1 /** @file
2
3 The EHCI register operation routines.
4
5 Copyright (c) 2007 - 2013, Intel Corporation. All rights reserved.<BR>
6 This program and the accompanying materials
7 are licensed and made available under the terms and conditions of the BSD License
8 which accompanies this distribution. The full text of the license may be found at
9 http://opensource.org/licenses/bsd-license.php
10
11 THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,
12 WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
13
14 **/
15
16 #include "Uhci.h"
17
18
19 /**
20 Create Frame List Structure.
21
22 @param Uhc UHCI device.
23
24 @retval EFI_OUT_OF_RESOURCES Can't allocate memory resources.
25 @retval EFI_UNSUPPORTED Map memory fail.
26 @retval EFI_SUCCESS Success.
27
28 **/
29 EFI_STATUS
UhciInitFrameList(IN USB_HC_DEV * Uhc)30 UhciInitFrameList (
31 IN USB_HC_DEV *Uhc
32 )
33 {
34 EFI_PHYSICAL_ADDRESS MappedAddr;
35 EFI_STATUS Status;
36 VOID *Buffer;
37 VOID *Mapping;
38 UINTN Pages;
39 UINTN Bytes;
40 UINTN Index;
41 EFI_PHYSICAL_ADDRESS PhyAddr;
42
43 //
44 // The Frame List is a common buffer that will be
45 // accessed by both the cpu and the usb bus master
46 // at the same time. The Frame List ocupies 4K bytes,
47 // and must be aligned on 4-Kbyte boundaries.
48 //
49 Bytes = 4096;
50 Pages = EFI_SIZE_TO_PAGES (Bytes);
51
52 Status = Uhc->PciIo->AllocateBuffer (
53 Uhc->PciIo,
54 AllocateAnyPages,
55 EfiBootServicesData,
56 Pages,
57 &Buffer,
58 0
59 );
60
61 if (EFI_ERROR (Status)) {
62 return EFI_OUT_OF_RESOURCES;
63 }
64
65 Status = Uhc->PciIo->Map (
66 Uhc->PciIo,
67 EfiPciIoOperationBusMasterCommonBuffer,
68 Buffer,
69 &Bytes,
70 &MappedAddr,
71 &Mapping
72 );
73
74 if (EFI_ERROR (Status) || (Bytes != 4096)) {
75 Status = EFI_UNSUPPORTED;
76 goto ON_ERROR;
77 }
78
79 Uhc->FrameBase = (UINT32 *) (UINTN) Buffer;
80 Uhc->FrameMapping = Mapping;
81
82 //
83 // Tell the Host Controller where the Frame List lies,
84 // by set the Frame List Base Address Register.
85 //
86 UhciSetFrameListBaseAddr (Uhc->PciIo, (VOID *) (UINTN) MappedAddr);
87
88 //
89 // Allocate the QH used by sync interrupt/control/bulk transfer.
90 // FS ctrl/bulk queue head is set to loopback so additional BW
91 // can be reclaimed. Notice, LS don't support bulk transfer and
92 // also doesn't support BW reclamation.
93 //
94 Uhc->SyncIntQh = UhciCreateQh (Uhc, 1);
95 Uhc->CtrlQh = UhciCreateQh (Uhc, 1);
96 Uhc->BulkQh = UhciCreateQh (Uhc, 1);
97
98 if ((Uhc->SyncIntQh == NULL) || (Uhc->CtrlQh == NULL) || (Uhc->BulkQh == NULL)) {
99 Uhc->PciIo->Unmap (Uhc->PciIo, Mapping);
100 Status = EFI_OUT_OF_RESOURCES;
101 goto ON_ERROR;
102 }
103
104 //
105 // +-------------+
106 // | |
107 // Link the three together: SyncIntQh->CtrlQh->BulkQh <---------+
108 // Each frame entry is linked to this sequence of QH. These QH
109 // will remain on the schedul, never got removed
110 //
111 PhyAddr = UsbHcGetPciAddressForHostMem (Uhc->MemPool, Uhc->CtrlQh, sizeof (UHCI_QH_HW));
112 Uhc->SyncIntQh->QhHw.HorizonLink = QH_HLINK (PhyAddr, FALSE);
113 Uhc->SyncIntQh->NextQh = Uhc->CtrlQh;
114
115 PhyAddr = UsbHcGetPciAddressForHostMem (Uhc->MemPool, Uhc->BulkQh, sizeof (UHCI_QH_HW));
116 Uhc->CtrlQh->QhHw.HorizonLink = QH_HLINK (PhyAddr, FALSE);
117 Uhc->CtrlQh->NextQh = Uhc->BulkQh;
118
119 //
120 // Some old platform such as Intel's Tiger 4 has a difficult time
121 // in supporting the full speed bandwidth reclamation in the previous
122 // mentioned form. Most new platforms don't suffer it.
123 //
124 Uhc->BulkQh->QhHw.HorizonLink = QH_HLINK (PhyAddr, FALSE);
125
126 Uhc->BulkQh->NextQh = NULL;
127
128 Uhc->FrameBaseHostAddr = AllocateZeroPool (4096);
129 if (Uhc->FrameBaseHostAddr == NULL) {
130 Status = EFI_OUT_OF_RESOURCES;
131 goto ON_ERROR;
132 }
133
134 PhyAddr = UsbHcGetPciAddressForHostMem (Uhc->MemPool, Uhc->SyncIntQh, sizeof (UHCI_QH_HW));
135 for (Index = 0; Index < UHCI_FRAME_NUM; Index++) {
136 Uhc->FrameBase[Index] = QH_HLINK (PhyAddr, FALSE);
137 Uhc->FrameBaseHostAddr[Index] = (UINT32)(UINTN)Uhc->SyncIntQh;
138 }
139
140 return EFI_SUCCESS;
141
142 ON_ERROR:
143 if (Uhc->SyncIntQh != NULL) {
144 UsbHcFreeMem (Uhc->MemPool, Uhc->SyncIntQh, sizeof (UHCI_QH_SW));
145 }
146
147 if (Uhc->CtrlQh != NULL) {
148 UsbHcFreeMem (Uhc->MemPool, Uhc->CtrlQh, sizeof (UHCI_QH_SW));
149 }
150
151 if (Uhc->BulkQh != NULL) {
152 UsbHcFreeMem (Uhc->MemPool, Uhc->BulkQh, sizeof (UHCI_QH_SW));
153 }
154
155 Uhc->PciIo->FreeBuffer (Uhc->PciIo, Pages, Buffer);
156 return Status;
157 }
158
159
160 /**
161 Destory FrameList buffer.
162
163 @param Uhc The UHCI device.
164
165 **/
166 VOID
UhciDestoryFrameList(IN USB_HC_DEV * Uhc)167 UhciDestoryFrameList (
168 IN USB_HC_DEV *Uhc
169 )
170 {
171 //
172 // Unmap the common buffer for framelist entry,
173 // and free the common buffer.
174 // Uhci's frame list occupy 4k memory.
175 //
176 Uhc->PciIo->Unmap (Uhc->PciIo, Uhc->FrameMapping);
177
178 Uhc->PciIo->FreeBuffer (
179 Uhc->PciIo,
180 EFI_SIZE_TO_PAGES (4096),
181 (VOID *) Uhc->FrameBase
182 );
183
184 if (Uhc->FrameBaseHostAddr != NULL) {
185 FreePool (Uhc->FrameBaseHostAddr);
186 }
187
188 if (Uhc->SyncIntQh != NULL) {
189 UsbHcFreeMem (Uhc->MemPool, Uhc->SyncIntQh, sizeof (UHCI_QH_SW));
190 }
191
192 if (Uhc->CtrlQh != NULL) {
193 UsbHcFreeMem (Uhc->MemPool, Uhc->CtrlQh, sizeof (UHCI_QH_SW));
194 }
195
196 if (Uhc->BulkQh != NULL) {
197 UsbHcFreeMem (Uhc->MemPool, Uhc->BulkQh, sizeof (UHCI_QH_SW));
198 }
199
200 Uhc->FrameBase = NULL;
201 Uhc->FrameBaseHostAddr = NULL;
202 Uhc->SyncIntQh = NULL;
203 Uhc->CtrlQh = NULL;
204 Uhc->BulkQh = NULL;
205 }
206
207
208 /**
209 Convert the poll rate to the maxium 2^n that is smaller
210 than Interval.
211
212 @param Interval The poll rate to convert.
213
214 @return The converted poll rate.
215
216 **/
217 UINTN
UhciConvertPollRate(IN UINTN Interval)218 UhciConvertPollRate (
219 IN UINTN Interval
220 )
221 {
222 UINTN BitCount;
223
224 ASSERT (Interval != 0);
225
226 //
227 // Find the index (1 based) of the highest non-zero bit
228 //
229 BitCount = 0;
230
231 while (Interval != 0) {
232 Interval >>= 1;
233 BitCount++;
234 }
235
236 return (UINTN)1 << (BitCount - 1);
237 }
238
239
240 /**
241 Link a queue head (for asynchronous interrupt transfer) to
242 the frame list.
243
244 @param Uhc The UHCI device.
245 @param Qh The queue head to link into.
246
247 **/
248 VOID
UhciLinkQhToFrameList(USB_HC_DEV * Uhc,UHCI_QH_SW * Qh)249 UhciLinkQhToFrameList (
250 USB_HC_DEV *Uhc,
251 UHCI_QH_SW *Qh
252 )
253 {
254 UINTN Index;
255 UHCI_QH_SW *Prev;
256 UHCI_QH_SW *Next;
257 EFI_PHYSICAL_ADDRESS PhyAddr;
258 EFI_PHYSICAL_ADDRESS QhPciAddr;
259
260 ASSERT ((Uhc->FrameBase != NULL) && (Qh != NULL));
261
262 QhPciAddr = UsbHcGetPciAddressForHostMem (Uhc->MemPool, Qh, sizeof (UHCI_QH_HW));
263
264 for (Index = 0; Index < UHCI_FRAME_NUM; Index += Qh->Interval) {
265 //
266 // First QH can't be NULL because we always keep static queue
267 // heads on the frame list
268 //
269 ASSERT (!LINK_TERMINATED (Uhc->FrameBase[Index]));
270 Next = (UHCI_QH_SW*)(UINTN)Uhc->FrameBaseHostAddr[Index];
271 Prev = NULL;
272
273 //
274 // Now, insert the queue head (Qh) into this frame:
275 // 1. Find a queue head with the same poll interval, just insert
276 // Qh after this queue head, then we are done.
277 //
278 // 2. Find the position to insert the queue head into:
279 // Previous head's interval is bigger than Qh's
280 // Next head's interval is less than Qh's
281 // Then, insert the Qh between then
282 //
283 // This method is very much the same as that used by EHCI.
284 // Because each QH's interval is round down to 2^n, poll
285 // rate is correct.
286 //
287 while (Next->Interval > Qh->Interval) {
288 Prev = Next;
289 Next = Next->NextQh;
290 ASSERT (Next != NULL);
291 }
292
293 //
294 // The entry may have been linked into the frame by early insertation.
295 // For example: if insert a Qh with Qh.Interval == 4, and there is a Qh
296 // with Qh.Interval == 8 on the frame. If so, we are done with this frame.
297 // It isn't necessary to compare all the QH with the same interval to
298 // Qh. This is because if there is other QH with the same interval, Qh
299 // should has been inserted after that at FrameBase[0] and at FrameBase[0] it is
300 // impossible (Next == Qh)
301 //
302 if (Next == Qh) {
303 continue;
304 }
305
306 if (Next->Interval == Qh->Interval) {
307 //
308 // If there is a QH with the same interval, it locates at
309 // FrameBase[0], and we can simply insert it after this QH. We
310 // are all done.
311 //
312 ASSERT ((Index == 0) && (Qh->NextQh == NULL));
313
314 Prev = Next;
315 Next = Next->NextQh;
316
317 Qh->NextQh = Next;
318 Prev->NextQh = Qh;
319
320 Qh->QhHw.HorizonLink = Prev->QhHw.HorizonLink;
321
322 Prev->QhHw.HorizonLink = QH_HLINK (QhPciAddr, FALSE);
323 break;
324 }
325
326 //
327 // OK, find the right position, insert it in. If Qh's next
328 // link has already been set, it is in position. This is
329 // guarranted by 2^n polling interval.
330 //
331 if (Qh->NextQh == NULL) {
332 Qh->NextQh = Next;
333 PhyAddr = UsbHcGetPciAddressForHostMem (Uhc->MemPool, Next, sizeof (UHCI_QH_HW));
334 Qh->QhHw.HorizonLink = QH_HLINK (PhyAddr, FALSE);
335 }
336
337 if (Prev == NULL) {
338 Uhc->FrameBase[Index] = QH_HLINK (QhPciAddr, FALSE);
339 Uhc->FrameBaseHostAddr[Index] = (UINT32)(UINTN)Qh;
340 } else {
341 Prev->NextQh = Qh;
342 Prev->QhHw.HorizonLink = QH_HLINK (QhPciAddr, FALSE);
343 }
344 }
345 }
346
347
348 /**
349 Unlink QH from the frame list is easier: find all
350 the precedence node, and pointer there next to QhSw's
351 next.
352
353 @param Uhc The UHCI device.
354 @param Qh The queue head to unlink.
355
356 **/
357 VOID
UhciUnlinkQhFromFrameList(USB_HC_DEV * Uhc,UHCI_QH_SW * Qh)358 UhciUnlinkQhFromFrameList (
359 USB_HC_DEV *Uhc,
360 UHCI_QH_SW *Qh
361 )
362 {
363 UINTN Index;
364 UHCI_QH_SW *Prev;
365 UHCI_QH_SW *This;
366
367 ASSERT ((Uhc->FrameBase != NULL) && (Qh != NULL));
368
369 for (Index = 0; Index < UHCI_FRAME_NUM; Index += Qh->Interval) {
370 //
371 // Frame link can't be NULL because we always keep static
372 // queue heads on the frame list
373 //
374 ASSERT (!LINK_TERMINATED (Uhc->FrameBase[Index]));
375 This = (UHCI_QH_SW*)(UINTN)Uhc->FrameBaseHostAddr[Index];
376 Prev = NULL;
377
378 //
379 // Walk through the frame's QH list to find the
380 // queue head to remove
381 //
382 while ((This != NULL) && (This != Qh)) {
383 Prev = This;
384 This = This->NextQh;
385 }
386
387 //
388 // Qh may have already been unlinked from this frame
389 // by early action.
390 //
391 if (This == NULL) {
392 continue;
393 }
394
395 if (Prev == NULL) {
396 //
397 // Qh is the first entry in the frame
398 //
399 Uhc->FrameBase[Index] = Qh->QhHw.HorizonLink;
400 Uhc->FrameBaseHostAddr[Index] = (UINT32)(UINTN)Qh->NextQh;
401 } else {
402 Prev->NextQh = Qh->NextQh;
403 Prev->QhHw.HorizonLink = Qh->QhHw.HorizonLink;
404 }
405 }
406 }
407
408
409 /**
410 Check TDs Results.
411
412 @param Uhc This UHCI device.
413 @param Td UHCI_TD_SW to check.
414 @param IsLow Is Low Speed Device.
415 @param QhResult Return the result of this TD list.
416
417 @return Whether the TD's result is finialized.
418
419 **/
420 BOOLEAN
UhciCheckTdStatus(IN USB_HC_DEV * Uhc,IN UHCI_TD_SW * Td,IN BOOLEAN IsLow,OUT UHCI_QH_RESULT * QhResult)421 UhciCheckTdStatus (
422 IN USB_HC_DEV *Uhc,
423 IN UHCI_TD_SW *Td,
424 IN BOOLEAN IsLow,
425 OUT UHCI_QH_RESULT *QhResult
426 )
427 {
428 UINTN Len;
429 UINT8 State;
430 UHCI_TD_HW *TdHw;
431 BOOLEAN Finished;
432
433 Finished = TRUE;
434
435 //
436 // Initialize the data toggle to that of the first
437 // TD. The next toggle to use is either:
438 // 1. first TD's toggle if no TD is executed OK
439 // 2. the next toggle of last executed-OK TD
440 //
441 QhResult->Result = EFI_USB_NOERROR;
442 QhResult->NextToggle = (UINT8)Td->TdHw.DataToggle;
443 QhResult->Complete = 0;
444
445 while (Td != NULL) {
446 TdHw = &Td->TdHw;
447 State = (UINT8)TdHw->Status;
448
449 //
450 // UHCI will set STALLED bit when it abort the execution
451 // of TD list. There are several reasons:
452 // 1. BABBLE error happened
453 // 2. Received a STALL response
454 // 3. Error count decreased to zero.
455 //
456 // It also set CRC/Timeout/NAK/Buffer Error/BitStuff Error
457 // bits when corresponding conditions happen. But these
458 // conditions are not deadly, that is a TD can successfully
459 // completes even these bits are set. But it is likely that
460 // upper layer won't distinguish these condtions. So, only
461 // set these bits when TD is actually halted.
462 //
463 if ((State & USBTD_STALLED) != 0) {
464 if ((State & USBTD_BABBLE) != 0) {
465 QhResult->Result |= EFI_USB_ERR_BABBLE;
466
467 } else if (TdHw->ErrorCount != 0) {
468 QhResult->Result |= EFI_USB_ERR_STALL;
469 }
470
471 if ((State & USBTD_CRC) != 0) {
472 QhResult->Result |= EFI_USB_ERR_CRC;
473 }
474
475 if ((State & USBTD_BUFFERR) != 0) {
476 QhResult->Result |= EFI_USB_ERR_BUFFER;
477 }
478
479 if ((Td->TdHw.Status & USBTD_BITSTUFF) != 0) {
480 QhResult->Result |= EFI_USB_ERR_BITSTUFF;
481 }
482
483 if (TdHw->ErrorCount == 0) {
484 QhResult->Result |= EFI_USB_ERR_TIMEOUT;
485 }
486
487 Finished = TRUE;
488 goto ON_EXIT;
489
490 } else if ((State & USBTD_ACTIVE) != 0) {
491 //
492 // The TD is still active, no need to check further.
493 //
494 QhResult->Result |= EFI_USB_ERR_NOTEXECUTE;
495
496 Finished = FALSE;
497 goto ON_EXIT;
498
499 } else {
500 //
501 // Update the next data toggle, it is always the
502 // next to the last known-good TD's data toggle if
503 // any TD is executed OK
504 //
505 QhResult->NextToggle = (UINT8) (1 - (UINT8)TdHw->DataToggle);
506
507 //
508 // This TD is finished OK or met short packet read. Update the
509 // transfer length if it isn't a SETUP.
510 //
511 Len = (TdHw->ActualLen + 1) & 0x7FF;
512
513 if (TdHw->PidCode != SETUP_PACKET_ID) {
514 QhResult->Complete += Len;
515 }
516
517 //
518 // Short packet condition for full speed input TD, also
519 // terminate the transfer
520 //
521 if (!IsLow && (TdHw->ShortPacket == 1) && (Len < Td->DataLen)) {
522 DEBUG ((EFI_D_VERBOSE, "UhciCheckTdStatus: short packet read occured\n"));
523
524 Finished = TRUE;
525 goto ON_EXIT;
526 }
527 }
528
529 Td = Td->NextTd;
530 }
531
532 ON_EXIT:
533 //
534 // Check whether HC is halted. Don't move this up. It must be
535 // called after data toggle is successfully updated.
536 //
537 if (!UhciIsHcWorking (Uhc->PciIo)) {
538 QhResult->Result |= EFI_USB_ERR_SYSTEM;
539 Finished = TRUE;
540 }
541
542 if (Finished) {
543 Uhc->PciIo->Flush (Uhc->PciIo);
544 }
545
546 UhciAckAllInterrupt (Uhc);
547 return Finished;
548 }
549
550
551 /**
552 Check the result of the transfer.
553
554 @param Uhc The UHCI device.
555 @param Qh The queue head of the transfer.
556 @param Td The first TDs of the transfer.
557 @param TimeOut TimeOut value in milliseconds.
558 @param IsLow Is Low Speed Device.
559 @param QhResult The variable to return result.
560
561 @retval EFI_SUCCESS The transfer finished with success.
562 @retval EFI_DEVICE_ERROR Transfer failed.
563
564 **/
565 EFI_STATUS
UhciExecuteTransfer(IN USB_HC_DEV * Uhc,IN UHCI_QH_SW * Qh,IN UHCI_TD_SW * Td,IN UINTN TimeOut,IN BOOLEAN IsLow,OUT UHCI_QH_RESULT * QhResult)566 UhciExecuteTransfer (
567 IN USB_HC_DEV *Uhc,
568 IN UHCI_QH_SW *Qh,
569 IN UHCI_TD_SW *Td,
570 IN UINTN TimeOut,
571 IN BOOLEAN IsLow,
572 OUT UHCI_QH_RESULT *QhResult
573 )
574 {
575 UINTN Index;
576 UINTN Delay;
577 BOOLEAN Finished;
578 EFI_STATUS Status;
579 BOOLEAN InfiniteLoop;
580
581 Finished = FALSE;
582 Status = EFI_SUCCESS;
583 Delay = TimeOut * UHC_1_MILLISECOND;
584 InfiniteLoop = FALSE;
585
586 //
587 // According to UEFI spec section 16.2.4, If Timeout is 0, then the caller
588 // must wait for the function to be completed until EFI_SUCCESS or EFI_DEVICE_ERROR
589 // is returned.
590 //
591 if (TimeOut == 0) {
592 InfiniteLoop = TRUE;
593 }
594
595 for (Index = 0; InfiniteLoop || (Index < Delay); Index++) {
596 Finished = UhciCheckTdStatus (Uhc, Td, IsLow, QhResult);
597
598 //
599 // Transfer is OK or some error occured (TD inactive)
600 //
601 if (Finished) {
602 break;
603 }
604
605 gBS->Stall (UHC_1_MICROSECOND);
606 }
607
608 if (!Finished) {
609 DEBUG ((EFI_D_ERROR, "UhciExecuteTransfer: execution not finished for %dms\n", (UINT32)TimeOut));
610 UhciDumpQh (Qh);
611 UhciDumpTds (Td);
612
613 Status = EFI_TIMEOUT;
614
615 } else if (QhResult->Result != EFI_USB_NOERROR) {
616 DEBUG ((EFI_D_ERROR, "UhciExecuteTransfer: execution failed with result %x\n", QhResult->Result));
617 UhciDumpQh (Qh);
618 UhciDumpTds (Td);
619
620 Status = EFI_DEVICE_ERROR;
621 }
622
623 return Status;
624 }
625
626
627 /**
628 Update Async Request, QH and TDs.
629
630 @param Uhc The UHCI device.
631 @param AsyncReq The UHCI asynchronous transfer to update.
632 @param Result Transfer reslut.
633 @param NextToggle The toggle of next data.
634
635 **/
636 VOID
UhciUpdateAsyncReq(IN USB_HC_DEV * Uhc,IN UHCI_ASYNC_REQUEST * AsyncReq,IN UINT32 Result,IN UINT32 NextToggle)637 UhciUpdateAsyncReq (
638 IN USB_HC_DEV *Uhc,
639 IN UHCI_ASYNC_REQUEST *AsyncReq,
640 IN UINT32 Result,
641 IN UINT32 NextToggle
642 )
643 {
644 UHCI_QH_SW *Qh;
645 UHCI_TD_SW *FirstTd;
646 UHCI_TD_SW *Td;
647
648 Qh = AsyncReq->QhSw;
649 FirstTd = AsyncReq->FirstTd;
650
651 if (Result == EFI_USB_NOERROR) {
652 //
653 // The last transfer succeeds. Then we need to update
654 // the Qh and Td for next round of transfer.
655 // 1. Update the TD's data toggle
656 // 2. Activate all the TDs
657 // 3. Link the TD to the queue head again since during
658 // execution, queue head's TD pointer is changed by
659 // hardware.
660 //
661 for (Td = FirstTd; Td != NULL; Td = Td->NextTd) {
662 Td->TdHw.DataToggle = NextToggle;
663 NextToggle ^= 1;
664 Td->TdHw.Status |= USBTD_ACTIVE;
665 }
666
667 UhciLinkTdToQh (Uhc, Qh, FirstTd);
668 return ;
669 }
670 }
671
672
673 /**
674 Create Async Request node, and Link to List.
675
676 @param Uhc The UHCI device.
677 @param Qh The queue head of the transfer.
678 @param FirstTd First TD of the transfer.
679 @param DevAddr Device Address.
680 @param EndPoint EndPoint Address.
681 @param DataLen Data length.
682 @param Interval Polling Interval when inserted to frame list.
683 @param Data Data buffer, unmapped.
684 @param Callback Callback after interrupt transfeer.
685 @param Context Callback Context passed as function parameter.
686 @param IsLow Is Low Speed.
687
688 @retval EFI_SUCCESS An asynchronous transfer is created.
689 @retval EFI_INVALID_PARAMETER Paremeter is error.
690 @retval EFI_OUT_OF_RESOURCES Failed because of resource shortage.
691
692 **/
693 EFI_STATUS
UhciCreateAsyncReq(IN USB_HC_DEV * Uhc,IN UHCI_QH_SW * Qh,IN UHCI_TD_SW * FirstTd,IN UINT8 DevAddr,IN UINT8 EndPoint,IN UINTN DataLen,IN UINTN Interval,IN UINT8 * Data,IN EFI_ASYNC_USB_TRANSFER_CALLBACK Callback,IN VOID * Context,IN BOOLEAN IsLow)694 UhciCreateAsyncReq (
695 IN USB_HC_DEV *Uhc,
696 IN UHCI_QH_SW *Qh,
697 IN UHCI_TD_SW *FirstTd,
698 IN UINT8 DevAddr,
699 IN UINT8 EndPoint,
700 IN UINTN DataLen,
701 IN UINTN Interval,
702 IN UINT8 *Data,
703 IN EFI_ASYNC_USB_TRANSFER_CALLBACK Callback,
704 IN VOID *Context,
705 IN BOOLEAN IsLow
706 )
707 {
708 UHCI_ASYNC_REQUEST *AsyncReq;
709
710 AsyncReq = AllocatePool (sizeof (UHCI_ASYNC_REQUEST));
711
712 if (AsyncReq == NULL) {
713 return EFI_OUT_OF_RESOURCES;
714 }
715
716 //
717 // Fill Request field. Data is allocated host memory, not mapped
718 //
719 AsyncReq->Signature = UHCI_ASYNC_INT_SIGNATURE;
720 AsyncReq->DevAddr = DevAddr;
721 AsyncReq->EndPoint = EndPoint;
722 AsyncReq->DataLen = DataLen;
723 AsyncReq->Interval = UhciConvertPollRate(Interval);
724 AsyncReq->Data = Data;
725 AsyncReq->Callback = Callback;
726 AsyncReq->Context = Context;
727 AsyncReq->QhSw = Qh;
728 AsyncReq->FirstTd = FirstTd;
729 AsyncReq->IsLow = IsLow;
730
731 //
732 // Insert the new interrupt transfer to the head of the list.
733 // The interrupt transfer's monitor function scans the whole
734 // list from head to tail. The new interrupt transfer MUST be
735 // added to the head of the list.
736 //
737 InsertHeadList (&(Uhc->AsyncIntList), &(AsyncReq->Link));
738
739 return EFI_SUCCESS;
740 }
741
742
743 /**
744 Free an asynchronous request's resource such as memory.
745
746 @param Uhc The UHCI device.
747 @param AsyncReq The asynchronous request to free.
748
749 **/
750 VOID
UhciFreeAsyncReq(IN USB_HC_DEV * Uhc,IN UHCI_ASYNC_REQUEST * AsyncReq)751 UhciFreeAsyncReq (
752 IN USB_HC_DEV *Uhc,
753 IN UHCI_ASYNC_REQUEST *AsyncReq
754 )
755 {
756 ASSERT ((Uhc != NULL) && (AsyncReq != NULL));
757
758 UhciDestoryTds (Uhc, AsyncReq->FirstTd);
759 UsbHcFreeMem (Uhc->MemPool, AsyncReq->QhSw, sizeof (UHCI_QH_SW));
760
761 if (AsyncReq->Data != NULL) {
762 UsbHcFreeMem (Uhc->MemPool, AsyncReq->Data, AsyncReq->DataLen);
763 }
764
765 gBS->FreePool (AsyncReq);
766 }
767
768
769 /**
770 Unlink an asynchronous request's from UHC's asynchronus list.
771 also remove the queue head from the frame list. If FreeNow,
772 release its resource also. Otherwise, add the request to the
773 UHC's recycle list to wait for a while before release the memory.
774 Until then, hardware won't hold point to the request.
775
776 @param Uhc The UHCI device.
777 @param AsyncReq The asynchronous request to free.
778 @param FreeNow If TRUE, free the resource immediately, otherwise
779 add the request to recycle wait list.
780
781 **/
782 VOID
UhciUnlinkAsyncReq(IN USB_HC_DEV * Uhc,IN UHCI_ASYNC_REQUEST * AsyncReq,IN BOOLEAN FreeNow)783 UhciUnlinkAsyncReq (
784 IN USB_HC_DEV *Uhc,
785 IN UHCI_ASYNC_REQUEST *AsyncReq,
786 IN BOOLEAN FreeNow
787 )
788 {
789 ASSERT ((Uhc != NULL) && (AsyncReq != NULL));
790
791 RemoveEntryList (&(AsyncReq->Link));
792 UhciUnlinkQhFromFrameList (Uhc, AsyncReq->QhSw);
793
794 if (FreeNow) {
795 UhciFreeAsyncReq (Uhc, AsyncReq);
796 } else {
797 //
798 // To sychronize with hardware, mark the queue head as inactive
799 // then add AsyncReq to UHC's recycle list
800 //
801 AsyncReq->QhSw->QhHw.VerticalLink = QH_VLINK (NULL, TRUE);
802 AsyncReq->Recycle = Uhc->RecycleWait;
803 Uhc->RecycleWait = AsyncReq;
804 }
805 }
806
807
808 /**
809 Delete Async Interrupt QH and TDs.
810
811 @param Uhc The UHCI device.
812 @param DevAddr Device Address.
813 @param EndPoint EndPoint Address.
814 @param Toggle The next data toggle to use.
815
816 @retval EFI_SUCCESS The request is deleted.
817 @retval EFI_INVALID_PARAMETER Paremeter is error.
818 @retval EFI_NOT_FOUND The asynchronous isn't found.
819
820 **/
821 EFI_STATUS
UhciRemoveAsyncReq(IN USB_HC_DEV * Uhc,IN UINT8 DevAddr,IN UINT8 EndPoint,OUT UINT8 * Toggle)822 UhciRemoveAsyncReq (
823 IN USB_HC_DEV *Uhc,
824 IN UINT8 DevAddr,
825 IN UINT8 EndPoint,
826 OUT UINT8 *Toggle
827 )
828 {
829 EFI_STATUS Status;
830 UHCI_ASYNC_REQUEST *AsyncReq;
831 UHCI_QH_RESULT QhResult;
832 LIST_ENTRY *Link;
833 BOOLEAN Found;
834
835 Status = EFI_SUCCESS;
836
837 //
838 // If no asynchronous interrupt transaction exists
839 //
840 if (IsListEmpty (&(Uhc->AsyncIntList))) {
841 return EFI_SUCCESS;
842 }
843
844 //
845 // Find the asynchronous transfer to this device/endpoint pair
846 //
847 Found = FALSE;
848 Link = Uhc->AsyncIntList.ForwardLink;
849
850 do {
851 AsyncReq = UHCI_ASYNC_INT_FROM_LINK (Link);
852 Link = Link->ForwardLink;
853
854 if ((AsyncReq->DevAddr == DevAddr) && (AsyncReq->EndPoint == EndPoint)) {
855 Found = TRUE;
856 break;
857 }
858
859 } while (Link != &(Uhc->AsyncIntList));
860
861 if (!Found) {
862 return EFI_NOT_FOUND;
863 }
864
865 //
866 // Check the result of the async transfer then update it
867 // to get the next data toggle to use.
868 //
869 UhciCheckTdStatus (Uhc, AsyncReq->FirstTd, AsyncReq->IsLow, &QhResult);
870 *Toggle = QhResult.NextToggle;
871
872 //
873 // Don't release the request now, keep it to synchronize with hardware.
874 //
875 UhciUnlinkAsyncReq (Uhc, AsyncReq, FALSE);
876 return Status;
877 }
878
879
880 /**
881 Recycle the asynchronouse request. When a queue head
882 is unlinked from frame list, host controller hardware
883 may still hold a cached pointer to it. To synchronize
884 with hardware, the request is released in two steps:
885 first it is linked to the UHC's RecycleWait list. At
886 the next time UhciMonitorAsyncReqList is fired, it is
887 moved to UHC's Recylelist. Then, at another timer
888 activation, all the requests on Recycle list is freed.
889 This guarrantes that each unlink queue head keeps
890 existing for at least 50ms, far enough for the hardware
891 to clear its cache.
892
893 @param Uhc The UHCI device.
894
895 **/
896 VOID
UhciRecycleAsyncReq(IN USB_HC_DEV * Uhc)897 UhciRecycleAsyncReq (
898 IN USB_HC_DEV *Uhc
899 )
900 {
901 UHCI_ASYNC_REQUEST *Req;
902 UHCI_ASYNC_REQUEST *Next;
903
904 Req = Uhc->Recycle;
905
906 while (Req != NULL) {
907 Next = Req->Recycle;
908 UhciFreeAsyncReq (Uhc, Req);
909 Req = Next;
910 }
911
912 Uhc->Recycle = Uhc->RecycleWait;
913 Uhc->RecycleWait = NULL;
914 }
915
916
917
918 /**
919 Release all the asynchronous transfers on the lsit.
920
921 @param Uhc The UHCI device.
922
923 **/
924 VOID
UhciFreeAllAsyncReq(IN USB_HC_DEV * Uhc)925 UhciFreeAllAsyncReq (
926 IN USB_HC_DEV *Uhc
927 )
928 {
929 LIST_ENTRY *Head;
930 UHCI_ASYNC_REQUEST *AsyncReq;
931
932 //
933 // Call UhciRecycleAsyncReq twice. The requests on Recycle
934 // will be released at the first call; The requests on
935 // RecycleWait will be released at the second call.
936 //
937 UhciRecycleAsyncReq (Uhc);
938 UhciRecycleAsyncReq (Uhc);
939
940 Head = &(Uhc->AsyncIntList);
941
942 if (IsListEmpty (Head)) {
943 return;
944 }
945
946 while (!IsListEmpty (Head)) {
947 AsyncReq = UHCI_ASYNC_INT_FROM_LINK (Head->ForwardLink);
948 UhciUnlinkAsyncReq (Uhc, AsyncReq, TRUE);
949 }
950 }
951
952
953 /**
954 Interrupt transfer periodic check handler.
955
956 @param Event The event of the time.
957 @param Context Context of the event, pointer to USB_HC_DEV.
958
959 **/
960 VOID
961 EFIAPI
UhciMonitorAsyncReqList(IN EFI_EVENT Event,IN VOID * Context)962 UhciMonitorAsyncReqList (
963 IN EFI_EVENT Event,
964 IN VOID *Context
965 )
966 {
967 UHCI_ASYNC_REQUEST *AsyncReq;
968 LIST_ENTRY *Link;
969 USB_HC_DEV *Uhc;
970 VOID *Data;
971 BOOLEAN Finished;
972 UHCI_QH_RESULT QhResult;
973
974 Uhc = (USB_HC_DEV *) Context;
975
976 //
977 // Recycle the asynchronous requests expired, and promote
978 // requests waiting to be recycled the next time when this
979 // timer expires
980 //
981 UhciRecycleAsyncReq (Uhc);
982
983 if (IsListEmpty (&(Uhc->AsyncIntList))) {
984 return ;
985 }
986
987 //
988 // This loop must be delete safe
989 //
990 Link = Uhc->AsyncIntList.ForwardLink;
991
992 do {
993 AsyncReq = UHCI_ASYNC_INT_FROM_LINK (Link);
994 Link = Link->ForwardLink;
995
996 Finished = UhciCheckTdStatus (Uhc, AsyncReq->FirstTd, AsyncReq->IsLow, &QhResult);
997
998 if (!Finished) {
999 continue;
1000 }
1001
1002 //
1003 // Copy the data to temporary buffer if there are some
1004 // data transferred. We may have zero-length packet
1005 //
1006 Data = NULL;
1007
1008 if (QhResult.Complete != 0) {
1009 Data = AllocatePool (QhResult.Complete);
1010
1011 if (Data == NULL) {
1012 return ;
1013 }
1014
1015 CopyMem (Data, AsyncReq->FirstTd->Data, QhResult.Complete);
1016 }
1017
1018 UhciUpdateAsyncReq (Uhc, AsyncReq, QhResult.Result, QhResult.NextToggle);
1019
1020 //
1021 // Now, either transfer is SUCCESS or met errors since
1022 // we have skipped to next transfer earlier if current
1023 // transfer is still active.
1024 //
1025 if (QhResult.Result == EFI_USB_NOERROR) {
1026 AsyncReq->Callback (Data, QhResult.Complete, AsyncReq->Context, QhResult.Result);
1027 } else {
1028 //
1029 // Leave error recovery to its related device driver.
1030 // A common case of the error recovery is to re-submit
1031 // the interrupt transfer. When an interrupt transfer
1032 // is re-submitted, its position in the linked list is
1033 // changed. It is inserted to the head of the linked
1034 // list, while this function scans the whole list from
1035 // head to tail. Thus, the re-submitted interrupt transfer's
1036 // callback function will not be called again in this round.
1037 //
1038 AsyncReq->Callback (NULL, 0, AsyncReq->Context, QhResult.Result);
1039 }
1040
1041 if (Data != NULL) {
1042 gBS->FreePool (Data);
1043 }
1044 } while (Link != &(Uhc->AsyncIntList));
1045 }
1046