DaVinci: EDMA: Add queue 2 and 3 for DM365 and DM6467
[linux-ginger.git] / drivers / ieee1394 / dv1394.c
blob2cd00b5b45b464ddf60d9862d3178b51660a634a
1 /*
2 * dv1394.c - DV input/output over IEEE 1394 on OHCI chips
3 * Copyright (C)2001 Daniel Maas <dmaas@dcine.com>
4 * receive by Dan Dennedy <dan@dennedy.org>
6 * based on:
7 * video1394.c - video driver for OHCI 1394 boards
8 * Copyright (C)1999,2000 Sebastien Rougeaux <sebastien.rougeaux@anu.edu.au>
10 * This program is free software; you can redistribute it and/or modify
11 * it under the terms of the GNU General Public License as published by
12 * the Free Software Foundation; either version 2 of the License, or
13 * (at your option) any later version.
15 * This program is distributed in the hope that it will be useful,
16 * but WITHOUT ANY WARRANTY; without even the implied warranty of
17 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
18 * GNU General Public License for more details.
20 * You should have received a copy of the GNU General Public License
21 * along with this program; if not, write to the Free Software Foundation,
22 * Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA.
26 OVERVIEW
28 I designed dv1394 as a "pipe" that you can use to shoot DV onto a
29 FireWire bus. In transmission mode, dv1394 does the following:
31 1. accepts contiguous frames of DV data from user-space, via write()
32 or mmap() (see dv1394.h for the complete API)
33 2. wraps IEC 61883 packets around the DV data, inserting
34 empty synchronization packets as necessary
35 3. assigns accurate SYT timestamps to the outgoing packets
36 4. shoots them out using the OHCI card's IT DMA engine
38 Thanks to Dan Dennedy, we now have a receive mode that does the following:
40 1. accepts raw IEC 61883 packets from the OHCI card
41 2. re-assembles the DV data payloads into contiguous frames,
42 discarding empty packets
43 3. sends the DV data to user-space via read() or mmap()
47 TODO:
49 - tunable frame-drop behavior: either loop last frame, or halt transmission
51 - use a scatter/gather buffer for DMA programs (f->descriptor_pool)
52 so that we don't rely on allocating 64KB of contiguous kernel memory
53 via pci_alloc_consistent()
55 DONE:
56 - during reception, better handling of dropped frames and continuity errors
57 - during reception, prevent DMA from bypassing the irq tasklets
58 - reduce irq rate during reception (1/250 packets).
59 - add many more internal buffers during reception with scatter/gather dma.
60 - add dbc (continuity) checking on receive, increment status.dropped_frames
61 if not continuous.
62 - restart IT DMA after a bus reset
63 - safely obtain and release ISO Tx channels in cooperation with OHCI driver
64 - map received DIF blocks to their proper location in DV frame (ensure
65 recovery if dropped packet)
66 - handle bus resets gracefully (OHCI card seems to take care of this itself(!))
67 - do not allow resizing the user_buf once allocated; eliminate nuke_buffer_mappings
68 - eliminated #ifdef DV1394_DEBUG_LEVEL by inventing macros debug_printk and irq_printk
69 - added wmb() and mb() to places where PCI read/write ordering needs to be enforced
70 - set video->id correctly
71 - store video_cards in an array indexed by OHCI card ID, rather than a list
72 - implement DMA context allocation to cooperate with other users of the OHCI
73 - fix all XXX showstoppers
74 - disable IR/IT DMA interrupts on shutdown
75 - flush pci writes to the card by issuing a read
76 - character device dispatching
77 - switch over to the new kernel DMA API (pci_map_*()) (* needs testing on platforms with IOMMU!)
78 - keep all video_cards in a list (for open() via chardev), set file->private_data = video
79 - dv1394_poll should indicate POLLIN when receiving buffers are available
80 - add proc fs interface to set cip_n, cip_d, syt_offset, and video signal
81 - expose xmit and recv as separate devices (not exclusive)
82 - expose NTSC and PAL as separate devices (can be overridden)
86 #include <linux/kernel.h>
87 #include <linux/list.h>
88 #include <linux/slab.h>
89 #include <linux/interrupt.h>
90 #include <linux/wait.h>
91 #include <linux/errno.h>
92 #include <linux/module.h>
93 #include <linux/init.h>
94 #include <linux/pci.h>
95 #include <linux/fs.h>
96 #include <linux/poll.h>
97 #include <linux/mutex.h>
98 #include <linux/bitops.h>
99 #include <asm/byteorder.h>
100 #include <asm/atomic.h>
101 #include <asm/io.h>
102 #include <asm/uaccess.h>
103 #include <linux/delay.h>
104 #include <asm/pgtable.h>
105 #include <asm/page.h>
106 #include <linux/sched.h>
107 #include <linux/types.h>
108 #include <linux/vmalloc.h>
109 #include <linux/string.h>
110 #include <linux/compat.h>
111 #include <linux/cdev.h>
113 #include "dv1394.h"
114 #include "dv1394-private.h"
115 #include "highlevel.h"
116 #include "hosts.h"
117 #include "ieee1394.h"
118 #include "ieee1394_core.h"
119 #include "ieee1394_hotplug.h"
120 #include "ieee1394_types.h"
121 #include "nodemgr.h"
122 #include "ohci1394.h"
124 /* DEBUG LEVELS:
125 0 - no debugging messages
126 1 - some debugging messages, but none during DMA frame transmission
127 2 - lots of messages, including during DMA frame transmission
128 (will cause undeflows if your machine is too slow!)
131 #define DV1394_DEBUG_LEVEL 0
133 /* for debugging use ONLY: allow more than one open() of the device */
134 /* #define DV1394_ALLOW_MORE_THAN_ONE_OPEN 1 */
136 #if DV1394_DEBUG_LEVEL >= 2
137 #define irq_printk( args... ) printk( args )
138 #else
139 #define irq_printk( args... ) do {} while (0)
140 #endif
142 #if DV1394_DEBUG_LEVEL >= 1
143 #define debug_printk( args... ) printk( args)
144 #else
145 #define debug_printk( args... ) do {} while (0)
146 #endif
148 /* issue a dummy PCI read to force the preceding write
149 to be posted to the PCI bus immediately */
151 static inline void flush_pci_write(struct ti_ohci *ohci)
153 mb();
154 reg_read(ohci, OHCI1394_IsochronousCycleTimer);
157 static void it_tasklet_func(unsigned long data);
158 static void ir_tasklet_func(unsigned long data);
160 #ifdef CONFIG_COMPAT
161 static long dv1394_compat_ioctl(struct file *file, unsigned int cmd,
162 unsigned long arg);
163 #endif
165 /* GLOBAL DATA */
167 /* list of all video_cards */
168 static LIST_HEAD(dv1394_cards);
169 static DEFINE_SPINLOCK(dv1394_cards_lock);
171 /* translate from a struct file* to the corresponding struct video_card* */
173 static inline struct video_card* file_to_video_card(struct file *file)
175 return (struct video_card*) file->private_data;
178 /*** FRAME METHODS *********************************************************/
180 static void frame_reset(struct frame *f)
182 f->state = FRAME_CLEAR;
183 f->done = 0;
184 f->n_packets = 0;
185 f->frame_begin_timestamp = NULL;
186 f->assigned_timestamp = 0;
187 f->cip_syt1 = NULL;
188 f->cip_syt2 = NULL;
189 f->mid_frame_timestamp = NULL;
190 f->frame_end_timestamp = NULL;
191 f->frame_end_branch = NULL;
194 static struct frame* frame_new(unsigned int frame_num, struct video_card *video)
196 struct frame *f = kmalloc(sizeof(*f), GFP_KERNEL);
197 if (!f)
198 return NULL;
200 f->video = video;
201 f->frame_num = frame_num;
203 f->header_pool = pci_alloc_consistent(f->video->ohci->dev, PAGE_SIZE, &f->header_pool_dma);
204 if (!f->header_pool) {
205 printk(KERN_ERR "dv1394: failed to allocate CIP header pool\n");
206 kfree(f);
207 return NULL;
210 debug_printk("dv1394: frame_new: allocated CIP header pool at virt 0x%08lx (contig) dma 0x%08lx size %ld\n",
211 (unsigned long) f->header_pool, (unsigned long) f->header_pool_dma, PAGE_SIZE);
213 f->descriptor_pool_size = MAX_PACKETS * sizeof(struct DMA_descriptor_block);
214 /* make it an even # of pages */
215 f->descriptor_pool_size += PAGE_SIZE - (f->descriptor_pool_size%PAGE_SIZE);
217 f->descriptor_pool = pci_alloc_consistent(f->video->ohci->dev,
218 f->descriptor_pool_size,
219 &f->descriptor_pool_dma);
220 if (!f->descriptor_pool) {
221 pci_free_consistent(f->video->ohci->dev, PAGE_SIZE, f->header_pool, f->header_pool_dma);
222 kfree(f);
223 return NULL;
226 debug_printk("dv1394: frame_new: allocated DMA program memory at virt 0x%08lx (contig) dma 0x%08lx size %ld\n",
227 (unsigned long) f->descriptor_pool, (unsigned long) f->descriptor_pool_dma, f->descriptor_pool_size);
229 f->data = 0;
230 frame_reset(f);
232 return f;
235 static void frame_delete(struct frame *f)
237 pci_free_consistent(f->video->ohci->dev, PAGE_SIZE, f->header_pool, f->header_pool_dma);
238 pci_free_consistent(f->video->ohci->dev, f->descriptor_pool_size, f->descriptor_pool, f->descriptor_pool_dma);
239 kfree(f);
246 frame_prepare() - build the DMA program for transmitting
248 Frame_prepare() must be called OUTSIDE the video->spinlock.
249 However, frame_prepare() must still be serialized, so
250 it should be called WITH the video->mtx taken.
253 static void frame_prepare(struct video_card *video, unsigned int this_frame)
255 struct frame *f = video->frames[this_frame];
256 int last_frame;
258 struct DMA_descriptor_block *block;
259 dma_addr_t block_dma;
260 struct CIP_header *cip;
261 dma_addr_t cip_dma;
263 unsigned int n_descriptors, full_packets, packets_per_frame, payload_size;
265 /* these flags denote packets that need special attention */
266 int empty_packet, first_packet, last_packet, mid_packet;
268 __le32 *branch_address, *last_branch_address = NULL;
269 unsigned long data_p;
270 int first_packet_empty = 0;
271 u32 cycleTimer, ct_sec, ct_cyc, ct_off;
272 unsigned long irq_flags;
274 irq_printk("frame_prepare( %d ) ---------------------\n", this_frame);
276 full_packets = 0;
280 if (video->pal_or_ntsc == DV1394_PAL)
281 packets_per_frame = DV1394_PAL_PACKETS_PER_FRAME;
282 else
283 packets_per_frame = DV1394_NTSC_PACKETS_PER_FRAME;
285 while ( full_packets < packets_per_frame ) {
286 empty_packet = first_packet = last_packet = mid_packet = 0;
288 data_p = f->data + full_packets * 480;
290 /************************************************/
291 /* allocate a descriptor block and a CIP header */
292 /************************************************/
294 /* note: these should NOT cross a page boundary (DMA restriction) */
296 if (f->n_packets >= MAX_PACKETS) {
297 printk(KERN_ERR "dv1394: FATAL ERROR: max packet count exceeded\n");
298 return;
301 /* the block surely won't cross a page boundary,
302 since an even number of descriptor_blocks fit on a page */
303 block = &(f->descriptor_pool[f->n_packets]);
305 /* DMA address of the block = offset of block relative
306 to the kernel base address of the descriptor pool
307 + DMA base address of the descriptor pool */
308 block_dma = ((unsigned long) block - (unsigned long) f->descriptor_pool) + f->descriptor_pool_dma;
311 /* the whole CIP pool fits on one page, so no worries about boundaries */
312 if ( ((unsigned long) &(f->header_pool[f->n_packets]) - (unsigned long) f->header_pool)
313 > PAGE_SIZE) {
314 printk(KERN_ERR "dv1394: FATAL ERROR: no room to allocate CIP header\n");
315 return;
318 cip = &(f->header_pool[f->n_packets]);
320 /* DMA address of the CIP header = offset of cip
321 relative to kernel base address of the header pool
322 + DMA base address of the header pool */
323 cip_dma = (unsigned long) cip % PAGE_SIZE + f->header_pool_dma;
325 /* is this an empty packet? */
327 if (video->cip_accum > (video->cip_d - video->cip_n)) {
328 empty_packet = 1;
329 payload_size = 8;
330 video->cip_accum -= (video->cip_d - video->cip_n);
331 } else {
332 payload_size = 488;
333 video->cip_accum += video->cip_n;
336 /* there are three important packets each frame:
338 the first packet in the frame - we ask the card to record the timestamp when
339 this packet is actually sent, so we can monitor
340 how accurate our timestamps are. Also, the first
341 packet serves as a semaphore to let us know that
342 it's OK to free the *previous* frame's DMA buffer
344 the last packet in the frame - this packet is used to detect buffer underflows.
345 if this is the last ready frame, the last DMA block
346 will have a branch back to the beginning of the frame
347 (so that the card will re-send the frame on underflow).
348 if this branch gets taken, we know that at least one
349 frame has been dropped. When the next frame is ready,
350 the branch is pointed to its first packet, and the
351 semaphore is disabled.
353 a "mid" packet slightly before the end of the frame - this packet should trigger
354 an interrupt so we can go and assign a timestamp to the first packet
355 in the next frame. We don't use the very last packet in the frame
356 for this purpose, because that would leave very little time to set
357 the timestamp before DMA starts on the next frame.
360 if (f->n_packets == 0) {
361 first_packet = 1;
362 } else if ( full_packets == (packets_per_frame-1) ) {
363 last_packet = 1;
364 } else if (f->n_packets == packets_per_frame) {
365 mid_packet = 1;
369 /********************/
370 /* setup CIP header */
371 /********************/
373 /* the timestamp will be written later from the
374 mid-frame interrupt handler. For now we just
375 store the address of the CIP header(s) that
376 need a timestamp. */
378 /* first packet in the frame needs a timestamp */
379 if (first_packet) {
380 f->cip_syt1 = cip;
381 if (empty_packet)
382 first_packet_empty = 1;
384 } else if (first_packet_empty && (f->n_packets == 1) ) {
385 /* if the first packet was empty, the second
386 packet's CIP header also needs a timestamp */
387 f->cip_syt2 = cip;
390 fill_cip_header(cip,
391 /* the node ID number of the OHCI card */
392 reg_read(video->ohci, OHCI1394_NodeID) & 0x3F,
393 video->continuity_counter,
394 video->pal_or_ntsc,
395 0xFFFF /* the timestamp is filled in later */);
397 /* advance counter, only for full packets */
398 if ( ! empty_packet )
399 video->continuity_counter++;
401 /******************************/
402 /* setup DMA descriptor block */
403 /******************************/
405 /* first descriptor - OUTPUT_MORE_IMMEDIATE, for the controller's IT header */
406 fill_output_more_immediate( &(block->u.out.omi), 1, video->channel, 0, payload_size);
408 if (empty_packet) {
409 /* second descriptor - OUTPUT_LAST for CIP header */
410 fill_output_last( &(block->u.out.u.empty.ol),
412 /* want completion status on all interesting packets */
413 (first_packet || mid_packet || last_packet) ? 1 : 0,
415 /* want interrupts on all interesting packets */
416 (first_packet || mid_packet || last_packet) ? 1 : 0,
418 sizeof(struct CIP_header), /* data size */
419 cip_dma);
421 if (first_packet)
422 f->frame_begin_timestamp = &(block->u.out.u.empty.ol.q[3]);
423 else if (mid_packet)
424 f->mid_frame_timestamp = &(block->u.out.u.empty.ol.q[3]);
425 else if (last_packet) {
426 f->frame_end_timestamp = &(block->u.out.u.empty.ol.q[3]);
427 f->frame_end_branch = &(block->u.out.u.empty.ol.q[2]);
430 branch_address = &(block->u.out.u.empty.ol.q[2]);
431 n_descriptors = 3;
432 if (first_packet)
433 f->first_n_descriptors = n_descriptors;
435 } else { /* full packet */
437 /* second descriptor - OUTPUT_MORE for CIP header */
438 fill_output_more( &(block->u.out.u.full.om),
439 sizeof(struct CIP_header), /* data size */
440 cip_dma);
443 /* third (and possibly fourth) descriptor - for DV data */
444 /* the 480-byte payload can cross a page boundary; if so,
445 we need to split it into two DMA descriptors */
447 /* does the 480-byte data payload cross a page boundary? */
448 if ( (PAGE_SIZE- ((unsigned long)data_p % PAGE_SIZE) ) < 480 ) {
450 /* page boundary crossed */
452 fill_output_more( &(block->u.out.u.full.u.cross.om),
453 /* data size - how much of data_p fits on the first page */
454 PAGE_SIZE - (data_p % PAGE_SIZE),
456 /* DMA address of data_p */
457 dma_region_offset_to_bus(&video->dv_buf,
458 data_p - (unsigned long) video->dv_buf.kvirt));
460 fill_output_last( &(block->u.out.u.full.u.cross.ol),
462 /* want completion status on all interesting packets */
463 (first_packet || mid_packet || last_packet) ? 1 : 0,
465 /* want interrupt on all interesting packets */
466 (first_packet || mid_packet || last_packet) ? 1 : 0,
468 /* data size - remaining portion of data_p */
469 480 - (PAGE_SIZE - (data_p % PAGE_SIZE)),
471 /* DMA address of data_p + PAGE_SIZE - (data_p % PAGE_SIZE) */
472 dma_region_offset_to_bus(&video->dv_buf,
473 data_p + PAGE_SIZE - (data_p % PAGE_SIZE) - (unsigned long) video->dv_buf.kvirt));
475 if (first_packet)
476 f->frame_begin_timestamp = &(block->u.out.u.full.u.cross.ol.q[3]);
477 else if (mid_packet)
478 f->mid_frame_timestamp = &(block->u.out.u.full.u.cross.ol.q[3]);
479 else if (last_packet) {
480 f->frame_end_timestamp = &(block->u.out.u.full.u.cross.ol.q[3]);
481 f->frame_end_branch = &(block->u.out.u.full.u.cross.ol.q[2]);
484 branch_address = &(block->u.out.u.full.u.cross.ol.q[2]);
486 n_descriptors = 5;
487 if (first_packet)
488 f->first_n_descriptors = n_descriptors;
490 full_packets++;
492 } else {
493 /* fits on one page */
495 fill_output_last( &(block->u.out.u.full.u.nocross.ol),
497 /* want completion status on all interesting packets */
498 (first_packet || mid_packet || last_packet) ? 1 : 0,
500 /* want interrupt on all interesting packets */
501 (first_packet || mid_packet || last_packet) ? 1 : 0,
503 480, /* data size (480 bytes of DV data) */
506 /* DMA address of data_p */
507 dma_region_offset_to_bus(&video->dv_buf,
508 data_p - (unsigned long) video->dv_buf.kvirt));
510 if (first_packet)
511 f->frame_begin_timestamp = &(block->u.out.u.full.u.nocross.ol.q[3]);
512 else if (mid_packet)
513 f->mid_frame_timestamp = &(block->u.out.u.full.u.nocross.ol.q[3]);
514 else if (last_packet) {
515 f->frame_end_timestamp = &(block->u.out.u.full.u.nocross.ol.q[3]);
516 f->frame_end_branch = &(block->u.out.u.full.u.nocross.ol.q[2]);
519 branch_address = &(block->u.out.u.full.u.nocross.ol.q[2]);
521 n_descriptors = 4;
522 if (first_packet)
523 f->first_n_descriptors = n_descriptors;
525 full_packets++;
529 /* link this descriptor block into the DMA program by filling in
530 the branch address of the previous block */
532 /* note: we are not linked into the active DMA chain yet */
534 if (last_branch_address) {
535 *(last_branch_address) = cpu_to_le32(block_dma | n_descriptors);
538 last_branch_address = branch_address;
541 f->n_packets++;
545 /* when we first assemble a new frame, set the final branch
546 to loop back up to the top */
547 *(f->frame_end_branch) = cpu_to_le32(f->descriptor_pool_dma | f->first_n_descriptors);
549 /* make the latest version of this frame visible to the PCI card */
550 dma_region_sync_for_device(&video->dv_buf, f->data - (unsigned long) video->dv_buf.kvirt, video->frame_size);
552 /* lock against DMA interrupt */
553 spin_lock_irqsave(&video->spinlock, irq_flags);
555 f->state = FRAME_READY;
557 video->n_clear_frames--;
559 last_frame = video->first_clear_frame - 1;
560 if (last_frame == -1)
561 last_frame = video->n_frames-1;
563 video->first_clear_frame = (video->first_clear_frame + 1) % video->n_frames;
565 irq_printk(" frame %d prepared, active_frame = %d, n_clear_frames = %d, first_clear_frame = %d\n last=%d\n",
566 this_frame, video->active_frame, video->n_clear_frames, video->first_clear_frame, last_frame);
568 irq_printk(" begin_ts %08lx mid_ts %08lx end_ts %08lx end_br %08lx\n",
569 (unsigned long) f->frame_begin_timestamp,
570 (unsigned long) f->mid_frame_timestamp,
571 (unsigned long) f->frame_end_timestamp,
572 (unsigned long) f->frame_end_branch);
574 if (video->active_frame != -1) {
576 /* if DMA is already active, we are almost done */
577 /* just link us onto the active DMA chain */
578 if (video->frames[last_frame]->frame_end_branch) {
579 u32 temp;
581 /* point the previous frame's tail to this frame's head */
582 *(video->frames[last_frame]->frame_end_branch) = cpu_to_le32(f->descriptor_pool_dma | f->first_n_descriptors);
584 /* this write MUST precede the next one, or we could silently drop frames */
585 wmb();
587 /* disable the want_status semaphore on the last packet */
588 temp = le32_to_cpu(*(video->frames[last_frame]->frame_end_branch - 2));
589 temp &= 0xF7CFFFFF;
590 *(video->frames[last_frame]->frame_end_branch - 2) = cpu_to_le32(temp);
592 /* flush these writes to memory ASAP */
593 flush_pci_write(video->ohci);
595 /* NOTE:
596 ideally the writes should be "atomic": if
597 the OHCI card reads the want_status flag in
598 between them, we'll falsely report a
599 dropped frame. Hopefully this window is too
600 small to really matter, and the consequence
601 is rather harmless. */
604 irq_printk(" new frame %d linked onto DMA chain\n", this_frame);
606 } else {
607 printk(KERN_ERR "dv1394: last frame not ready???\n");
610 } else {
612 u32 transmit_sec, transmit_cyc;
613 u32 ts_cyc, ts_off;
615 /* DMA is stopped, so this is the very first frame */
616 video->active_frame = this_frame;
618 /* set CommandPtr to address and size of first descriptor block */
619 reg_write(video->ohci, video->ohci_IsoXmitCommandPtr,
620 video->frames[video->active_frame]->descriptor_pool_dma |
621 f->first_n_descriptors);
623 /* assign a timestamp based on the current cycle time...
624 We'll tell the card to begin DMA 100 cycles from now,
625 and assign a timestamp 103 cycles from now */
627 cycleTimer = reg_read(video->ohci, OHCI1394_IsochronousCycleTimer);
629 ct_sec = cycleTimer >> 25;
630 ct_cyc = (cycleTimer >> 12) & 0x1FFF;
631 ct_off = cycleTimer & 0xFFF;
633 transmit_sec = ct_sec;
634 transmit_cyc = ct_cyc + 100;
636 transmit_sec += transmit_cyc/8000;
637 transmit_cyc %= 8000;
639 ts_off = ct_off;
640 ts_cyc = transmit_cyc + 3;
641 ts_cyc %= 8000;
643 f->assigned_timestamp = (ts_cyc&0xF) << 12;
645 /* now actually write the timestamp into the appropriate CIP headers */
646 if (f->cip_syt1) {
647 f->cip_syt1->b[6] = f->assigned_timestamp >> 8;
648 f->cip_syt1->b[7] = f->assigned_timestamp & 0xFF;
650 if (f->cip_syt2) {
651 f->cip_syt2->b[6] = f->assigned_timestamp >> 8;
652 f->cip_syt2->b[7] = f->assigned_timestamp & 0xFF;
655 /* --- start DMA --- */
657 /* clear all bits in ContextControl register */
659 reg_write(video->ohci, video->ohci_IsoXmitContextControlClear, 0xFFFFFFFF);
660 wmb();
662 /* the OHCI card has the ability to start ISO transmission on a
663 particular cycle (start-on-cycle). This way we can ensure that
664 the first DV frame will have an accurate timestamp.
666 However, start-on-cycle only appears to work if the OHCI card
667 is cycle master! Since the consequences of messing up the first
668 timestamp are minimal*, just disable start-on-cycle for now.
670 * my DV deck drops the first few frames before it "locks in;"
671 so the first frame having an incorrect timestamp is inconsequential.
674 #if 0
675 reg_write(video->ohci, video->ohci_IsoXmitContextControlSet,
676 (1 << 31) /* enable start-on-cycle */
677 | ( (transmit_sec & 0x3) << 29)
678 | (transmit_cyc << 16));
679 wmb();
680 #endif
682 video->dma_running = 1;
684 /* set the 'run' bit */
685 reg_write(video->ohci, video->ohci_IsoXmitContextControlSet, 0x8000);
686 flush_pci_write(video->ohci);
688 /* --- DMA should be running now --- */
690 debug_printk(" Cycle = %4u ContextControl = %08x CmdPtr = %08x\n",
691 (reg_read(video->ohci, OHCI1394_IsochronousCycleTimer) >> 12) & 0x1FFF,
692 reg_read(video->ohci, video->ohci_IsoXmitContextControlSet),
693 reg_read(video->ohci, video->ohci_IsoXmitCommandPtr));
695 debug_printk(" DMA start - current cycle %4u, transmit cycle %4u (%2u), assigning ts cycle %2u\n",
696 ct_cyc, transmit_cyc, transmit_cyc & 0xF, ts_cyc & 0xF);
698 #if DV1394_DEBUG_LEVEL >= 2
700 /* check if DMA is really running */
701 int i = 0;
702 while (i < 20) {
703 mb();
704 mdelay(1);
705 if (reg_read(video->ohci, video->ohci_IsoXmitContextControlSet) & (1 << 10)) {
706 printk("DMA ACTIVE after %d msec\n", i);
707 break;
709 i++;
712 printk("set = %08x, cmdPtr = %08x\n",
713 reg_read(video->ohci, video->ohci_IsoXmitContextControlSet),
714 reg_read(video->ohci, video->ohci_IsoXmitCommandPtr)
717 if ( ! (reg_read(video->ohci, video->ohci_IsoXmitContextControlSet) & (1 << 10)) ) {
718 printk("DMA did NOT go active after 20ms, event = %x\n",
719 reg_read(video->ohci, video->ohci_IsoXmitContextControlSet) & 0x1F);
720 } else
721 printk("DMA is RUNNING!\n");
723 #endif
728 spin_unlock_irqrestore(&video->spinlock, irq_flags);
733 /*** RECEIVE FUNCTIONS *****************************************************/
736 frame method put_packet
738 map and copy the packet data to its location in the frame
739 based upon DIF section and sequence
742 static void inline
743 frame_put_packet (struct frame *f, struct packet *p)
745 int section_type = p->data[0] >> 5; /* section type is in bits 5 - 7 */
746 int dif_sequence = p->data[1] >> 4; /* dif sequence number is in bits 4 - 7 */
747 int dif_block = p->data[2];
749 /* sanity check */
750 if (dif_sequence > 11 || dif_block > 149) return;
752 switch (section_type) {
753 case 0: /* 1 Header block */
754 memcpy( (void *) f->data + dif_sequence * 150 * 80, p->data, 480);
755 break;
757 case 1: /* 2 Subcode blocks */
758 memcpy( (void *) f->data + dif_sequence * 150 * 80 + (1 + dif_block) * 80, p->data, 480);
759 break;
761 case 2: /* 3 VAUX blocks */
762 memcpy( (void *) f->data + dif_sequence * 150 * 80 + (3 + dif_block) * 80, p->data, 480);
763 break;
765 case 3: /* 9 Audio blocks interleaved with video */
766 memcpy( (void *) f->data + dif_sequence * 150 * 80 + (6 + dif_block * 16) * 80, p->data, 480);
767 break;
769 case 4: /* 135 Video blocks interleaved with audio */
770 memcpy( (void *) f->data + dif_sequence * 150 * 80 + (7 + (dif_block / 15) + dif_block) * 80, p->data, 480);
771 break;
773 default: /* we can not handle any other data */
774 break;
779 static void start_dma_receive(struct video_card *video)
781 if (video->first_run == 1) {
782 video->first_run = 0;
784 /* start DMA once all of the frames are READY */
785 video->n_clear_frames = 0;
786 video->first_clear_frame = -1;
787 video->current_packet = 0;
788 video->active_frame = 0;
790 /* reset iso recv control register */
791 reg_write(video->ohci, video->ohci_IsoRcvContextControlClear, 0xFFFFFFFF);
792 wmb();
794 /* clear bufferFill, set isochHeader and speed (0=100) */
795 reg_write(video->ohci, video->ohci_IsoRcvContextControlSet, 0x40000000);
797 /* match on all tags, listen on channel */
798 reg_write(video->ohci, video->ohci_IsoRcvContextMatch, 0xf0000000 | video->channel);
800 /* address and first descriptor block + Z=1 */
801 reg_write(video->ohci, video->ohci_IsoRcvCommandPtr,
802 video->frames[0]->descriptor_pool_dma | 1); /* Z=1 */
803 wmb();
805 video->dma_running = 1;
807 /* run */
808 reg_write(video->ohci, video->ohci_IsoRcvContextControlSet, 0x8000);
809 flush_pci_write(video->ohci);
811 debug_printk("dv1394: DMA started\n");
813 #if DV1394_DEBUG_LEVEL >= 2
815 int i;
817 for (i = 0; i < 1000; ++i) {
818 mdelay(1);
819 if (reg_read(video->ohci, video->ohci_IsoRcvContextControlSet) & (1 << 10)) {
820 printk("DMA ACTIVE after %d msec\n", i);
821 break;
824 if ( reg_read(video->ohci, video->ohci_IsoRcvContextControlSet) & (1 << 11) ) {
825 printk("DEAD, event = %x\n",
826 reg_read(video->ohci, video->ohci_IsoRcvContextControlSet) & 0x1F);
827 } else
828 printk("RUNNING!\n");
830 #endif
831 } else if ( reg_read(video->ohci, video->ohci_IsoRcvContextControlSet) & (1 << 11) ) {
832 debug_printk("DEAD, event = %x\n",
833 reg_read(video->ohci, video->ohci_IsoRcvContextControlSet) & 0x1F);
835 /* wake */
836 reg_write(video->ohci, video->ohci_IsoRcvContextControlSet, (1 << 12));
842 receive_packets() - build the DMA program for receiving
845 static void receive_packets(struct video_card *video)
847 struct DMA_descriptor_block *block = NULL;
848 dma_addr_t block_dma = 0;
849 struct packet *data = NULL;
850 dma_addr_t data_dma = 0;
851 __le32 *last_branch_address = NULL;
852 unsigned long irq_flags;
853 int want_interrupt = 0;
854 struct frame *f = NULL;
855 int i, j;
857 spin_lock_irqsave(&video->spinlock, irq_flags);
859 for (j = 0; j < video->n_frames; j++) {
861 /* connect frames */
862 if (j > 0 && f != NULL && f->frame_end_branch != NULL)
863 *(f->frame_end_branch) = cpu_to_le32(video->frames[j]->descriptor_pool_dma | 1); /* set Z=1 */
865 f = video->frames[j];
867 for (i = 0; i < MAX_PACKETS; i++) {
868 /* locate a descriptor block and packet from the buffer */
869 block = &(f->descriptor_pool[i]);
870 block_dma = ((unsigned long) block - (unsigned long) f->descriptor_pool) + f->descriptor_pool_dma;
872 data = ((struct packet*)video->packet_buf.kvirt) + f->frame_num * MAX_PACKETS + i;
873 data_dma = dma_region_offset_to_bus( &video->packet_buf,
874 ((unsigned long) data - (unsigned long) video->packet_buf.kvirt) );
876 /* setup DMA descriptor block */
877 want_interrupt = ((i % (MAX_PACKETS/2)) == 0 || i == (MAX_PACKETS-1));
878 fill_input_last( &(block->u.in.il), want_interrupt, 512, data_dma);
880 /* link descriptors */
881 last_branch_address = f->frame_end_branch;
883 if (last_branch_address != NULL)
884 *(last_branch_address) = cpu_to_le32(block_dma | 1); /* set Z=1 */
886 f->frame_end_branch = &(block->u.in.il.q[2]);
889 } /* next j */
891 spin_unlock_irqrestore(&video->spinlock, irq_flags);
897 /*** MANAGEMENT FUNCTIONS **************************************************/
899 static int do_dv1394_init(struct video_card *video, struct dv1394_init *init)
901 unsigned long flags, new_buf_size;
902 int i;
903 u64 chan_mask;
904 int retval = -EINVAL;
906 debug_printk("dv1394: initialising %d\n", video->id);
907 if (init->api_version != DV1394_API_VERSION)
908 return -EINVAL;
910 /* first sanitize all the parameters */
911 if ( (init->n_frames < 2) || (init->n_frames > DV1394_MAX_FRAMES) )
912 return -EINVAL;
914 if ( (init->format != DV1394_NTSC) && (init->format != DV1394_PAL) )
915 return -EINVAL;
917 if ( (init->syt_offset == 0) || (init->syt_offset > 50) )
918 /* default SYT offset is 3 cycles */
919 init->syt_offset = 3;
921 if (init->channel > 63)
922 init->channel = 63;
924 chan_mask = (u64)1 << init->channel;
926 /* calculate what size DMA buffer is needed */
927 if (init->format == DV1394_NTSC)
928 new_buf_size = DV1394_NTSC_FRAME_SIZE * init->n_frames;
929 else
930 new_buf_size = DV1394_PAL_FRAME_SIZE * init->n_frames;
932 /* round up to PAGE_SIZE */
933 if (new_buf_size % PAGE_SIZE) new_buf_size += PAGE_SIZE - (new_buf_size % PAGE_SIZE);
935 /* don't allow the user to allocate the DMA buffer more than once */
936 if (video->dv_buf.kvirt && video->dv_buf_size != new_buf_size) {
937 printk("dv1394: re-sizing the DMA buffer is not allowed\n");
938 return -EINVAL;
941 /* shutdown the card if it's currently active */
942 /* (the card should not be reset if the parameters are screwy) */
944 do_dv1394_shutdown(video, 0);
946 /* try to claim the ISO channel */
947 spin_lock_irqsave(&video->ohci->IR_channel_lock, flags);
948 if (video->ohci->ISO_channel_usage & chan_mask) {
949 spin_unlock_irqrestore(&video->ohci->IR_channel_lock, flags);
950 retval = -EBUSY;
951 goto err;
953 video->ohci->ISO_channel_usage |= chan_mask;
954 spin_unlock_irqrestore(&video->ohci->IR_channel_lock, flags);
956 video->channel = init->channel;
958 /* initialize misc. fields of video */
959 video->n_frames = init->n_frames;
960 video->pal_or_ntsc = init->format;
962 video->cip_accum = 0;
963 video->continuity_counter = 0;
965 video->active_frame = -1;
966 video->first_clear_frame = 0;
967 video->n_clear_frames = video->n_frames;
968 video->dropped_frames = 0;
970 video->write_off = 0;
972 video->first_run = 1;
973 video->current_packet = -1;
974 video->first_frame = 0;
976 if (video->pal_or_ntsc == DV1394_NTSC) {
977 video->cip_n = init->cip_n != 0 ? init->cip_n : CIP_N_NTSC;
978 video->cip_d = init->cip_d != 0 ? init->cip_d : CIP_D_NTSC;
979 video->frame_size = DV1394_NTSC_FRAME_SIZE;
980 } else {
981 video->cip_n = init->cip_n != 0 ? init->cip_n : CIP_N_PAL;
982 video->cip_d = init->cip_d != 0 ? init->cip_d : CIP_D_PAL;
983 video->frame_size = DV1394_PAL_FRAME_SIZE;
986 video->syt_offset = init->syt_offset;
988 /* find and claim DMA contexts on the OHCI card */
990 if (video->ohci_it_ctx == -1) {
991 ohci1394_init_iso_tasklet(&video->it_tasklet, OHCI_ISO_TRANSMIT,
992 it_tasklet_func, (unsigned long) video);
994 if (ohci1394_register_iso_tasklet(video->ohci, &video->it_tasklet) < 0) {
995 printk(KERN_ERR "dv1394: could not find an available IT DMA context\n");
996 retval = -EBUSY;
997 goto err;
1000 video->ohci_it_ctx = video->it_tasklet.context;
1001 debug_printk("dv1394: claimed IT DMA context %d\n", video->ohci_it_ctx);
1004 if (video->ohci_ir_ctx == -1) {
1005 ohci1394_init_iso_tasklet(&video->ir_tasklet, OHCI_ISO_RECEIVE,
1006 ir_tasklet_func, (unsigned long) video);
1008 if (ohci1394_register_iso_tasklet(video->ohci, &video->ir_tasklet) < 0) {
1009 printk(KERN_ERR "dv1394: could not find an available IR DMA context\n");
1010 retval = -EBUSY;
1011 goto err;
1013 video->ohci_ir_ctx = video->ir_tasklet.context;
1014 debug_printk("dv1394: claimed IR DMA context %d\n", video->ohci_ir_ctx);
1017 /* allocate struct frames */
1018 for (i = 0; i < init->n_frames; i++) {
1019 video->frames[i] = frame_new(i, video);
1021 if (!video->frames[i]) {
1022 printk(KERN_ERR "dv1394: Cannot allocate frame structs\n");
1023 retval = -ENOMEM;
1024 goto err;
1028 if (!video->dv_buf.kvirt) {
1029 /* allocate the ringbuffer */
1030 retval = dma_region_alloc(&video->dv_buf, new_buf_size, video->ohci->dev, PCI_DMA_TODEVICE);
1031 if (retval)
1032 goto err;
1034 video->dv_buf_size = new_buf_size;
1036 debug_printk("dv1394: Allocated %d frame buffers, total %u pages (%u DMA pages), %lu bytes\n",
1037 video->n_frames, video->dv_buf.n_pages,
1038 video->dv_buf.n_dma_pages, video->dv_buf_size);
1041 /* set up the frame->data pointers */
1042 for (i = 0; i < video->n_frames; i++)
1043 video->frames[i]->data = (unsigned long) video->dv_buf.kvirt + i * video->frame_size;
1045 if (!video->packet_buf.kvirt) {
1046 /* allocate packet buffer */
1047 video->packet_buf_size = sizeof(struct packet) * video->n_frames * MAX_PACKETS;
1048 if (video->packet_buf_size % PAGE_SIZE)
1049 video->packet_buf_size += PAGE_SIZE - (video->packet_buf_size % PAGE_SIZE);
1051 retval = dma_region_alloc(&video->packet_buf, video->packet_buf_size,
1052 video->ohci->dev, PCI_DMA_FROMDEVICE);
1053 if (retval)
1054 goto err;
1056 debug_printk("dv1394: Allocated %d packets in buffer, total %u pages (%u DMA pages), %lu bytes\n",
1057 video->n_frames*MAX_PACKETS, video->packet_buf.n_pages,
1058 video->packet_buf.n_dma_pages, video->packet_buf_size);
1061 /* set up register offsets for IT context */
1062 /* IT DMA context registers are spaced 16 bytes apart */
1063 video->ohci_IsoXmitContextControlSet = OHCI1394_IsoXmitContextControlSet+16*video->ohci_it_ctx;
1064 video->ohci_IsoXmitContextControlClear = OHCI1394_IsoXmitContextControlClear+16*video->ohci_it_ctx;
1065 video->ohci_IsoXmitCommandPtr = OHCI1394_IsoXmitCommandPtr+16*video->ohci_it_ctx;
1067 /* enable interrupts for IT context */
1068 reg_write(video->ohci, OHCI1394_IsoXmitIntMaskSet, (1 << video->ohci_it_ctx));
1069 debug_printk("dv1394: interrupts enabled for IT context %d\n", video->ohci_it_ctx);
1071 /* set up register offsets for IR context */
1072 /* IR DMA context registers are spaced 32 bytes apart */
1073 video->ohci_IsoRcvContextControlSet = OHCI1394_IsoRcvContextControlSet+32*video->ohci_ir_ctx;
1074 video->ohci_IsoRcvContextControlClear = OHCI1394_IsoRcvContextControlClear+32*video->ohci_ir_ctx;
1075 video->ohci_IsoRcvCommandPtr = OHCI1394_IsoRcvCommandPtr+32*video->ohci_ir_ctx;
1076 video->ohci_IsoRcvContextMatch = OHCI1394_IsoRcvContextMatch+32*video->ohci_ir_ctx;
1078 /* enable interrupts for IR context */
1079 reg_write(video->ohci, OHCI1394_IsoRecvIntMaskSet, (1 << video->ohci_ir_ctx) );
1080 debug_printk("dv1394: interrupts enabled for IR context %d\n", video->ohci_ir_ctx);
1082 return 0;
1084 err:
1085 do_dv1394_shutdown(video, 1);
1086 return retval;
1089 /* if the user doesn't bother to call ioctl(INIT) before starting
1090 mmap() or read()/write(), just give him some default values */
1092 static int do_dv1394_init_default(struct video_card *video)
1094 struct dv1394_init init;
1096 init.api_version = DV1394_API_VERSION;
1097 init.n_frames = DV1394_MAX_FRAMES / 4;
1098 init.channel = video->channel;
1099 init.format = video->pal_or_ntsc;
1100 init.cip_n = video->cip_n;
1101 init.cip_d = video->cip_d;
1102 init.syt_offset = video->syt_offset;
1104 return do_dv1394_init(video, &init);
1107 /* do NOT call from interrupt context */
1108 static void stop_dma(struct video_card *video)
1110 unsigned long flags;
1111 int i;
1113 /* no interrupts */
1114 spin_lock_irqsave(&video->spinlock, flags);
1116 video->dma_running = 0;
1118 if ( (video->ohci_it_ctx == -1) && (video->ohci_ir_ctx == -1) )
1119 goto out;
1121 /* stop DMA if in progress */
1122 if ( (video->active_frame != -1) ||
1123 (reg_read(video->ohci, video->ohci_IsoXmitContextControlClear) & (1 << 10)) ||
1124 (reg_read(video->ohci, video->ohci_IsoRcvContextControlClear) & (1 << 10)) ) {
1126 /* clear the .run bits */
1127 reg_write(video->ohci, video->ohci_IsoXmitContextControlClear, (1 << 15));
1128 reg_write(video->ohci, video->ohci_IsoRcvContextControlClear, (1 << 15));
1129 flush_pci_write(video->ohci);
1131 video->active_frame = -1;
1132 video->first_run = 1;
1134 /* wait until DMA really stops */
1135 i = 0;
1136 while (i < 1000) {
1138 /* wait 0.1 millisecond */
1139 udelay(100);
1141 if ( (reg_read(video->ohci, video->ohci_IsoXmitContextControlClear) & (1 << 10)) ||
1142 (reg_read(video->ohci, video->ohci_IsoRcvContextControlClear) & (1 << 10)) ) {
1143 /* still active */
1144 debug_printk("dv1394: stop_dma: DMA not stopped yet\n" );
1145 mb();
1146 } else {
1147 debug_printk("dv1394: stop_dma: DMA stopped safely after %d ms\n", i/10);
1148 break;
1151 i++;
1154 if (i == 1000) {
1155 printk(KERN_ERR "dv1394: stop_dma: DMA still going after %d ms!\n", i/10);
1158 else
1159 debug_printk("dv1394: stop_dma: already stopped.\n");
1161 out:
1162 spin_unlock_irqrestore(&video->spinlock, flags);
1167 static void do_dv1394_shutdown(struct video_card *video, int free_dv_buf)
1169 int i;
1171 debug_printk("dv1394: shutdown...\n");
1173 /* stop DMA if in progress */
1174 stop_dma(video);
1176 /* release the DMA contexts */
1177 if (video->ohci_it_ctx != -1) {
1178 video->ohci_IsoXmitContextControlSet = 0;
1179 video->ohci_IsoXmitContextControlClear = 0;
1180 video->ohci_IsoXmitCommandPtr = 0;
1182 /* disable interrupts for IT context */
1183 reg_write(video->ohci, OHCI1394_IsoXmitIntMaskClear, (1 << video->ohci_it_ctx));
1185 /* remove tasklet */
1186 ohci1394_unregister_iso_tasklet(video->ohci, &video->it_tasklet);
1187 debug_printk("dv1394: IT context %d released\n", video->ohci_it_ctx);
1188 video->ohci_it_ctx = -1;
1191 if (video->ohci_ir_ctx != -1) {
1192 video->ohci_IsoRcvContextControlSet = 0;
1193 video->ohci_IsoRcvContextControlClear = 0;
1194 video->ohci_IsoRcvCommandPtr = 0;
1195 video->ohci_IsoRcvContextMatch = 0;
1197 /* disable interrupts for IR context */
1198 reg_write(video->ohci, OHCI1394_IsoRecvIntMaskClear, (1 << video->ohci_ir_ctx));
1200 /* remove tasklet */
1201 ohci1394_unregister_iso_tasklet(video->ohci, &video->ir_tasklet);
1202 debug_printk("dv1394: IR context %d released\n", video->ohci_ir_ctx);
1203 video->ohci_ir_ctx = -1;
1206 /* release the ISO channel */
1207 if (video->channel != -1) {
1208 u64 chan_mask;
1209 unsigned long flags;
1211 chan_mask = (u64)1 << video->channel;
1213 spin_lock_irqsave(&video->ohci->IR_channel_lock, flags);
1214 video->ohci->ISO_channel_usage &= ~(chan_mask);
1215 spin_unlock_irqrestore(&video->ohci->IR_channel_lock, flags);
1217 video->channel = -1;
1220 /* free the frame structs */
1221 for (i = 0; i < DV1394_MAX_FRAMES; i++) {
1222 if (video->frames[i])
1223 frame_delete(video->frames[i]);
1224 video->frames[i] = NULL;
1227 video->n_frames = 0;
1229 /* we can't free the DMA buffer unless it is guaranteed that
1230 no more user-space mappings exist */
1232 if (free_dv_buf) {
1233 dma_region_free(&video->dv_buf);
1234 video->dv_buf_size = 0;
1237 /* free packet buffer */
1238 dma_region_free(&video->packet_buf);
1239 video->packet_buf_size = 0;
1241 debug_printk("dv1394: shutdown OK\n");
1245 **********************************
1246 *** MMAP() THEORY OF OPERATION ***
1247 **********************************
1249 The ringbuffer cannot be re-allocated or freed while
1250 a user program maintains a mapping of it. (note that a mapping
1251 can persist even after the device fd is closed!)
1253 So, only let the user process allocate the DMA buffer once.
1254 To resize or deallocate it, you must close the device file
1255 and open it again.
1257 Previously Dan M. hacked out a scheme that allowed the DMA
1258 buffer to change by forcefully unmapping it from the user's
1259 address space. It was prone to error because it's very hard to
1260 track all the places the buffer could have been mapped (we
1261 would have had to walk the vma list of every process in the
1262 system to be sure we found all the mappings!). Instead, we
1263 force the user to choose one buffer size and stick with
1264 it. This small sacrifice is worth the huge reduction in
1265 error-prone code in dv1394.
1268 static int dv1394_mmap(struct file *file, struct vm_area_struct *vma)
1270 struct video_card *video = file_to_video_card(file);
1271 int retval = -EINVAL;
1274 * We cannot use the blocking variant mutex_lock here because .mmap
1275 * is called with mmap_sem held, while .ioctl, .read, .write acquire
1276 * video->mtx and subsequently call copy_to/from_user which will
1277 * grab mmap_sem in case of a page fault.
1279 if (!mutex_trylock(&video->mtx))
1280 return -EAGAIN;
1282 if ( ! video_card_initialized(video) ) {
1283 retval = do_dv1394_init_default(video);
1284 if (retval)
1285 goto out;
1288 retval = dma_region_mmap(&video->dv_buf, file, vma);
1289 out:
1290 mutex_unlock(&video->mtx);
1291 return retval;
1294 /*** DEVICE FILE INTERFACE *************************************************/
1296 /* no need to serialize, multiple threads OK */
1297 static unsigned int dv1394_poll(struct file *file, struct poll_table_struct *wait)
1299 struct video_card *video = file_to_video_card(file);
1300 unsigned int mask = 0;
1301 unsigned long flags;
1303 poll_wait(file, &video->waitq, wait);
1305 spin_lock_irqsave(&video->spinlock, flags);
1306 if ( video->n_frames == 0 ) {
1308 } else if ( video->active_frame == -1 ) {
1309 /* nothing going on */
1310 mask |= POLLOUT;
1311 } else {
1312 /* any clear/ready buffers? */
1313 if (video->n_clear_frames >0)
1314 mask |= POLLOUT | POLLIN;
1316 spin_unlock_irqrestore(&video->spinlock, flags);
1318 return mask;
1321 static int dv1394_fasync(int fd, struct file *file, int on)
1323 /* I just copied this code verbatim from Alan Cox's mouse driver example
1324 (Documentation/DocBook/) */
1326 struct video_card *video = file_to_video_card(file);
1328 return fasync_helper(fd, file, on, &video->fasync);
1331 static ssize_t dv1394_write(struct file *file, const char __user *buffer, size_t count, loff_t *ppos)
1333 struct video_card *video = file_to_video_card(file);
1334 DECLARE_WAITQUEUE(wait, current);
1335 ssize_t ret;
1336 size_t cnt;
1337 unsigned long flags;
1338 int target_frame;
1340 /* serialize this to prevent multi-threaded mayhem */
1341 if (file->f_flags & O_NONBLOCK) {
1342 if (!mutex_trylock(&video->mtx))
1343 return -EAGAIN;
1344 } else {
1345 if (mutex_lock_interruptible(&video->mtx))
1346 return -ERESTARTSYS;
1349 if ( !video_card_initialized(video) ) {
1350 ret = do_dv1394_init_default(video);
1351 if (ret) {
1352 mutex_unlock(&video->mtx);
1353 return ret;
1357 ret = 0;
1358 add_wait_queue(&video->waitq, &wait);
1360 while (count > 0) {
1362 /* must set TASK_INTERRUPTIBLE *before* checking for free
1363 buffers; otherwise we could miss a wakeup if the interrupt
1364 fires between the check and the schedule() */
1366 set_current_state(TASK_INTERRUPTIBLE);
1368 spin_lock_irqsave(&video->spinlock, flags);
1370 target_frame = video->first_clear_frame;
1372 spin_unlock_irqrestore(&video->spinlock, flags);
1374 if (video->frames[target_frame]->state == FRAME_CLEAR) {
1376 /* how much room is left in the target frame buffer */
1377 cnt = video->frame_size - (video->write_off - target_frame * video->frame_size);
1379 } else {
1380 /* buffer is already used */
1381 cnt = 0;
1384 if (cnt > count)
1385 cnt = count;
1387 if (cnt <= 0) {
1388 /* no room left, gotta wait */
1389 if (file->f_flags & O_NONBLOCK) {
1390 if (!ret)
1391 ret = -EAGAIN;
1392 break;
1394 if (signal_pending(current)) {
1395 if (!ret)
1396 ret = -ERESTARTSYS;
1397 break;
1400 schedule();
1402 continue; /* start over from 'while(count > 0)...' */
1405 if (copy_from_user(video->dv_buf.kvirt + video->write_off, buffer, cnt)) {
1406 if (!ret)
1407 ret = -EFAULT;
1408 break;
1411 video->write_off = (video->write_off + cnt) % (video->n_frames * video->frame_size);
1413 count -= cnt;
1414 buffer += cnt;
1415 ret += cnt;
1417 if (video->write_off == video->frame_size * ((target_frame + 1) % video->n_frames))
1418 frame_prepare(video, target_frame);
1421 remove_wait_queue(&video->waitq, &wait);
1422 set_current_state(TASK_RUNNING);
1423 mutex_unlock(&video->mtx);
1424 return ret;
1428 static ssize_t dv1394_read(struct file *file, char __user *buffer, size_t count, loff_t *ppos)
1430 struct video_card *video = file_to_video_card(file);
1431 DECLARE_WAITQUEUE(wait, current);
1432 ssize_t ret;
1433 size_t cnt;
1434 unsigned long flags;
1435 int target_frame;
1437 /* serialize this to prevent multi-threaded mayhem */
1438 if (file->f_flags & O_NONBLOCK) {
1439 if (!mutex_trylock(&video->mtx))
1440 return -EAGAIN;
1441 } else {
1442 if (mutex_lock_interruptible(&video->mtx))
1443 return -ERESTARTSYS;
1446 if ( !video_card_initialized(video) ) {
1447 ret = do_dv1394_init_default(video);
1448 if (ret) {
1449 mutex_unlock(&video->mtx);
1450 return ret;
1452 video->continuity_counter = -1;
1454 receive_packets(video);
1456 start_dma_receive(video);
1459 ret = 0;
1460 add_wait_queue(&video->waitq, &wait);
1462 while (count > 0) {
1464 /* must set TASK_INTERRUPTIBLE *before* checking for free
1465 buffers; otherwise we could miss a wakeup if the interrupt
1466 fires between the check and the schedule() */
1468 set_current_state(TASK_INTERRUPTIBLE);
1470 spin_lock_irqsave(&video->spinlock, flags);
1472 target_frame = video->first_clear_frame;
1474 spin_unlock_irqrestore(&video->spinlock, flags);
1476 if (target_frame >= 0 &&
1477 video->n_clear_frames > 0 &&
1478 video->frames[target_frame]->state == FRAME_CLEAR) {
1480 /* how much room is left in the target frame buffer */
1481 cnt = video->frame_size - (video->write_off - target_frame * video->frame_size);
1483 } else {
1484 /* buffer is already used */
1485 cnt = 0;
1488 if (cnt > count)
1489 cnt = count;
1491 if (cnt <= 0) {
1492 /* no room left, gotta wait */
1493 if (file->f_flags & O_NONBLOCK) {
1494 if (!ret)
1495 ret = -EAGAIN;
1496 break;
1498 if (signal_pending(current)) {
1499 if (!ret)
1500 ret = -ERESTARTSYS;
1501 break;
1504 schedule();
1506 continue; /* start over from 'while(count > 0)...' */
1509 if (copy_to_user(buffer, video->dv_buf.kvirt + video->write_off, cnt)) {
1510 if (!ret)
1511 ret = -EFAULT;
1512 break;
1515 video->write_off = (video->write_off + cnt) % (video->n_frames * video->frame_size);
1517 count -= cnt;
1518 buffer += cnt;
1519 ret += cnt;
1521 if (video->write_off == video->frame_size * ((target_frame + 1) % video->n_frames)) {
1522 spin_lock_irqsave(&video->spinlock, flags);
1523 video->n_clear_frames--;
1524 video->first_clear_frame = (video->first_clear_frame + 1) % video->n_frames;
1525 spin_unlock_irqrestore(&video->spinlock, flags);
1529 remove_wait_queue(&video->waitq, &wait);
1530 set_current_state(TASK_RUNNING);
1531 mutex_unlock(&video->mtx);
1532 return ret;
1536 /*** DEVICE IOCTL INTERFACE ************************************************/
1538 static long dv1394_ioctl(struct file *file, unsigned int cmd, unsigned long arg)
1540 struct video_card *video = file_to_video_card(file);
1541 unsigned long flags;
1542 int ret = -EINVAL;
1543 void __user *argp = (void __user *)arg;
1545 DECLARE_WAITQUEUE(wait, current);
1547 /* serialize this to prevent multi-threaded mayhem */
1548 if (file->f_flags & O_NONBLOCK) {
1549 if (!mutex_trylock(&video->mtx))
1550 return -EAGAIN;
1551 } else {
1552 if (mutex_lock_interruptible(&video->mtx))
1553 return -ERESTARTSYS;
1556 switch(cmd)
1558 case DV1394_IOC_SUBMIT_FRAMES: {
1559 unsigned int n_submit;
1561 if ( !video_card_initialized(video) ) {
1562 ret = do_dv1394_init_default(video);
1563 if (ret)
1564 goto out;
1567 n_submit = (unsigned int) arg;
1569 if (n_submit > video->n_frames) {
1570 ret = -EINVAL;
1571 goto out;
1574 while (n_submit > 0) {
1576 add_wait_queue(&video->waitq, &wait);
1577 set_current_state(TASK_INTERRUPTIBLE);
1579 spin_lock_irqsave(&video->spinlock, flags);
1581 /* wait until video->first_clear_frame is really CLEAR */
1582 while (video->frames[video->first_clear_frame]->state != FRAME_CLEAR) {
1584 spin_unlock_irqrestore(&video->spinlock, flags);
1586 if (signal_pending(current)) {
1587 remove_wait_queue(&video->waitq, &wait);
1588 set_current_state(TASK_RUNNING);
1589 ret = -EINTR;
1590 goto out;
1593 schedule();
1594 set_current_state(TASK_INTERRUPTIBLE);
1596 spin_lock_irqsave(&video->spinlock, flags);
1598 spin_unlock_irqrestore(&video->spinlock, flags);
1600 remove_wait_queue(&video->waitq, &wait);
1601 set_current_state(TASK_RUNNING);
1603 frame_prepare(video, video->first_clear_frame);
1605 n_submit--;
1608 ret = 0;
1609 break;
1612 case DV1394_IOC_WAIT_FRAMES: {
1613 unsigned int n_wait;
1615 if ( !video_card_initialized(video) ) {
1616 ret = -EINVAL;
1617 goto out;
1620 n_wait = (unsigned int) arg;
1622 /* since we re-run the last frame on underflow, we will
1623 never actually have n_frames clear frames; at most only
1624 n_frames - 1 */
1626 if (n_wait > (video->n_frames-1) ) {
1627 ret = -EINVAL;
1628 goto out;
1631 add_wait_queue(&video->waitq, &wait);
1632 set_current_state(TASK_INTERRUPTIBLE);
1634 spin_lock_irqsave(&video->spinlock, flags);
1636 while (video->n_clear_frames < n_wait) {
1638 spin_unlock_irqrestore(&video->spinlock, flags);
1640 if (signal_pending(current)) {
1641 remove_wait_queue(&video->waitq, &wait);
1642 set_current_state(TASK_RUNNING);
1643 ret = -EINTR;
1644 goto out;
1647 schedule();
1648 set_current_state(TASK_INTERRUPTIBLE);
1650 spin_lock_irqsave(&video->spinlock, flags);
1653 spin_unlock_irqrestore(&video->spinlock, flags);
1655 remove_wait_queue(&video->waitq, &wait);
1656 set_current_state(TASK_RUNNING);
1657 ret = 0;
1658 break;
1661 case DV1394_IOC_RECEIVE_FRAMES: {
1662 unsigned int n_recv;
1664 if ( !video_card_initialized(video) ) {
1665 ret = -EINVAL;
1666 goto out;
1669 n_recv = (unsigned int) arg;
1671 /* at least one frame must be active */
1672 if (n_recv > (video->n_frames-1) ) {
1673 ret = -EINVAL;
1674 goto out;
1677 spin_lock_irqsave(&video->spinlock, flags);
1679 /* release the clear frames */
1680 video->n_clear_frames -= n_recv;
1682 /* advance the clear frame cursor */
1683 video->first_clear_frame = (video->first_clear_frame + n_recv) % video->n_frames;
1685 /* reset dropped_frames */
1686 video->dropped_frames = 0;
1688 spin_unlock_irqrestore(&video->spinlock, flags);
1690 ret = 0;
1691 break;
1694 case DV1394_IOC_START_RECEIVE: {
1695 if ( !video_card_initialized(video) ) {
1696 ret = do_dv1394_init_default(video);
1697 if (ret)
1698 goto out;
1701 video->continuity_counter = -1;
1703 receive_packets(video);
1705 start_dma_receive(video);
1707 ret = 0;
1708 break;
1711 case DV1394_IOC_INIT: {
1712 struct dv1394_init init;
1713 if (!argp) {
1714 ret = do_dv1394_init_default(video);
1715 } else {
1716 if (copy_from_user(&init, argp, sizeof(init))) {
1717 ret = -EFAULT;
1718 goto out;
1720 ret = do_dv1394_init(video, &init);
1722 break;
1725 case DV1394_IOC_SHUTDOWN:
1726 do_dv1394_shutdown(video, 0);
1727 ret = 0;
1728 break;
1731 case DV1394_IOC_GET_STATUS: {
1732 struct dv1394_status status;
1734 if ( !video_card_initialized(video) ) {
1735 ret = -EINVAL;
1736 goto out;
1739 status.init.api_version = DV1394_API_VERSION;
1740 status.init.channel = video->channel;
1741 status.init.n_frames = video->n_frames;
1742 status.init.format = video->pal_or_ntsc;
1743 status.init.cip_n = video->cip_n;
1744 status.init.cip_d = video->cip_d;
1745 status.init.syt_offset = video->syt_offset;
1747 status.first_clear_frame = video->first_clear_frame;
1749 /* the rest of the fields need to be locked against the interrupt */
1750 spin_lock_irqsave(&video->spinlock, flags);
1752 status.active_frame = video->active_frame;
1753 status.n_clear_frames = video->n_clear_frames;
1755 status.dropped_frames = video->dropped_frames;
1757 /* reset dropped_frames */
1758 video->dropped_frames = 0;
1760 spin_unlock_irqrestore(&video->spinlock, flags);
1762 if (copy_to_user(argp, &status, sizeof(status))) {
1763 ret = -EFAULT;
1764 goto out;
1767 ret = 0;
1768 break;
1771 default:
1772 break;
1775 out:
1776 mutex_unlock(&video->mtx);
1777 return ret;
1780 /*** DEVICE FILE INTERFACE CONTINUED ***************************************/
1782 static int dv1394_open(struct inode *inode, struct file *file)
1784 struct video_card *video = NULL;
1786 if (file->private_data) {
1787 video = (struct video_card*) file->private_data;
1789 } else {
1790 /* look up the card by ID */
1791 unsigned long flags;
1792 int idx = ieee1394_file_to_instance(file);
1794 spin_lock_irqsave(&dv1394_cards_lock, flags);
1795 if (!list_empty(&dv1394_cards)) {
1796 struct video_card *p;
1797 list_for_each_entry(p, &dv1394_cards, list) {
1798 if ((p->id) == idx) {
1799 video = p;
1800 break;
1804 spin_unlock_irqrestore(&dv1394_cards_lock, flags);
1806 if (!video) {
1807 debug_printk("dv1394: OHCI card %d not found", idx);
1808 return -ENODEV;
1811 file->private_data = (void*) video;
1814 #ifndef DV1394_ALLOW_MORE_THAN_ONE_OPEN
1816 if ( test_and_set_bit(0, &video->open) ) {
1817 /* video is already open by someone else */
1818 return -EBUSY;
1821 #endif
1823 printk(KERN_INFO "%s: NOTE, the dv1394 interface is unsupported "
1824 "and will not be available in the new firewire driver stack. "
1825 "Try libraw1394 based programs instead.\n", current->comm);
1827 return 0;
1831 static int dv1394_release(struct inode *inode, struct file *file)
1833 struct video_card *video = file_to_video_card(file);
1835 /* OK to free the DMA buffer, no more mappings can exist */
1836 do_dv1394_shutdown(video, 1);
1838 /* give someone else a turn */
1839 clear_bit(0, &video->open);
1841 return 0;
1845 /*** DEVICE DRIVER HANDLERS ************************************************/
1847 static void it_tasklet_func(unsigned long data)
1849 int wake = 0;
1850 struct video_card *video = (struct video_card*) data;
1852 spin_lock(&video->spinlock);
1854 if (!video->dma_running)
1855 goto out;
1857 irq_printk("ContextControl = %08x, CommandPtr = %08x\n",
1858 reg_read(video->ohci, video->ohci_IsoXmitContextControlSet),
1859 reg_read(video->ohci, video->ohci_IsoXmitCommandPtr)
1863 if ( (video->ohci_it_ctx != -1) &&
1864 (reg_read(video->ohci, video->ohci_IsoXmitContextControlSet) & (1 << 10)) ) {
1866 struct frame *f;
1867 unsigned int frame, i;
1870 if (video->active_frame == -1)
1871 frame = 0;
1872 else
1873 frame = video->active_frame;
1875 /* check all the DMA-able frames */
1876 for (i = 0; i < video->n_frames; i++, frame = (frame+1) % video->n_frames) {
1878 irq_printk("IRQ checking frame %d...", frame);
1879 f = video->frames[frame];
1880 if (f->state != FRAME_READY) {
1881 irq_printk("clear, skipping\n");
1882 /* we don't own this frame */
1883 continue;
1886 irq_printk("DMA\n");
1888 /* check the frame begin semaphore to see if we can free the previous frame */
1889 if ( *(f->frame_begin_timestamp) ) {
1890 int prev_frame;
1891 struct frame *prev_f;
1895 /* don't reset, need this later *(f->frame_begin_timestamp) = 0; */
1896 irq_printk(" BEGIN\n");
1898 prev_frame = frame - 1;
1899 if (prev_frame == -1)
1900 prev_frame += video->n_frames;
1901 prev_f = video->frames[prev_frame];
1903 /* make sure we can actually garbage collect
1904 this frame */
1905 if ( (prev_f->state == FRAME_READY) &&
1906 prev_f->done && (!f->done) )
1908 frame_reset(prev_f);
1909 video->n_clear_frames++;
1910 wake = 1;
1911 video->active_frame = frame;
1913 irq_printk(" BEGIN - freeing previous frame %d, new active frame is %d\n", prev_frame, frame);
1914 } else {
1915 irq_printk(" BEGIN - can't free yet\n");
1918 f->done = 1;
1922 /* see if we need to set the timestamp for the next frame */
1923 if ( *(f->mid_frame_timestamp) ) {
1924 struct frame *next_frame;
1925 u32 begin_ts, ts_cyc, ts_off;
1927 *(f->mid_frame_timestamp) = 0;
1929 begin_ts = le32_to_cpu(*(f->frame_begin_timestamp));
1931 irq_printk(" MIDDLE - first packet was sent at cycle %4u (%2u), assigned timestamp was (%2u) %4u\n",
1932 begin_ts & 0x1FFF, begin_ts & 0xF,
1933 f->assigned_timestamp >> 12, f->assigned_timestamp & 0xFFF);
1935 /* prepare next frame and assign timestamp */
1936 next_frame = video->frames[ (frame+1) % video->n_frames ];
1938 if (next_frame->state == FRAME_READY) {
1939 irq_printk(" MIDDLE - next frame is ready, good\n");
1940 } else {
1941 debug_printk("dv1394: Underflow! At least one frame has been dropped.\n");
1942 next_frame = f;
1945 /* set the timestamp to the timestamp of the last frame sent,
1946 plus the length of the last frame sent, plus the syt latency */
1947 ts_cyc = begin_ts & 0xF;
1948 /* advance one frame, plus syt latency (typically 2-3) */
1949 ts_cyc += f->n_packets + video->syt_offset ;
1951 ts_off = 0;
1953 ts_cyc += ts_off/3072;
1954 ts_off %= 3072;
1956 next_frame->assigned_timestamp = ((ts_cyc&0xF) << 12) + ts_off;
1957 if (next_frame->cip_syt1) {
1958 next_frame->cip_syt1->b[6] = next_frame->assigned_timestamp >> 8;
1959 next_frame->cip_syt1->b[7] = next_frame->assigned_timestamp & 0xFF;
1961 if (next_frame->cip_syt2) {
1962 next_frame->cip_syt2->b[6] = next_frame->assigned_timestamp >> 8;
1963 next_frame->cip_syt2->b[7] = next_frame->assigned_timestamp & 0xFF;
1968 /* see if the frame looped */
1969 if ( *(f->frame_end_timestamp) ) {
1971 *(f->frame_end_timestamp) = 0;
1973 debug_printk(" END - the frame looped at least once\n");
1975 video->dropped_frames++;
1978 } /* for (each frame) */
1981 if (wake) {
1982 kill_fasync(&video->fasync, SIGIO, POLL_OUT);
1984 /* wake readers/writers/ioctl'ers */
1985 wake_up_interruptible(&video->waitq);
1988 out:
1989 spin_unlock(&video->spinlock);
1992 static void ir_tasklet_func(unsigned long data)
1994 int wake = 0;
1995 struct video_card *video = (struct video_card*) data;
1997 spin_lock(&video->spinlock);
1999 if (!video->dma_running)
2000 goto out;
2002 if ( (video->ohci_ir_ctx != -1) &&
2003 (reg_read(video->ohci, video->ohci_IsoRcvContextControlSet) & (1 << 10)) ) {
2005 int sof=0; /* start-of-frame flag */
2006 struct frame *f;
2007 u16 packet_length, packet_time;
2008 int i, dbc=0;
2009 struct DMA_descriptor_block *block = NULL;
2010 u16 xferstatus;
2012 int next_i, prev_i;
2013 struct DMA_descriptor_block *next = NULL;
2014 dma_addr_t next_dma = 0;
2015 struct DMA_descriptor_block *prev = NULL;
2017 /* loop over all descriptors in all frames */
2018 for (i = 0; i < video->n_frames*MAX_PACKETS; i++) {
2019 struct packet *p = dma_region_i(&video->packet_buf, struct packet, video->current_packet);
2021 /* make sure we are seeing the latest changes to p */
2022 dma_region_sync_for_cpu(&video->packet_buf,
2023 (unsigned long) p - (unsigned long) video->packet_buf.kvirt,
2024 sizeof(struct packet));
2026 packet_length = le16_to_cpu(p->data_length);
2027 packet_time = le16_to_cpu(p->timestamp);
2029 irq_printk("received packet %02d, timestamp=%04x, length=%04x, sof=%02x%02x\n", video->current_packet,
2030 packet_time, packet_length,
2031 p->data[0], p->data[1]);
2033 /* get the descriptor based on packet_buffer cursor */
2034 f = video->frames[video->current_packet / MAX_PACKETS];
2035 block = &(f->descriptor_pool[video->current_packet % MAX_PACKETS]);
2036 xferstatus = le32_to_cpu(block->u.in.il.q[3]) >> 16;
2037 xferstatus &= 0x1F;
2038 irq_printk("ir_tasklet_func: xferStatus/resCount [%d] = 0x%08x\n", i, le32_to_cpu(block->u.in.il.q[3]) );
2040 /* get the current frame */
2041 f = video->frames[video->active_frame];
2043 /* exclude empty packet */
2044 if (packet_length > 8 && xferstatus == 0x11) {
2045 /* check for start of frame */
2046 /* DRD> Changed to check section type ([0]>>5==0)
2047 and dif sequence ([1]>>4==0) */
2048 sof = ( (p->data[0] >> 5) == 0 && (p->data[1] >> 4) == 0);
2050 dbc = (int) (p->cip_h1 >> 24);
2051 if ( video->continuity_counter != -1 && dbc > ((video->continuity_counter + 1) % 256) )
2053 printk(KERN_WARNING "dv1394: discontinuity detected, dropping all frames\n" );
2054 video->dropped_frames += video->n_clear_frames + 1;
2055 video->first_frame = 0;
2056 video->n_clear_frames = 0;
2057 video->first_clear_frame = -1;
2059 video->continuity_counter = dbc;
2061 if (!video->first_frame) {
2062 if (sof) {
2063 video->first_frame = 1;
2066 } else if (sof) {
2067 /* close current frame */
2068 frame_reset(f); /* f->state = STATE_CLEAR */
2069 video->n_clear_frames++;
2070 if (video->n_clear_frames > video->n_frames) {
2071 video->dropped_frames++;
2072 printk(KERN_WARNING "dv1394: dropped a frame during reception\n" );
2073 video->n_clear_frames = video->n_frames-1;
2074 video->first_clear_frame = (video->first_clear_frame + 1) % video->n_frames;
2076 if (video->first_clear_frame == -1)
2077 video->first_clear_frame = video->active_frame;
2079 /* get the next frame */
2080 video->active_frame = (video->active_frame + 1) % video->n_frames;
2081 f = video->frames[video->active_frame];
2082 irq_printk(" frame received, active_frame = %d, n_clear_frames = %d, first_clear_frame = %d\n",
2083 video->active_frame, video->n_clear_frames, video->first_clear_frame);
2085 if (video->first_frame) {
2086 if (sof) {
2087 /* open next frame */
2088 f->state = FRAME_READY;
2091 /* copy to buffer */
2092 if (f->n_packets > (video->frame_size / 480)) {
2093 printk(KERN_ERR "frame buffer overflow during receive\n");
2096 frame_put_packet(f, p);
2098 } /* first_frame */
2101 /* stop, end of ready packets */
2102 else if (xferstatus == 0) {
2103 break;
2106 /* reset xferStatus & resCount */
2107 block->u.in.il.q[3] = cpu_to_le32(512);
2109 /* terminate dma chain at this (next) packet */
2110 next_i = video->current_packet;
2111 f = video->frames[next_i / MAX_PACKETS];
2112 next = &(f->descriptor_pool[next_i % MAX_PACKETS]);
2113 next_dma = ((unsigned long) block - (unsigned long) f->descriptor_pool) + f->descriptor_pool_dma;
2114 next->u.in.il.q[0] |= cpu_to_le32(3 << 20); /* enable interrupt */
2115 next->u.in.il.q[2] = cpu_to_le32(0); /* disable branch */
2117 /* link previous to next */
2118 prev_i = (next_i == 0) ? (MAX_PACKETS * video->n_frames - 1) : (next_i - 1);
2119 f = video->frames[prev_i / MAX_PACKETS];
2120 prev = &(f->descriptor_pool[prev_i % MAX_PACKETS]);
2121 if (prev_i % (MAX_PACKETS/2)) {
2122 prev->u.in.il.q[0] &= ~cpu_to_le32(3 << 20); /* no interrupt */
2123 } else {
2124 prev->u.in.il.q[0] |= cpu_to_le32(3 << 20); /* enable interrupt */
2126 prev->u.in.il.q[2] = cpu_to_le32(next_dma | 1); /* set Z=1 */
2127 wmb();
2129 /* wake up DMA in case it fell asleep */
2130 reg_write(video->ohci, video->ohci_IsoRcvContextControlSet, (1 << 12));
2132 /* advance packet_buffer cursor */
2133 video->current_packet = (video->current_packet + 1) % (MAX_PACKETS * video->n_frames);
2135 } /* for all packets */
2137 wake = 1; /* why the hell not? */
2139 } /* receive interrupt */
2141 if (wake) {
2142 kill_fasync(&video->fasync, SIGIO, POLL_IN);
2144 /* wake readers/writers/ioctl'ers */
2145 wake_up_interruptible(&video->waitq);
2148 out:
2149 spin_unlock(&video->spinlock);
2152 static struct cdev dv1394_cdev;
2153 static const struct file_operations dv1394_fops=
2155 .owner = THIS_MODULE,
2156 .poll = dv1394_poll,
2157 .unlocked_ioctl = dv1394_ioctl,
2158 #ifdef CONFIG_COMPAT
2159 .compat_ioctl = dv1394_compat_ioctl,
2160 #endif
2161 .mmap = dv1394_mmap,
2162 .open = dv1394_open,
2163 .write = dv1394_write,
2164 .read = dv1394_read,
2165 .release = dv1394_release,
2166 .fasync = dv1394_fasync,
2170 /*** HOTPLUG STUFF **********************************************************/
2172 * Export information about protocols/devices supported by this driver.
2174 #ifdef MODULE
2175 static const struct ieee1394_device_id dv1394_id_table[] = {
2177 .match_flags = IEEE1394_MATCH_SPECIFIER_ID | IEEE1394_MATCH_VERSION,
2178 .specifier_id = AVC_UNIT_SPEC_ID_ENTRY & 0xffffff,
2179 .version = AVC_SW_VERSION_ENTRY & 0xffffff
2184 MODULE_DEVICE_TABLE(ieee1394, dv1394_id_table);
2185 #endif /* MODULE */
2187 static struct hpsb_protocol_driver dv1394_driver = {
2188 .name = "dv1394",
2192 /*** IEEE1394 HPSB CALLBACKS ***********************************************/
2194 static int dv1394_init(struct ti_ohci *ohci, enum pal_or_ntsc format, enum modes mode)
2196 struct video_card *video;
2197 unsigned long flags;
2198 int i;
2200 video = kzalloc(sizeof(*video), GFP_KERNEL);
2201 if (!video) {
2202 printk(KERN_ERR "dv1394: cannot allocate video_card\n");
2203 return -1;
2206 video->ohci = ohci;
2207 /* lower 2 bits of id indicate which of four "plugs"
2208 per host */
2209 video->id = ohci->host->id << 2;
2210 if (format == DV1394_NTSC)
2211 video->id |= mode;
2212 else
2213 video->id |= 2 + mode;
2215 video->ohci_it_ctx = -1;
2216 video->ohci_ir_ctx = -1;
2218 video->ohci_IsoXmitContextControlSet = 0;
2219 video->ohci_IsoXmitContextControlClear = 0;
2220 video->ohci_IsoXmitCommandPtr = 0;
2222 video->ohci_IsoRcvContextControlSet = 0;
2223 video->ohci_IsoRcvContextControlClear = 0;
2224 video->ohci_IsoRcvCommandPtr = 0;
2225 video->ohci_IsoRcvContextMatch = 0;
2227 video->n_frames = 0; /* flag that video is not initialized */
2228 video->channel = 63; /* default to broadcast channel */
2229 video->active_frame = -1;
2231 /* initialize the following */
2232 video->pal_or_ntsc = format;
2233 video->cip_n = 0; /* 0 = use builtin default */
2234 video->cip_d = 0;
2235 video->syt_offset = 0;
2236 video->mode = mode;
2238 for (i = 0; i < DV1394_MAX_FRAMES; i++)
2239 video->frames[i] = NULL;
2241 dma_region_init(&video->dv_buf);
2242 video->dv_buf_size = 0;
2243 dma_region_init(&video->packet_buf);
2244 video->packet_buf_size = 0;
2246 clear_bit(0, &video->open);
2247 spin_lock_init(&video->spinlock);
2248 video->dma_running = 0;
2249 mutex_init(&video->mtx);
2250 init_waitqueue_head(&video->waitq);
2251 video->fasync = NULL;
2253 spin_lock_irqsave(&dv1394_cards_lock, flags);
2254 INIT_LIST_HEAD(&video->list);
2255 list_add_tail(&video->list, &dv1394_cards);
2256 spin_unlock_irqrestore(&dv1394_cards_lock, flags);
2258 debug_printk("dv1394: dv1394_init() OK on ID %d\n", video->id);
2259 return 0;
2262 static void dv1394_remove_host(struct hpsb_host *host)
2264 struct video_card *video, *tmp_video;
2265 unsigned long flags;
2266 int found_ohci_card = 0;
2268 do {
2269 video = NULL;
2270 spin_lock_irqsave(&dv1394_cards_lock, flags);
2271 list_for_each_entry(tmp_video, &dv1394_cards, list) {
2272 if ((tmp_video->id >> 2) == host->id) {
2273 list_del(&tmp_video->list);
2274 video = tmp_video;
2275 found_ohci_card = 1;
2276 break;
2279 spin_unlock_irqrestore(&dv1394_cards_lock, flags);
2281 if (video) {
2282 do_dv1394_shutdown(video, 1);
2283 kfree(video);
2285 } while (video);
2287 if (found_ohci_card)
2288 device_destroy(hpsb_protocol_class, MKDEV(IEEE1394_MAJOR,
2289 IEEE1394_MINOR_BLOCK_DV1394 * 16 + (host->id << 2)));
2292 static void dv1394_add_host(struct hpsb_host *host)
2294 struct ti_ohci *ohci;
2295 int id = host->id;
2297 /* We only work with the OHCI-1394 driver */
2298 if (strcmp(host->driver->name, OHCI1394_DRIVER_NAME))
2299 return;
2301 ohci = (struct ti_ohci *)host->hostdata;
2303 device_create(hpsb_protocol_class, NULL,
2304 MKDEV(IEEE1394_MAJOR,
2305 IEEE1394_MINOR_BLOCK_DV1394 * 16 + (id<<2)),
2306 NULL, "dv1394-%d", id);
2308 dv1394_init(ohci, DV1394_NTSC, MODE_RECEIVE);
2309 dv1394_init(ohci, DV1394_NTSC, MODE_TRANSMIT);
2310 dv1394_init(ohci, DV1394_PAL, MODE_RECEIVE);
2311 dv1394_init(ohci, DV1394_PAL, MODE_TRANSMIT);
2315 /* Bus reset handler. In the event of a bus reset, we may need to
2316 re-start the DMA contexts - otherwise the user program would
2317 end up waiting forever.
2320 static void dv1394_host_reset(struct hpsb_host *host)
2322 struct ti_ohci *ohci;
2323 struct video_card *video = NULL, *tmp_vid;
2324 unsigned long flags;
2326 /* We only work with the OHCI-1394 driver */
2327 if (strcmp(host->driver->name, OHCI1394_DRIVER_NAME))
2328 return;
2330 ohci = (struct ti_ohci *)host->hostdata;
2333 /* find the corresponding video_cards */
2334 spin_lock_irqsave(&dv1394_cards_lock, flags);
2335 list_for_each_entry(tmp_vid, &dv1394_cards, list) {
2336 if ((tmp_vid->id >> 2) == host->id) {
2337 video = tmp_vid;
2338 break;
2341 spin_unlock_irqrestore(&dv1394_cards_lock, flags);
2343 if (!video)
2344 return;
2347 spin_lock_irqsave(&video->spinlock, flags);
2349 if (!video->dma_running)
2350 goto out;
2352 /* check IT context */
2353 if (video->ohci_it_ctx != -1) {
2354 u32 ctx;
2356 ctx = reg_read(video->ohci, video->ohci_IsoXmitContextControlSet);
2358 /* if (RUN but not ACTIVE) */
2359 if ( (ctx & (1<<15)) &&
2360 !(ctx & (1<<10)) ) {
2362 debug_printk("dv1394: IT context stopped due to bus reset; waking it up\n");
2364 /* to be safe, assume a frame has been dropped. User-space programs
2365 should handle this condition like an underflow. */
2366 video->dropped_frames++;
2368 /* for some reason you must clear, then re-set the RUN bit to restart DMA */
2370 /* clear RUN */
2371 reg_write(video->ohci, video->ohci_IsoXmitContextControlClear, (1 << 15));
2372 flush_pci_write(video->ohci);
2374 /* set RUN */
2375 reg_write(video->ohci, video->ohci_IsoXmitContextControlSet, (1 << 15));
2376 flush_pci_write(video->ohci);
2378 /* set the WAKE bit (just in case; this isn't strictly necessary) */
2379 reg_write(video->ohci, video->ohci_IsoXmitContextControlSet, (1 << 12));
2380 flush_pci_write(video->ohci);
2382 irq_printk("dv1394: AFTER IT restart ctx 0x%08x ptr 0x%08x\n",
2383 reg_read(video->ohci, video->ohci_IsoXmitContextControlSet),
2384 reg_read(video->ohci, video->ohci_IsoXmitCommandPtr));
2388 /* check IR context */
2389 if (video->ohci_ir_ctx != -1) {
2390 u32 ctx;
2392 ctx = reg_read(video->ohci, video->ohci_IsoRcvContextControlSet);
2394 /* if (RUN but not ACTIVE) */
2395 if ( (ctx & (1<<15)) &&
2396 !(ctx & (1<<10)) ) {
2398 debug_printk("dv1394: IR context stopped due to bus reset; waking it up\n");
2400 /* to be safe, assume a frame has been dropped. User-space programs
2401 should handle this condition like an overflow. */
2402 video->dropped_frames++;
2404 /* for some reason you must clear, then re-set the RUN bit to restart DMA */
2405 /* XXX this doesn't work for me, I can't get IR DMA to restart :[ */
2407 /* clear RUN */
2408 reg_write(video->ohci, video->ohci_IsoRcvContextControlClear, (1 << 15));
2409 flush_pci_write(video->ohci);
2411 /* set RUN */
2412 reg_write(video->ohci, video->ohci_IsoRcvContextControlSet, (1 << 15));
2413 flush_pci_write(video->ohci);
2415 /* set the WAKE bit (just in case; this isn't strictly necessary) */
2416 reg_write(video->ohci, video->ohci_IsoRcvContextControlSet, (1 << 12));
2417 flush_pci_write(video->ohci);
2419 irq_printk("dv1394: AFTER IR restart ctx 0x%08x ptr 0x%08x\n",
2420 reg_read(video->ohci, video->ohci_IsoRcvContextControlSet),
2421 reg_read(video->ohci, video->ohci_IsoRcvCommandPtr));
2425 out:
2426 spin_unlock_irqrestore(&video->spinlock, flags);
2428 /* wake readers/writers/ioctl'ers */
2429 wake_up_interruptible(&video->waitq);
2432 static struct hpsb_highlevel dv1394_highlevel = {
2433 .name = "dv1394",
2434 .add_host = dv1394_add_host,
2435 .remove_host = dv1394_remove_host,
2436 .host_reset = dv1394_host_reset,
2439 #ifdef CONFIG_COMPAT
2441 #define DV1394_IOC32_INIT _IOW('#', 0x06, struct dv1394_init32)
2442 #define DV1394_IOC32_GET_STATUS _IOR('#', 0x0c, struct dv1394_status32)
2444 struct dv1394_init32 {
2445 u32 api_version;
2446 u32 channel;
2447 u32 n_frames;
2448 u32 format;
2449 u32 cip_n;
2450 u32 cip_d;
2451 u32 syt_offset;
2454 struct dv1394_status32 {
2455 struct dv1394_init32 init;
2456 s32 active_frame;
2457 u32 first_clear_frame;
2458 u32 n_clear_frames;
2459 u32 dropped_frames;
2462 /* RED-PEN: this should use compat_alloc_userspace instead */
2464 static int handle_dv1394_init(struct file *file, unsigned int cmd, unsigned long arg)
2466 struct dv1394_init32 dv32;
2467 struct dv1394_init dv;
2468 mm_segment_t old_fs;
2469 int ret;
2471 if (file->f_op->unlocked_ioctl != dv1394_ioctl)
2472 return -EFAULT;
2474 if (copy_from_user(&dv32, (void __user *)arg, sizeof(dv32)))
2475 return -EFAULT;
2477 dv.api_version = dv32.api_version;
2478 dv.channel = dv32.channel;
2479 dv.n_frames = dv32.n_frames;
2480 dv.format = dv32.format;
2481 dv.cip_n = (unsigned long)dv32.cip_n;
2482 dv.cip_d = (unsigned long)dv32.cip_d;
2483 dv.syt_offset = dv32.syt_offset;
2485 old_fs = get_fs();
2486 set_fs(KERNEL_DS);
2487 ret = dv1394_ioctl(file, DV1394_IOC_INIT, (unsigned long)&dv);
2488 set_fs(old_fs);
2490 return ret;
2493 static int handle_dv1394_get_status(struct file *file, unsigned int cmd, unsigned long arg)
2495 struct dv1394_status32 dv32;
2496 struct dv1394_status dv;
2497 mm_segment_t old_fs;
2498 int ret;
2500 if (file->f_op->unlocked_ioctl != dv1394_ioctl)
2501 return -EFAULT;
2503 old_fs = get_fs();
2504 set_fs(KERNEL_DS);
2505 ret = dv1394_ioctl(file, DV1394_IOC_GET_STATUS, (unsigned long)&dv);
2506 set_fs(old_fs);
2508 if (!ret) {
2509 dv32.init.api_version = dv.init.api_version;
2510 dv32.init.channel = dv.init.channel;
2511 dv32.init.n_frames = dv.init.n_frames;
2512 dv32.init.format = dv.init.format;
2513 dv32.init.cip_n = (u32)dv.init.cip_n;
2514 dv32.init.cip_d = (u32)dv.init.cip_d;
2515 dv32.init.syt_offset = dv.init.syt_offset;
2516 dv32.active_frame = dv.active_frame;
2517 dv32.first_clear_frame = dv.first_clear_frame;
2518 dv32.n_clear_frames = dv.n_clear_frames;
2519 dv32.dropped_frames = dv.dropped_frames;
2521 if (copy_to_user((struct dv1394_status32 __user *)arg, &dv32, sizeof(dv32)))
2522 ret = -EFAULT;
2525 return ret;
2530 static long dv1394_compat_ioctl(struct file *file, unsigned int cmd,
2531 unsigned long arg)
2533 switch (cmd) {
2534 case DV1394_IOC_SHUTDOWN:
2535 case DV1394_IOC_SUBMIT_FRAMES:
2536 case DV1394_IOC_WAIT_FRAMES:
2537 case DV1394_IOC_RECEIVE_FRAMES:
2538 case DV1394_IOC_START_RECEIVE:
2539 return dv1394_ioctl(file, cmd, arg);
2541 case DV1394_IOC32_INIT:
2542 return handle_dv1394_init(file, cmd, arg);
2543 case DV1394_IOC32_GET_STATUS:
2544 return handle_dv1394_get_status(file, cmd, arg);
2545 default:
2546 return -ENOIOCTLCMD;
2550 #endif /* CONFIG_COMPAT */
2553 /*** KERNEL MODULE HANDLERS ************************************************/
2555 MODULE_AUTHOR("Dan Maas <dmaas@dcine.com>, Dan Dennedy <dan@dennedy.org>");
2556 MODULE_DESCRIPTION("driver for DV input/output on OHCI board");
2557 MODULE_SUPPORTED_DEVICE("dv1394");
2558 MODULE_LICENSE("GPL");
2560 static void __exit dv1394_exit_module(void)
2562 hpsb_unregister_protocol(&dv1394_driver);
2563 hpsb_unregister_highlevel(&dv1394_highlevel);
2564 cdev_del(&dv1394_cdev);
2567 static int __init dv1394_init_module(void)
2569 int ret;
2571 cdev_init(&dv1394_cdev, &dv1394_fops);
2572 dv1394_cdev.owner = THIS_MODULE;
2573 ret = cdev_add(&dv1394_cdev, IEEE1394_DV1394_DEV, 16);
2574 if (ret) {
2575 printk(KERN_ERR "dv1394: unable to register character device\n");
2576 return ret;
2579 hpsb_register_highlevel(&dv1394_highlevel);
2581 ret = hpsb_register_protocol(&dv1394_driver);
2582 if (ret) {
2583 printk(KERN_ERR "dv1394: failed to register protocol\n");
2584 hpsb_unregister_highlevel(&dv1394_highlevel);
2585 cdev_del(&dv1394_cdev);
2586 return ret;
2589 return 0;
2592 module_init(dv1394_init_module);
2593 module_exit(dv1394_exit_module);