb pipe supports).
327	*/
328	unsigned int maxpkt;
329
330	/*
331	* max number of frames per xfer we'll need
332	*/
333	unsigned int nframes_max;
334
335	/*
336	* At usb2.0 speed, the number of (micro-)frames per
337	* transfer must correspond to 1ms, which is the usb1.1
338	* frame duration. This is required by lower level usb
339	* drivers.
340	*
341	* The nframes_mask variable is used to test if the
342	* number of frames per transfer is usable (by checking
343	* that least significant bits are zero). For instance,
344	* nframes_mask will be set to 0x0 on usb1.1 device and
345	* 0x7 on usb2.0 devices running at 8000 fps.
346	*/
347	unsigned int nframes_mask;
348
349	unsigned int data_nextxfer, sync_nextxfer;
350	struct usbd_pipe *data_pipe;
351	struct usbd_pipe *sync_pipe;
352	void (intr)(void );
353	void *arg;
354
355	/* audio ring extents, passed to trigger() methods */
356	unsigned char ring_start, ring_end;
357
358	/* pointer to first byte available */
359	unsigned char *ring_pos;
360
361	/* audio(9) block size in bytes */
362	int ring_blksz;
363
364	/* xfer position relative to block boundary */
365	int ring_offs;
366
367	/*
368	* As USB sample-per-frame is not constant, we must
369	* schedule transfers slightly larger that one audio
370	* block. This is the "safe" block size, that ensures
371	* the transfer will cross the audio block boundary.
372	*/
373	int safe_blksz;
374
375	/*
376	* Number of bytes completed, when it reaches a
377	* block size, we fire an audio(9) interrupt.
378	*/
379	int ring_icnt;
380
381	/*
382	* USB transfers are used as a FIFO which is the
383	* concatenation of all transfers. This is the write
384	* (read) position of the play (rec) stream
385	*/
386	unsigned int ubuf_xfer; /* xfer index */
387	unsigned int ubuf_pos; /* offset in bytes */
388	} pstream, rstream;
389
390	int ctl_ifnum; /* aka AC interface */
391
392	int mode; /* open() mode */
393	int trigger_mode; /* trigger() mode */
394
395	unsigned int rate; /* current sample rate */
396	unsigned int ufps; /* USB frames per second */
397	unsigned int sync_pktsz; /* size of sync packet */
398	unsigned int host_nframes; /* max frames we can schedule */
399
400	int diff_nsamp; /* samples play is ahead of rec */
401	int diff_nframes; /* frames play is ahead of rec */
402	unsigned int adjspf_age; /* frames since last uaudio_adjspf */
403
404	/*
405	* bytes pending to be copied to transfer buffer. This is play
406	* only, as recorded frames are copied as soon they are
407	* received.
408	*/
409	size_t copy_todo;
410	};
411
412	int uaudio_match(struct device , void , void *);
413	void uaudio_attach(struct device , struct device , void *);
414	int uaudio_detach(struct device *, int);
415
416	int uaudio_open(void *, int);
417	void uaudio_close(void *);
418	int uaudio_set_params(void , int, int, struct audio_params ,
419	struct audio_params *);
420	unsigned int uaudio_set_blksz(void *, int,
421	struct audio_params , struct audio_params , unsigned int);
422	int uaudio_trigger_output(void , void , void *, int,
423	void ()(void ), void , struct audio_params );
424	int uaudio_trigger_input(void , void , void *, int,
425	void ()(void ), void , struct audio_params );
426	void uaudio_copy_output(void *, size_t);
427	void uaudio_underrun(void *);
428	int uaudio_halt_output(void *);
429	int uaudio_halt_input(void *);
430	int uaudio_query_devinfo(void , struct mixer_devinfo );
431	int uaudio_get_port(void , struct mixer_ctrl );
432	int uaudio_set_port(void , struct mixer_ctrl );
433
434	int uaudio_process_unit(struct uaudio_softc *,
435	struct uaudio_unit *, int,
436	struct uaudio_blob,
437	struct uaudio_unit **);
438
439	void uaudio_pdata_intr(struct usbd_xfer , void , usbd_status);
440	void uaudio_rdata_intr(struct usbd_xfer , void , usbd_status);
441	void uaudio_psync_intr(struct usbd_xfer , void , usbd_status);
442
443	#ifdef UAUDIO_DEBUG
444	char *uaudio_isoname(int isotype);
445	char *uaudio_modename(int mode);
446	char *uaudio_usagename(int usage);
447	void uaudio_rates_print(int rates);
448	void uaudio_ranges_print(struct uaudio_ranges *r);
449	void uaudio_print_unit(struct uaudio_softc sc, struct uaudio_unit u);
450	void uaudio_mixer_print(struct uaudio_softc *sc);
451	void uaudio_conf_print(struct uaudio_softc *sc);
452
453	/*
454	* 0 - nothing, same as if UAUDIO_DEBUG isn't defined
455	* 1 - initialisations & setup
456	* 2 - audio(4) calls
457	* 3 - transfers
458	*/
459	int uaudio_debug = 1;
460	#endif
461
462	struct cfdriver uaudio_cd = {
463	NULL((void *)0), "uaudio", DV_DULL
464	};
465
466	const struct cfattach uaudio_ca = {
467	sizeof(struct uaudio_softc), uaudio_match, uaudio_attach, uaudio_detach
468	};
469
470	const struct audio_hw_if uaudio_hw_if = {
471	.open = uaudio_open,
472	.close = uaudio_close,
473	.set_params = uaudio_set_params,
474	.halt_output = uaudio_halt_output,
475	.halt_input = uaudio_halt_input,
476	.set_port = uaudio_set_port,
477	.get_port = uaudio_get_port,
478	.query_devinfo = uaudio_query_devinfo,
479	.trigger_output = uaudio_trigger_output,
480	.trigger_input = uaudio_trigger_input,
481	.copy_output = uaudio_copy_output,
482	.underrun = uaudio_underrun,
483	.set_blksz = uaudio_set_blksz,
484	};
485
486	/*
487	* To keep things simple, we support only the following rates, we
488	* don't care about continuous sample rates or other "advanced"
489	* features which complicate implementation.
490	*/
491	const int uaudio_rates[] = {
492	8000, 11025, 12000, 16000, 22050, 24000, 32000, 44100, 48000,
493	64000, 88200, 96000, 128000, 176400, 192000
494	};
495
496	/*
497	* Convert 8, 16, or 24-bit signed value to an int by expanding the
498	* sign bit.
499	*/
500	int
501	uaudio_sign_expand(unsigned int val, int opsize)
502	{
503	unsigned int s;
504
505	s = 1 << (8 * opsize - 1);
506	return (val ^ s) - s;
507	}
508
509	int
510	uaudio_req(struct uaudio_softc *sc,
511	unsigned int type,
512	unsigned int req,
513	unsigned int sel,
514	unsigned int chan,
515	unsigned int ifnum,
516	unsigned int id,
517	unsigned char *buf,
518	size_t size)
519	{
520	struct usb_device_request r;
521	int err;
522
523	r.bmRequestType = type;
524	r.bRequest = req;
525	USETW(r.wValue, sel << 8 \| chan)((u_int16_t )(r.wValue) = (sel << 8 \| chan));
526	USETW(r.wIndex, id << 8 \| ifnum)((u_int16_t )(r.wIndex) = (id << 8 \| ifnum));
527	USETW(r.wLength, size)((u_int16_t )(r.wLength) = (size));
528
529	DPRINTF("%s: type = 0x%x, req = 0x%x, val = 0x%x, "do {} while(0)
530	"index = 0x%x, size = %d\n", __func__,do {} while(0)
531	type, req, UGETW(r.wValue), UGETW(r.wIndex), UGETW(r.wLength))do {} while(0);
532
533	err = usbd_do_request(sc->udev, &r, buf);
534	if (err) {
535	DPRINTF("%s: failed: %s\n", __func__, usbd_errstr(err))do {} while(0);
536	return 0;
537	}
538	return 1;
539	}
540
541	/*
542	* Read a number of the given size (in bytes) from the given
543	* blob. Return 0 on error.
544	*/
545	int
546	uaudio_getnum(struct uaudio_blob p, unsigned int size, unsigned int ret)
547	{
548	unsigned int i, num = 0;
549
550	if (p->wptr - p->rptr < size) {
551	DPRINTF("%s: %d: too small\n", __func__, size)do {} while(0);
552	return 0;
553	}
554
555	for (i = 0; i < size; i++)
556	num \|= p->rptr++ << (8 i);
557
558	if (ret)
559	*ret = num;
560	return 1;
561	}
562
563	/*
564	* Read a USB descriptor from the given blob. Return 0 on error.
565	*/
566	int
567	uaudio_getdesc(struct uaudio_blob p, struct uaudio_blob ret)
568	{
569	unsigned int size;
570
571	if (!uaudio_getnum(p, 1, &size))
572	return 0;
573	if (size-- == 0) {
574	DPRINTF("%s: zero sized desc\n", __func__)do {} while(0);
575	return 0;
576	}
577	if (p->wptr - p->rptr < size) {
578	DPRINTF("%s: too small\n", __func__)do {} while(0);
579	return 0;
580	}
581	ret->rptr = p->rptr;
582	ret->wptr = p->rptr + size;
583	p->rptr += size;
584	return 1;
585	}
586
587	/*
588	* Find the unit with the given id, return NULL if not found.
589	*/
590	struct uaudio_unit *
591	uaudio_unit_byid(struct uaudio_softc *sc, unsigned int id)
592	{
593	struct uaudio_unit *u;
594
595	for (u = sc->unit_list; u != NULL((void *)0); u = u->unit_next) {
596	if (u->id == id)
597	break;
598	}
599	return u;
600	}
601
602	/*
603	* Return a terminal name for the given terminal type.
604	*/
605	char *
606	uaudio_tname(struct uaudio_softc *sc, unsigned int type, int isout)
607	{
608	unsigned int hi, lo;
609	char *name;
610
611	hi = type >> 8;
612	lo = type & 0xff;
613
614	/* usb data stream */
615	if (hi == 1)
616	return isout ? UAUDIO_NAME_REC"record" : UAUDIO_NAME_PLAY"dac";
617
618	/* if there is only one input (output) use "input" ("output") */
619	if (isout) {
620	if (sc->nout == 1)
621	return "output";
622	} else {
623	if (sc->nin == 1)
624	return "input";
625	}
626
627	/* determine name from USB terminal type */
628	switch (hi) {
629	case 2:
630	/* embedded inputs */
631	name = isout ? "mic-out" : "mic";
632	break;
633	case 3:
634	/* embedded outputs, mostly speakers, except 0x302 */
635	switch (lo) {
636	case 0x02:
637	name = isout ? "hp" : "hp-in";
638	break;
639	default:
640	name = isout ? "spkr" : "spkr-in";
641	break;
642	}
643	break;
644	case 4:
645	/* handsets and headset */
646	name = isout ? "spkr" : "mic";
647	break;
648	case 5:
649	/* phone line */
650	name = isout ? "phone-in" : "phone-out";
651	break;
652	case 6:
653	/* external sources/sinks */
654	switch (lo) {
655	case 0x02:
656	case 0x05:
657	case 0x06:
658	case 0x07:
659	case 0x09:
660	case 0x0a:
661	name = isout ? "dig-out" : "dig-in";
662	break;
663	default:
664	name = isout ? "line-out" : "line-in";
665	break;
666	}
667	break;
668	case 7:
669	/* internal devices */
670	name = isout ? "int-out" : "int-in";
671	break;
672	default:
673	name = isout ? "unk-out" : "unk-in";
674	}
675	return name;
676	}
677
678	/*
679	* Return a clock name for the given clock type.
680	*/
681	char *
682	uaudio_clkname(unsigned int attr)
683	{
684	static char *names[] = {"ext", "fixed", "var", "prog"};
685
686	return names[attr & 3];
687	}
688
689	/*
690	* Return an unique name for the given template.
691	*/
692	void
693	uaudio_mkname(struct uaudio_softc sc, char templ, char *res)
694	{
695	struct uaudio_name *n;
696	char *sep;
697
698	/*
699	* if this is not a terminal name (i.e. there's a underscore
700	* in the name, like in "spkr2_mic3"), then use underscore as
701	* separator to avoid concatenating two numbers
702	*/
703	sep = strchr(templ, '_') != NULL((void *)0) ? "_" : "";
704
705	n = sc->names;
706	while (1) {
707	if (n == NULL((void *)0)) {
708	n = malloc(sizeof(struct uaudio_name),
709	M_USBDEV102, M_WAITOK0x0001);
710	n->templ = templ;
711	n->unit = 0;
712	n->next = sc->names;
713	sc->names = n;
714	}
715	if (strcmp(n->templ, templ) == 0)
716	break;
717	n = n->next;
718	}
719	if (n->unit == 0)
720	snprintf(res, UAUDIO_NAMEMAX16, "%s", templ);
721	else
722	snprintf(res, UAUDIO_NAMEMAX16, "%s%s%u", templ, sep, n->unit);
723	n->unit++;
724	}
725
726	/*
727	* Convert UAC v1.0 feature bitmap to UAC v2.0 feature bitmap.
728	*/
729	unsigned int
730	uaudio_feature_fixup(struct uaudio_softc *sc, unsigned int ctl)
731	{
732	int i;
733	unsigned int bits, n;
734
735	switch (sc->version) {
736	case UAUDIO_V10x100:
737	n = 0;
738	for (i = 0; i < 16; i++) {
739	bits = (ctl >> i) & 1;
740	if (bits)
741	bits \|= 2;
742	n \|= bits << (2 * i);
743	}
744	return n;
745	case UAUDIO_V20x200:
746	break;
747	}
748	return ctl;
749	}
750
751	/*
752	* Initialize a uaudio_ranges to the empty set
753	*/
754	void
755	uaudio_ranges_init(struct uaudio_ranges *r)
756	{
757	r->el = NULL((void *)0);
758	r->nval = 0;
759	}
760
761	/*
762	* Add the given range to the uaudio_ranges structures. Ranges are
763	* not supposed to overlap (required by USB spec). If they do we just
764	* return.
765	*/
766	void
767	uaudio_ranges_add(struct uaudio_ranges *r, int min, int max, int res)
768	{
769	struct uaudio_ranges_el e, *pe;
770
771	if (min > max) {
772	DPRINTF("%s: [%d:%d]/%d: bad range\n", __func__,do {} while(0)
773	min, max, res)do {} while(0);
774	return;
775	}
776
777	for (pe = &r->el; (e = pe) != NULL((void )0); pe = &e->next) {
778	if (min <= e->max && max >= e->min) {
779	DPRINTF("%s: overlapping ranges\n", __func__)do {} while(0);
780	return;
781	}
782	if (min < e->max)
783	break;
784	}
785
786	/* XXX: use 'res' here */
787	r->nval += max - min + 1;
788
789	e = malloc(sizeof(struct uaudio_ranges_el), M_USBDEV102, M_WAITOK0x0001);
790	e->min = min;
791	e->max = max;
792	e->res = res;
793	e->next = *pe;
794	*pe = e;
795	}
796
797	/*
798	* Free all ranges making the uaudio_ranges the empty set
799	*/
800	void
801	uaudio_ranges_clear(struct uaudio_ranges *r)
802	{
803	struct uaudio_ranges_el *e;
804
805	while ((e = r->el) != NULL((void *)0)) {
806	r->el = e->next;
807	free(e, M_USBDEV102, sizeof(struct uaudio_ranges_el));
808	}
809	r->nval = 0;
810	}
811
812	/*
813	* Convert a value in the given uaudio_ranges, into a 0..255 integer
814	* suitable for mixer usage
815	*/
816	int
817	uaudio_ranges_decode(struct uaudio_ranges *r, int val)
818	{
819	struct uaudio_ranges_el *e;
820	int diff, pos;
821
822	pos = 0;
823
824	for (e = r->el; e != NULL((void *)0); e = e->next) {
825	if (val >= e->min && val <= e->max) {
826	pos += val - e->min;
827	return (r->nval == 1) ? 0 :
828	(pos * 255 + (r->nval - 1) / 2) / (r->nval - 1);
829	}
830	diff = e->max - e->min + 1;
831	pos += diff;
832	}
833	return 0;
834	}
835
836	/*
837	* Convert a 0..255 to a value in the uaudio_ranges suitable for a USB
838	* request.
839	*/
840	unsigned int
841	uaudio_ranges_encode(struct uaudio_ranges *r, int val)
842	{
843	struct uaudio_ranges_el *e;
844	int diff, pos;
845
846	pos = (val * (r->nval - 1) + 127) / 255;
847
848	for (e = r->el; e != NULL((void *)0); e = e->next) {
849	diff = e->max - e->min + 1;
850	if (pos < diff)
851	return e->min + pos;
852	pos -= diff;
853	}
854	return 0;
855	}
856
857	/*
858	* Return the bitmap of supported rates included in the given ranges.
859	* This is not a mixer thing, UAC v2.0 uses ranges to report sample
860	* rates.
861	*/
862	int
863	uaudio_ranges_getrates(struct uaudio_ranges *r,
864	unsigned int mult, unsigned int div)
865	{
866	struct uaudio_ranges_el *e;
867	int rates, i, v;
868
869	rates = 0;
870
871	for (e = r->el; e != NULL((void *)0); e = e->next) {
872	for (i = 0; i < nitems(uaudio_rates)(sizeof((uaudio_rates)) / sizeof((uaudio_rates)[0])); i++) {
873	v = (unsigned long long)uaudio_rates[i] * mult / div;
874	if (v < e->min \|\| v > e->max)
875	continue;
876	if (e->res == 0 \|\| v - e->min % e->res == 0)
877	rates \|= 1 << i;
878	}
879	}
880
881	return rates;
882	}
883
884	/*
885	* Return the index in the uaudio_rates[] array of rate closest to the
886	* given rate in Hz.
887	*/
888	int
889	uaudio_rates_indexof(int mask, int rate)
890	{
891	int i, diff, best_index, best_diff;
892
893	best_index = -1;
894	best_diff = INT_MAX0x7fffffff;
895	for (i = 0; i < nitems(uaudio_rates)(sizeof((uaudio_rates)) / sizeof((uaudio_rates)[0])); i++) {
896	if ((mask & (1 << i)) == 0)
897	continue;
898	diff = uaudio_rates[i] - rate;
899	if (diff < 0)
900	diff = -diff;
901	if (diff < best_diff) {
902	best_index = i;
903	best_diff = diff;
904	}
905	}
906	return best_index;
907	}
908
909	/*
910	* Do a request that results in a uaudio_ranges. On UAC v1.0, this is
911	* simply a min/max/res triplet. On UAC v2.0, this is an array of
912	* min/max/res triplets.
913	*/
914	int
915	uaudio_req_ranges(struct uaudio_softc *sc,
916	unsigned int opsize,
917	unsigned int sel,
918	unsigned int chan,
919	unsigned int ifnum,
920	unsigned int id,
921	struct uaudio_ranges *r)
922	{
923	unsigned char req_buf[16], req = NULL((void )0);
924	size_t req_size;
925	struct uaudio_blob p;
926	unsigned int count, min, max, res;
927	int i;
928
929	switch (sc->version) {
930	case UAUDIO_V10x100:
931	count = 1;
932	req = req_buf;
933	p.rptr = p.wptr = req;
934	if (!uaudio_req(sc, UT_READ_CLASS_INTERFACE(0x80 \| 0x20 \| 0x01),
935	UAUDIO_V1_REQ_GET_MIN0x82, sel, chan,
936	ifnum, id, p.wptr, opsize))
937	return 0;
938	p.wptr += opsize;
939	if (!uaudio_req(sc, UT_READ_CLASS_INTERFACE(0x80 \| 0x20 \| 0x01),
940	UAUDIO_V1_REQ_GET_MAX0x83, sel, chan,
941	ifnum, id, p.wptr, opsize))
942	return 0;
943	p.wptr += opsize;
944	if (!uaudio_req(sc, UT_READ_CLASS_INTERFACE(0x80 \| 0x20 \| 0x01),
945	UAUDIO_V1_REQ_GET_RES0x84, sel, chan,
946	ifnum, id, p.wptr, opsize))
947	return 0;
948	p.wptr += opsize;
949	break;
950	case UAUDIO_V20x200:
951	/* fetch the ranges count only (first 2 bytes) */
952	if (!uaudio_req(sc, UT_READ_CLASS_INTERFACE(0x80 \| 0x20 \| 0x01),
953	UAUDIO_V2_REQ_RANGES2, sel, chan,
954	ifnum, id, req_buf, 2))
955	return 0;
956
957	/* count is at most 65535 */
958	count = req_buf[0] \| req_buf[1] << 8;
959
960	/* restart the request on a large enough buffer */
961	req_size = 2 + 3 * opsize * count;
962	if (sizeof(req_buf) >= req_size)
963	req = req_buf;
964	else
965	req = malloc(req_size, M_USBDEV102, M_WAITOK0x0001);
966
967	p.rptr = p.wptr = req;
968	if (!uaudio_req(sc, UT_READ_CLASS_INTERFACE(0x80 \| 0x20 \| 0x01),
969	UAUDIO_V2_REQ_RANGES2, sel, chan,
970	ifnum, id, p.wptr, req_size))
971	return 0;
972	p.wptr += req_size;
973
974	/* skip initial 2 bytes of count */
975	p.rptr += 2;
976	break;
977	}
978
979	for (i = 0; i < count; i++) {
980	if (!uaudio_getnum(&p, opsize, &min))
981	return 0;
982	if (!uaudio_getnum(&p, opsize, &max))
983	return 0;
984	if (!uaudio_getnum(&p, opsize, &res))
985	return 0;
986	uaudio_ranges_add(r,
987	uaudio_sign_expand(min, opsize),
988	uaudio_sign_expand(max, opsize),
989	uaudio_sign_expand(res, opsize));
990	}
991
992	if (req != req_buf)
993	free(req, M_USBDEV102, req_size);
994
995	return 1;
996	}
997
998	/*
999	* Return the rates bitmap of the given interface alt setting
1000	*/
1001	int
1002	uaudio_alt_getrates(struct uaudio_softc sc, struct uaudio_alt p)
1003	{
1004	struct uaudio_unit *u;
1005	unsigned int mult = 1, div = 1;
1006
1007	switch (sc->version) {
1008	case UAUDIO_V10x100:
1009	return p->v1_rates;
1010	case UAUDIO_V20x200:
1011	u = sc->clock;
1012	while (1) {
1013	switch (u->type) {
1014	case UAUDIO_AC_CLKSRC0xa:
1015	return uaudio_ranges_getrates(&u->rates,
1016	mult, div);
1017	case UAUDIO_AC_CLKSEL0xb:
1018	u = u->clock;
1019	break;
1020	case UAUDIO_AC_CLKMULT0xc:
1021	case UAUDIO_AC_RATECONV0xd:
1022	/* XXX: adjust rate with multiplier */
1023	u = u->src_list;
1024	break;
1025	default:
1026	DPRINTF("%s: no clock\n", __func__)do {} while(0);
1027	return 0;
1028	}
1029	}
1030	}
1031	return 0;
1032	}
1033
1034	/*
1035	* return the clock unit of the given terminal unit (v2 only)
1036	*/
1037	int
1038	uaudio_clock_id(struct uaudio_softc *sc)
1039	{
1040	struct uaudio_unit *u;
1041
1042	u = sc->clock;
1043	while (1) {
1044	if (u == NULL((void *)0)) {
1045	DPRINTF("%s: NULL clock pointer\n", __func__)do {} while(0);
1046	return -1;
1047	}
1048	switch (u->type) {
1049	case UAUDIO_AC_CLKSRC0xa:
1050	return u->id;
1051	case UAUDIO_AC_CLKSEL0xb:
1052	u = u->clock;
1053	break;
1054	case UAUDIO_AC_CLKMULT0xc:
1055	case UAUDIO_AC_RATECONV0xd:
1056	u = u->src_list;
1057	break;
1058	default:
1059	DPRINTF("%s: no clock\n", __func__)do {} while(0);
1060	return -1;
1061	}
1062	}
1063	}
1064
1065	/*
1066	* Return the rates bitmap of the given parameters setting
1067	*/
1068	int
1069	uaudio_getrates(struct uaudio_softc sc, struct uaudio_params p)
1070	{
1071	switch (sc->version) {
1072	case UAUDIO_V10x100:
1073	return p->v1_rates;
1074	case UAUDIO_V20x200:
1075	return uaudio_alt_getrates(sc, p->palt ? p->palt : p->ralt);
1076	}
1077	return 0;
1078	}
1079
1080	/*
1081	* Add the given feature (aka mixer control) to the given unit.
1082	*/
1083	void
1084	uaudio_feature_addent(struct uaudio_softc *sc,
1085	struct uaudio_unit *u, int uac_type, int chan)
1086	{
1087	static struct {
1088	char *name;
1089	int mix_type;
1090	int req_sel;
1091	} features[] = {
1092	{"mute", UAUDIO_MIX_SW0, UAUDIO_REQSEL_MUTE0x01},
1093	{"level", UAUDIO_MIX_NUM1, UAUDIO_REQSEL_VOLUME0x02},
1094	{"bass", UAUDIO_MIX_NUM1, UAUDIO_REQSEL_BASS0x03},
1095	{"mid", UAUDIO_MIX_NUM1, UAUDIO_REQSEL_MID0x04},
1096	{"treble", UAUDIO_MIX_NUM1, UAUDIO_REQSEL_TREBLE0x05},
1097	{"eq", UAUDIO_MIX_NUM1, UAUDIO_REQSEL_EQ0x06},
1098	{"agc", UAUDIO_MIX_SW0, UAUDIO_REQSEL_AGC0x07},
1099	{NULL((void )0), -1, -1}, / delay */
1100	{"bassboost", UAUDIO_MIX_SW0, UAUDIO_REQSEL_BASSBOOST0x09},
1101	{"loud", UAUDIO_MIX_SW0, UAUDIO_REQSEL_LOUDNESS0x0a},
1102	{"gain", UAUDIO_MIX_NUM1, UAUDIO_REQSEL_GAIN0x0b},
1103	{"gainpad", UAUDIO_MIX_SW0, UAUDIO_REQSEL_GAINPAD0x0c},
1104	{"phase", UAUDIO_MIX_SW0, UAUDIO_REQSEL_PHASEINV0x0d},
1105	{NULL((void )0), -1, -1}, / underflow */
1106	{NULL((void )0), -1, -1} / overflow */
1107	};
1108	struct uaudio_mixent m, i, **pi;
1109	int cmp;
1110
1111	if (uac_type >= sizeof(features) / sizeof(features[0])) {
1112	printf("%s: skipped unknown feature\n", DEVNAME(sc)((sc)->dev.dv_xname));
1113	return;
1114	}
1115
1116	m = malloc(sizeof(struct uaudio_mixent), M_USBDEV102, M_WAITOK0x0001);
1117	m->chan = chan;
1118	m->fname = features[uac_type].name;
1119	m->type = features[uac_type].mix_type;
1120	m->req_sel = features[uac_type].req_sel;
1121	uaudio_ranges_init(&m->ranges);
1122
1123	if (m->type == UAUDIO_MIX_NUM1) {
1124	if (!uaudio_req_ranges(sc, 2,
1125	m->req_sel, chan < 0 ? 0 : chan + 1,
1126	sc->ctl_ifnum, u->id,
1127	&m->ranges)) {
1128	printf("%s: failed to get ranges for %s control\n",
1129	DEVNAME(sc)((sc)->dev.dv_xname), m->fname);
1130	free(m, M_USBDEV102, sizeof(struct uaudio_mixent));
1131	return;
1132	}
1133	if (m->ranges.el == NULL((void *)0)) {
1134	printf("%s: skipped %s control with empty range\n",
1135	DEVNAME(sc)((sc)->dev.dv_xname), m->fname);
1136	free(m, M_USBDEV102, sizeof(struct uaudio_mixent));
1137	return;
1138	}
1139	#ifdef UAUDIO_DEBUG
1140	if (uaudio_debug)
1141	uaudio_ranges_print(&m->ranges);
1142	#endif
1143	}
1144
1145	/*
1146	* Add to unit's mixer controls list, sorting entries by name
1147	* and increasing channel number.
1148	*/
1149	for (pi = &u->mixent_list; (i = pi) != NULL((void )0); pi = &i->next) {
1150	cmp = strcmp(i->fname, m->fname);
1151	if (cmp == 0)
1152	cmp = i->chan - m->chan;
1153	if (cmp == 0) {
1154	DPRINTF("%02u: %s.%s: duplicate feature for chan %d\n",do {} while(0)
1155	u->id, u->name, m->fname, m->chan)do {} while(0);
1156	free(m, M_USBDEV102, sizeof(struct uaudio_mixent));
1157	return;
1158	}
1159	if (cmp > 0)
1160	break;
1161	}
1162	m->next = *pi;
1163	*pi = m;
1164
1165	DPRINTF("\t%s[%d]\n", m->fname, m->chan)do {} while(0);
1166	}
1167
1168	/*
1169	* For the given unit, parse the list of its sources and recursively
1170	* call uaudio_process_unit() for each.
1171	*/
1172	int
1173	uaudio_process_srcs(struct uaudio_softc *sc,
1174	struct uaudio_unit *u, struct uaudio_blob units,
1175	struct uaudio_blob *p)
1176	{
1177	struct uaudio_unit s, *ps;
1178	unsigned int i, npin, sid;
1179
1180	if (!uaudio_getnum(p, 1, &npin))
1181	return 0;
1182	ps = &u->src_list;
1183	for (i = 0; i < npin; i++) {
1184	if (!uaudio_getnum(p, 1, &sid))
1185	return 0;
1186	if (!uaudio_process_unit(sc, u, sid, units, &s))
1187	return 0;
1188	s->src_next = NULL((void *)0);
1189	*ps = s;
1190	ps = &s->src_next;
1191	}
1192	return 1;
1193	}
1194
1195	/*
1196	* Parse the number of channels.
1197	*/
1198	int
1199	uaudio_process_nch(struct uaudio_softc *sc,
1200	struct uaudio_unit u, struct uaudio_blob p)
1201	{
1202	if (!uaudio_getnum(p, 1, &u->nch))
1203	return 0;
1204	/* skip junk */
1205	switch (sc->version) {
1206	case UAUDIO_V10x100:
1207	if (!uaudio_getnum(p, 2, NULL((void )0))) / bmChannelConfig */
1208	return 0;
1209	break;
1210	case UAUDIO_V20x200:
1211	if (!uaudio_getnum(p, 4, NULL((void )0))) / wChannelConfig */
1212	return 0;
1213	break;
1214	}
1215	if (!uaudio_getnum(p, 1, NULL((void )0))) / iChannelNames */
1216	return 0;
1217	return 1;
1218	}
1219
1220	/*
1221	* Find the AC class-specific descriptor for this unit id.
1222	*/
1223	int
1224	uaudio_unit_getdesc(struct uaudio_softc *sc, int id,
1225	struct uaudio_blob units,
1226	struct uaudio_blob *p,
1227	unsigned int *rtype)
1228	{
1229	unsigned int i, type, subtype;
1230
1231	/*
1232	* Find the usb descriptor for this id.
1233	*/
1234	while (1) {
1235	if (units.rptr == units.wptr) {
1236	DPRINTF("%s: %02u: not found\n", __func__, id)do {} while(0);
1237	return 0;
1238	}
1239	if (!uaudio_getdesc(&units, p))
1240	return 0;
1241	if (!uaudio_getnum(p, 1, &type))
1242	return 0;
1243	if (!uaudio_getnum(p, 1, &subtype))
1244	return 0;
1245	if (!uaudio_getnum(p, 1, &i))
1246	return 0;
1247	if (i == id)
1248	break;
1249	}
1250	*rtype = subtype;
1251	return 1;
1252	}
1253
1254	/*
1255	* Parse a unit, possibly calling uaudio_process_unit() for each of
1256	* its sources.
1257	*/
1258	int
1259	uaudio_process_unit(struct uaudio_softc *sc,
1260	struct uaudio_unit *dest, int id,
1261	struct uaudio_blob units,
1262	struct uaudio_unit **rchild)
1263	{
1264	struct uaudio_blob p;
1265	struct uaudio_unit u, s;
1266	unsigned int i, j, size, ctl, type, subtype, assoc, clk;
1267	#ifdef UAUDIO_DEBUG
1268	unsigned int bit;
1269	#endif
1270
1271	if (!uaudio_unit_getdesc(sc, id, units, &p, &subtype))
1272	return 0;
1273
1274	/*
1275	* find this unit on the list as it may be already processed as
1276	* the source of another destination
1277	*/
1278	u = uaudio_unit_byid(sc, id);
1279	if (u == NULL((void *)0)) {
1280	u = malloc(sizeof(struct uaudio_unit), M_USBDEV102, M_WAITOK0x0001);
1281	u->id = id;
1282	u->type = subtype;
1283	u->term = 0;
1284	u->src_list = NULL((void *)0);
1285	u->dst_list = NULL((void *)0);
1286	u->clock = NULL((void *)0);
1287	u->mixent_list = NULL((void *)0);
1288	u->nch = 0;
1289	u->name[0] = 0;
1290	uaudio_ranges_init(&u->rates);
1291	u->unit_next = sc->unit_list;
1292	sc->unit_list = u;
1293	} else {
1294	switch (u->type) {
1295	case UAUDIO_AC_CLKSRC0xa:
1296	case UAUDIO_AC_CLKSEL0xb:
1297	case UAUDIO_AC_CLKMULT0xc:
1298	case UAUDIO_AC_RATECONV0xd:
1299	/* not using 'dest' list */
1300	*rchild = u;
1301	return 1;
1302	}
1303	}
1304
1305	if (dest) {
1306	dest->dst_next = u->dst_list;
1307	u->dst_list = dest;
1308	if (dest->dst_next != NULL((void *)0)) {
1309	/* already seen */
1310	*rchild = u;
1311	return 1;
1312	}
1313	}
1314
1315	switch (u->type) {
1316	case UAUDIO_AC_INPUT0x2:
1317	if (!uaudio_getnum(&p, 2, &u->term))
1318	return 0;
1319	if (!uaudio_getnum(&p, 1, &assoc))
1320	return 0;
1321	if (u->term >> 8 != 1)
1322	sc->nin++;
1323	switch (sc->version) {
1324	case UAUDIO_V10x100:
1325	break;
1326	case UAUDIO_V20x200:
1327	if (!uaudio_getnum(&p, 1, &clk))
1328	return 0;
1329	if (!uaudio_process_unit(sc, NULL((void *)0),
1330	clk, units, &u->clock))
1331	return 0;
1332	break;
1333	}
1334	if (!uaudio_getnum(&p, 1, &u->nch))
1335	return 0;
1336	DPRINTF("%02u: "do {} while(0)
1337	"in, nch = %d, term = 0x%x, assoc = %d\n",do {} while(0)
1338	u->id, u->nch, u->term, assoc)do {} while(0);
1339	break;
1340	case UAUDIO_AC_OUTPUT0x3:
1341	if (!uaudio_getnum(&p, 2, &u->term))
1342	return 0;
1343	if (!uaudio_getnum(&p, 1, &assoc))
1344	return 0;
1345	if (!uaudio_getnum(&p, 1, &id))
1346	return 0;
1347	if (!uaudio_process_unit(sc, u, id, units, &s))
1348	return 0;
1349	if (u->term >> 8 != 1)
1350	sc->nout++;
1351	switch (sc->version) {
1352	case UAUDIO_V10x100:
1353	break;
1354	case UAUDIO_V20x200:
1355	if (!uaudio_getnum(&p, 1, &clk))
1356	return 0;
1357	if (!uaudio_process_unit(sc, NULL((void *)0),
1358	clk, units, &u->clock))
1359	return 0;
1360	break;
1361	}
1362	u->src_list = s;
1363	s->src_next = NULL((void *)0);
1364	u->nch = s->nch;
1365	DPRINTF("%02u: "do {} while(0)
1366	"out, id = %d, nch = %d, term = 0x%x, assoc = %d\n",do {} while(0)
1367	u->id, id, u->nch, u->term, assoc)do {} while(0);
1368	break;
1369	case UAUDIO_AC_MIXER0x4:
1370	if (!uaudio_process_srcs(sc, u, units, &p))
1371	return 0;
1372	if (!uaudio_process_nch(sc, u, &p))
1373	return 0;
1374	DPRINTF("%02u: mixer, nch = %u:\n", u->id, u->nch)do {} while(0);
1375
1376	#ifdef UAUDIO_DEBUG
1377	/*
1378	* Print the list of available mixer's unit knobs (a bit
1379	* matrix). Matrix mixers are rare because levels are
1380	* already controlled by feature units, making the mixer
1381	* knobs redundant with the feature's knobs. So, for
1382	* now, we don't add clutter to the mixer(4) interface
1383	* and ignore all knobs. Other popular OSes doesn't
1384	* seem to expose them either.
1385	*/
1386	bit = 0;
1387	for (s = u->src_list; s != NULL((void *)0); s = s->src_next) {
1388	for (i = 0; i < s->nch; i++) {
1389	for (j = 0; j < u->nch; j++) {
1390	if ((bit++ & 7) == 0) {
1391	if (!uaudio_getnum(&p, 1, &ctl))
1392	return 0;
1393	}
1394	if (ctl & 0x80)
1395	DPRINTF("\t%02u[%d] -> [%d]\n",do {} while(0)
1396	s->id, i, j)do {} while(0);
1397	ctl <<= 1;
1398	}
1399	}
1400	}
1401	#endif
1402	break;
1403	case UAUDIO_AC_SELECTOR0x5:
1404	/*
1405	* Selectors are extremely rare, so not supported yet.
1406	*/
1407	if (!uaudio_process_srcs(sc, u, units, &p))
1408	return 0;
1409	if (u->src_list == NULL((void *)0)) {
1410	printf("%s: selector %02u has no sources\n",
1411	DEVNAME(sc)((sc)->dev.dv_xname), u->id);
1412	return 0;
1413	}
1414	u->nch = u->src_list->nch;
1415	DPRINTF("%02u: selector, nch = %u\n", u->id, u->nch)do {} while(0);
1416	break;
1417	case UAUDIO_AC_FEATURE0x6:
1418	if (!uaudio_getnum(&p, 1, &id))
1419	return 0;
1420	if (!uaudio_process_unit(sc, u, id, units, &s))
1421	return 0;
1422	s->src_next = u->src_list;
1423	u->src_list = s;
1424	u->nch = s->nch;
1425	switch (sc->version) {
1426	case UAUDIO_V10x100:
1427	if (!uaudio_getnum(&p, 1, &size))
1428	return 0;
1429	break;
1430	case UAUDIO_V20x200:
1431	size = 4;
1432	break;
1433	}
1434	DPRINTF("%02d: feature id = %d, nch = %d, size = %d\n",do {} while(0)
1435	u->id, id, u->nch, size)do {} while(0);
1436
1437	if (!uaudio_getnum(&p, size, &ctl))
1438	return 0;
1439	ctl = uaudio_feature_fixup(sc, ctl);
1440	for (i = 0; i < 16; i++) {
1441	if ((ctl & 3) == 3)
1442	uaudio_feature_addent(sc, u, i, -1);
1443	ctl >>= 2;
1444	}
1445
1446	/*
1447	* certain devices provide no per-channel control descriptors
1448	*/
1449	if (p.wptr - p.rptr == 1)
1450	break;
1451
1452	for (j = 0; j < u->nch; j++) {
1453	if (!uaudio_getnum(&p, size, &ctl))
1454	return 0;
1455	ctl = uaudio_feature_fixup(sc, ctl);
1456	for (i = 0; i < 16; i++) {
1457	if ((ctl & 3) == 3)
1458	uaudio_feature_addent(sc, u, i, j);
1459	ctl >>= 2;
1460	}
1461	}
1462	break;
1463	case UAUDIO_AC_EFFECT0x7:
1464	if (!uaudio_getnum(&p, 2, &type))
1465	return 0;
1466	if (!uaudio_getnum(&p, 1, &id))
1467	return 0;
1468	if (!uaudio_process_unit(sc, u, id, units, &s))
1469	return 0;
1470	s->src_next = u->src_list;
1471	u->src_list = s;
1472	u->nch = s->nch;
1473	DPRINTF("%02d: effect, type = %u, id = %d, nch = %d\n",do {} while(0)
1474	u->id, type, id, u->nch)do {} while(0);
1475	break;
1476	case UAUDIO_AC_PROCESSING0x8:
1477	case UAUDIO_AC_EXTENSION0x9:
1478	if (!uaudio_getnum(&p, 2, &type))
1479	return 0;
1480	if (!uaudio_process_srcs(sc, u, units, &p))
1481	return 0;
1482	if (!uaudio_process_nch(sc, u, &p))
1483	return 0;
1484	DPRINTF("%02u: proc/ext, type = 0x%x, nch = %u\n",do {} while(0)
1485	u->id, type, u->nch)do {} while(0);
1486	for (s = u->src_list; s != NULL((void *)0); s = s->src_next) {
1487	DPRINTF("%u:\tpin %u:\n", u->id, s->id)do {} while(0);
1488	}
1489	break;
1490	case UAUDIO_AC_CLKSRC0xa:
1491	if (!uaudio_getnum(&p, 1, &u->term))
1492	return 0;
1493	if (!uaudio_getnum(&p, 1, &ctl))
1494	return 0;
1495	DPRINTF("%02u: clock source, attr = 0x%x, ctl = 0x%x\n",do {} while(0)
1496	u->id, u->term, ctl)do {} while(0);
1497	break;
1498	case UAUDIO_AC_CLKSEL0xb:
1499	DPRINTF("%02u: clock sel\n", u->id)do {} while(0);
1500	if (!uaudio_process_srcs(sc, u, units, &p))
1501	return 0;
1502	if (u->src_list == NULL((void *)0)) {
1503	printf("%s: clock selector %02u with no srcs\n",
1504	DEVNAME(sc)((sc)->dev.dv_xname), u->id);
1505	return 0;
1506	}
1507	break;
1508	case UAUDIO_AC_CLKMULT0xc:
1509	DPRINTF("%02u: clock mult\n", u->id)do {} while(0);
1510
1511	/* XXX: fetch multiplier */
1512	printf("%s: clock multiplier not supported\n", DEVNAME(sc)((sc)->dev.dv_xname));
1513	break;
1514	case UAUDIO_AC_RATECONV0xd:
1515	DPRINTF("%02u: rate conv\n", u->id)do {} while(0);
1516
1517	/* XXX: fetch multiplier */
1518	printf("%s: rate converter not supported\n", DEVNAME(sc)((sc)->dev.dv_xname));
1519	break;
1520	}
1521	if (rchild)
1522	*rchild = u;
1523	return 1;
1524	}
1525
1526	/*
1527	* Try to set the unit name to the name of its destination terminal. If
1528	* the name is ambiguous (already given to another source unit or having
1529	* multiple destinations) then return 0.
1530	*/
1531	int
1532	uaudio_setname_dsts(struct uaudio_softc sc, struct uaudio_unit u, char *name)
1533	{
1534	struct uaudio_unit *d = u;
1535
1536	while (d != NULL((void *)0)) {
1537	if (d->dst_list == NULL((void )0) \|\| d->dst_list->dst_next != NULL((void )0))
1538	break;
1539	d = d->dst_list;
1540	if (d->src_list == NULL((void )0) \|\| d->src_list->src_next != NULL((void )0))
1541	break;
1542	if (d->name[0] != '\0') {
1543	if (name != NULL((void *)0) && strcmp(name, d->name) != 0)
1544	break;
1545	strlcpy(u->name, d->name, UAUDIO_NAMEMAX16);
1546	return 1;
1547	}
1548	}
1549	return 0;
1550	}
1551
1552	/*
1553	* Try to set the unit name to the name of its source terminal. If the
1554	* name is ambiguous (already given to another destination unit or
1555	* having multiple sources) then return 0.
1556	*/
1557	int
1558	uaudio_setname_srcs(struct uaudio_softc sc, struct uaudio_unit u, char *name)
1559	{
1560	struct uaudio_unit *s = u;
1561
1562	while (s != NULL((void *)0)) {
1563	if (s->src_list == NULL((void )0) \|\| s->src_list->src_next != NULL((void )0))
1564	break;
1565	s = s->src_list;
1566	if (s->dst_list == NULL((void )0) \|\| s->dst_list->dst_next != NULL((void )0))
1567	break;
1568	if (s->name[0] != '\0') {
1569	if (name != NULL((void *)0) && strcmp(name, s->name) != 0)
1570	break;
1571	strlcpy(u->name, s->name, UAUDIO_NAMEMAX16);
1572	return 1;
1573	}
1574	}
1575	return 0;
1576	}
1577
1578	/*
1579	* Set the name of the given unit by using both its source and
1580	* destination units. This is naming scheme is only useful to units
1581	* that would have ambiguous names if only sources or only destination
1582	* were used.
1583	*/
1584	void
1585	uaudio_setname_middle(struct uaudio_softc sc, struct uaudio_unit u)
1586	{
1587	struct uaudio_unit s, d;
1588	char name[UAUDIO_NAMEMAX16];
1589
1590	s = u->src_list;
1591	while (1) {
1592	if (s == NULL((void *)0)) {
1593	DPRINTF("%s: %02u: has no srcs\n",do {} while(0)
1594	__func__, u->id)do {} while(0);
1595	return;
1596	}
1597	if (s->name[0] != '\0')
1598	break;
1599	s = s->src_list;
1600	}
1601
1602	d = u->dst_list;
1603	while (1) {
1604	if (d == NULL((void *)0)) {
1605	DPRINTF("%s: %02u: has no dests\n",do {} while(0)
1606	__func__, u->id)do {} while(0);
1607	return;
1608	}
1609	if (d->name[0] != '\0')
1610	break;
1611	d = d->dst_list;
1612	}
1613
1614	snprintf(name, UAUDIO_NAMEMAX16, "%s_%s", d->name, s->name);
1615	uaudio_mkname(sc, name, u->name);
1616	}
1617
1618	#ifdef UAUDIO_DEBUG
1619	/*
1620	* Return the synchronization type name, for debug purposes only.
1621	*/
1622	char *
1623	uaudio_isoname(int isotype)
1624	{
1625	switch (isotype) {
1626	case UE_ISO_ASYNC0x04:
1627	return "async";
1628	case UE_ISO_ADAPT0x08:
1629	return "adapt";
1630	case UE_ISO_SYNC0x0c:
1631	return "sync";
1632	default:
1633	return "unk";
1634	}
1635	}
1636
1637	/*
1638	* Return the name of the given mode, debug only
1639	*/
1640	char *
1641	uaudio_modename(int mode)
1642	{
1643	switch (mode) {
1644	case 0:
1645	return "none";
1646	case AUMODE_PLAY0x01:
1647	return "play";
1648	case AUMODE_RECORD0x02:
1649	return "rec";
1650	case AUMODE_PLAY0x01 \| AUMODE_RECORD0x02:
1651	return "duplex";
1652	default:
1653	return "unk";
1654	}
1655	}
1656
1657	/*
1658	* Return UAC v2.0 endpoint usage, debug only
1659	*/
1660	char *
1661	uaudio_usagename(int usage)
1662	{
1663	switch (usage) {
1664	case UE_ISO_USAGE_DATA0x00:
1665	return "data";
1666	case UE_ISO_USAGE_FEEDBACK0x10:
1667	return "feed";
1668	case UE_ISO_USAGE_IMPL0x20:
1669	return "impl";
1670	default:
1671	return "unk";
1672	}
1673	}
1674
1675	/*
1676	* Print a bitmap of rates on the console.
1677	*/
1678	void
1679	uaudio_rates_print(int rates)
1680	{
1681	unsigned int i;
1682
1683	for (i = 0; i < nitems(uaudio_rates)(sizeof((uaudio_rates)) / sizeof((uaudio_rates)[0])); i++) {
1684	if (rates & (1 << i))
1685	printf(" %d", uaudio_rates[i]);
1686	}
1687	printf("\n");
1688	}
1689
1690
1691	/*
1692	* Print uaudio_ranges to console.
1693	*/
1694	void
1695	uaudio_ranges_print(struct uaudio_ranges *r)
1696	{
1697	struct uaudio_ranges_el *e;
1698	int more = 0;
1699
1700	for (e = r->el; e != NULL((void *)0); e = e->next) {
1701	if (more)
1702	printf(", ");
1703	if (e->min == e->max)
1704	printf("%d", e->min);
1705	else
1706	printf("[%d:%d]/%d", e->min, e->max, e->res);
1707	more = 1;
1708	}
1709	printf(" (%d vals)\n", r->nval);
1710	}
1711
1712	/*
1713	* Print unit to the console.
1714	*/
1715	void
1716	uaudio_print_unit(struct uaudio_softc sc, struct uaudio_unit u)
1717	{
1718	struct uaudio_unit *s;
1719
1720	switch (u->type) {
1721	case UAUDIO_AC_INPUT0x2:
1722	printf("%02u: input <%s>, dest = %02u <%s>\n",
1723	u->id, u->name, u->dst_list->id, u->dst_list->name);
1724	break;
1725	case UAUDIO_AC_OUTPUT0x3:
1726	printf("%02u: output <%s>, source = %02u <%s>\n",
1727	u->id, u->name, u->src_list->id, u->src_list->name);
1728	break;
1729	case UAUDIO_AC_MIXER0x4:
1730	printf("%02u: mixer <%s>:\n", u->id, u->name);
1731	for (s = u->src_list; s != NULL((void *)0); s = s->src_next)
1732	printf("%02u:\tsource %u <%s>:\n",
1733	u->id, s->id, s->name);
1734	break;
1735	case UAUDIO_AC_SELECTOR0x5:
1736	printf("%02u: selector <%s>:\n", u->id, u->name);
1737	for (s = u->src_list; s != NULL((void *)0); s = s->src_next)
1738	printf("%02u:\tsource %u <%s>:\n",
1739	u->id, s->id, s->name);
1740	break;
1741	case UAUDIO_AC_FEATURE0x6:
1742	printf("%02u: feature <%s>, "
1743	"src = %02u <%s>, dst = %02u <%s>, cls = %d\n",
1744	u->id, u->name,
1745	u->src_list->id, u->src_list->name,
1746	u->dst_list->id, u->dst_list->name, u->mixer_class);
1747	break;
1748	case UAUDIO_AC_EFFECT0x7:
1749	printf("%02u: effect <%s>, "
1750	"src = %02u <%s>, dst = %02u <%s>\n",
1751	u->id, u->name,
1752	u->src_list->id, u->src_list->name,
1753	u->dst_list->id, u->dst_list->name);
1754	break;
1755	case UAUDIO_AC_PROCESSING0x8:
1756	case UAUDIO_AC_EXTENSION0x9:
1757	printf("%02u: proc/ext <%s>:\n", u->id, u->name);
1758	for (s = u->src_list; s != NULL((void *)0); s = s->src_next)
1759	printf("%02u:\tsource %u <%s>:\n",
1760	u->id, s->id, s->name);
1761	break;
1762	case UAUDIO_AC_CLKSRC0xa:
1763	printf("%02u: clock source <%s>\n", u->id, u->name);
1764	break;
1765	case UAUDIO_AC_CLKSEL0xb:
1766	printf("%02u: clock sel <%s>\n", u->id, u->name);
1767	break;
1768	case UAUDIO_AC_CLKMULT0xc:
1769	printf("%02u: clock mult\n", u->id);
1770	break;
1771	case UAUDIO_AC_RATECONV0xd:
1772	printf("%02u: rate conv\n", u->id);
1773	break;
1774	}
1775	}
1776
1777	/*
1778	* Print the full mixer on the console.
1779	*/
1780	void
1781	uaudio_mixer_print(struct uaudio_softc *sc)
1782	{
1783	struct uaudio_mixent *m;
1784	struct uaudio_unit *u;
1785
1786	for (u = sc->unit_list; u != NULL((void *)0); u = u->unit_next) {
1787	for (m = u->mixent_list; m != NULL((void *)0); m = m->next) {
1788	printf("%02u:\t%s.%s",
1789	u->id, u->name, m->fname);
1790	if (m->chan >= 0)
1791	printf("[%u]", m->chan);
1792	printf("\n");
1793	}
1794	}
1795	}
1796
1797	/*
1798	* Print the full device configuration on the console.
1799	*/
1800	void
1801	uaudio_conf_print(struct uaudio_softc *sc)
1802	{
1803	struct uaudio_alt *a;
1804	struct uaudio_params *p;
1805	struct mixer_devinfo mi;
1806	struct mixer_ctrl ctl;
1807	int i, rates;
1808
1809	mi.index = 0;
1810	while (1) {
1811	if (uaudio_query_devinfo(sc, &mi) != 0)
1812	break;
1813
1814	if (mi.type != AUDIO_MIXER_CLASS0) {
1815	ctl.dev = mi.index;
1816	if (uaudio_get_port(sc, &ctl) != 0) {
1817	printf("%02u: failed to get port\n", mi.index);
1818	memset(&ctl.un, 0, sizeof(ctl.un))__builtin_memset((&ctl.un), (0), (sizeof(ctl.un)));
1819	}
1820	}
1821
1822	printf("%02u: <%s>, next = %d, prev = %d, class = %d",
1823	mi.index, mi.label.name, mi.next, mi.prev, mi.mixer_class);
1824
1825	switch (mi.type) {
1826	case AUDIO_MIXER_CLASS0:
1827	break;
1828	case AUDIO_MIXER_VALUE3:
1829	printf(", nch = %d, delta = %d",
1830	mi.un.v.num_channels, mi.un.v.delta);
1831	printf(", val =");
1832	for (i = 0; i < mi.un.v.num_channels; i++)
1833	printf(" %d", ctl.un.value.level[i]);
1834	break;
1835	case AUDIO_MIXER_ENUM1:
1836	printf(", members:");
1837	for (i = 0; i != mi.un.e.num_mem; i++) {
1838	printf(" %s(=%d)",
1839	mi.un.e.member[i].label.name,
1840	mi.un.e.member[i].ord);
1841	}
1842	printf(", val = %d", ctl.un.ord);
1843	break;
1844	}
1845
1846	printf("\n");
1847	mi.index++;
1848	}
1849
1850	printf("%d controls\n", mi.index);
1851
1852	printf("alts:\n");
1853	for (a = sc->alts; a != NULL((void *)0); a = a->next) {
1854	rates = uaudio_alt_getrates(sc, a);
1855	printf("mode = %s, ifnum = %d, altnum = %d, "
1856	"addr = 0x%x, maxpkt = %d, sync = 0x%x, "
1857	"nch = %d, fmt = s%dle%d, rates:",
1858	uaudio_modename(a->mode),
1859	a->ifnum, a->altnum,
1860	a->data_addr, a->maxpkt,
1861	a->sync_addr,
1862	a->nch, a->bits, a->bps);
1863	uaudio_rates_print(rates);
1864	}
1865
1866	printf("parameters:\n");
1867	for (p = sc->params_list; p != NULL((void *)0); p = p->next) {
1868	switch (sc->version) {
1869	case UAUDIO_V10x100:
1870	rates = p->v1_rates;
1871	break;
1872	case UAUDIO_V20x200:
1873	rates = uaudio_getrates(sc, p);
1874	break;
1875	}
1876	printf("pchan = %d, s%dle%d, rchan = %d, s%dle%d, rates:",
1877	p->palt ? p->palt->nch : 0,
1878	p->palt ? p->palt->bits : 0,
1879	p->palt ? p->palt->bps : 0,
1880	p->ralt ? p->ralt->nch : 0,
1881	p->ralt ? p->ralt->bits : 0,
1882	p->ralt ? p->ralt->bps : 0);
1883	uaudio_rates_print(rates);
1884	}
1885	}
1886	#endif
1887
1888	/*
1889	* Return the number of mixer controls that have the same name but
1890	* control different channels of the same stream.
1891	*/
1892	int
1893	uaudio_mixer_nchan(struct uaudio_mixent m, struct uaudio_mixent *rnext)
1894	{
1895	char *name;
1896	int i;
1897
1898	i = 0;
1899	name = m->fname;
1900	while (m != NULL((void *)0) && strcmp(name, m->fname) == 0) {
1901	m = m->next;
1902	i++;
1903	}
1904	if (rnext)
1905	*rnext = m;
1906	return i;
1907	}
1908
1909	/*
1910	* Skip redundant mixer entries that we don't want to expose to userland.
1911	* For instance if there is a mute-all-channels control and per-channel
1912	* mute controls, we don't want both (we expose the per-channel mute)
1913	*/
1914	void
1915	uaudio_mixer_skip(struct uaudio_mixent **pm)
1916	{
1917	struct uaudio_mixent m = pm;
1918
1919	if (m != NULL((void *)0) &&
1920	m->chan == -1 &&
1921	m->next != NULL((void *)0) &&
1922	strcmp(m->fname, m->next->fname) == 0)
1923	m = m->next;
1924
1925	*pm = m;
1926	}
1927
1928	/*
1929	* Return pointer to the unit and mixer entry which have the given
1930	* index exposed by the mixer(4) API.
1931	*/
1932	int
1933	uaudio_mixer_byindex(struct uaudio_softc *sc, int index,
1934	struct uaudio_unit ru, struct uaudio_mixent rm)
1935	{
1936	struct uaudio_unit *u;
1937	struct uaudio_mixent *m;
1938	char *name;
1939	int i;
1940
1941	i = UAUDIO_CLASS_COUNT2;
1942	for (u = sc->unit_list; u != NULL((void *)0); u = u->unit_next) {
1943	m = u->mixent_list;
1944	while (1) {
1945	uaudio_mixer_skip(&m);
1946	if (m == NULL((void *)0))
1947	break;
1948	if (index == i) {
1949	*ru = u;
1950	*rm = m;
1951	return 1;
1952	}
1953	if (m->type == UAUDIO_MIX_NUM1) {
1954	name = m->fname;
1955	while (m != NULL((void *)0) &&
1956	strcmp(name, m->fname) == 0)
1957	m = m->next;
1958	} else
1959	m = m->next;
1960	i++;
1961	}
1962	}
1963	return 0;
1964	}
1965
1966	/*
1967	* Parse AC header descriptor, we use it only to determine UAC
1968	* version. Other properties (like wTotalLength) can be determined
1969	* using other descriptors, so we try to no rely on them to avoid
1970	* inconsistencies and the need for certain quirks.
1971	*/
1972	int
1973	uaudio_process_header(struct uaudio_softc sc, struct uaudio_blob p)
1974	{
1975	struct uaudio_blob ph;
1976	unsigned int type, subtype;
1977
1978	if (!uaudio_getdesc(p, &ph))
1979	return 0;
1980	if (!uaudio_getnum(&ph, 1, &type))
1981	return 0;
1982	if (type != UDESC_CS_INTERFACE0x24) {
1983	DPRINTF("%s: expected cs iface desc\n", __func__)do {} while(0);
1984	return 0;
1985	}
1986	if (!uaudio_getnum(&ph, 1, &subtype))
1987	return 0;
1988	if (subtype != UAUDIO_AC_HEADER0x1) {
1989	DPRINTF("%s: expected header desc\n", __func__)do {} while(0);
1990	return 0;
1991	}
1992	if (!uaudio_getnum(&ph, 2, &sc->version))
1993	return 0;
1994
1995	DPRINTF("%s: version 0x%x\n", __func__, sc->version)do {} while(0);
1996	return 1;
1997	}
1998
1999	/*
2000	* Process AC interrupt endpoint descriptor, this is mainly to skip
2001	* the descriptor as we use neither of its properties. Our mixer
2002	* interface doesn't support unsolicitated state changes, so we've no
2003	* use of it yet.
2004	*/
2005	int
2006	uaudio_process_ac_ep(struct uaudio_softc sc, struct uaudio_blob p)
2007	{
2008	#ifdef UAUDIO_DEBUG
2009	static const char *xfer[] = {
2010	"ctl", "iso", "bulk", "intr"
2011	};
2012	#endif
2013	struct uaudio_blob dp;
2014	unsigned int type, addr, attr, maxpkt, ival;
2015	unsigned char *savepos;
2016
2017	/*
2018	* parse optional interrupt endpoint descriptor
2019	*/
2020	if (p->rptr == p->wptr)
2021	return 1;
2022	savepos = p->rptr;
2023	if (!uaudio_getdesc(p, &dp))
2024	return 0;
2025	if (!uaudio_getnum(&dp, 1, &type))
2026	return 0;
2027	if (type != UDESC_ENDPOINT0x05) {
2028	p->rptr = savepos;
2029	return 1;
2030	}
2031
2032	if (!uaudio_getnum(&dp, 1, &addr))
2033	return 0;
2034	if (!uaudio_getnum(&dp, 1, &attr))
2035	return 0;
2036	if (!uaudio_getnum(&dp, 2, &maxpkt))
2037	return 0;
2038	if (!uaudio_getnum(&dp, 1, &ival))
2039	return 0;
2040
2041	DPRINTF("%s: addr = 0x%x, type = %s, maxpkt = %d, ival = %d\n",do {} while(0)
2042	__func__, addr, xfer[UE_GET_XFERTYPE(attr)],do {} while(0)
2043	UE_GET_SIZE(maxpkt), ival)do {} while(0);
2044
2045	return 1;
2046	}
2047
2048	/*
2049	* Process the AC interface descriptors: mainly build the mixer and,
2050	* for UAC v2.0, find the clock source.
2051	*
2052	* The audio device exposes an audio control (AC) interface with a big
2053	* set of USB descriptors which expose the complete circuit the
2054	* device. The circuit describes how the signal flows between the USB
2055	* streaming interfaces to the terminal connectors (jacks, speakers,
2056	* mics, ...). The circuit is build of mixers, source selectors, gain
2057	* controls, mutters, processors, and alike; each comes with its own
2058	* set of controls. Most of the boring driver work is to parse the
2059	* circuit and build a human-usable set of controls that could be
2060	* exposed through the mixer(4) interface.
2061	*/
2062	int
2063	uaudio_process_ac(struct uaudio_softc sc, struct uaudio_blob p, int ifnum)
2064	{
2065	struct uaudio_blob units, pu;
2066	struct uaudio_unit u, v;
2067	unsigned char *savepos;
2068	unsigned int type, subtype, id;
2069	char *name, val;
2070
2071	DPRINTF("%s: ifnum = %d, %zd bytes to process\n", __func__,do {} while(0)
2072	ifnum, p->wptr - p->rptr)do {} while(0);
2073
2074	sc->ctl_ifnum = ifnum;
2075
2076	/* The first AC class-specific descriptor is the AC header */
2077	if (!uaudio_process_header(sc, p))
2078	return 0;
2079
2080	/*
2081	* Determine the size of the AC descriptors array: scan
2082	* descriptors until we get the first non-class-specific
2083	* descriptor. This avoids relying on the wTotalLength field.
2084	*/
2085	savepos = p->rptr;
2086	units.rptr = units.wptr = p->rptr;
2087	while (p->rptr != p->wptr) {
2088	if (!uaudio_getdesc(p, &pu))
2089	return 0;
2090	if (!uaudio_getnum(&pu, 1, &type))
2091	return 0;
2092	if (type != UDESC_CS_INTERFACE0x24)
2093	break;
2094	units.wptr = p->rptr;
2095	}
2096	p->rptr = savepos;
2097
2098	/*
2099	* Load units, walking from outputs to inputs, as
2100	* the usb audio class spec requires.
2101	*/
2102	while (p->rptr != units.wptr) {
2103	if (!uaudio_getdesc(p, &pu))
2104	return 0;
2105	if (!uaudio_getnum(&pu, 1, &type))
2106	return 0;
2107	if (!uaudio_getnum(&pu, 1, &subtype))
2108	return 0;
2109	if (subtype == UAUDIO_AC_OUTPUT0x3) {
2110	if (!uaudio_getnum(&pu, 1, &id))
2111	return 0;
2112	if (!uaudio_process_unit(sc, NULL((void )0), id, units, NULL((void )0)))
2113	return 0;
2114	}
2115	}
2116
2117	/*
2118	* set terminal, effect, and processor unit names
2119	*/
2120	for (u = sc->unit_list; u != NULL((void *)0); u = u->unit_next) {
2121	switch (u->type) {
2122	case UAUDIO_AC_INPUT0x2:
2123	uaudio_mkname(sc, uaudio_tname(sc, u->term, 0), u->name);
2124	break;
2125	case UAUDIO_AC_OUTPUT0x3:
2126	uaudio_mkname(sc, uaudio_tname(sc, u->term, 1), u->name);
2127	break;
2128	case UAUDIO_AC_CLKSRC0xa:
2129	uaudio_mkname(sc, uaudio_clkname(u->term), u->name);
2130	break;
2131	case UAUDIO_AC_CLKSEL0xb:
2132	uaudio_mkname(sc, "clksel", u->name);
2133	break;
2134	case UAUDIO_AC_EFFECT0x7:
2135	uaudio_mkname(sc, "fx", u->name);
2136	break;
2137	case UAUDIO_AC_PROCESSING0x8:
2138	uaudio_mkname(sc, "proc", u->name);
2139	break;
2140	case UAUDIO_AC_EXTENSION0x9:
2141	uaudio_mkname(sc, "ext", u->name);
2142	break;
2143	}
2144	}
2145
2146	/*
2147	* set mixer/selector unit names
2148	*/
2149	for (u = sc->unit_list; u != NULL((void *)0); u = u->unit_next) {
2150	if (u->type != UAUDIO_AC_MIXER0x4 &&
2151	u->type != UAUDIO_AC_SELECTOR0x5)
2152	continue;
2153	if (!uaudio_setname_dsts(sc, u, NULL((void *)0))) {
2154	switch (u->type) {
2155	case UAUDIO_AC_MIXER0x4:
2156	name = "mix";
2157	break;
2158	case UAUDIO_AC_SELECTOR0x5:
2159	name = "sel";
2160	break;
2161	}
2162	uaudio_mkname(sc, name, u->name);
2163	}
2164	}
2165
2166	/*
2167	* set feature unit names and classes
2168	*/
2169	for (u = sc->unit_list; u != NULL((void *)0); u = u->unit_next) {
2170	if (u->type != UAUDIO_AC_FEATURE0x6)
2171	continue;
2172	if (uaudio_setname_dsts(sc, u, UAUDIO_NAME_REC"record")) {
2173	u->mixer_class = UAUDIO_CLASS_IN1;
2174	continue;
2175	}
2176	if (uaudio_setname_srcs(sc, u, UAUDIO_NAME_PLAY"dac")) {
2177	u->mixer_class = UAUDIO_CLASS_OUT0;
2178	continue;
2179	}
2180	if (uaudio_setname_dsts(sc, u, NULL((void *)0))) {
2181	u->mixer_class = UAUDIO_CLASS_OUT0;
2182	continue;
2183	}
2184	if (uaudio_setname_srcs(sc, u, NULL((void *)0))) {
2185	u->mixer_class = UAUDIO_CLASS_IN1;
2186	continue;
2187	}
2188	uaudio_setname_middle(sc, u);
2189	u->mixer_class = UAUDIO_CLASS_IN1;
2190	}
2191
2192	#ifdef UAUDIO_DEBUG
2193	if (uaudio_debug) {
2194	printf("%s: units list:\n", DEVNAME(sc)((sc)->dev.dv_xname));
2195	for (u = sc->unit_list; u != NULL((void *)0); u = u->unit_next)
2196	uaudio_print_unit(sc, u);
2197
2198	printf("%s: mixer controls:\n", DEVNAME(sc)((sc)->dev.dv_xname));
2199	uaudio_mixer_print(sc);
2200	}
2201	#endif
2202
2203	/* follows optional interrupt endpoint descriptor */
2204	if (!uaudio_process_ac_ep(sc, p))
2205	return 0;
2206
2207	/* fetch clock source rates */
2208	for (u = sc->unit_list; u != NULL((void *)0); u = u->unit_next) {
2209	switch (u->type) {
2210	case UAUDIO_AC_CLKSRC0xa:
2211	if (!uaudio_req_ranges(sc, 4,
2212	UAUDIO_V2_REQSEL_CLKFREQ1,
2213	0, /* channel (not used) */
2214	sc->ctl_ifnum,
2215	u->id,
2216	&u->rates)) {
2217	printf("%s: failed to read clock rates\n",
2218	DEVNAME(sc)((sc)->dev.dv_xname));
2219	return 0;
2220	}
2221	#ifdef UAUDIO_DEBUG
2222	if (uaudio_debug) {
2223	printf("%02u: clock rates: ", u->id);
2224	uaudio_ranges_print(&u->rates);
2225	}
2226	#endif
2227	break;
2228	case UAUDIO_AC_CLKSEL0xb:
2229	if (!uaudio_req(sc, UT_READ_CLASS_INTERFACE(0x80 \| 0x20 \| 0x01),
2230	UAUDIO_V2_REQ_CUR1,
2231	UAUDIO_V2_REQSEL_CLKSEL1, 0,
2232	sc->ctl_ifnum, u->id,
2233	&val, 1)) {
2234	printf("%s: failed to read clock selector\n",
2235	DEVNAME(sc)((sc)->dev.dv_xname));
2236	return 0;
2237	}
2238	for (v = u->src_list; v != NULL((void *)0); v = v->src_next) {
2239	if (--val == 0)
2240	break;
2241	}
2242	u->clock = v;
2243	break;
2244	}
2245	}
2246
2247	if (sc->version == UAUDIO_V20x200) {
2248	/*
2249	* Find common clock unit. We assume all terminals
2250	* belong to the same clock domain (ie are connected
2251	* to the same source)
2252	*/
2253	sc->clock = NULL((void *)0);
2254	for (u = sc->unit_list; u != NULL((void *)0); u = u->unit_next) {
2255	if (u->type != UAUDIO_AC_INPUT0x2 &&
2256	u->type != UAUDIO_AC_OUTPUT0x3)
2257	continue;
2258	if (sc->clock == NULL((void *)0)) {
2259	if (u->clock == NULL((void *)0)) {
2260	printf("%s: terminal with no clock\n",
2261	DEVNAME(sc)((sc)->dev.dv_xname));
2262	return 0;
2263	}
2264	sc->clock = u->clock;
2265	} else if (u->clock != sc->clock) {
2266	printf("%s: only one clock domain supported\n",
2267	DEVNAME(sc)((sc)->dev.dv_xname));
2268	return 0;
2269	}
2270	}
2271
2272	if (sc->clock == NULL((void *)0)) {
2273	printf("%s: no clock found\n", DEVNAME(sc)((sc)->dev.dv_xname));
2274	return 0;
2275	}
2276	}
2277	return 1;
2278	}
2279
2280	/*
2281	* Parse endpoint descriptor with the following format:
2282	*
2283	* For playback there's a output data endpoint, of the
2284	* following types:
2285	*
2286	* type sync descr
2287	* -------------------------------------------------------
2288	* async: Yes the device uses its own clock but
2289	* sends feedback on a (input) sync endpoint
2290	* for the host to adjust next packet size
2291	*
2292	* sync: - data rate is constant, and device
2293	* is clocked to the usb bus.
2294	*
2295	* adapt: - the device adapts to data rate of the
2296	* host. If fixed packet size is used,
2297	* data rate is equivalent to the usb clock
2298	* so this mode is the same as the
2299	* sync mode.
2300	*
2301	* For recording there's and input data endpoint, of
2302	* the following types:
2303	*
2304	* type sync descr
2305	* -------------------------------------------------------
2306	* async: - the device uses its own clock and
2307	* adjusts packet sizes.
2308	*
2309	* sync: - the device uses usb clock rate
2310	*
2311	* adapt: Yes the device uses host's feedback (on
2312	* on a dedicated (output) sync endpoint
2313	* to adapt to software's desired rate
2314	*
2315	*
2316	* For usb1.1 ival is cardcoded to 1 for isochronous
2317	* transfers, which means one transfer every ms. I.e one
2318	* transfer every frame period.
2319	*
2320	* For usb2, ival the poll interval is:
2321	*
2322	* frame_period * 2^(ival - 1)
2323	*
2324	* so, if we use this formula, we get something working in all
2325	* cases.
2326	*
2327	* The MaxPacketsOnly attribute is used only by "Type II" encodings,
2328	* so we don't care about it.
2329	*/
2330	int
2331	uaudio_process_as_ep(struct uaudio_softc *sc,
2332	struct uaudio_blob p, struct uaudio_alt a, int nep)
2333	{
2334	unsigned int addr, attr, maxpkt, isotype, ival;
2335
2336	if (!uaudio_getnum(p, 1, &addr))
2337	return 0;
2338	if (!uaudio_getnum(p, 1, &attr))
2339	return 0;
2340	if (!uaudio_getnum(p, 2, &maxpkt))
2341	return 0;
2342	if (!uaudio_getnum(p, 1, &ival)) /* bInterval */
2343	return 0;
2344
2345	DPRINTF("%s: addr = 0x%x, %s/%s, "do {} while(0)
2346	"maxpktsz = %d, ival = %d\n",do {} while(0)
2347	__func__, addr,do {} while(0)
2348	uaudio_isoname(UE_GET_ISO_TYPE(attr)),do {} while(0)
2349	uaudio_usagename(UE_GET_ISO_USAGE(attr)),do {} while(0)
2350	maxpkt, ival)do {} while(0);
2351
2352	if (UE_GET_XFERTYPE(attr)((attr) & 0x03) != UE_ISOCHRONOUS0x01) {
2353	printf("%s: skipped non-isoc endpt.\n", DEVNAME(sc)((sc)->dev.dv_xname));
2354	return 1;
2355	}
2356
2357	/*
2358	* For each AS interface setting, there's a single data
2359	* endpoint and an optional feedback endpoint. The
2360	* synchronization type is non-zero and must be set in the data
2361	* endpoints.
2362	*
2363	* However, the isoc sync type field of the attribute can't be
2364	* trusted: a lot of devices have it wrong. If the isoc sync
2365	* type is set it's necessarily a data endpoint, if it's not,
2366	* then if it is the only endpoint, it necessarily the data
2367	* endpoint.
2368	*/
2369	isotype = UE_GET_ISO_TYPE(attr)((attr) & 0x0c);
2370	if (isotype \|\| nep == 1) {
2371	/* this is the data endpoint */
2372
2373	if (a->data_addr && addr != a->data_addr) {
2374	printf("%s: skipped extra data endpt.\n", DEVNAME(sc)((sc)->dev.dv_xname));
2375	return 1;
2376	}
2377
2378	a->mode = (UE_GET_DIR(addr)((addr) & 0x80) == UE_DIR_IN0x80) ?
2379	AUMODE_RECORD0x02 : AUMODE_PLAY0x01;
2380	a->data_addr = addr;
2381	a->fps = sc->ufps / (1 << (ival - 1));
2382	a->maxpkt = UE_GET_SIZE(maxpkt)((maxpkt) & 0x7ff);
2383	} else {
2384	/* this is the sync endpoint */
2385
2386	if (a->sync_addr && addr != a->sync_addr) {
2387	printf("%s: skipped extra sync endpt.\n", DEVNAME(sc)((sc)->dev.dv_xname));
2388	return 1;
2389	}
2390	a->sync_addr = addr;
2391	}
2392
2393	return 1;
2394	}
2395
2396	/*
2397	* Parse AS general descriptor. Non-PCM interfaces are skipped. UAC
2398	* v2.0 report the number of channels. For UAC v1.0 we set the number
2399	* of channels to zero, it will be determined later from the format
2400	* descriptor.
2401	*/
2402	int
2403	uaudio_process_as_general(struct uaudio_softc *sc,
2404	struct uaudio_blob p, int rispcm, struct uaudio_alt *a)
2405	{
2406	unsigned int term, fmt, ctl, fmt_type, fmt_map, nch;
2407
2408	if (!uaudio_getnum(p, 1, &term))
2409	return 0;
2410	switch (sc->version) {
2411	case UAUDIO_V10x100:
2412	if (!uaudio_getnum(p, 1, NULL((void )0))) / bDelay */
2413	return 0;
2414	if (!uaudio_getnum(p, 1, &fmt))
2415	return 0;
2416	*rispcm = (fmt == UAUDIO_V1_FMT_PCM0x1);
2417	break;
2418	case UAUDIO_V20x200:
2419	/* XXX: should we check if alt setting control is valid ? */
2420	if (!uaudio_getnum(p, 1, &ctl))
2421	return 0;
2422	if (!uaudio_getnum(p, 1, &fmt_type))
2423	return 0;
2424	if (!uaudio_getnum(p, 4, &fmt_map))
2425	return 0;
2426	if (!uaudio_getnum(p, 1, &nch))
2427	return 0;
2428	a->nch = nch;
2429	*rispcm = (fmt_type == 1) && (fmt_map & UAUDIO_V2_FMT_PCM0x01);
2430	}
2431	return 1;
2432	}
2433
2434	/*
2435	* Parse AS format descriptor: we support only "Type 1" formats, aka
2436	* PCM. Other formats are not really audio, they are data-only
2437	* interfaces that we don't want to support: ethernet is much better
2438	* for raw data transfers.
2439	*
2440	* XXX: handle ieee 754 32-bit floating point formats.
2441	*/
2442	int
2443	uaudio_process_as_format(struct uaudio_softc *sc,
2444	struct uaudio_blob p, struct uaudio_alt a, int *ispcm)
2445	{
2446	unsigned int type, bps, bits, nch, nrates, rate_min, rate_max, rates;
2447	int i, j;
2448
2449	switch (sc->version) {
2450	case UAUDIO_V10x100:
2451	if (!uaudio_getnum(p, 1, &type))
2452	return 0;
2453	if (type != 1) {
2454	DPRINTF("%s: class v1: "do {} while(0)
2455	"skipped unsupported type = %d\n", __func__, type)do {} while(0);
2456	*ispcm = 0;
2457	return 1;
2458	}
2459	if (!uaudio_getnum(p, 1, &nch))
2460	return 0;
2461	if (!uaudio_getnum(p, 1, &bps))
2462	return 0;
2463	if (!uaudio_getnum(p, 1, &bits))
2464	return 0;
2465	if (!uaudio_getnum(p, 1, &nrates))
2466	return 0;
2467	rates = 0;
2468	if (nrates == 0) {
2469	if (!uaudio_getnum(p, 3, &rate_min))
2470	return 0;
2471	if (!uaudio_getnum(p, 3, &rate_max))
2472	return 0;
2473	for (i = 0; i < nitems(uaudio_rates)(sizeof((uaudio_rates)) / sizeof((uaudio_rates)[0])); i++) {
2474	if (uaudio_rates[i] >= rate_min &&
2475	uaudio_rates[i] <= rate_max)
2476	rates \|= 1 << i;
2477	}
2478	} else {
2479	for (j = 0; j < nrates; j++) {
2480	if (!uaudio_getnum(p, 3, &rate_min))
2481	return 0;
2482	for (i = 0; i < nitems(uaudio_rates)(sizeof((uaudio_rates)) / sizeof((uaudio_rates)[0])); i++) {
2483	if (uaudio_rates[i] == rate_min)
2484	rates \|= 1 << i;
2485	}
2486	}
2487	}
2488	a->v1_rates = rates;
2489	a->nch = nch;
2490	break;
2491	case UAUDIO_V20x200:
2492	/*
2493	* sample rate ranges are obtained with requests to
2494	* the clock source, as defined by the clock source
2495	* descriptor
2496	*
2497	* the number of channels is in the GENERAL descriptor
2498	*/
2499	if (!uaudio_getnum(p, 1, &type))
2500	return 0;
2501	if (type != 1) {
2502	DPRINTF("%s: class v2: "do {} while(0)
2503	"skipped unsupported type = %d\n", __func__, type)do {} while(0);
2504	*ispcm = 0;
2505	return 1;
2506	}
2507	if (!uaudio_getnum(p, 1, &bps))
2508	return 0;
2509	if (!uaudio_getnum(p, 1, &bits))
2510	return 0;
2511
2512	/*
2513	* nch is in the v2 general desc, rates come from the
2514	* clock source, so we're done.
2515	*/
2516	break;
2517	}
2518	a->bps = bps;
2519	a->bits = bits;
2520	*ispcm = 1;
2521	return 1;
2522	}
2523
2524	/*
2525	* Parse AS descriptors.
2526	*
2527	* The audio streaming (AS) interfaces are used to move data between
2528	* the host and the device. On the one hand, the device has
2529	* analog-to-digital (ADC) and digital-to-analog (DAC) converters
2530	* which have their own low-jitter clock source. On other hand, the
2531	* USB host runs a bus clock using another clock source. So both
2532	* drift. That's why, the device sends feedback to the driver for the
2533	* host to adjust continuously its data rate, hence the need for sync
2534	* endpoints.
2535	*/
2536	int
2537	uaudio_process_as(struct uaudio_softc *sc,
2538	struct uaudio_blob *p, int ifnum, int altnum, int nep)
2539	{
2540	struct uaudio_alt a, anext, **pa;
2541	struct uaudio_blob dp;
2542	unsigned char *savep;
2543	unsigned int type, subtype;
2544	int ispcm = 0;
2545
2546	a = malloc(sizeof(struct uaudio_alt), M_USBDEV102, M_WAITOK0x0001);
2547	a->mode = 0;
2548	a->nch = 0;
2549	a->v1_rates = 0;
2550	a->data_addr = 0;
2551	a->sync_addr = 0;
2552	a->ifnum = ifnum;
2553	a->altnum = altnum;
2554
2555	while (p->rptr != p->wptr) {
2556	savep = p->rptr;
2557	if (!uaudio_getdesc(p, &dp))
2558	goto failed;
2559	if (!uaudio_getnum(&dp, 1, &type))
2560	goto failed;
2561	if (type != UDESC_CS_INTERFACE0x24) {
2562	p->rptr = savep;
2563	break;
2564	}
2565	if (!uaudio_getnum(&dp, 1, &subtype))
2566	goto failed;
2567	switch (subtype) {
2568	case UAUDIO_AS_GENERAL0x1:
2569	if (!uaudio_process_as_general(sc, &dp, &ispcm, a))
2570	goto failed;
2571	break;
2572	case UAUDIO_AS_FORMAT0x2:
2573	if (!uaudio_process_as_format(sc, &dp, a, &ispcm))
2574	goto failed;
2575	break;
2576	default:
2577	DPRINTF("%s: unknown desc\n", __func__)do {} while(0);
2578	continue;
2579	}
2580	if (!ispcm) {
2581	DPRINTF("%s: non-pcm iface\n", __func__)do {} while(0);
2582	free(a, M_USBDEV102, sizeof(struct uaudio_alt));
2583	return 1;
2584	}
2585	}
2586
2587	while (p->rptr != p->wptr) {
2588	savep = p->rptr;
2589	if (!uaudio_getdesc(p, &dp))
2590	goto failed;
2591	if (!uaudio_getnum(&dp, 1, &type))
2592	goto failed;
2593	if (type == UDESC_CS_ENDPOINT0x25)
2594	continue;
2595	if (type != UDESC_ENDPOINT0x05) {
2596	p->rptr = savep;
2597	break;
2598	}
2599	if (!uaudio_process_as_ep(sc, &dp, a, nep))
2600	goto failed;
2601	}
2602
2603	if (a->mode == 0) {
2604	printf("%s: no data endpoints found\n", DEVNAME(sc)((sc)->dev.dv_xname));
2605	free(a, M_USBDEV102, sizeof(struct uaudio_alt));
2606	return 1;
2607	}
2608
2609	/*
2610	* Append to list of alts, but keep the list sorted by number
2611	* of channels, bits and rate. From the most capable to the
2612	* less capable.
2613	*/
2614	pa = &sc->alts;
2615	while (1) {
2616	if ((anext = pa) == NULL((void )0))
2617	break;
2618	if (a->nch > anext->nch)
2619	break;
2620	else if (a->nch == anext->nch) {
2621	if (a->bits > anext->bits)
2622	break;
2623	else if (sc->version == UAUDIO_V10x100 &&
2624	a->v1_rates > anext->v1_rates)
2625	break;
2626	}
2627	pa = &anext->next;
2628	}
2629	a->next = *pa;
2630	*pa = a;
2631	return 1;
2632	failed:
2633	free(a, M_USBDEV102, sizeof(struct uaudio_alt));
2634	return 0;
2635	}
2636
2637	/*
2638	* Populate the sc->params_list with combinations of play and rec alt
2639	* settings that work together in full-duplex.
2640	*/
2641	void
2642	uaudio_fixup_params(struct uaudio_softc *sc)
2643	{
2644	struct uaudio_alt ap, ar, *a;
2645	struct uaudio_params p, *pp;
2646	int rates;
2647
2648	/*
2649	* Add full-duplex parameter combinations.
2650	*/
2651	pp = &sc->params_list;
2652	for (ap = sc->alts; ap != NULL((void *)0); ap = ap->next) {
2653	if (ap->mode != AUMODE_PLAY0x01)
2654	continue;
2655	for (ar = sc->alts; ar != NULL((void *)0); ar = ar->next) {
2656	if (ar->mode != AUMODE_RECORD0x02)
2657	continue;
2658	if (ar->bps != ap->bps \|\| ar->bits != ap->bits)
2659	continue;
2660	switch (sc->version) {
2661	case UAUDIO_V10x100:
2662	rates = ap->v1_rates & ar->v1_rates;
2663	if (rates == 0)
2664	continue;
2665	break;
2666	case UAUDIO_V20x200:
2667	/* UAC v2.0 common rates */
2668	rates = 0;
2669	break;
2670	}
2671	p = malloc(sizeof(struct uaudio_params),
2672	M_USBDEV102, M_WAITOK0x0001);
2673	p->palt = ap;
2674	p->ralt = ar;
2675	p->v1_rates = rates;
2676	p->next = NULL((void *)0);
2677	*pp = p;
2678	pp = &p->next;
2679	}
2680	}
2681
2682	/*
2683	* For unidirectional devices, add play-only and or rec-only
2684	* parameters.
2685	*/
2686	if (sc->params_list == NULL((void *)0)) {
2687	for (a = sc->alts; a != NULL((void *)0); a = a->next) {
2688	p = malloc(sizeof(struct uaudio_params),
2689	M_USBDEV102, M_WAITOK0x0001);
2690	if (a->mode == AUMODE_PLAY0x01) {
2691	p->palt = a;
2692	p->ralt = NULL((void *)0);
2693	} else {
2694	p->palt = NULL((void *)0);
2695	p->ralt = a;
2696	}
2697	p->v1_rates = a->v1_rates;
2698	p->next = NULL((void *)0);
2699	*pp = p;
2700	pp = &p->next;
2701	}
2702	}
2703	}
2704
2705	/*
2706	* Parse all descriptors and build configuration of the device.
2707	*/
2708	int
2709	uaudio_process_conf(struct uaudio_softc sc, struct uaudio_blob p)
2710	{
2711	struct uaudio_blob dp;
2712	struct uaudio_alt *a;
2713	unsigned int type, ifnum, altnum, nep, class, subclass;
2714
2715	while (p->rptr != p->wptr) {
2716	if (!uaudio_getdesc(p, &dp))
2717	return 0;
2718	if (!uaudio_getnum(&dp, 1, &type))
2719	return 0;
2720	if (type != UDESC_INTERFACE0x04)
2721	continue;
2722	if (!uaudio_getnum(&dp, 1, &ifnum))
2723	return 0;
2724	if (!uaudio_getnum(&dp, 1, &altnum))
2725	return 0;
2726	if (!uaudio_getnum(&dp, 1, &nep))
2727	return 0;
2728	if (!uaudio_getnum(&dp, 1, &class))
2729	return 0;
2730	if (!uaudio_getnum(&dp, 1, &subclass))
2731	return 0;
2732	if (class != UICLASS_AUDIO0x01) {
2733	DPRINTF("%s: skipped iface\n", __func__)do {} while(0);
2734	continue;
2735	}
2736
2737	switch (subclass) {
2738	case UISUBCLASS_AUDIOCONTROL1:
2739	if (usbd_iface_claimed(sc->udev, ifnum)) {
2740	DPRINTF("%s: %d: AC already claimed\n", __func__, ifnum)do {} while(0);
2741	break;
2742	}
2743	if (sc->unit_list != NULL((void *)0)) {
2744	DPRINTF("%s: >1 AC ifaces\n", __func__)do {} while(0);
2745	goto done;
2746	}
2747	if (!uaudio_process_ac(sc, p, ifnum))
2748	return 0;
2749	break;
2750	case UISUBCLASS_AUDIOSTREAM2:
2751	if (usbd_iface_claimed(sc->udev, ifnum)) {
2752	DPRINTF("%s: %d: AS already claimed\n", __func__, ifnum)do {} while(0);
2753	break;
2754	}
2755	if (nep == 0) {
2756	DPRINTF("%s: "do {} while(0)
2757	"stop altnum %d\n", __func__, altnum)do {} while(0);
2758	break; /* 0 is "stop sound", skip it */
2759	}
2760	if (!uaudio_process_as(sc, p, ifnum, altnum, nep))
2761	return 0;
2762	}
2763	}
2764	done:
2765	uaudio_fixup_params(sc);
2766
2767	/*
2768	* Claim all interfaces we use. This prevents other uaudio(4)
2769	* devices from trying to use them.
2770	*/
2771	for (a = sc->alts; a != NULL((void *)0); a = a->next)
2772	usbd_claim_iface(sc->udev, a->ifnum);
2773
2774	usbd_claim_iface(sc->udev, sc->ctl_ifnum);
2775
2776	return 1;
2777	}
2778
2779	/*
2780	* Allocate a isochronous transfer and its bounce-buffers with the
2781	* given maximum framesize and maximum frames per transfer.
2782	*/
2783	int
2784	uaudio_xfer_alloc(struct uaudio_softc sc, struct uaudio_xfer xfer,
2785	unsigned int framesize, unsigned int count)
2786	{
2787	xfer->usb_xfer = usbd_alloc_xfer(sc->udev);
2788	if (xfer->usb_xfer == NULL((void *)0))
2789	return ENOMEM12;
2790
2791	xfer->buf = usbd_alloc_buffer(xfer->usb_xfer, framesize * count);
2792	if (xfer->buf == NULL((void *)0))
2793	return ENOMEM12;
2794
2795	xfer->sizes = mallocarray(count,
2796	sizeof(xfer->sizes[0]), M_USBDEV102, M_WAITOK0x0001);
2797	if (xfer->sizes == NULL((void *)0))
2798	return ENOMEM12;
2799
2800	return 0;
2801	}
2802
2803	/*
2804	* Free a isochronous transfer and its bounce-buffers.
2805	*/
2806	void
2807	uaudio_xfer_free(struct uaudio_softc sc, struct uaudio_xfer xfer,
2808	unsigned int count)
2809	{
2810	if (xfer->usb_xfer != NULL((void *)0)) {
2811	/* frees request buffer as well */
2812	usbd_free_xfer(xfer->usb_xfer);
2813	xfer->usb_xfer = NULL((void *)0);
2814	}
2815	if (xfer->sizes != NULL((void *)0)) {
2816	free(xfer->sizes, M_USBDEV102,
2817	sizeof(xfer->sizes[0]) * count);
2818	xfer->sizes = NULL((void *)0);
2819	}
2820	}
2821
2822	/*
2823	* Close a stream and free all associated resources
2824	*/
2825	void
2826	uaudio_stream_close(struct uaudio_softc *sc, int dir)
2827	{
2828	struct uaudio_stream *s = &sc->pstream;
2829	struct uaudio_alt *a = sc->params->palt;
2830	struct usbd_interface *iface;
2831	int err, i;
2832
2833	if (dir == AUMODE_PLAY0x01) {
2834	s = &sc->pstream;
2835	a = sc->params->palt;
2836	} else {
2837	s = &sc->rstream;
2838	a = sc->params->ralt;
2839	}
2840
2841	if (s->data_pipe) {
2842	usbd_close_pipe(s->data_pipe);
2843	s->data_pipe = NULL((void *)0);
2844	}
2845
2846	if (s->sync_pipe) {
2847	usbd_close_pipe(s->sync_pipe);
2848	s->sync_pipe = NULL((void *)0);
2849	}
2850
2851	err = usbd_device2interface_handle(sc->udev, a->ifnum, &iface);
2852	if (err)
2853	printf("%s: can't get iface handle\n", DEVNAME(sc)((sc)->dev.dv_xname));
2854	else {
2855	err = usbd_set_interface(iface, 0);
2856	if (err)
2857	printf("%s: can't reset interface\n", DEVNAME(sc)((sc)->dev.dv_xname));
2858	}
2859
2860	for (i = 0; i < UAUDIO_NXFERS_MAX8; i++) {
2861	uaudio_xfer_free(sc, s->data_xfers + i, s->nframes_max);
2862	uaudio_xfer_free(sc, s->sync_xfers + i, 1);
2863	}
2864	}
2865
2866	/*
2867	* Open a stream with the given buffer settings and set the current
2868	* interface alt setting.
2869	*/
2870	int
2871	uaudio_stream_open(struct uaudio_softc *sc, int dir,
2872	void start, void end, size_t blksz, void (intr)(void ), void *arg)
2873	{
2874	struct uaudio_stream *s;
2875	struct uaudio_alt *a;
2876	struct usbd_interface *iface;
2877	unsigned char req_buf[4];
2878	unsigned int bpa, spf_max, min_blksz;
2879	int err, clock_id, i;
2880
2881	if (dir == AUMODE_PLAY0x01) {
2882	s = &sc->pstream;
2883	a = sc->params->palt;
2884	} else {
2885	s = &sc->rstream;
2886	a = sc->params->ralt;
2887	}
2888
2889	for (i = 0; i < UAUDIO_NXFERS_MAX8; i++) {
2890	s->data_xfers[i].usb_xfer = NULL((void *)0);
2891	s->data_xfers[i].sizes = NULL((void *)0);
2892	s->sync_xfers[i].usb_xfer = NULL((void *)0);
2893	s->sync_xfers[i].sizes = NULL((void *)0);
2894	}
2895	s->data_pipe = NULL((void *)0);
2896	s->sync_pipe = NULL((void *)0);
2897
2898	s->nframes_mask = 0;
2899	i = a->fps;
2900	while (i > 1000) {
2901	s->nframes_mask = (s->nframes_mask << 1) \| 1;
2902	i >>= 1;
2903	}
2904
2905	/* bytes per audio frame */
2906	bpa = a->bps * a->nch;
2907
2908	/* ideal samples per usb frame, fixed-point */
2909	s->spf = (uint64_t)sc->rate * UAUDIO_SPF_DIV327680 / a->fps;
2910
2911	/*
2912	* UAC2.0 spec allows 1000PPM tolerance in sample frequency,
2913	* while USB1.1 requires 1Hz, which is 125PPM at 8kHz. We
2914	* accept as much as 1/256, which is 2500PPM.
2915	*/
2916	s->spf_min = (uint64_t)s->spf * 255 / 256;
2917	s->spf_max = (uint64_t)s->spf * 257 / 256;
2918
2919	/* max spf can't exceed the device usb packet size */
2920	spf_max = (a->maxpkt / bpa) * UAUDIO_SPF_DIV327680;
2921	if (s->spf > spf_max) {
2922	printf("%s: samples per frame too large\n", DEVNAME(sc)((sc)->dev.dv_xname));
2923	return EIO5;
2924	}
2925	if (s->spf_max > spf_max)
2926	s->spf_max = spf_max;
2927
2928	/*
2929	* Upon transfer completion the device must reach the audio
2930	* block boundary, which is propagated to upper layers. In the
2931	* worst case, we schedule only frames of spf_max samples, but
2932	* the device returns only frames of spf_min samples; in this
2933	* case the amount actually transferred is at least:
2934	*
2935	* min_blksz = blksz / spf_max * spf_min
2936	*
2937	* As we've UAUDIO_NXFERS outstanding blocks, worst-case
2938	* remaining bytes is at most:
2939	*
2940	* UAUDIO_NXFERS * (blksz - min_blksz)
2941	*/
2942	min_blksz = (((uint64_t)blksz << 32) / s->spf_max * s->spf_min) >> 32;
2943
2944	/* round to sample size */
2945	min_blksz -= min_blksz % bpa;
2946
2947	/* finally this is what ensures we cross block boundary */
2948	s->safe_blksz = blksz + UAUDIO_NXFERS_MAX8 * (blksz - min_blksz);
2949
2950	/* max number of (micro-)frames we'll ever use */
2951	s->nframes_max = (uint64_t)(s->safe_blksz / bpa) *
2952	UAUDIO_SPF_DIV327680 / s->spf_min + 1;
2953
2954	/* round to next usb1.1 frame */
2955	s->nframes_max = (s->nframes_max + s->nframes_mask) &
2956	~s->nframes_mask;
2957
2958	/* this is the max packet size we'll ever need */
2959	s->maxpkt = bpa *
2960	((s->spf_max + UAUDIO_SPF_DIV327680 - 1) / UAUDIO_SPF_DIV327680);
2961
2962	/* how many xfers we need to fill sc->host_nframes */
2963	s->nxfers = sc->host_nframes / s->nframes_max;
2964	if (s->nxfers > UAUDIO_NXFERS_MAX8)
2965	s->nxfers = UAUDIO_NXFERS_MAX8;
2966
2967	DPRINTF("%s: %s: blksz = %zu, rate = %u, fps = %u\n", __func__,do {} while(0)
2968	dir == AUMODE_PLAY ? "play" : "rec", blksz, sc->rate, a->fps)do {} while(0);
2969	DPRINTF("%s: spf = 0x%x in [0x%x:0x%x]\n", __func__,do {} while(0)
2970	s->spf, s->spf_min, s->spf_max)do {} while(0);
2971	DPRINTF("%s: nframes_max = %u, nframes_mask = %u, maxpkt = %u\n",do {} while(0)
2972	__func__, s->nframes_max, s->nframes_mask, s->maxpkt)do {} while(0);
2973	DPRINTF("%s: safe_blksz = %d, nxfers = %d\n", __func__,do {} while(0)
2974	s->safe_blksz, s->nxfers)do {} while(0);
2975
2976	if (s->nxfers < UAUDIO_NXFERS_MIN2) {
2977	printf("%s: block size too large\n", DEVNAME(sc)((sc)->dev.dv_xname));
2978	return EIO5;
2979	}
2980
2981	/*
2982	* Require at least 2ms block size to ensure no
2983	* transfer exceeds two blocks.
2984	*
2985	* XXX: use s->nframes_mask instead of 1000
2986	*/
2987	if (1000 * blksz < 2 * sc->rate * bpa) {
2988	printf("%s: audio block too small\n", DEVNAME(sc)((sc)->dev.dv_xname));
2989	return EIO5;
2990	}
2991
2992	for (i = 0; i < s->nxfers; i++) {
2993	err = uaudio_xfer_alloc(sc, s->data_xfers + i,
2994	s->maxpkt, s->nframes_max);
2995	if (err)
2996	goto failed;
2997	if (a->sync_addr) {
2998	err = uaudio_xfer_alloc(sc, s->sync_xfers + i,
2999	sc->sync_pktsz, 1);
3000	if (err)
3001	goto failed;
3002	}
3003	}
3004
3005	err = usbd_device2interface_handle(sc->udev, a->ifnum, &iface);
3006	if (err) {
3007	printf("%s: can't get iface handle\n", DEVNAME(sc)((sc)->dev.dv_xname));
3008	goto failed;
3009	}
3010
3011	err = usbd_set_interface(iface, a->altnum);
3012	if (err) {
3013	printf("%s: can't set interface\n", DEVNAME(sc)((sc)->dev.dv_xname));
3014	goto failed;
3015	}
3016
3017	/*
3018	* Set the sample rate.
3019	*
3020	* Certain devices are able to lock their clock to the data
3021	* rate and expose no frequency control. In this case, the
3022	* request to set the frequency will fail, but this error is
3023	* safe to ignore.
3024	*
3025	* Such devices expose this capability in the class-specific
3026	* endpoint descriptor (UAC v1.0) or in the clock unit
3027	* descriptor (UAC v2.0) but we don't want to use them for now
3028	* as certain devices have them wrong, missing or misplaced.
3029	*/
3030	switch (sc->version) {
3031	case UAUDIO_V10x100:
3032	req_buf[0] = sc->rate;
3033	req_buf[1] = sc->rate >> 8;
3034	req_buf[2] = sc->rate >> 16;
3035	if (!uaudio_req(sc, UT_WRITE_CLASS_ENDPOINT(0x00 \| 0x20 \| 0x02),
3036	UAUDIO_V1_REQ_SET_CUR0x01, UAUDIO_REQSEL_RATE0x01, 0,
3037	a->data_addr, 0, req_buf, 3)) {
3038	DPRINTF("%s: not setting endpoint rate\n", __func__)do {} while(0);
3039	}
3040	break;
3041	case UAUDIO_V20x200:
3042	req_buf[0] = sc->rate;
3043	req_buf[1] = sc->rate >> 8;
3044	req_buf[2] = sc->rate >> 16;
3045	req_buf[3] = sc->rate >> 24;
3046	clock_id = uaudio_clock_id(sc);
3047	if (clock_id < 0) {
3048	printf("%s: can't get clock id\n", DEVNAME(sc)((sc)->dev.dv_xname));
3049	goto failed;
3050	}
3051	if (!uaudio_req(sc, UT_WRITE_CLASS_INTERFACE(0x00 \| 0x20 \| 0x01),
3052	UAUDIO_V2_REQ_CUR1, UAUDIO_REQSEL_RATE0x01, 0,
3053	sc->ctl_ifnum, clock_id, req_buf, 4)) {
3054	DPRINTF("%s: not setting clock rate\n", __func__)do {} while(0);
3055	}
3056	break;
3057	}
3058
3059	err = usbd_open_pipe(iface, a->data_addr, 0, &s->data_pipe);
3060	if (err) {
3061	printf("%s: can't open data pipe\n", DEVNAME(sc)((sc)->dev.dv_xname));
3062	goto failed;
3063	}
3064
3065	if (a->sync_addr) {
3066	err = usbd_open_pipe(iface, a->sync_addr, 0, &s->sync_pipe);
3067	if (err) {
3068	printf("%s: can't open sync pipe\n", DEVNAME(sc)((sc)->dev.dv_xname));
3069	goto failed;
3070	}
3071	}
3072
3073	s->data_nextxfer = 0;
3074	s->sync_nextxfer = 0;
3075	s->spf_remain = 0;
3076
3077	s->intr = intr;
3078	s->arg = arg;
3079	s->ring_start = start;
3080	s->ring_end = end;
3081	s->ring_blksz = blksz;
3082
3083	s->ring_pos = s->ring_start;
3084	s->ring_offs = 0;
3085	s->ring_icnt = 0;
3086
3087	s->ubuf_xfer = 0;
3088	s->ubuf_pos = 0;
3089	return 0;
3090
3091	failed:
3092	uaudio_stream_close(sc, dir);
3093	return ENOMEM12;
3094	}
3095
3096	/*
3097	* Adjust play samples-per-frame to keep play and rec streams in sync.
3098	*/
3099	void
3100	uaudio_adjspf(struct uaudio_softc *sc)
3101	{
3102	struct uaudio_stream *s = &sc->pstream;
3103	int diff;
3104
3105	if (sc->mode != (AUMODE_RECORD0x02 \| AUMODE_PLAY0x01))
3106	return;
3107	if (s->sync_pipe != NULL((void *)0))
3108	return;
3109
3110	/*
3111	* number of samples play stream is ahead of record stream.
3112	*/
3113	diff = sc->diff_nsamp;
3114	if (sc->diff_nframes > 0) {
3115	diff -= (uint64_t)sc->pstream.spf *
3116	sc->diff_nframes / UAUDIO_SPF_DIV327680;
3117	} else {
3118	diff += (uint64_t)sc->rstream.spf *
3119	-sc->diff_nframes / UAUDIO_SPF_DIV327680;
3120	}
3121
3122	/*
3123	* adjust samples-per-frames to resync within the next second
3124	*/
3125	s->spf = (uint64_t)(sc->rate - diff) * UAUDIO_SPF_DIV327680 / sc->ufps;
3126	if (s->spf > s->spf_max)
3127	s->spf = s->spf_max;
3128	else if (s->spf < s->spf_min)
3129	s->spf = s->spf_min;
3130	#ifdef UAUDIO_DEBUG
3131	if (uaudio_debug >= 2)
3132	printf("%s: diff = %d, spf = 0x%x\n", __func__, diff, s->spf);
3133	#endif
3134	}
3135
3136	/*
3137	* Copy one audio block to the xfer buffer.
3138	*/
3139	void
3140	uaudio_pdata_copy(struct uaudio_softc *sc)
3141	{
3142	struct uaudio_stream *s = &sc->pstream;
3143	struct uaudio_xfer *xfer;
3144	size_t count, avail;
3145	int index;
3146	#ifdef UAUDIO_DEBUG
3147	struct timeval tv;
3148
3149	getmicrotime(&tv);
3150	#endif
3151	while (sc->copy_todo > 0 && s->ubuf_xfer < s->nxfers) {
3152	index = s->data_nextxfer + s->ubuf_xfer;
3153	if (index >= s->nxfers)
3154	index -= s->nxfers;
3155	xfer = s->data_xfers + index;
3156	avail = s->ring_end - s->ring_pos;
3157	count = xfer->size - s->ubuf_pos;
3158	if (count > avail)
3159	count = avail;
3160	if (count > sc->copy_todo)
3161	count = sc->copy_todo;
3162	#ifdef UAUDIO_DEBUG
3163	if (uaudio_debug >= 2) {
3164	printf("%s: %llu.%06lu: %zd..%zd -> %u:%u..%zu\n",
3165	__func__, tv.tv_sec, tv.tv_usec,
3166	s->ring_pos - s->ring_start,
3167	s->ring_pos - s->ring_start + count,
3168	s->ubuf_xfer, s->ubuf_pos, s->ubuf_pos + count);
3169	}
3170	#endif
3171	memcpy(xfer->buf + s->ubuf_pos, s->ring_pos, count)__builtin_memcpy((xfer->buf + s->ubuf_pos), (s->ring_pos ), (count));
3172	sc->copy_todo -= count;
3173	s->ring_pos += count;
3174	if (s->ring_pos == s->ring_end) {
3175	s->ring_pos = s->ring_start;
3176	}
3177	s->ubuf_pos += count;
3178	if (s->ubuf_pos == xfer->size) {
3179	usb_syncmem(&xfer->usb_xfer->dmabuf, 0, xfer->size,
3180	BUS_DMASYNC_PREWRITE0x04);
3181	s->ubuf_pos = 0;
3182	#ifdef DIAGNOSTIC1
3183	if (s->ubuf_xfer == s->nxfers) {
3184	printf("%s: overflow\n", __func__);
3185	return;
3186	}
3187	#endif
3188	s->ubuf_xfer++;
3189	}
3190	}
3191	}
3192
3193	/*
3194	* Calculate and fill xfer frames sizes.
3195	*/
3196	void
3197	uaudio_pdata_calcsizes(struct uaudio_softc sc, struct uaudio_xfer xfer)
3198	{
3199	#ifdef UAUDIO_DEBUG
3200	struct timeval tv;
3201	#endif
3202	struct uaudio_stream *s = &sc->pstream;
3203	struct uaudio_alt *a = sc->params->palt;
3204	unsigned int fsize, bpf;
3205	int done;
3206
3207	bpf = a->bps * a->nch;
3208	done = s->ring_offs;
3209	xfer->nframes = 0;
3210
3211	while (1) {
3212	/*
3213	* if we crossed the next block boundary, we're done
3214	*/
3215	if ((xfer->nframes & s->nframes_mask) == 0 &&
3216	done > s->safe_blksz)
3217	break;
3218
3219	/*
3220	* this can't happen, debug only
3221	*/
3222	if (xfer->nframes == s->nframes_max) {
3223	printf("%s: too many frames for play xfer: "
3224	"done = %u, blksz = %d\n",
3225	DEVNAME(sc)((sc)->dev.dv_xname), done, s->ring_blksz);
3226	break;
3227	}
3228
3229	/*
3230	* calculate frame size and adjust state
3231	*/
3232	s->spf_remain += s->spf;
3233	fsize = s->spf_remain / UAUDIO_SPF_DIV327680 * bpf;
3234	s->spf_remain %= UAUDIO_SPF_DIV327680;
3235	done += fsize;
3236	xfer->sizes[xfer->nframes] = fsize;
3237	xfer->nframes++;
3238	}
3239
3240	xfer->size = done - s->ring_offs;
3241	s->ring_offs = done - s->ring_blksz;
3242
3243	#ifdef UAUDIO_DEBUG
3244	if (uaudio_debug >= 3) {
3245	getmicrotime(&tv);
3246	printf("%s: size = %d, offs -> %d\n", __func__,
3247	xfer->size, s->ring_offs);
3248	}
3249	#endif
3250	memset(xfer->buf, 0, xfer->size)__builtin_memset((xfer->buf), (0), (xfer->size));
3251	}
3252
3253	/*
3254	* Submit a play data transfer to the USB driver.
3255	*/
3256	void
3257	uaudio_pdata_xfer(struct uaudio_softc *sc)
3258	{
3259	#ifdef UAUDIO_DEBUG
3260	struct timeval tv;
3261	#endif
3262	struct uaudio_stream *s = &sc->pstream;
3263	struct uaudio_xfer *xfer;
3264	int err;
3265
3266	xfer = s->data_xfers + s->data_nextxfer;
3267
3268	#ifdef UAUDIO_DEBUG
3269	if (uaudio_debug >= 3) {
3270	getmicrotime(&tv);
3271	printf("%s: %llu.%06lu: "
3272	"%d bytes, %u frames, remain = 0x%x, offs = %d\n",
3273	__func__, tv.tv_sec, tv.tv_usec,
3274	xfer->size, xfer->nframes,
3275	s->spf_remain, s->ring_offs);
3276	}
3277	#endif
3278
3279	/* this can't happen, debug only */
3280	if (xfer->nframes == 0) {
3281	printf("%s: zero frame play xfer\n", DEVNAME(sc)((sc)->dev.dv_xname));
3282	return;
3283	}
3284
3285	/*
3286	* We accept short transfers because in case of babble/stale frames
3287	* the transfer will be short
3288	*/
3289	usbd_setup_isoc_xfer(xfer->usb_xfer, s->data_pipe, sc,
3290	xfer->sizes, xfer->nframes,
3291	USBD_NO_COPY0x01 \| USBD_SHORT_XFER_OK0x04,
3292	uaudio_pdata_intr);
3293
3294	err = usbd_transfer(xfer->usb_xfer);
3295	if (err != 0 && err != USBD_IN_PROGRESS)
3296	printf("%s: play xfer, err = %d\n", DEVNAME(sc)((sc)->dev.dv_xname), err);
3297
3298	if (++s->data_nextxfer == s->nxfers)
3299	s->data_nextxfer = 0;
3300	}
3301
3302	/*
3303	* Callback called by the USB driver upon completion of play data transfer.
3304	*/
3305	void
3306	uaudio_pdata_intr(struct usbd_xfer usb_xfer, void arg, usbd_status status)
3307	{
3308	#ifdef UAUDIO_DEBUG
3309	struct timeval tv;
3310	#endif
3311	struct uaudio_softc *sc = arg;
3312	struct uaudio_stream *s = &sc->pstream;
3313	struct uaudio_xfer *xfer;
3314	uint32_t size;
3315	int nintr;
3316
3317	if (status != 0 && status != USBD_IOERROR) {
3318	DPRINTF("%s: xfer status = %d\n", __func__, status)do {} while(0);
3319	return;
3320	}
3321
3322	xfer = s->data_xfers + s->data_nextxfer;
3323	if (xfer->usb_xfer != usb_xfer) {
3324	DPRINTF("%s: wrong xfer\n", __func__)do {} while(0);
3325	return;
3326	}
3327
3328	sc->diff_nsamp += xfer->size /
3329	(sc->params->palt->nch * sc->params->palt->bps);
3330	sc->diff_nframes += xfer->nframes;
3331
3332	#ifdef UAUDIO_DEBUG
3333	if (uaudio_debug >= 2) {
3334	getmicrotime(&tv);
3335	printf("%s: %llu.%06lu: %u: %u bytes\n",
3336	__func__, tv.tv_sec, tv.tv_usec,
3337	s->data_nextxfer, xfer->size);
3338	}
3339	#endif
3340	usbd_get_xfer_status(usb_xfer, NULL((void )0), NULL((void )0), &size, NULL((void *)0));
3341	if (size != xfer->size) {
3342	DPRINTF("%s: %u bytes out of %u: incomplete play xfer\n",do {} while(0)
3343	DEVNAME(sc), size, xfer->size)do {} while(0);
3344	}
3345
3346	/*
3347	* Upper layer call-back may call uaudio_underrun(), which
3348	* needs the current size of this transfer. So, don't
3349	* recalculate the sizes and don't schedule the transfer yet.
3350	*/
3351	s->ring_icnt += xfer->size;
3352	nintr = 0;
3353	mtx_enter(&audio_lock);
3354	while (s->ring_icnt >= s->ring_blksz) {
3355	s->intr(s->arg);
3356	s->ring_icnt -= s->ring_blksz;
3357	nintr++;
3358	}
3359	mtx_leave(&audio_lock);
3360	if (nintr != 1)
3361	printf("%s: %d: bad play intr count\n", __func__, nintr);
3362
3363	uaudio_pdata_calcsizes(sc, xfer);
3364	uaudio_pdata_xfer(sc);
3365	#ifdef DIAGNOSTIC1
3366	if (s->ubuf_xfer == 0) {
3367	printf("%s: underflow\n", __func__);
3368	return;
3369	}
3370	#endif
3371	s->ubuf_xfer--;
3372	uaudio_pdata_copy(sc);
3373	}
3374
3375	/*
3376	* Submit a play sync transfer to the USB driver.
3377	*/
3378	void
3379	uaudio_psync_xfer(struct uaudio_softc *sc)
3380	{
3381	#ifdef UAUDIO_DEBUG
3382	struct timeval tv;
3383	#endif
3384	struct uaudio_stream *s = &sc->pstream;
3385	struct uaudio_xfer *xfer;
3386	unsigned int i;
3387	int err;
3388
3389	xfer = s->sync_xfers + s->sync_nextxfer;
3390	xfer->nframes = 1;
3391
3392	for (i = 0; i < xfer->nframes; i++)
3393	xfer->sizes[i] = sc->sync_pktsz;
3394
3395	xfer->size = xfer->nframes * sc->sync_pktsz;
3396
3397	#ifdef UAUDIO_DEBUG
3398	memset(xfer->buf, 0xd0, sc->sync_pktsz * xfer->nframes)__builtin_memset((xfer->buf), (0xd0), (sc->sync_pktsz * xfer->nframes));
3399	#endif
3400
3401	usbd_setup_isoc_xfer(xfer->usb_xfer, s->sync_pipe, sc,
3402	xfer->sizes, xfer->nframes,
3403	USBD_NO_COPY0x01 \| USBD_SHORT_XFER_OK0x04,
3404	uaudio_psync_intr);
3405
3406	err = usbd_transfer(xfer->usb_xfer);
3407	if (err != 0 && err != USBD_IN_PROGRESS)
3408	printf("%s: sync play xfer, err = %d\n", DEVNAME(sc)((sc)->dev.dv_xname), err);
3409
3410	if (++s->sync_nextxfer == s->nxfers)
3411	s->sync_nextxfer = 0;
3412
3413	#ifdef UAUDIO_DEBUG
3414	if (uaudio_debug >= 3) {
3415	getmicrotime(&tv);
3416	printf("%s: %llu.%06lu: %dB, %d fr\n", __func__,
3417	tv.tv_sec, tv.tv_usec, sc->sync_pktsz, xfer->nframes);
3418	}
3419	#endif
3420	}
3421
3422	/*
3423	* Callback called by the USB driver upon completion of play sync transfer.
3424	*/
3425	void
3426	uaudio_psync_intr(struct usbd_xfer usb_xfer, void arg, usbd_status status)
3427	{
3428	#ifdef UAUDIO_DEBUG
3429	struct timeval tv;
3430	#endif
3431	struct uaudio_softc *sc = arg;
3432	struct uaudio_stream *s = &sc->pstream;
3433	struct uaudio_xfer *xfer;
3434	unsigned char *buf;
3435	unsigned int i;
3436	int32_t val;
3437
3438	if (status != 0) {
3439	DPRINTF("%s: xfer status = %d\n", __func__, status)do {} while(0);
3440	return;
3441	}
3442
3443	xfer = s->sync_xfers + s->sync_nextxfer;
3444	if (xfer->usb_xfer != usb_xfer) {
3445	DPRINTF("%s: wrong xfer\n", __func__)do {} while(0);
3446	return;
3447	}
3448
3449	/* XXX: there's only one frame, the loop is not necessary */
3450
3451	buf = xfer->buf;
3452	for (i = 0; i < xfer->nframes; i++) {
3453	if (xfer->sizes[i] == sc->sync_pktsz) {
3454	val = buf[0] \| buf[1] << 8 \| buf[2] << 16;
3455	if (sc->sync_pktsz == 4)
3456	val \|= xfer->buf[3] << 24;
3457	else
3458	val <<= 2;
3459	val *= UAUDIO_SPF_DIV327680 / (1 << 16);
3460	#ifdef UAUDIO_DEBUG
3461	if (uaudio_debug >= 2) {
3462	getmicrotime(&tv);
3463	printf("%s: %llu.%06lu: spf: %08x\n",
3464	__func__, tv.tv_sec, tv.tv_usec, val);
3465	}
3466	#endif
3467	if (val > s->spf_max)
3468	s->spf = s->spf_max;
3469	else if (val < s->spf_min)
3470	s->spf = s->spf_min;
3471	else
3472	s->spf = val;
3473	}
3474	buf += sc->sync_pktsz;
3475	}
3476
3477	uaudio_psync_xfer(sc);
3478	}
3479
3480	/*
3481	* Submit a rec data transfer to the USB driver.
3482	*/
3483	void
3484	uaudio_rdata_xfer(struct uaudio_softc *sc)
3485	{
3486	#ifdef UAUDIO_DEBUG
3487	struct timeval tv;
3488	#endif
3489	struct uaudio_stream *s = &sc->rstream;
3490	struct uaudio_alt *a = sc->params->ralt;
3491	struct uaudio_xfer *xfer;
3492	unsigned int fsize, bpf;
3493	int done;
3494	int err;
3495
3496	xfer = s->data_xfers + s->data_nextxfer;
3497	bpf = a->bps * a->nch;
3498	xfer->nframes = 0;
3499	done = s->ring_offs;
3500
3501	while (1) {
3502	/*
3503	* if we crossed the next block boundary, we're done
3504	*/
3505	if ((xfer->nframes & s->nframes_mask) == 0 &&
3506	done > s->safe_blksz) {
3507	done:
3508	xfer->size = done - s->ring_offs;
3509	s->ring_offs = done - s->ring_blksz;
3510	break;
3511	}
3512
3513	/*
3514	* this can't happen, debug only
3515	*/
3516	if (xfer->nframes == s->nframes_max) {
3517	printf("%s: too many frames for rec xfer: "
3518	"done = %d, blksz = %d\n",
3519	DEVNAME(sc)((sc)->dev.dv_xname), done, s->ring_blksz);
3520	goto done;
3521	}
3522
3523	/*
3524	* estimate next block using s->spf, but allow
3525	* transfers up to maxpkt
3526	*/
3527	s->spf_remain += s->spf;
3528	fsize = s->spf_remain / UAUDIO_SPF_DIV327680 * bpf;
3529	s->spf_remain %= UAUDIO_SPF_DIV327680;
3530	done += fsize;
3531	xfer->sizes[xfer->nframes] = s->maxpkt;
3532	xfer->nframes++;
3533	}
3534
3535	#ifdef UAUDIO_DEBUG
3536	if (uaudio_debug >= 3) {
3537	getmicrotime(&tv);
3538	printf("%s: %llu.%06lu: "
3539	"%u fr, %d bytes (max %d), offs = %d\n",
3540	__func__, tv.tv_sec, tv.tv_usec,
3541	xfer->nframes, xfer->size,
3542	s->maxpkt * xfer->nframes, s->ring_offs);
3543	}
3544	#endif
3545
3546	/* this can't happen, debug only */
3547	if (xfer->nframes == 0) {
3548	printf("%s: zero frame rec xfer\n", DEVNAME(sc)((sc)->dev.dv_xname));
3549	return;
3550	}
3551
3552	#ifdef UAUDIO_DEBUG
3553	memset(xfer->buf, 0xd0, s->maxpkt * xfer->nframes)__builtin_memset((xfer->buf), (0xd0), (s->maxpkt * xfer ->nframes));
3554	#endif
3555	usbd_setup_isoc_xfer(xfer->usb_xfer, s->data_pipe, sc,
3556	xfer->sizes, xfer->nframes, USBD_NO_COPY0x01 \| USBD_SHORT_XFER_OK0x04,
3557	uaudio_rdata_intr);
3558
3559	err = usbd_transfer(xfer->usb_xfer);
3560	if (err != 0 && err != USBD_IN_PROGRESS)
3561	printf("%s: rec xfer, err = %d\n", DEVNAME(sc)((sc)->dev.dv_xname), err);
3562
3563	if (++s->data_nextxfer == s->nxfers)
3564	s->data_nextxfer = 0;
3565	}
3566
3567	/*
3568	* Callback called by the USB driver upon completion of rec data transfer.
3569	*/
3570	void
3571	uaudio_rdata_intr(struct usbd_xfer usb_xfer, void arg, usbd_status status)
3572	{
3573	#ifdef UAUDIO_DEBUG
3574	struct timeval tv;
3575	#endif
3576	struct uaudio_softc *sc = arg;
3577	struct uaudio_stream *s = &sc->rstream;
3578	struct uaudio_alt *a = sc->params->ralt;
3579	struct uaudio_xfer *xfer;
3580	unsigned char buf, framebuf;
3581	unsigned int count, fsize, fsize_min, nframes, bpf;
3582	unsigned int data_size, null_count;
3583	unsigned int nintr;
3584
3585	if (status != 0) {
3586	DPRINTF("%s: xfer status = %d\n", __func__, status)do {} while(0);
3587	return;
3588	}
3589
3590	xfer = s->data_xfers + s->data_nextxfer;
3591	if (xfer->usb_xfer != usb_xfer) {
3592	DPRINTF("%s: wrong xfer\n", __func__)do {} while(0);
3593	return;
3594	}
3595
3596	bpf = a->bps * a->nch;
3597	framebuf = xfer->buf;
3598	nframes = 0;
	Value stored to 'nframes' is never read
3599	null_count = 0;
3600	data_size = 0;
3601	fsize_min = s->spf_min / UAUDIO_SPF_DIV327680;
3602	for (nframes = 0; nframes < xfer->nframes; nframes++) {
3603
3604	/*
3605	* Device clock may take some time to lock during which
3606	* we'd receive empty or incomplete packets for which we
3607	* need to generate silence.
3608	*/
3609	fsize = xfer->sizes[nframes];
3610	if (fsize < fsize_min) {
3611	s->spf_remain += s->spf;
3612	fsize = s->spf_remain / UAUDIO_SPF_DIV327680 * bpf;
3613	s->spf_remain %= UAUDIO_SPF_DIV327680;
3614	memset(framebuf, 0, fsize)__builtin_memset((framebuf), (0), (fsize));
3615	null_count++;
3616	}
3617	data_size += fsize;
3618
3619	/*
3620	* fill ring from frame buffer, handling
3621	* boundary conditions
3622	*/
3623	buf = framebuf;
3624	while (fsize > 0) {
3625	count = s->ring_end - s->ring_pos;
3626	if (count > fsize)
3627	count = fsize;
3628	memcpy(s->ring_pos, buf, count)__builtin_memcpy((s->ring_pos), (buf), (count));
3629	s->ring_pos += count;
3630	if (s->ring_pos == s->ring_end)
3631	s->ring_pos = s->ring_start;
3632	buf += count;
3633	fsize -= count;
3634	}
3635
3636	framebuf += s->maxpkt;
3637	}
3638
3639	s->ring_offs += data_size - xfer->size;
3640	s->ring_icnt += data_size;
3641
3642	sc->diff_nsamp -= data_size /
3643	(sc->params->ralt->nch * sc->params->ralt->bps);
3644	sc->diff_nframes -= xfer->nframes;
3645
3646	sc->adjspf_age += xfer->nframes;
3647	if (sc->adjspf_age >= sc->ufps / 8) {
3648	sc->adjspf_age -= sc->ufps / 8;
3649	uaudio_adjspf(sc);
3650	}
3651
3652	#ifdef UAUDIO_DEBUG
3653	if (uaudio_debug >= 2) {
3654	getmicrotime(&tv);
3655	printf("%s: %llu.%06lu: %u: "
3656	"%u bytes of %u, offs -> %d\n",
3657	__func__, tv.tv_sec, tv.tv_usec,
3658	s->data_nextxfer, data_size, xfer->size, s->ring_offs);
3659	}
3660	if (null_count > 0) {
3661	DPRINTF("%s: %u null frames out of %u: incomplete record xfer\n",do {} while(0)
3662	DEVNAME(sc), null_count, xfer->nframes)do {} while(0);
3663	}
3664	#endif
3665	uaudio_rdata_xfer(sc);
3666
3667	nintr = 0;
3668	mtx_enter(&audio_lock);
3669	while (s->ring_icnt >= s->ring_blksz) {
3670	s->intr(s->arg);
3671	s->ring_icnt -= s->ring_blksz;
3672	nintr++;
3673	}
3674	mtx_leave(&audio_lock);
3675	if (nintr != 1)
3676	printf("%s: %u: bad rec intr count\n", DEVNAME(sc)((sc)->dev.dv_xname), nintr);
3677	}
3678
3679	/*
3680	* Start simultaneously playback and recording, unless trigger_input()
3681	* and trigger_output() were not both called yet.
3682	*/
3683	void
3684	uaudio_trigger(struct uaudio_softc *sc)
3685	{
3686	int i, s;
3687
3688	if (sc->mode != sc->trigger_mode)
3689	return;
3690
3691	DPRINTF("%s: preparing\n", __func__)do {} while(0);
3692	if (sc->mode & AUMODE_PLAY0x01) {
3693	for (i = 0; i < sc->pstream.nxfers; i++)
3694	uaudio_pdata_calcsizes(sc, sc->pstream.data_xfers + i);
3695
3696	uaudio_pdata_copy(sc);
3697	}
3698
3699	sc->diff_nsamp = 0;
3700	sc->diff_nframes = 0;
3701	sc->adjspf_age = 0;
3702
3703	DPRINTF("%s: starting\n", __func__)do {} while(0);
3704	s = splusb()splraise(0x2);
3705	for (i = 0; i < UAUDIO_NXFERS_MAX8; i++) {
3706	if ((sc->mode & AUMODE_PLAY0x01) && i < sc->pstream.nxfers) {
3707	if (sc->pstream.sync_pipe)
3708	uaudio_psync_xfer(sc);
3709	uaudio_pdata_xfer(sc);
3710	}
3711	if ((sc->mode & AUMODE_RECORD0x02) && i < sc->rstream.nxfers)
3712	uaudio_rdata_xfer(sc);
3713	}
3714	splx(s)spllower(s);
3715	}
3716
3717	void
3718	uaudio_print(struct uaudio_softc *sc)
3719	{
3720	struct uaudio_unit *u;
3721	struct uaudio_mixent *m;
3722	struct uaudio_params *p;
3723	int pchan = 0, rchan = 0, async = 0;
3724	int nctl = 0;
3725
3726	for (u = sc->unit_list; u != NULL((void *)0); u = u->unit_next) {
3727	m = u->mixent_list;
3728	while (1) {
3729	uaudio_mixer_skip(&m);
3730	if (m == NULL((void *)0))
3731	break;
3732	m = m->next;
3733	nctl++;
3734	}
3735	}
3736
3737	for (p = sc->params_list; p != NULL((void *)0); p = p->next) {
3738	if (p->palt && p->palt->nch > pchan)
3739	pchan = p->palt->nch;
3740	if (p->ralt && p->ralt->nch > rchan)
3741	rchan = p->ralt->nch;
3742	if (p->palt && p->palt->sync_addr)
3743	async = 1;
3744	if (p->ralt && p->ralt->sync_addr)
3745	async = 1;
3746	}
3747
3748	printf("%s: class v%d, %s, %s, channels: %d play, %d rec, %d ctls\n",
3749	DEVNAME(sc)((sc)->dev.dv_xname),
3750	sc->version >> 8,
3751	sc->ufps == 1000 ? "full-speed" : "high-speed",
3752	async ? "async" : "sync",
3753	pchan, rchan, nctl);
3754	}
3755
3756	int
3757	uaudio_match(struct device parent, void match, void *aux)
3758	{
3759	struct usb_attach_arg *arg = aux;
3760	struct usb_interface_descriptor *idesc;
3761
3762	if (arg->iface == NULL((void )0) \|\| arg->device == NULL((void )0))
3763	return UMATCH_NONE0;
3764
3765	idesc = usbd_get_interface_descriptor(arg->iface);
3766	if (idesc == NULL((void *)0)) {
3767	DPRINTF("%s: couldn't get idesc\n", __func__)do {} while(0);
3768	return UMATCH_NONE0;
3769	}
3770
3771	if (idesc->bInterfaceClass != UICLASS_AUDIO0x01 \|\|
3772	idesc->bInterfaceSubClass != UISUBCLASS_AUDIOSTREAM2)
3773	return UMATCH_NONE0;
3774
3775	return UMATCH_VENDOR_PRODUCT_CONF_IFACE8;
3776	}
3777
3778	void
3779	uaudio_attach(struct device parent, struct device self, void *aux)
3780	{
3781	struct uaudio_softc sc = (struct uaudio_softc )self;
3782	struct usb_attach_arg *arg = aux;
3783	struct usb_config_descriptor *cdesc;
3784	struct uaudio_blob desc;
3785
3786	/*
3787	* this device has audio AC or AS or MS interface, get the
3788	* full config descriptor and attach audio devices
3789	*/
3790
3791	cdesc = usbd_get_config_descriptor(arg->device);
3792	if (cdesc == NULL((void *)0))
3793	return;
3794
3795	desc.rptr = (unsigned char *)cdesc;
3796	desc.wptr = desc.rptr + UGETW(cdesc->wTotalLength)((u_int16_t )(cdesc->wTotalLength));
3797
3798	sc->udev = arg->device;
3799	sc->unit_list = NULL((void *)0);
3800	sc->names = NULL((void *)0);
3801	sc->alts = NULL((void *)0);
3802	sc->params_list = NULL((void *)0);
3803	sc->clock = NULL((void *)0);
3804	sc->params = NULL((void *)0);
3805	sc->rate = 0;
3806	sc->mode = 0;
3807	sc->trigger_mode = 0;
3808	sc->copy_todo = 0;
3809
3810	/*
3811	* Ideally the USB host controller should expose the number of
3812	* frames we're allowed to schedule, but there's no such
3813	* interface. The uhci(4) driver can buffer up to 128 frames
3814	* (or it crashes), ehci(4) starts recording null frames if we
3815	* exceed 256 (micro-)frames, ohci(4) works with at most 50
3816	* frames.
3817	*/
3818	switch (sc->udev->speed) {
3819	case USB_SPEED_LOW1:
3820	case USB_SPEED_FULL2:
3821	sc->ufps = 1000;
3822	sc->sync_pktsz = 3;
3823	sc->host_nframes = 50;
3824	break;
3825	case USB_SPEED_HIGH3:
3826	case USB_SPEED_SUPER4:
3827	sc->ufps = 8000;
3828	sc->sync_pktsz = 4;
3829	sc->host_nframes = 240;
3830	break;
3831	default:
3832	printf("%s: unsupported bus speed\n", DEVNAME(sc)((sc)->dev.dv_xname));
3833	return;
3834	}
3835
3836	if (!uaudio_process_conf(sc, &desc))
3837	return;
3838
3839	#ifdef UAUDIO_DEBUG
3840	if (uaudio_debug)
3841	uaudio_conf_print(sc);
3842	#endif
3843	/* print a nice uaudio attach line */
3844	uaudio_print(sc);
3845
3846	audio_attach_mi(&uaudio_hw_if, sc, arg->cookie, &sc->dev);
3847	}
3848
3849	int
3850	uaudio_detach(struct device *self, int flags)
3851	{
3852	struct uaudio_softc sc = (struct uaudio_softc )self;
3853	struct uaudio_unit *unit;
3854	struct uaudio_params *params;
3855	struct uaudio_alt *alt;
3856	struct uaudio_name *name;
3857	struct uaudio_mixent *mixent;
3858	int rv;
3859
3860	rv = config_detach_children(self, flags);
3861
3862	usbd_ref_wait(sc->udev);
3863
3864	while ((alt = sc->alts) != NULL((void *)0)) {
3865	sc->alts = alt->next;
3866	free(alt, M_USBDEV102, sizeof(struct uaudio_alt));
3867	}
3868
3869	while ((params = sc->params_list) != NULL((void *)0)) {
3870	sc->params_list = params->next;
3871	free(params, M_USBDEV102, sizeof(struct uaudio_params));
3872	}
3873
3874	while ((unit = sc->unit_list) != NULL((void *)0)) {
3875	sc->unit_list = unit->unit_next;
3876	while ((mixent = unit->mixent_list) != NULL((void *)0)) {
3877	unit->mixent_list = mixent->next;
3878	uaudio_ranges_clear(&mixent->ranges);
3879	free(mixent, M_USBDEV102, sizeof(struct uaudio_mixent));
3880	}
3881	uaudio_ranges_clear(&unit->rates);
3882	free(unit, M_USBDEV102, sizeof(struct uaudio_unit));
3883	}
3884
3885	while ((name = sc->names)) {
3886	sc->names = name->next;
3887	free(name, M_USBDEV102, sizeof(struct uaudio_name));
3888	}
3889
3890	return rv;
3891	}
3892
3893	int
3894	uaudio_open(void *self, int flags)
3895	{
3896	struct uaudio_softc *sc = self;
3897	struct uaudio_params *p;
3898
3899	if (usbd_is_dying(sc->udev))
3900	return EIO5;
3901
3902	usbd_ref_incr(sc->udev);
3903
3904	flags &= (FREAD0x0001 \| FWRITE0x0002);
3905
3906	for (p = sc->params_list; p != NULL((void *)0); p = p->next) {
3907	switch (flags) {
3908	case FWRITE0x0002:
3909	if (!p->palt)
3910	break;
3911	sc->mode = AUMODE_PLAY0x01;
3912	return 0;
3913	case FREAD0x0001:
3914	if (!p->ralt)
3915	break;
3916	sc->mode = AUMODE_RECORD0x02;
3917	return 0;
3918	case FREAD0x0001 \| FWRITE0x0002:
3919	if (!(p->ralt && p->palt))
3920	break;
3921	sc->mode = AUMODE_RECORD0x02 \| AUMODE_PLAY0x01;
3922	return 0;
3923	}
3924	}
3925
3926	usbd_ref_decr(sc->udev);
3927	return ENXIO6;
3928	}
3929
3930	void
3931	uaudio_close(void *self)
3932	{
3933	struct uaudio_softc *sc = self;
3934
3935	sc->mode = 0;
3936	usbd_ref_decr(sc->udev);
3937	}
3938
3939	int
3940	uaudio_set_params(void *self, int setmode, int usemode,
3941	struct audio_params ap, struct audio_params ar)
3942	{
3943	struct uaudio_softc sc = (struct uaudio_softc )self;
3944	struct uaudio_params p, best_mode, best_rate, best_nch;
3945	int rate, rateindex;
3946
3947	#ifdef DIAGNOSTIC1
3948	if (setmode != usemode \|\| setmode != sc->mode) {
3949	printf("%s: bad call to uaudio_set_params()\n", DEVNAME(sc)((sc)->dev.dv_xname));
3950	return EINVAL22;
3951	}
3952	if (sc->mode == 0) {
3953	printf("%s: uaudio_set_params(): not open\n", DEVNAME(sc)((sc)->dev.dv_xname));
3954	return EINVAL22;
3955	}
3956	#endif
3957	/*
3958	* audio(4) layer requests equal play and record rates
3959	*/
3960	rate = (sc->mode & AUMODE_PLAY0x01) ? ap->sample_rate : ar->sample_rate;
3961	rateindex = uaudio_rates_indexof(~0, rate);
3962
3963	DPRINTF("%s: rate %d -> %d (index %d)\n", __func__,do {} while(0)
3964	rate, uaudio_rates[rateindex], rateindex)do {} while(0);
3965
3966	best_mode = best_rate = best_nch = NULL((void *)0);
3967
3968	for (p = sc->params_list; p != NULL((void *)0); p = p->next) {
3969
3970	/* test if params match the requested mode */
3971	if (sc->mode & AUMODE_PLAY0x01) {
3972	if (p->palt == NULL((void *)0))
3973	continue;
3974	}
3975	if (sc->mode & AUMODE_RECORD0x02) {
3976	if (p->ralt == NULL((void *)0))
3977	continue;
3978	}
3979	if (best_mode == NULL((void *)0))
3980	best_mode = p;
3981
3982	/* test if params match the requested rate */
3983	if ((uaudio_getrates(sc, p) & (1 << rateindex)) == 0)
3984	continue;
3985	if (best_rate == NULL((void *)0))
3986	best_rate = p;
3987
3988	/* test if params match the requested channel counts */
3989	if (sc->mode & AUMODE_PLAY0x01) {
3990	if (p->palt->nch != ap->channels)
3991	continue;
3992	}
3993	if (sc->mode & AUMODE_RECORD0x02) {
3994	if (p->ralt->nch != ar->channels)
3995	continue;
3996	}
3997	if (best_nch == NULL((void *)0))
3998	best_nch = p;
3999
4000	/* test if params match the requested precision */
4001	if (sc->mode & AUMODE_PLAY0x01) {
4002	if (p->palt->bits != ap->precision)
4003	continue;
4004	}
4005	if (sc->mode & AUMODE_RECORD0x02) {
4006	if (p->ralt->bits != ar->precision)
4007	continue;
4008	}
4009
4010	/* everything matched, we're done */
4011	break;
4012	}
4013
4014	if (p == NULL((void *)0)) {
4015	if (best_nch)
4016	p = best_nch;
4017	else if (best_rate)
4018	p = best_rate;
4019	else if (best_mode)
4020	p = best_mode;
4021	else
4022	return ENOTTY25;
4023	}
4024
4025	/*
4026	* Recalculate rate index, because the chosen parameters
4027	* may not support the requested one
4028	*/
4029	rateindex = uaudio_rates_indexof(uaudio_getrates(sc, p), rate);
4030	if (rateindex < 0)
4031	return ENOTTY25;
4032
4033	sc->params = p;
4034	sc->rate = uaudio_rates[rateindex];
4035
4036	DPRINTF("%s: rate = %u\n", __func__, sc->rate)do {} while(0);
4037
4038	if (sc->mode & AUMODE_PLAY0x01) {
4039	ap->sample_rate = sc->rate;
4040	ap->precision = p->palt->bits;
4041	ap->encoding = AUDIO_ENCODING_SLINEAR_LE6;
4042	ap->bps = p->palt->bps;
4043	ap->msb = 1;
4044	ap->channels = p->palt->nch;
4045	}
4046	if (sc->mode & AUMODE_RECORD0x02) {
4047	ar->sample_rate = sc->rate;
4048	ar->precision = p->ralt->bits;
4049	ar->encoding = AUDIO_ENCODING_SLINEAR_LE6;
4050	ar->bps = p->ralt->bps;
4051	ar->msb = 1;
4052	ar->channels = p->ralt->nch;
4053	}
4054
4055	return 0;
4056	}
4057
4058	unsigned int
4059	uaudio_set_blksz(void *self, int mode,
4060	struct audio_params p, struct audio_params r, unsigned int blksz)
4061	{
4062	struct uaudio_softc *sc = self;
4063	unsigned int fps, fps_min;
4064	unsigned int blksz_max, blksz_min;
4065
4066	/*
4067	* minimum block size is two transfers, see uaudio_stream_open()
4068	*/
4069	fps_min = sc->ufps;
4070	if (mode & AUMODE_PLAY0x01) {
4071	fps = sc->params->palt->fps;
4072	if (fps_min > fps)
4073	fps_min = fps;
4074	}
4075	if (mode & AUMODE_RECORD0x02) {
4076	fps = sc->params->ralt->fps;
4077	if (fps_min > fps)
4078	fps_min = fps;
4079	}
4080	blksz_min = (sc->rate * 2 + fps_min - 1) / fps_min;
4081
4082	/*
4083	* max block size is only limited by the number of frames the
4084	* host can schedule
4085	*/
4086	blksz_max = sc->rate * (sc->host_nframes / UAUDIO_NXFERS_MIN2) /
4087	sc->ufps * 85 / 100;
4088
4089	if (blksz > blksz_max)
4090	blksz = blksz_max;
4091	else if (blksz < blksz_min)
4092	blksz = blksz_min;
4093
4094	return blksz;
4095	}
4096
4097	int
4098	uaudio_trigger_output(void self, void start, void *end, int blksz,
4099	void (intr)(void ), void arg, struct audio_params param)
4100	{
4101	struct uaudio_softc *sc = self;
4102	int err;
4103
4104	err = uaudio_stream_open(sc,
4105	AUMODE_PLAY0x01, start, end, blksz, intr, arg);
4106	if (err)
4107	return err;
4108
4109	sc->trigger_mode \|= AUMODE_PLAY0x01;
4110	uaudio_trigger(sc);
4111	return 0;
4112	}
4113
4114	int
4115	uaudio_trigger_input(void self, void start, void *end, int blksz,
4116	void (intr)(void ), void arg, struct audio_params param)
4117	{
4118	struct uaudio_softc *sc = self;
4119	int err;
4120
4121	err = uaudio_stream_open(sc,
4122	AUMODE_RECORD0x02, start, end, blksz, intr, arg);
4123	if (err)
4124	return err;
4125
4126	sc->trigger_mode \|= AUMODE_RECORD0x02;
4127	uaudio_trigger(sc);
4128	return 0;
4129	}
4130
4131	void
4132	uaudio_copy_output(void *self, size_t todo)
4133	{
4134	struct uaudio_softc sc = (struct uaudio_softc )self;
4135	int s;
4136
4137	s = splusb()splraise(0x2);
4138	sc->copy_todo += todo;
4139
4140	#ifdef UAUDIO_DEBUG
4141	if (uaudio_debug >= 3) {
4142	printf("%s: copy_todo -> %zd (+%zd)\n", __func__,
4143	sc->copy_todo, todo);
4144	}
4145	#endif
4146
4147	if (sc->mode == sc->trigger_mode)
4148	uaudio_pdata_copy(sc);
4149	splx(s)spllower(s);
4150	}
4151
4152	void
4153	uaudio_underrun(void *self)
4154	{
4155	struct uaudio_softc sc = (struct uaudio_softc )self;
4156	struct uaudio_stream *s = &sc->pstream;
4157
4158	sc->copy_todo += s->ring_blksz;
4159
4160	#ifdef UAUDIO_DEBUG
4161	if (uaudio_debug >= 3)
4162	printf("%s: copy_todo -> %zd\n", __func__, sc->copy_todo);
4163	#endif
4164
4165	/* copy data (actually silence) produced by the audio(4) layer */
4166	uaudio_pdata_copy(sc);
4167	}
4168
4169	int
4170	uaudio_halt_output(void *self)
4171	{
4172	struct uaudio_softc sc = (struct uaudio_softc )self;
4173
4174	uaudio_stream_close(sc, AUMODE_PLAY0x01);
4175	sc->trigger_mode &= ~AUMODE_PLAY0x01;
4176	sc->copy_todo = 0;
4177	return 0;
4178	}
4179
4180	int
4181	uaudio_halt_input(void *self)
4182	{
4183	struct uaudio_softc sc = (struct uaudio_softc )self;
4184
4185	uaudio_stream_close(sc, AUMODE_RECORD0x02);
4186	sc->trigger_mode &= ~AUMODE_RECORD0x02;
4187	return 0;
4188	}
4189
4190	int
4191	uaudio_get_port_do(struct uaudio_softc sc, struct mixer_ctrl ctl)
4192	{
4193	struct uaudio_unit *u;
4194	struct uaudio_mixent *m;
4195	unsigned char req_buf[4];
4196	struct uaudio_blob p;
4197	int i, nch, val, req_num;
4198
4199	if (!uaudio_mixer_byindex(sc, ctl->dev, &u, &m))
4200	return ENOENT2;
4201
4202	switch (sc->version) {
4203	case UAUDIO_V10x100:
4204	req_num = UAUDIO_V1_REQ_GET_CUR0x81;
4205	break;
4206	case UAUDIO_V20x200:
4207	req_num = UAUDIO_V2_REQ_CUR1;
4208	}
4209
4210	switch (m->type) {
4211	case UAUDIO_MIX_SW0:
4212	p.rptr = p.wptr = req_buf;
4213	if (!uaudio_req(sc,
4214	UT_READ_CLASS_INTERFACE(0x80 \| 0x20 \| 0x01),
4215	req_num,
4216	m->req_sel,
4217	m->chan < 0 ? 0 : m->chan,
4218	sc->ctl_ifnum,
4219	u->id,
4220	req_buf,
4221	1))
4222	return EIO5;
4223	p.wptr++;
4224	if (!uaudio_getnum(&p, 1, &val))
4225	return EIO5;
4226	ctl->un.ord = !!val;
4227	break;
4228	case UAUDIO_MIX_NUM1:
4229	nch = uaudio_mixer_nchan(m, NULL((void *)0));
4230	ctl->un.value.num_channels = nch;
4231	for (i = 0; i < nch; i++) {
4232	p.rptr = p.wptr = req_buf;
4233	if (!uaudio_req(sc,
4234	UT_READ_CLASS_INTERFACE(0x80 \| 0x20 \| 0x01),
4235	req_num,
4236	m->req_sel,
4237	m->chan < 0 ? 0 : i + 1,
4238	sc->ctl_ifnum,
4239	u->id,
4240	req_buf,
4241	2))
4242	return EIO5;
4243	p.wptr += 2;
4244	if (!uaudio_getnum(&p, 2, &val))
4245	return EIO5;
4246	ctl->un.value.level[i] =
4247	uaudio_ranges_decode(&m->ranges,
4248	uaudio_sign_expand(val, 2));
4249	m = m->next;
4250	}
4251	break;
4252	case UAUDIO_MIX_ENUM2:
4253	/* XXX: not used yet */
4254	break;
4255	}
4256	return 0;
4257	}
4258
4259	int
4260	uaudio_set_port_do(struct uaudio_softc sc, struct mixer_ctrl ctl)
4261	{
4262	struct uaudio_unit *u;
4263	struct uaudio_mixent *m;
4264	unsigned char req_buf[4];
4265	unsigned int val;
4266	int i, nch;
4267
4268	if (!uaudio_mixer_byindex(sc, ctl->dev, &u, &m))
4269	return ENOENT2;
4270
4271	switch (m->type) {
4272	case UAUDIO_MIX_SW0:
4273	if (ctl->un.ord < 0 \|\| ctl->un.ord > 1)
4274	return EINVAL22;
4275	req_buf[0] = ctl->un.ord;
4276	if (!uaudio_req(sc,
4277	UT_WRITE_CLASS_INTERFACE(0x00 \| 0x20 \| 0x01),
4278	UAUDIO_V1_REQ_SET_CUR0x01,
4279	m->req_sel,
4280	m->chan < 0 ? 0 : m->chan,
4281	sc->ctl_ifnum,
4282	u->id,
4283	req_buf,
4284	1))
4285	return EIO5;
4286	break;
4287	case UAUDIO_MIX_NUM1:
4288	nch = uaudio_mixer_nchan(m, NULL((void *)0));
4289	ctl->un.value.num_channels = nch;
4290	for (i = 0; i < nch; i++) {
4291	val = uaudio_ranges_encode(&m->ranges,
4292	ctl->un.value.level[i]);
4293	DPRINTF("%s: ch %d, ctl %d, num val %d\n", __func__,do {} while(0)
4294	i, ctl->un.value.level[i], val)do {} while(0);
4295	req_buf[0] = val;
4296	req_buf[1] = val >> 8;
4297	if (!uaudio_req(sc,
4298	UT_WRITE_CLASS_INTERFACE(0x00 \| 0x20 \| 0x01),
4299	UAUDIO_V1_REQ_SET_CUR0x01,
4300	m->req_sel,
4301	m->chan < 0 ? 0 : i + 1,
4302	sc->ctl_ifnum,
4303	u->id,
4304	req_buf,
4305	2))
4306	return EIO5;
4307	m = m->next;
4308	}
4309	break;
4310	case UAUDIO_MIX_ENUM2:
4311	/* XXX: not used yet */
4312	break;
4313	}
4314	return 0;
4315	}
4316
4317	int
4318	uaudio_query_devinfo_do(struct uaudio_softc sc, struct mixer_devinfo devinfo)
4319	{
4320	struct uaudio_unit *u;
4321	struct uaudio_mixent *m;
4322
4323	devinfo->next = -1;
4324	devinfo->prev = -1;
4325	switch (devinfo->index) {
4326	case UAUDIO_CLASS_IN1:
4327	strlcpy(devinfo->label.name, AudioCinputs"inputs", MAX_AUDIO_DEV_LEN16);
4328	devinfo->type = AUDIO_MIXER_CLASS0;
4329	devinfo->mixer_class = -1;
4330	return 0;
4331	case UAUDIO_CLASS_OUT0:
4332	strlcpy(devinfo->label.name, AudioCoutputs"outputs", MAX_AUDIO_DEV_LEN16);
4333	devinfo->type = AUDIO_MIXER_CLASS0;
4334	devinfo->mixer_class = -1;
4335	return 0;
4336	}
4337
4338	/*
4339	* find the unit & mixent structure for the given index
4340	*/
4341	if (!uaudio_mixer_byindex(sc, devinfo->index, &u, &m))
4342	return ENOENT2;
4343
4344	if (strcmp(m->fname, "level") == 0) {
4345	/*
4346	* mixer(4) interface doesn't give a names to level
4347	* controls
4348	*/
4349	strlcpy(devinfo->label.name, u->name, MAX_AUDIO_DEV_LEN16);
4350	} else {
4351	if (m->chan == -1) {
4352	snprintf(devinfo->label.name, MAX_AUDIO_DEV_LEN16,
4353	"%s_%s", u->name, m->fname);
4354	} else {
4355	snprintf(devinfo->label.name, MAX_AUDIO_DEV_LEN16,
4356	"%s_%s%u", u->name, m->fname, m->chan);
4357	}
4358	}
4359
4360	devinfo->mixer_class = u->mixer_class;
4361	switch (m->type) {
4362	case UAUDIO_MIX_SW0:
4363	devinfo->type = AUDIO_MIXER_ENUM1;
4364	devinfo->un.e.num_mem = 2;
4365	devinfo->un.e.member[0].ord = 0;
4366	strlcpy(devinfo->un.e.member[0].label.name, "off",
4367	MAX_AUDIO_DEV_LEN16);
4368	devinfo->un.e.member[1].ord = 1;
4369	strlcpy(devinfo->un.e.member[1].label.name, "on",
4370	MAX_AUDIO_DEV_LEN16);
4371	break;
4372	case UAUDIO_MIX_NUM1:
4373	devinfo->type = AUDIO_MIXER_VALUE3;
4374	devinfo->un.v.num_channels = uaudio_mixer_nchan(m, NULL((void *)0));
4375	devinfo->un.v.delta = 1;
4376	break;
4377	case UAUDIO_MIX_ENUM2:
4378	/* XXX: not used yet */
4379	devinfo->type = AUDIO_MIXER_ENUM1;
4380	devinfo->un.e.num_mem = 0;
4381	break;
4382	}
4383	return 0;
4384	}
4385
4386	int
4387	uaudio_get_port(void arg, struct mixer_ctrl ctl)
4388	{
4389	struct uaudio_softc *sc = arg;
4390	int rc;
4391
4392	usbd_ref_incr(sc->udev);
4393	rc = uaudio_get_port_do(sc, ctl);
4394	usbd_ref_decr(sc->udev);
4395	return rc;
4396	}
4397
4398	int
4399	uaudio_set_port(void arg, struct mixer_ctrl ctl)
4400	{
4401	struct uaudio_softc *sc = arg;
4402	int rc;
4403
4404	usbd_ref_incr(sc->udev);
4405	rc = uaudio_set_port_do(sc, ctl);
4406	usbd_ref_decr(sc->udev);
4407	return rc;
4408	}
4409
4410	int
4411	uaudio_query_devinfo(void arg, struct mixer_devinfo devinfo)
4412	{
4413	struct uaudio_softc *sc = arg;
4414	int rc;
4415
4416	usbd_ref_incr(sc->udev);
4417	rc = uaudio_query_devinfo_do(sc, devinfo);
4418	usbd_ref_decr(sc->udev);
4419	return rc;
4420	}