| blob | 3394c34320117542ccab9adc4607a1caedb18f53 |
1 /*
2 * uvc_video.c -- USB Video Class driver - Video handling
3 *
4 * Copyright (C) 2005-2010
5 * Laurent Pinchart (laurent.pinchart@ideasonboard.com)
6 *
7 * This program is free software; you can redistribute it and/or modify
8 * it under the terms of the GNU General Public License as published by
9 * the Free Software Foundation; either version 2 of the License, or
10 * (at your option) any later version.
11 *
12 */
14 #include <linux/kernel.h>
15 #include <linux/list.h>
16 #include <linux/module.h>
17 #include <linux/slab.h>
18 #include <linux/usb.h>
19 #include <linux/videodev2.h>
20 #include <linux/vmalloc.h>
21 #include <linux/wait.h>
22 #include <linux/atomic.h>
23 #include <asm/unaligned.h>
25 #include <media/v4l2-common.h>
29 /* ------------------------------------------------------------------------
30 * UVC Controls
31 */
36 {
46 }
49 {
69 }
70 }
74 {
78 UVC_CTRL_CONTROL_TIMEOUT);
84 }
87 }
91 {
100 }
101 }
110 }
111 }
125 u32 interval;
126 u32 bandwidth;
132 /* Compute a bandwidth estimation by multiplying the frame
133 * size by the number of video frames per second, divide the
134 * result by the number of USB frames (or micro-frames for
135 * high-speed devices) per second and add the UVC header size
136 * (assumed to be 12 bytes long).
137 */
145 /* The bandwidth estimate is too low for many cameras. Don't use
146 * maximum packet sizes lower than 1024 bytes to try and work
147 * around the problem. According to measurements done on two
148 * different camera models, the value is high enough to get most
149 * resolutions working while not preventing two simultaneous
150 * VGA streams at 15 fps.
151 */
155 }
156 }
160 {
162 __u16 size;
179 /* Some cameras, mostly based on Bison Electronics chipsets,
180 * answer a GET_MIN or GET_MAX request with the wCompQuality
181 * field only.
182 */
184 "compliance - GET_MIN/MAX(PROBE) incorrectly "
191 /* Many cameras don't support the GET_DEF request on their
192 * video probe control. Warn once and return, the caller will
193 * fall back to GET_CUR.
194 */
196 "compliance - GET_DEF(PROBE) not supported. "
206 }
232 }
234 /* Some broken devices return null or wrong dwMaxVideoFrameSize and
235 * dwMaxPayloadTransferSize fields. Try to get the value from the
236 * format and frame descriptors.
237 */
241 out:
244 }
248 {
250 __u16 size;
276 }
286 }
290 }
294 {
296 __u16 bandwidth;
300 /* Perform probing. The device should adjust the requested values
301 * according to its capabilities. However, some devices, namely the
302 * first generation UVC Logitech webcams, don't implement the Video
303 * Probe control properly, and just return the needed bandwidth. For
304 * that reason, if the needed bandwidth exceeds the maximum available
305 * bandwidth, try to lower the quality.
306 */
311 /* Get the minimum and maximum values for compression settings. */
321 }
341 }
343 /* TODO: negotiate compression parameters */
348 }
350 done:
352 }
356 {
358 }
360 /* -----------------------------------------------------------------------------
361 * Clocks and timestamps
362 */
364 static void
367 {
374 u16 host_sof;
375 u16 dev_sof;
394 }
396 /* Check for invalid headers. */
400 /* Extract the timestamps:
401 *
402 * - store the frame PTS in the buffer structure
403 * - if the SCR field is present, retrieve the host SOF counter and
404 * kernel timestamps and store them with the SCR STC and SOF fields
405 * in the ring buffer
406 */
413 /* To limit the amount of data, drop SCRs with an SOF identical to the
414 * previous one.
415 */
425 /* The UVC specification allows device implementations that can't obtain
426 * the USB frame number to keep their own frame counters as long as they
427 * match the size and frequency of the frame number associated with USB
428 * SOF tokens. The SOF values sent by such devices differ from the USB
429 * SOF tokens by a fixed offset that needs to be estimated and accounted
430 * for to make timestamp recovery as accurate as possible.
431 *
432 * The offset is estimated the first time a device SOF value is received
433 * as the difference between the host and device SOF values. As the two
434 * SOF values can differ slightly due to transmission delays, consider
435 * that the offset is null if the difference is not higher than 10 ms
436 * (negative differences can not happen and are thus considered as an
437 * offset). The video commit control wDelay field should be used to
438 * compute a dynamic threshold instead of using a fixed 10 ms value, but
439 * devices don't report reliable wDelay values.
440 *
441 * See uvc_video_clock_host_sof() for an explanation regarding why only
442 * the 8 LSBs of the delta are kept.
443 */
448 else
450 }
462 /* Update the sliding window head and count. */
469 }
472 {
479 }
482 {
489 GFP_KERNEL);
496 }
499 {
502 }
504 /*
505 * uvc_video_clock_host_sof - Return the host SOF value for a clock sample
506 *
507 * Host SOF counters reported by usb_get_current_frame_number() usually don't
508 * cover the whole 11-bits SOF range (0-2047) but are limited to the HCI frame
509 * schedule window. They can be limited to 8, 9 or 10 bits depending on the host
510 * controller and its configuration.
511 *
512 * We thus need to recover the SOF value corresponding to the host frame number.
513 * As the device and host frame numbers are sampled in a short interval, the
514 * difference between their values should be equal to a small delta plus an
515 * integer multiple of 256 caused by the host frame number limited precision.
516 *
517 * To obtain the recovered host SOF value, compute the small delta by masking
518 * the high bits of the host frame counter and device SOF difference and add it
519 * to the device SOF value.
520 */
522 {
523 /* The delta value can be negative. */
524 s8 delta_sof;
529 }
531 /*
532 * uvc_video_clock_update - Update the buffer timestamp
533 *
534 * This function converts the buffer PTS timestamp to the host clock domain by
535 * going through the USB SOF clock domain and stores the result in the V4L2
536 * buffer timestamp field.
537 *
538 * The relationship between the device clock and the host clock isn't known.
539 * However, the device and the host share the common USB SOF clock which can be
540 * used to recover that relationship.
541 *
542 * The relationship between the device clock and the USB SOF clock is considered
543 * to be linear over the clock samples sliding window and is given by
544 *
545 * SOF = m * PTS + p
546 *
547 * Several methods to compute the slope (m) and intercept (p) can be used. As
548 * the clock drift should be small compared to the sliding window size, we
549 * assume that the line that goes through the points at both ends of the window
550 * is a good approximation. Naming those points P1 and P2, we get
551 *
552 * SOF = (SOF2 - SOF1) / (STC2 - STC1) * PTS
553 * + (SOF1 * STC2 - SOF2 * STC1) / (STC2 - STC1)
554 *
555 * or
556 *
557 * SOF = ((SOF2 - SOF1) * PTS + SOF1 * STC2 - SOF2 * STC1) / (STC2 - STC1) (1)
558 *
559 * to avoid loosing precision in the division. Similarly, the host timestamp is
560 * computed with
561 *
562 * TS = ((TS2 - TS1) * PTS + TS1 * SOF2 - TS2 * SOF1) / (SOF2 - SOF1) (2)
563 *
564 * SOF values are coded on 11 bits by USB. We extend their precision with 16
565 * decimal bits, leading to a 11.16 coding.
566 *
567 * TODO: To avoid surprises with device clock values, PTS/STC timestamps should
568 * be normalized using the nominal device clock frequency reported through the
569 * UVC descriptors.
570 *
571 * Both the PTS/STC and SOF counters roll over, after a fixed but device
572 * specific amount of time for PTS/STC and after 2048ms for SOF. As long as the
573 * sliding window size is smaller than the rollover period, differences computed
574 * on unsigned integers will produce the correct result. However, the p term in
575 * the linear relations will be miscomputed.
576 *
577 * To fix the issue, we subtract a constant from the PTS and STC values to bring
578 * PTS to half the 32 bit STC range. The sliding window STC values then fit into
579 * the 32 bit range without any rollover.
580 *
581 * Similarly, we add 2048 to the device SOF values to make sure that the SOF
582 * computed by (1) will never be smaller than 0. This offset is then compensated
583 * by adding 2048 to the SOF values used in (2). However, this doesn't prevent
584 * rollovers between (1) and (2): the SOF value computed by (1) can be slightly
585 * lower than 4096, and the host SOF counters can have rolled over to 2048. This
586 * case is handled by subtracting 2048 from the SOF value if it exceeds the host
587 * SOF value at the end of the sliding window.
588 *
589 * Finally we subtract a constant from the host timestamps to bring the first
590 * timestamp of the sliding window to 1s.
591 */
595 {
601 u32 delta_stc;
604 u32 mean;
605 u32 sof;
606 u32 div;
607 u32 rem;
608 u64 y;
618 /* First step, PTS to SOF conversion. */
643 /* Second step, SOF to host clock conversion. */
655 /* Interpolated and host SOF timestamps can wrap around at slightly
656 * different times. Handle this by adding or removing 2048 to or from
657 * the computed SOF value to keep it close to the SOF samples mean
658 * value.
659 */
676 }
687 /* Update the V4L2 buffer. */
691 done:
693 }
695 /* ------------------------------------------------------------------------
696 * Stream statistics
697 */
701 {
730 }
732 /* Check for invalid headers. */
736 }
738 /* Extract the timestamps. */
745 }
747 /* Is PTS constant through the whole frame ? */
753 }
754 }
759 }
761 /* Do all frames have a PTS in their first non-empty packet, or before
762 * their first empty packet ?
763 */
769 }
771 /* Do the SCR.STC and SCR.SOF fields vary through the frame ? */
775 }
778 /* Expand the SOF counter to 32 bits and store its value. */
793 }
795 /* Record the first non-empty packet number. */
799 /* Update the frame size. */
802 /* Update the packets counters. */
809 }
812 {
816 "%u/%u/%u pts (%searly %sinitial), %u/%u scr, "
844 }
848 {
861 }
863 /* Compute the SCR.SOF frequency estimate. At the nominal 1kHz SOF
864 * frequency this will not overflow before more than 1h.
865 */
870 else
897 }
900 {
903 }
906 {
908 }
910 /* ------------------------------------------------------------------------
911 * Video codecs
912 */
914 /* Video payload decoding is handled by uvc_video_decode_start(),
915 * uvc_video_decode_data() and uvc_video_decode_end().
916 *
917 * uvc_video_decode_start is called with URB data at the start of a bulk or
918 * isochronous payload. It processes header data and returns the header size
919 * in bytes if successful. If an error occurs, it returns a negative error
920 * code. The following error codes have special meanings.
921 *
922 * - EAGAIN informs the caller that the current video buffer should be marked
923 * as done, and that the function should be called again with the same data
924 * and a new video buffer. This is used when end of frame conditions can be
925 * reliably detected at the beginning of the next frame only.
926 *
927 * If an error other than -EAGAIN is returned, the caller will drop the current
928 * payload. No call to uvc_video_decode_data and uvc_video_decode_end will be
929 * made until the next payload. -ENODATA can be used to drop the current
930 * payload if no other error code is appropriate.
931 *
932 * uvc_video_decode_data is called for every URB with URB data. It copies the
933 * data to the video buffer.
934 *
935 * uvc_video_decode_end is called with header data at the end of a bulk or
936 * isochronous payload. It performs any additional header data processing and
937 * returns 0 or a negative error code if an error occurred. As header data have
938 * already been processed by uvc_video_decode_start, this functions isn't
939 * required to perform sanity checks a second time.
940 *
941 * For isochronous transfers where a payload is always transferred in a single
942 * URB, the three functions will be called in a row.
943 *
944 * To let the decoder process header data and update its internal state even
945 * when no video buffer is available, uvc_video_decode_start must be prepared
946 * to be called with a NULL buf parameter. uvc_video_decode_data and
947 * uvc_video_decode_end will never be called with a NULL buffer.
948 */
951 {
952 __u8 fid;
954 /* Sanity checks:
955 * - packet must be at least 2 bytes long
956 * - bHeaderLength value must be at least 2 bytes (see above)
957 * - bHeaderLength value can't be larger than the packet size.
958 */
962 }
966 /* Increase the sequence number regardless of any buffer states, so
967 * that discontinuous sequence numbers always indicate lost frames.
968 */
973 }
978 /* Store the payload FID bit and return immediately when the buffer is
979 * NULL.
980 */
984 }
986 /* Mark the buffer as bad if the error bit is set. */
991 }
993 /* Synchronize to the input stream by waiting for the FID bit to be
994 * toggled when the the buffer state is not UVC_BUF_STATE_ACTIVE.
995 * stream->last_fid is initialized to -1, so the first isochronous
996 * frame will always be in sync.
997 *
998 * If the device doesn't toggle the FID bit, invert stream->last_fid
999 * when the EOF bit is set to force synchronisation on the next packet.
1000 */
1011 }
1015 else
1023 /* TODO: Handle PTS and SCR. */
1025 }
1027 /* Mark the buffer as done if we're at the beginning of a new frame.
1028 * End of frame detection is better implemented by checking the EOF
1029 * bit (FID bit toggling is delayed by one frame compared to the EOF
1030 * bit), but some devices don't set the bit at end of frame (and the
1031 * last payload can be lost anyway). We thus must check if the FID has
1032 * been toggled.
1033 *
1034 * stream->last_fid is initialized to -1, so the first isochronous
1035 * frame will never trigger an end of frame detection.
1036 *
1037 * Empty buffers (bytesused == 0) don't trigger end of frame detection
1038 * as it doesn't make sense to return an empty buffer. This also
1039 * avoids detecting end of frame conditions at FID toggling if the
1040 * previous payload had the EOF bit set.
1041 */
1047 }
1052 }
1056 {
1063 /* Copy the video data to the buffer. */
1070 /* Complete the current frame if the buffer size was exceeded. */
1074 }
1075 }
1079 {
1080 /* Mark the buffer as done if the EOF marker is set. */
1088 }
1089 }
1091 /* Video payload encoding is handled by uvc_video_encode_header() and
1092 * uvc_video_encode_data(). Only bulk transfers are currently supported.
1093 *
1094 * uvc_video_encode_header is called at the start of a payload. It adds header
1095 * data to the transfer buffer and returns the header size. As the only known
1096 * UVC output device transfers a whole frame in a single payload, the EOF bit
1097 * is always set in the header.
1098 *
1099 * uvc_video_encode_data is called for every URB and copies the data from the
1100 * video buffer to the transfer buffer.
1101 */
1104 {
1109 }
1113 {
1118 /* Copy video data to the URB buffer. */
1122 nbytes);
1128 }
1130 /* ------------------------------------------------------------------------
1131 * URB handling
1132 */
1134 /*
1135 * Completion handler for video URBs.
1136 */
1139 {
1147 /* Mark the buffer as faulty. */
1151 }
1153 /* Decode the payload header. */
1160 buf);
1166 /* Decode the payload data. */
1170 /* Process the header again. */
1177 UVC_FMT_FLAG_COMPRESSED))
1181 }
1182 }
1183 }
1187 {
1191 /*
1192 * Ignore ZLPs if they're not part of a frame, otherwise process them
1193 * to trigger the end of payload detection.
1194 */
1202 /* If the URB is the first of its payload, decode and save the
1203 * header.
1204 */
1210 buf);
1213 /* If an error occurred skip the rest of the payload. */
1222 }
1223 }
1225 /* The buffer queue might have been cancelled while a bulk transfer
1226 * was in progress, so we can reach here with buf equal to NULL. Make
1227 * sure buf is never dereferenced if NULL.
1228 */
1230 /* Process video data. */
1234 /* Detect the payload end by a URB smaller than the maximum size (or
1235 * a payload size equal to the maximum) and process the header again.
1236 */
1244 buf);
1245 }
1250 }
1251 }
1255 {
1262 }
1264 /* If the URB is the first of its payload, add the header. */
1271 }
1273 /* Process video data. */
1287 }
1291 }
1294 }
1297 {
1320 }
1325 queue);
1332 ret);
1333 }
1334 }
1336 /*
1337 * Free transfer buffers.
1338 */
1340 {
1345 #ifndef CONFIG_DMA_NONCOHERENT
1348 #else
1350 #endif
1352 }
1353 }
1356 }
1358 /*
1359 * Allocate transfer buffers. This function can be called with buffers
1360 * already allocated when resuming from suspend, in which case it will
1361 * return without touching the buffers.
1362 *
1363 * Limit the buffer size to UVC_MAX_PACKETS bulk/isochronous packets. If the
1364 * system is too low on memory try successively smaller numbers of packets
1365 * until allocation succeeds.
1366 *
1367 * Return the number of allocated packets on success or 0 when out of memory.
1368 */
1371 {
1375 /* Buffers are already allocated, bail out. */
1379 /* Compute the number of packets. Bulk endpoints might transfer UVC
1380 * payloads across multiple URBs.
1381 */
1386 /* Retry allocations until one succeed. */
1390 #ifndef CONFIG_DMA_NONCOHERENT
1394 #else
1397 #endif
1401 }
1402 }
1407 psize);
1409 }
1410 }
1415 }
1417 /*
1418 * Uninitialize isochronous/bulk URBs and free transfer buffers.
1419 */
1421 {
1435 }
1439 }
1441 /*
1442 * Compute the maximum number of bytes per interval for an endpoint.
1443 */
1446 {
1447 u16 psize;
1458 }
1459 }
1461 /*
1462 * Initialize isochronous URBs and allocate transfer buffers. The packet size
1463 * is given by the endpoint.
1464 */
1467 {
1470 u16 psize;
1471 u32 size;
1487 }
1493 #ifndef CONFIG_DMA_NONCOHERENT
1496 #else
1498 #endif
1508 }
1511 }
1514 }
1516 /*
1517 * Initialize bulk URBs and allocate transfer buffers. The packet size is
1518 * given by the endpoint.
1519 */
1522 {
1525 u16 psize;
1526 u32 size;
1541 else
1553 }
1557 stream);
1558 #ifndef CONFIG_DMA_NONCOHERENT
1561 #endif
1564 }
1567 }
1569 /*
1570 * Initialize isochronous/bulk URBs and allocate transfer buffers.
1571 */
1573 {
1594 /* Isochronous endpoint, select the alternate setting. */
1604 }
1616 /* Check if the bandwidth is high enough. */
1622 }
1623 }
1629 }
1640 /* Bulk endpoint, proceed to URB initialization. */
1647 }
1652 /* Submit the URBs. */
1660 }
1661 }
1664 }
1666 /* --------------------------------------------------------------------------
1667 * Suspend/resume
1668 */
1670 /*
1671 * Stop streaming without disabling the video queue.
1672 *
1673 * To let userspace applications resume without trouble, we must not touch the
1674 * video buffers in any way. We mark the device as frozen to make sure the URB
1675 * completion handler won't try to cancel the queue when we kill the URBs.
1676 */
1678 {
1686 }
1688 /*
1689 * Reconfigure the video interface and restart streaming if it was enabled
1690 * before suspend.
1691 *
1692 * If an error occurs, disable the video queue. This will wake all pending
1693 * buffers, making sure userspace applications are notified of the problem
1694 * instead of waiting forever.
1695 */
1697 {
1700 /* If the bus has been reset on resume, set the alternate setting to 0.
1701 * This should be the default value, but some devices crash or otherwise
1702 * misbehave if they don't receive a SET_INTERFACE request before any
1703 * other video control request.
1704 */
1716 }
1726 }
1728 /* ------------------------------------------------------------------------
1729 * Video device
1730 */
1732 /*
1733 * Initialize the UVC video device by switching to alternate setting 0 and
1734 * retrieve the default format.
1735 *
1736 * Some cameras (namely the Fuji Finepix) set the format and frame
1737 * indexes to zero. The UVC standard doesn't clearly make this a spec
1738 * violation, so try to silently fix the values if possible.
1739 *
1740 * This function is called before registering the device with V4L.
1741 */
1743 {
1753 }
1757 /* Initialize the video buffers queue. */
1762 /* Alternate setting 0 should be the default, yet the XBox Live Vision
1763 * Cam (and possibly other devices) crash or otherwise misbehave if
1764 * they don't receive a SET_INTERFACE request before any other video
1765 * control request.
1766 */
1769 /* Set the streaming probe control with default streaming parameters
1770 * retrieved from the device. Webcams that don't suport GET_DEF
1771 * requests on the probe control will just keep their current streaming
1772 * parameters.
1773 */
1777 /* Initialize the streaming parameters with the probe control current
1778 * value. This makes sure SET_CUR requests on the streaming commit
1779 * control will always use values retrieved from a successful GET_CUR
1780 * request on the probe control, as required by the UVC specification.
1781 */
1786 /* Check if the default format descriptor exists. Use the first
1787 * available format otherwise.
1788 */
1793 }
1799 }
1801 /* Zero bFrameIndex might be correct. Stream-based formats (including
1802 * MPEG-2 TS and DV) do not support frames but have a dummy frame
1803 * descriptor with bFrameIndex set to zero. If the default frame
1804 * descriptor is not found, use the first available frame.
1805 */
1810 }
1819 /* Select the video decoding function */
1825 else
1834 }
1835 }
1838 }
1840 /*
1841 * Enable or disable the video stream.
1842 */
1844 {
1853 }
1863 /* Commit the streaming parameters. */
1874 error_video:
1876 error_commit:
1878 error_queue:
1882 }