3 XHCI transfer scheduling routines.
5 Copyright (c) 2011 - 2015, 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
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.
19 Create a command transfer TRB to support XHCI command interfaces.
21 @param Xhc The XHCI Instance.
22 @param CmdTrb The cmd TRB to be executed.
24 @return Created URB or NULL.
29 IN USB_XHCI_INSTANCE
*Xhc
,
30 IN TRB_TEMPLATE
*CmdTrb
35 Urb
= AllocateZeroPool (sizeof (URB
));
40 Urb
->Signature
= XHC_URB_SIG
;
42 Urb
->Ring
= &Xhc
->CmdRing
;
43 XhcSyncTrsRing (Xhc
, Urb
->Ring
);
45 Urb
->TrbStart
= Urb
->Ring
->RingEnqueue
;
46 CopyMem (Urb
->TrbStart
, CmdTrb
, sizeof (TRB_TEMPLATE
));
47 Urb
->TrbStart
->CycleBit
= Urb
->Ring
->RingPCS
& BIT0
;
48 Urb
->TrbEnd
= Urb
->TrbStart
;
54 Execute a XHCI cmd TRB pointed by CmdTrb.
56 @param Xhc The XHCI Instance.
57 @param CmdTrb The cmd TRB to be executed.
58 @param Timeout Indicates the maximum time, in millisecond, which the
59 transfer is allowed to complete.
60 @param EvtTrb The event TRB corresponding to the cmd TRB.
62 @retval EFI_SUCCESS The transfer was completed successfully.
63 @retval EFI_INVALID_PARAMETER Some parameters are invalid.
64 @retval EFI_TIMEOUT The transfer failed due to timeout.
65 @retval EFI_DEVICE_ERROR The transfer failed due to host controller error.
71 IN USB_XHCI_INSTANCE
*Xhc
,
72 IN TRB_TEMPLATE
*CmdTrb
,
74 OUT TRB_TEMPLATE
**EvtTrb
81 // Validate the parameters
83 if ((Xhc
== NULL
) || (CmdTrb
== NULL
)) {
84 return EFI_INVALID_PARAMETER
;
87 Status
= EFI_DEVICE_ERROR
;
89 if (XhcIsHalt (Xhc
) || XhcIsSysError (Xhc
)) {
90 DEBUG ((EFI_D_ERROR
, "XhcCmdTransfer: HC is halted\n"));
95 // Create a new URB, then poll the execution status.
97 Urb
= XhcCreateCmdTrb (Xhc
, CmdTrb
);
100 DEBUG ((EFI_D_ERROR
, "XhcCmdTransfer: failed to create URB\n"));
101 Status
= EFI_OUT_OF_RESOURCES
;
105 Status
= XhcExecTransfer (Xhc
, TRUE
, Urb
, Timeout
);
106 *EvtTrb
= Urb
->EvtTrb
;
108 if (Urb
->Result
== EFI_USB_NOERROR
) {
109 Status
= EFI_SUCCESS
;
112 XhcFreeUrb (Xhc
, Urb
);
119 Create a new URB for a new transaction.
121 @param Xhc The XHCI Instance
122 @param BusAddr The logical device address assigned by UsbBus driver
123 @param EpAddr Endpoint addrress
124 @param DevSpeed The device speed
125 @param MaxPacket The max packet length of the endpoint
126 @param Type The transaction type
127 @param Request The standard USB request for control transfer
128 @param Data The user data to transfer
129 @param DataLen The length of data buffer
130 @param Callback The function to call when data is transferred
131 @param Context The context to the callback
133 @return Created URB or NULL
138 IN USB_XHCI_INSTANCE
*Xhc
,
144 IN EFI_USB_DEVICE_REQUEST
*Request
,
147 IN EFI_ASYNC_USB_TRANSFER_CALLBACK Callback
,
155 Urb
= AllocateZeroPool (sizeof (URB
));
160 Urb
->Signature
= XHC_URB_SIG
;
161 InitializeListHead (&Urb
->UrbList
);
164 Ep
->BusAddr
= BusAddr
;
165 Ep
->EpAddr
= (UINT8
)(EpAddr
& 0x0F);
166 Ep
->Direction
= ((EpAddr
& 0x80) != 0) ? EfiUsbDataIn
: EfiUsbDataOut
;
167 Ep
->DevSpeed
= DevSpeed
;
168 Ep
->MaxPacket
= MaxPacket
;
171 Urb
->Request
= Request
;
173 Urb
->DataLen
= DataLen
;
174 Urb
->Callback
= Callback
;
175 Urb
->Context
= Context
;
177 Status
= XhcCreateTransferTrb (Xhc
, Urb
);
178 ASSERT_EFI_ERROR (Status
);
179 if (EFI_ERROR (Status
)) {
180 DEBUG ((EFI_D_ERROR
, "XhcCreateUrb: XhcCreateTransferTrb Failed, Status = %r\n", Status
));
189 Free an allocated URB.
191 @param Xhc The XHCI device.
192 @param Urb The URB to free.
197 IN USB_XHCI_INSTANCE
*Xhc
,
201 if ((Xhc
== NULL
) || (Urb
== NULL
)) {
205 if (Urb
->DataMap
!= NULL
) {
206 Xhc
->PciIo
->Unmap (Xhc
->PciIo
, Urb
->DataMap
);
213 Create a transfer TRB.
215 @param Xhc The XHCI Instance
216 @param Urb The urb used to construct the transfer TRB.
218 @return Created TRB or NULL
222 XhcCreateTransferTrb (
223 IN USB_XHCI_INSTANCE
*Xhc
,
228 TRANSFER_RING
*EPRing
;
236 EFI_PCI_IO_PROTOCOL_OPERATION MapOp
;
237 EFI_PHYSICAL_ADDRESS PhyAddr
;
241 SlotId
= XhcBusDevAddrToSlotId (Xhc
, Urb
->Ep
.BusAddr
);
243 return EFI_DEVICE_ERROR
;
246 Urb
->Finished
= FALSE
;
247 Urb
->StartDone
= FALSE
;
248 Urb
->EndDone
= FALSE
;
250 Urb
->Result
= EFI_USB_NOERROR
;
252 Dci
= XhcEndpointToDci (Urb
->Ep
.EpAddr
, (UINT8
)(Urb
->Ep
.Direction
));
254 EPRing
= (TRANSFER_RING
*)(UINTN
) Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1];
256 OutputContext
= Xhc
->UsbDevContext
[SlotId
].OutputContext
;
257 if (Xhc
->HcCParams
.Data
.Csz
== 0) {
258 EPType
= (UINT8
) ((DEVICE_CONTEXT
*)OutputContext
)->EP
[Dci
-1].EPType
;
260 EPType
= (UINT8
) ((DEVICE_CONTEXT_64
*)OutputContext
)->EP
[Dci
-1].EPType
;
263 if (Urb
->Data
!= NULL
) {
264 if (((UINT8
) (Urb
->Ep
.Direction
)) == EfiUsbDataIn
) {
265 MapOp
= EfiPciIoOperationBusMasterWrite
;
267 MapOp
= EfiPciIoOperationBusMasterRead
;
271 Status
= Xhc
->PciIo
->Map (Xhc
->PciIo
, MapOp
, Urb
->Data
, &Len
, &PhyAddr
, &Map
);
273 if (EFI_ERROR (Status
) || (Len
!= Urb
->DataLen
)) {
274 DEBUG ((EFI_D_ERROR
, "XhcCreateTransferTrb: Fail to map Urb->Data.\n"));
275 return EFI_OUT_OF_RESOURCES
;
278 Urb
->DataPhy
= (VOID
*) ((UINTN
) PhyAddr
);
285 XhcSyncTrsRing (Xhc
, EPRing
);
286 Urb
->TrbStart
= EPRing
->RingEnqueue
;
288 case ED_CONTROL_BIDIR
:
290 // For control transfer, create SETUP_STAGE_TRB first.
292 TrbStart
= (TRB
*)(UINTN
)EPRing
->RingEnqueue
;
293 TrbStart
->TrbCtrSetup
.bmRequestType
= Urb
->Request
->RequestType
;
294 TrbStart
->TrbCtrSetup
.bRequest
= Urb
->Request
->Request
;
295 TrbStart
->TrbCtrSetup
.wValue
= Urb
->Request
->Value
;
296 TrbStart
->TrbCtrSetup
.wIndex
= Urb
->Request
->Index
;
297 TrbStart
->TrbCtrSetup
.wLength
= Urb
->Request
->Length
;
298 TrbStart
->TrbCtrSetup
.Length
= 8;
299 TrbStart
->TrbCtrSetup
.IntTarget
= 0;
300 TrbStart
->TrbCtrSetup
.IOC
= 1;
301 TrbStart
->TrbCtrSetup
.IDT
= 1;
302 TrbStart
->TrbCtrSetup
.Type
= TRB_TYPE_SETUP_STAGE
;
303 if (Urb
->Ep
.Direction
== EfiUsbDataIn
) {
304 TrbStart
->TrbCtrSetup
.TRT
= 3;
305 } else if (Urb
->Ep
.Direction
== EfiUsbDataOut
) {
306 TrbStart
->TrbCtrSetup
.TRT
= 2;
308 TrbStart
->TrbCtrSetup
.TRT
= 0;
311 // Update the cycle bit
313 TrbStart
->TrbCtrSetup
.CycleBit
= EPRing
->RingPCS
& BIT0
;
317 // For control transfer, create DATA_STAGE_TRB.
319 if (Urb
->DataLen
> 0) {
320 XhcSyncTrsRing (Xhc
, EPRing
);
321 TrbStart
= (TRB
*)(UINTN
)EPRing
->RingEnqueue
;
322 TrbStart
->TrbCtrData
.TRBPtrLo
= XHC_LOW_32BIT(Urb
->DataPhy
);
323 TrbStart
->TrbCtrData
.TRBPtrHi
= XHC_HIGH_32BIT(Urb
->DataPhy
);
324 TrbStart
->TrbCtrData
.Length
= (UINT32
) Urb
->DataLen
;
325 TrbStart
->TrbCtrData
.TDSize
= 0;
326 TrbStart
->TrbCtrData
.IntTarget
= 0;
327 TrbStart
->TrbCtrData
.ISP
= 1;
328 TrbStart
->TrbCtrData
.IOC
= 1;
329 TrbStart
->TrbCtrData
.IDT
= 0;
330 TrbStart
->TrbCtrData
.CH
= 0;
331 TrbStart
->TrbCtrData
.Type
= TRB_TYPE_DATA_STAGE
;
332 if (Urb
->Ep
.Direction
== EfiUsbDataIn
) {
333 TrbStart
->TrbCtrData
.DIR = 1;
334 } else if (Urb
->Ep
.Direction
== EfiUsbDataOut
) {
335 TrbStart
->TrbCtrData
.DIR = 0;
337 TrbStart
->TrbCtrData
.DIR = 0;
340 // Update the cycle bit
342 TrbStart
->TrbCtrData
.CycleBit
= EPRing
->RingPCS
& BIT0
;
346 // For control transfer, create STATUS_STAGE_TRB.
347 // Get the pointer to next TRB for status stage use
349 XhcSyncTrsRing (Xhc
, EPRing
);
350 TrbStart
= (TRB
*)(UINTN
)EPRing
->RingEnqueue
;
351 TrbStart
->TrbCtrStatus
.IntTarget
= 0;
352 TrbStart
->TrbCtrStatus
.IOC
= 1;
353 TrbStart
->TrbCtrStatus
.CH
= 0;
354 TrbStart
->TrbCtrStatus
.Type
= TRB_TYPE_STATUS_STAGE
;
355 if (Urb
->Ep
.Direction
== EfiUsbDataIn
) {
356 TrbStart
->TrbCtrStatus
.DIR = 0;
357 } else if (Urb
->Ep
.Direction
== EfiUsbDataOut
) {
358 TrbStart
->TrbCtrStatus
.DIR = 1;
360 TrbStart
->TrbCtrStatus
.DIR = 0;
363 // Update the cycle bit
365 TrbStart
->TrbCtrStatus
.CycleBit
= EPRing
->RingPCS
& BIT0
;
367 // Update the enqueue pointer
369 XhcSyncTrsRing (Xhc
, EPRing
);
371 Urb
->TrbEnd
= (TRB_TEMPLATE
*)(UINTN
)TrbStart
;
380 TrbStart
= (TRB
*)(UINTN
)EPRing
->RingEnqueue
;
381 while (TotalLen
< Urb
->DataLen
) {
382 if ((TotalLen
+ 0x10000) >= Urb
->DataLen
) {
383 Len
= Urb
->DataLen
- TotalLen
;
387 TrbStart
= (TRB
*)(UINTN
)EPRing
->RingEnqueue
;
388 TrbStart
->TrbNormal
.TRBPtrLo
= XHC_LOW_32BIT((UINT8
*) Urb
->DataPhy
+ TotalLen
);
389 TrbStart
->TrbNormal
.TRBPtrHi
= XHC_HIGH_32BIT((UINT8
*) Urb
->DataPhy
+ TotalLen
);
390 TrbStart
->TrbNormal
.Length
= (UINT32
) Len
;
391 TrbStart
->TrbNormal
.TDSize
= 0;
392 TrbStart
->TrbNormal
.IntTarget
= 0;
393 TrbStart
->TrbNormal
.ISP
= 1;
394 TrbStart
->TrbNormal
.IOC
= 1;
395 TrbStart
->TrbNormal
.Type
= TRB_TYPE_NORMAL
;
397 // Update the cycle bit
399 TrbStart
->TrbNormal
.CycleBit
= EPRing
->RingPCS
& BIT0
;
401 XhcSyncTrsRing (Xhc
, EPRing
);
406 Urb
->TrbNum
= TrbNum
;
407 Urb
->TrbEnd
= (TRB_TEMPLATE
*)(UINTN
)TrbStart
;
410 case ED_INTERRUPT_OUT
:
411 case ED_INTERRUPT_IN
:
415 TrbStart
= (TRB
*)(UINTN
)EPRing
->RingEnqueue
;
416 while (TotalLen
< Urb
->DataLen
) {
417 if ((TotalLen
+ 0x10000) >= Urb
->DataLen
) {
418 Len
= Urb
->DataLen
- TotalLen
;
422 TrbStart
= (TRB
*)(UINTN
)EPRing
->RingEnqueue
;
423 TrbStart
->TrbNormal
.TRBPtrLo
= XHC_LOW_32BIT((UINT8
*) Urb
->DataPhy
+ TotalLen
);
424 TrbStart
->TrbNormal
.TRBPtrHi
= XHC_HIGH_32BIT((UINT8
*) Urb
->DataPhy
+ TotalLen
);
425 TrbStart
->TrbNormal
.Length
= (UINT32
) Len
;
426 TrbStart
->TrbNormal
.TDSize
= 0;
427 TrbStart
->TrbNormal
.IntTarget
= 0;
428 TrbStart
->TrbNormal
.ISP
= 1;
429 TrbStart
->TrbNormal
.IOC
= 1;
430 TrbStart
->TrbNormal
.Type
= TRB_TYPE_NORMAL
;
432 // Update the cycle bit
434 TrbStart
->TrbNormal
.CycleBit
= EPRing
->RingPCS
& BIT0
;
436 XhcSyncTrsRing (Xhc
, EPRing
);
441 Urb
->TrbNum
= TrbNum
;
442 Urb
->TrbEnd
= (TRB_TEMPLATE
*)(UINTN
)TrbStart
;
446 DEBUG ((EFI_D_INFO
, "Not supported EPType 0x%x!\n",EPType
));
456 Initialize the XHCI host controller for schedule.
458 @param Xhc The XHCI Instance to be initialized.
463 IN USB_XHCI_INSTANCE
*Xhc
467 EFI_PHYSICAL_ADDRESS DcbaaPhy
;
469 EFI_PHYSICAL_ADDRESS CmdRingPhy
;
471 UINT32 MaxScratchpadBufs
;
473 EFI_PHYSICAL_ADDRESS ScratchPhy
;
474 UINT64
*ScratchEntry
;
475 EFI_PHYSICAL_ADDRESS ScratchEntryPhy
;
477 UINTN
*ScratchEntryMap
;
481 // Initialize memory management.
483 Xhc
->MemPool
= UsbHcInitMemPool (Xhc
->PciIo
);
484 ASSERT (Xhc
->MemPool
!= NULL
);
487 // Program the Max Device Slots Enabled (MaxSlotsEn) field in the CONFIG register (5.4.7)
488 // to enable the device slots that system software is going to use.
490 Xhc
->MaxSlotsEn
= Xhc
->HcSParams1
.Data
.MaxSlots
;
491 ASSERT (Xhc
->MaxSlotsEn
>= 1 && Xhc
->MaxSlotsEn
<= 255);
492 XhcWriteOpReg (Xhc
, XHC_CONFIG_OFFSET
, Xhc
->MaxSlotsEn
);
495 // The Device Context Base Address Array entry associated with each allocated Device Slot
496 // shall contain a 64-bit pointer to the base of the associated Device Context.
497 // The Device Context Base Address Array shall contain MaxSlotsEn + 1 entries.
498 // Software shall set Device Context Base Address Array entries for unallocated Device Slots to '0'.
500 Entries
= (Xhc
->MaxSlotsEn
+ 1) * sizeof(UINT64
);
501 Dcbaa
= UsbHcAllocateMem (Xhc
->MemPool
, Entries
);
502 ASSERT (Dcbaa
!= NULL
);
503 ZeroMem (Dcbaa
, Entries
);
506 // A Scratchpad Buffer is a PAGESIZE block of system memory located on a PAGESIZE boundary.
507 // System software shall allocate the Scratchpad Buffer(s) before placing the xHC in to Run
508 // mode (Run/Stop(R/S) ='1').
510 MaxScratchpadBufs
= ((Xhc
->HcSParams2
.Data
.ScratchBufHi
) << 5) | (Xhc
->HcSParams2
.Data
.ScratchBufLo
);
511 Xhc
->MaxScratchpadBufs
= MaxScratchpadBufs
;
512 ASSERT (MaxScratchpadBufs
<= 1023);
513 if (MaxScratchpadBufs
!= 0) {
515 // Allocate the buffer to record the Mapping for each scratch buffer in order to Unmap them
517 ScratchEntryMap
= AllocateZeroPool (sizeof (UINTN
) * MaxScratchpadBufs
);
518 ASSERT (ScratchEntryMap
!= NULL
);
519 Xhc
->ScratchEntryMap
= ScratchEntryMap
;
522 // Allocate the buffer to record the host address for each entry
524 ScratchEntry
= AllocateZeroPool (sizeof (UINT64
) * MaxScratchpadBufs
);
525 ASSERT (ScratchEntry
!= NULL
);
526 Xhc
->ScratchEntry
= ScratchEntry
;
529 Status
= UsbHcAllocateAlignedPages (
531 EFI_SIZE_TO_PAGES (MaxScratchpadBufs
* sizeof (UINT64
)),
533 (VOID
**) &ScratchBuf
,
537 ASSERT_EFI_ERROR (Status
);
539 ZeroMem (ScratchBuf
, MaxScratchpadBufs
* sizeof (UINT64
));
540 Xhc
->ScratchBuf
= ScratchBuf
;
543 // Allocate each scratch buffer
545 for (Index
= 0; Index
< MaxScratchpadBufs
; Index
++) {
547 Status
= UsbHcAllocateAlignedPages (
549 EFI_SIZE_TO_PAGES (Xhc
->PageSize
),
551 (VOID
**) &ScratchEntry
[Index
],
553 (VOID
**) &ScratchEntryMap
[Index
]
555 ASSERT_EFI_ERROR (Status
);
556 ZeroMem ((VOID
*)(UINTN
)ScratchEntry
[Index
], Xhc
->PageSize
);
558 // Fill with the PCI device address
560 *ScratchBuf
++ = ScratchEntryPhy
;
563 // The Scratchpad Buffer Array contains pointers to the Scratchpad Buffers. Entry 0 of the
564 // Device Context Base Address Array points to the Scratchpad Buffer Array.
566 *(UINT64
*)Dcbaa
= (UINT64
)(UINTN
) ScratchPhy
;
570 // Program the Device Context Base Address Array Pointer (DCBAAP) register (5.4.6) with
571 // a 64-bit address pointing to where the Device Context Base Address Array is located.
573 Xhc
->DCBAA
= (UINT64
*)(UINTN
)Dcbaa
;
575 // Some 3rd party XHCI external cards don't support single 64-bytes width register access,
576 // So divide it to two 32-bytes width register access.
578 DcbaaPhy
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, Dcbaa
, Entries
);
579 XhcWriteOpReg (Xhc
, XHC_DCBAAP_OFFSET
, XHC_LOW_32BIT(DcbaaPhy
));
580 XhcWriteOpReg (Xhc
, XHC_DCBAAP_OFFSET
+ 4, XHC_HIGH_32BIT (DcbaaPhy
));
582 DEBUG ((EFI_D_INFO
, "XhcInitSched:DCBAA=0x%x\n", (UINT64
)(UINTN
)Xhc
->DCBAA
));
585 // Define the Command Ring Dequeue Pointer by programming the Command Ring Control Register
586 // (5.4.5) with a 64-bit address pointing to the starting address of the first TRB of the Command Ring.
587 // Note: The Command Ring is 64 byte aligned, so the low order 6 bits of the Command Ring Pointer shall
590 CreateTransferRing (Xhc
, CMD_RING_TRB_NUMBER
, &Xhc
->CmdRing
);
592 // The xHC uses the Enqueue Pointer to determine when a Transfer Ring is empty. As it fetches TRBs from a
593 // Transfer Ring it checks for a Cycle bit transition. If a transition detected, the ring is empty.
594 // So we set RCS as inverted PCS init value to let Command Ring empty
596 CmdRing
= (UINT64
)(UINTN
)Xhc
->CmdRing
.RingSeg0
;
597 CmdRingPhy
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, (VOID
*)(UINTN
) CmdRing
, sizeof (TRB_TEMPLATE
) * CMD_RING_TRB_NUMBER
);
598 ASSERT ((CmdRingPhy
& 0x3F) == 0);
599 CmdRingPhy
|= XHC_CRCR_RCS
;
601 // Some 3rd party XHCI external cards don't support single 64-bytes width register access,
602 // So divide it to two 32-bytes width register access.
604 XhcWriteOpReg (Xhc
, XHC_CRCR_OFFSET
, XHC_LOW_32BIT(CmdRingPhy
));
605 XhcWriteOpReg (Xhc
, XHC_CRCR_OFFSET
+ 4, XHC_HIGH_32BIT (CmdRingPhy
));
607 DEBUG ((EFI_D_INFO
, "XhcInitSched:XHC_CRCR=0x%x\n", Xhc
->CmdRing
.RingSeg0
));
610 // Disable the 'interrupter enable' bit in USB_CMD
611 // and clear IE & IP bit in all Interrupter X Management Registers.
613 XhcClearOpRegBit (Xhc
, XHC_USBCMD_OFFSET
, XHC_USBCMD_INTE
);
614 for (Index
= 0; Index
< (UINT16
)(Xhc
->HcSParams1
.Data
.MaxIntrs
); Index
++) {
615 XhcClearRuntimeRegBit (Xhc
, XHC_IMAN_OFFSET
+ (Index
* 32), XHC_IMAN_IE
);
616 XhcSetRuntimeRegBit (Xhc
, XHC_IMAN_OFFSET
+ (Index
* 32), XHC_IMAN_IP
);
620 // Allocate EventRing for Cmd, Ctrl, Bulk, Interrupt, AsynInterrupt transfer
622 CreateEventRing (Xhc
, &Xhc
->EventRing
);
623 DEBUG ((EFI_D_INFO
, "XhcInitSched:XHC_EVENTRING=0x%x\n", Xhc
->EventRing
.EventRingSeg0
));
627 System software shall use a Reset Endpoint Command (section 4.11.4.7) to remove the Halted
628 condition in the xHC. After the successful completion of the Reset Endpoint Command, the Endpoint
629 Context is transitioned from the Halted to the Stopped state and the Transfer Ring of the endpoint is
630 reenabled. The next write to the Doorbell of the Endpoint will transition the Endpoint Context from the
631 Stopped to the Running state.
633 @param Xhc The XHCI Instance.
634 @param Urb The urb which makes the endpoint halted.
636 @retval EFI_SUCCESS The recovery is successful.
637 @retval Others Failed to recovery halted endpoint.
642 XhcRecoverHaltedEndpoint (
643 IN USB_XHCI_INSTANCE
*Xhc
,
651 Status
= EFI_SUCCESS
;
652 SlotId
= XhcBusDevAddrToSlotId (Xhc
, Urb
->Ep
.BusAddr
);
654 return EFI_DEVICE_ERROR
;
656 Dci
= XhcEndpointToDci (Urb
->Ep
.EpAddr
, (UINT8
)(Urb
->Ep
.Direction
));
659 DEBUG ((EFI_D_INFO
, "Recovery Halted Slot = %x,Dci = %x\n", SlotId
, Dci
));
662 // 1) Send Reset endpoint command to transit from halt to stop state
664 Status
= XhcResetEndpoint(Xhc
, SlotId
, Dci
);
665 if (EFI_ERROR(Status
)) {
666 DEBUG ((EFI_D_ERROR
, "XhcRecoverHaltedEndpoint: Reset Endpoint Failed, Status = %r\n", Status
));
671 // 2)Set dequeue pointer
673 Status
= XhcSetTrDequeuePointer(Xhc
, SlotId
, Dci
, Urb
);
674 if (EFI_ERROR(Status
)) {
675 DEBUG ((EFI_D_ERROR
, "XhcRecoverHaltedEndpoint: Set Transfer Ring Dequeue Pointer Failed, Status = %r\n", Status
));
680 // 3)Ring the doorbell to transit from stop to active
682 XhcRingDoorBell (Xhc
, SlotId
, Dci
);
689 System software shall use a Stop Endpoint Command (section 4.6.9) and the Set TR Dequeue Pointer
690 Command (section 4.6.10) to remove the timed-out TDs from the xHC transfer ring. The next write to
691 the Doorbell of the Endpoint will transition the Endpoint Context from the Stopped to the Running
694 @param Xhc The XHCI Instance.
695 @param Urb The urb which doesn't get completed in a specified timeout range.
697 @retval EFI_SUCCESS The dequeuing of the TDs is successful.
698 @retval Others Failed to stop the endpoint and dequeue the TDs.
703 XhcDequeueTrbFromEndpoint (
704 IN USB_XHCI_INSTANCE
*Xhc
,
712 Status
= EFI_SUCCESS
;
713 SlotId
= XhcBusDevAddrToSlotId (Xhc
, Urb
->Ep
.BusAddr
);
715 return EFI_DEVICE_ERROR
;
717 Dci
= XhcEndpointToDci (Urb
->Ep
.EpAddr
, (UINT8
)(Urb
->Ep
.Direction
));
720 DEBUG ((EFI_D_INFO
, "Stop Slot = %x,Dci = %x\n", SlotId
, Dci
));
723 // 1) Send Stop endpoint command to stop xHC from executing of the TDs on the endpoint
725 Status
= XhcStopEndpoint(Xhc
, SlotId
, Dci
);
726 if (EFI_ERROR(Status
)) {
727 DEBUG ((EFI_D_ERROR
, "XhcDequeueTrbFromEndpoint: Stop Endpoint Failed, Status = %r\n", Status
));
732 // 2)Set dequeue pointer
734 Status
= XhcSetTrDequeuePointer(Xhc
, SlotId
, Dci
, Urb
);
735 if (EFI_ERROR(Status
)) {
736 DEBUG ((EFI_D_ERROR
, "XhcDequeueTrbFromEndpoint: Set Transfer Ring Dequeue Pointer Failed, Status = %r\n", Status
));
741 // 3)Ring the doorbell to transit from stop to active
743 XhcRingDoorBell (Xhc
, SlotId
, Dci
);
750 Create XHCI event ring.
752 @param Xhc The XHCI Instance.
753 @param EventRing The created event ring.
758 IN USB_XHCI_INSTANCE
*Xhc
,
759 OUT EVENT_RING
*EventRing
763 EVENT_RING_SEG_TABLE_ENTRY
*ERSTBase
;
765 EFI_PHYSICAL_ADDRESS ERSTPhy
;
766 EFI_PHYSICAL_ADDRESS DequeuePhy
;
768 ASSERT (EventRing
!= NULL
);
770 Size
= sizeof (TRB_TEMPLATE
) * EVENT_RING_TRB_NUMBER
;
771 Buf
= UsbHcAllocateMem (Xhc
->MemPool
, Size
);
772 ASSERT (Buf
!= NULL
);
773 ASSERT (((UINTN
) Buf
& 0x3F) == 0);
776 EventRing
->EventRingSeg0
= Buf
;
777 EventRing
->TrbNumber
= EVENT_RING_TRB_NUMBER
;
778 EventRing
->EventRingDequeue
= (TRB_TEMPLATE
*) EventRing
->EventRingSeg0
;
779 EventRing
->EventRingEnqueue
= (TRB_TEMPLATE
*) EventRing
->EventRingSeg0
;
781 DequeuePhy
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, Buf
, Size
);
784 // Software maintains an Event Ring Consumer Cycle State (CCS) bit, initializing it to '1'
785 // and toggling it every time the Event Ring Dequeue Pointer wraps back to the beginning of the Event Ring.
787 EventRing
->EventRingCCS
= 1;
789 Size
= sizeof (EVENT_RING_SEG_TABLE_ENTRY
) * ERST_NUMBER
;
790 Buf
= UsbHcAllocateMem (Xhc
->MemPool
, Size
);
791 ASSERT (Buf
!= NULL
);
792 ASSERT (((UINTN
) Buf
& 0x3F) == 0);
795 ERSTBase
= (EVENT_RING_SEG_TABLE_ENTRY
*) Buf
;
796 EventRing
->ERSTBase
= ERSTBase
;
797 ERSTBase
->PtrLo
= XHC_LOW_32BIT (DequeuePhy
);
798 ERSTBase
->PtrHi
= XHC_HIGH_32BIT (DequeuePhy
);
799 ERSTBase
->RingTrbSize
= EVENT_RING_TRB_NUMBER
;
801 ERSTPhy
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, ERSTBase
, Size
);
804 // Program the Interrupter Event Ring Segment Table Size (ERSTSZ) register (5.5.2.3.1)
812 // Program the Interrupter Event Ring Dequeue Pointer (ERDP) register (5.5.2.3.3)
814 // Some 3rd party XHCI external cards don't support single 64-bytes width register access,
815 // So divide it to two 32-bytes width register access.
820 XHC_LOW_32BIT((UINT64
)(UINTN
)DequeuePhy
)
825 XHC_HIGH_32BIT((UINT64
)(UINTN
)DequeuePhy
)
828 // Program the Interrupter Event Ring Segment Table Base Address (ERSTBA) register(5.5.2.3.2)
830 // Some 3rd party XHCI external cards don't support single 64-bytes width register access,
831 // So divide it to two 32-bytes width register access.
836 XHC_LOW_32BIT((UINT64
)(UINTN
)ERSTPhy
)
840 XHC_ERSTBA_OFFSET
+ 4,
841 XHC_HIGH_32BIT((UINT64
)(UINTN
)ERSTPhy
)
844 // Need set IMAN IE bit to enble the ring interrupt
846 XhcSetRuntimeRegBit (Xhc
, XHC_IMAN_OFFSET
, XHC_IMAN_IE
);
850 Create XHCI transfer ring.
852 @param Xhc The XHCI Instance.
853 @param TrbNum The number of TRB in the ring.
854 @param TransferRing The created transfer ring.
859 IN USB_XHCI_INSTANCE
*Xhc
,
861 OUT TRANSFER_RING
*TransferRing
866 EFI_PHYSICAL_ADDRESS PhyAddr
;
868 Buf
= UsbHcAllocateMem (Xhc
->MemPool
, sizeof (TRB_TEMPLATE
) * TrbNum
);
869 ASSERT (Buf
!= NULL
);
870 ASSERT (((UINTN
) Buf
& 0x3F) == 0);
871 ZeroMem (Buf
, sizeof (TRB_TEMPLATE
) * TrbNum
);
873 TransferRing
->RingSeg0
= Buf
;
874 TransferRing
->TrbNumber
= TrbNum
;
875 TransferRing
->RingEnqueue
= (TRB_TEMPLATE
*) TransferRing
->RingSeg0
;
876 TransferRing
->RingDequeue
= (TRB_TEMPLATE
*) TransferRing
->RingSeg0
;
877 TransferRing
->RingPCS
= 1;
879 // 4.9.2 Transfer Ring Management
880 // To form a ring (or circular queue) a Link TRB may be inserted at the end of a ring to
881 // point to the first TRB in the ring.
883 EndTrb
= (LINK_TRB
*) ((UINTN
)Buf
+ sizeof (TRB_TEMPLATE
) * (TrbNum
- 1));
884 EndTrb
->Type
= TRB_TYPE_LINK
;
885 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, Buf
, sizeof (TRB_TEMPLATE
) * TrbNum
);
886 EndTrb
->PtrLo
= XHC_LOW_32BIT (PhyAddr
);
887 EndTrb
->PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
889 // Toggle Cycle (TC). When set to '1', the xHC shall toggle its interpretation of the Cycle bit.
893 // Set Cycle bit as other TRB PCS init value
895 EndTrb
->CycleBit
= 0;
899 Free XHCI event ring.
901 @param Xhc The XHCI Instance.
902 @param EventRing The event ring to be freed.
908 IN USB_XHCI_INSTANCE
*Xhc
,
909 IN EVENT_RING
*EventRing
912 if(EventRing
->EventRingSeg0
== NULL
) {
917 // Free EventRing Segment 0
919 UsbHcFreeMem (Xhc
->MemPool
, EventRing
->EventRingSeg0
, sizeof (TRB_TEMPLATE
) * EVENT_RING_TRB_NUMBER
);
924 UsbHcFreeMem (Xhc
->MemPool
, EventRing
->ERSTBase
, sizeof (EVENT_RING_SEG_TABLE_ENTRY
) * ERST_NUMBER
);
929 Free the resouce allocated at initializing schedule.
931 @param Xhc The XHCI Instance.
936 IN USB_XHCI_INSTANCE
*Xhc
940 UINT64
*ScratchEntry
;
942 if (Xhc
->ScratchBuf
!= NULL
) {
943 ScratchEntry
= Xhc
->ScratchEntry
;
944 for (Index
= 0; Index
< Xhc
->MaxScratchpadBufs
; Index
++) {
946 // Free Scratchpad Buffers
948 UsbHcFreeAlignedPages (Xhc
->PciIo
, (VOID
*)(UINTN
)ScratchEntry
[Index
], EFI_SIZE_TO_PAGES (Xhc
->PageSize
), (VOID
*) Xhc
->ScratchEntryMap
[Index
]);
951 // Free Scratchpad Buffer Array
953 UsbHcFreeAlignedPages (Xhc
->PciIo
, Xhc
->ScratchBuf
, EFI_SIZE_TO_PAGES (Xhc
->MaxScratchpadBufs
* sizeof (UINT64
)), Xhc
->ScratchMap
);
954 FreePool (Xhc
->ScratchEntryMap
);
955 FreePool (Xhc
->ScratchEntry
);
958 if (Xhc
->CmdRing
.RingSeg0
!= NULL
) {
959 UsbHcFreeMem (Xhc
->MemPool
, Xhc
->CmdRing
.RingSeg0
, sizeof (TRB_TEMPLATE
) * CMD_RING_TRB_NUMBER
);
960 Xhc
->CmdRing
.RingSeg0
= NULL
;
963 XhcFreeEventRing (Xhc
,&Xhc
->EventRing
);
965 if (Xhc
->DCBAA
!= NULL
) {
966 UsbHcFreeMem (Xhc
->MemPool
, Xhc
->DCBAA
, (Xhc
->MaxSlotsEn
+ 1) * sizeof(UINT64
));
971 // Free memory pool at last
973 if (Xhc
->MemPool
!= NULL
) {
974 UsbHcFreeMemPool (Xhc
->MemPool
);
980 Check if the Trb is a transaction of the URBs in XHCI's asynchronous transfer list.
982 @param Xhc The XHCI Instance.
983 @param Trb The TRB to be checked.
984 @param Urb The pointer to the matched Urb.
986 @retval TRUE The Trb is matched with a transaction of the URBs in the async list.
987 @retval FALSE The Trb is not matched with any URBs in the async list.
992 IN USB_XHCI_INSTANCE
*Xhc
,
993 IN TRB_TEMPLATE
*Trb
,
999 TRB_TEMPLATE
*CheckedTrb
;
1003 EFI_LIST_FOR_EACH_SAFE (Entry
, Next
, &Xhc
->AsyncIntTransfers
) {
1004 CheckedUrb
= EFI_LIST_CONTAINER (Entry
, URB
, UrbList
);
1005 CheckedTrb
= CheckedUrb
->TrbStart
;
1006 for (Index
= 0; Index
< CheckedUrb
->TrbNum
; Index
++) {
1007 if (Trb
== CheckedTrb
) {
1013 // If the checked TRB is the link TRB at the end of the transfer ring,
1014 // recircle it to the head of the ring.
1016 if (CheckedTrb
->Type
== TRB_TYPE_LINK
) {
1017 CheckedTrb
= (TRB_TEMPLATE
*) CheckedUrb
->Ring
->RingSeg0
;
1026 Check if the Trb is a transaction of the URB.
1028 @param Trb The TRB to be checked
1029 @param Urb The transfer ring to be checked.
1031 @retval TRUE It is a transaction of the URB.
1032 @retval FALSE It is not any transaction of the URB.
1037 IN TRB_TEMPLATE
*Trb
,
1041 TRB_TEMPLATE
*CheckedTrb
;
1044 CheckedTrb
= Urb
->Ring
->RingSeg0
;
1046 ASSERT (Urb
->Ring
->TrbNumber
== CMD_RING_TRB_NUMBER
|| Urb
->Ring
->TrbNumber
== TR_RING_TRB_NUMBER
);
1048 for (Index
= 0; Index
< Urb
->Ring
->TrbNumber
; Index
++) {
1049 if (Trb
== CheckedTrb
) {
1059 Check the URB's execution result and update the URB's
1062 @param Xhc The XHCI Instance.
1063 @param Urb The URB to check result.
1065 @return Whether the result of URB transfer is finialized.
1070 IN USB_XHCI_INSTANCE
*Xhc
,
1074 EVT_TRB_TRANSFER
*EvtTrb
;
1075 TRB_TEMPLATE
*TRBPtr
;
1084 EFI_PHYSICAL_ADDRESS PhyAddr
;
1086 ASSERT ((Xhc
!= NULL
) && (Urb
!= NULL
));
1088 Status
= EFI_SUCCESS
;
1091 if (Urb
->Finished
) {
1097 if (XhcIsHalt (Xhc
) || XhcIsSysError (Xhc
)) {
1098 Urb
->Result
|= EFI_USB_ERR_SYSTEM
;
1103 // Traverse the event ring to find out all new events from the previous check.
1105 XhcSyncEventRing (Xhc
, &Xhc
->EventRing
);
1106 for (Index
= 0; Index
< Xhc
->EventRing
.TrbNumber
; Index
++) {
1107 Status
= XhcCheckNewEvent (Xhc
, &Xhc
->EventRing
, ((TRB_TEMPLATE
**)&EvtTrb
));
1108 if (Status
== EFI_NOT_READY
) {
1110 // All new events are handled, return directly.
1116 // Only handle COMMAND_COMPLETETION_EVENT and TRANSFER_EVENT.
1118 if ((EvtTrb
->Type
!= TRB_TYPE_COMMAND_COMPLT_EVENT
) && (EvtTrb
->Type
!= TRB_TYPE_TRANS_EVENT
)) {
1123 // Need convert pci device address to host address
1125 PhyAddr
= (EFI_PHYSICAL_ADDRESS
)(EvtTrb
->TRBPtrLo
| LShiftU64 ((UINT64
) EvtTrb
->TRBPtrHi
, 32));
1126 TRBPtr
= (TRB_TEMPLATE
*)(UINTN
) UsbHcGetHostAddrForPciAddr (Xhc
->MemPool
, (VOID
*)(UINTN
) PhyAddr
, sizeof (TRB_TEMPLATE
));
1129 // Update the status of Urb according to the finished event regardless of whether
1130 // the urb is current checked one or in the XHCI's async transfer list.
1131 // This way is used to avoid that those completed async transfer events don't get
1132 // handled in time and are flushed by newer coming events.
1134 if (IsTransferRingTrb (TRBPtr
, Urb
)) {
1136 } else if (IsAsyncIntTrb (Xhc
, TRBPtr
, &AsyncUrb
)) {
1137 CheckedUrb
= AsyncUrb
;
1142 switch (EvtTrb
->Completecode
) {
1143 case TRB_COMPLETION_STALL_ERROR
:
1144 CheckedUrb
->Result
|= EFI_USB_ERR_STALL
;
1145 CheckedUrb
->Finished
= TRUE
;
1146 DEBUG ((EFI_D_ERROR
, "XhcCheckUrbResult: STALL_ERROR! Completecode = %x\n",EvtTrb
->Completecode
));
1149 case TRB_COMPLETION_BABBLE_ERROR
:
1150 CheckedUrb
->Result
|= EFI_USB_ERR_BABBLE
;
1151 CheckedUrb
->Finished
= TRUE
;
1152 DEBUG ((EFI_D_ERROR
, "XhcCheckUrbResult: BABBLE_ERROR! Completecode = %x\n",EvtTrb
->Completecode
));
1155 case TRB_COMPLETION_DATA_BUFFER_ERROR
:
1156 CheckedUrb
->Result
|= EFI_USB_ERR_BUFFER
;
1157 CheckedUrb
->Finished
= TRUE
;
1158 DEBUG ((EFI_D_ERROR
, "XhcCheckUrbResult: ERR_BUFFER! Completecode = %x\n",EvtTrb
->Completecode
));
1161 case TRB_COMPLETION_USB_TRANSACTION_ERROR
:
1162 CheckedUrb
->Result
|= EFI_USB_ERR_TIMEOUT
;
1163 CheckedUrb
->Finished
= TRUE
;
1164 DEBUG ((EFI_D_ERROR
, "XhcCheckUrbResult: TRANSACTION_ERROR! Completecode = %x\n",EvtTrb
->Completecode
));
1167 case TRB_COMPLETION_SHORT_PACKET
:
1168 case TRB_COMPLETION_SUCCESS
:
1169 if (EvtTrb
->Completecode
== TRB_COMPLETION_SHORT_PACKET
) {
1170 DEBUG ((EFI_D_ERROR
, "XhcCheckUrbResult: short packet happens!\n"));
1173 TRBType
= (UINT8
) (TRBPtr
->Type
);
1174 if ((TRBType
== TRB_TYPE_DATA_STAGE
) ||
1175 (TRBType
== TRB_TYPE_NORMAL
) ||
1176 (TRBType
== TRB_TYPE_ISOCH
)) {
1177 CheckedUrb
->Completed
+= (((TRANSFER_TRB_NORMAL
*)TRBPtr
)->Length
- EvtTrb
->Length
);
1183 DEBUG ((EFI_D_ERROR
, "Transfer Default Error Occur! Completecode = 0x%x!\n",EvtTrb
->Completecode
));
1184 CheckedUrb
->Result
|= EFI_USB_ERR_TIMEOUT
;
1185 CheckedUrb
->Finished
= TRUE
;
1190 // Only check first and end Trb event address
1192 if (TRBPtr
== CheckedUrb
->TrbStart
) {
1193 CheckedUrb
->StartDone
= TRUE
;
1196 if (TRBPtr
== CheckedUrb
->TrbEnd
) {
1197 CheckedUrb
->EndDone
= TRUE
;
1200 if (CheckedUrb
->StartDone
&& CheckedUrb
->EndDone
) {
1201 CheckedUrb
->Finished
= TRUE
;
1202 CheckedUrb
->EvtTrb
= (TRB_TEMPLATE
*)EvtTrb
;
1209 // Advance event ring to last available entry
1211 // Some 3rd party XHCI external cards don't support single 64-bytes width register access,
1212 // So divide it to two 32-bytes width register access.
1214 Low
= XhcReadRuntimeReg (Xhc
, XHC_ERDP_OFFSET
);
1215 High
= XhcReadRuntimeReg (Xhc
, XHC_ERDP_OFFSET
+ 4);
1216 XhcDequeue
= (UINT64
)(LShiftU64((UINT64
)High
, 32) | Low
);
1218 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, Xhc
->EventRing
.EventRingDequeue
, sizeof (TRB_TEMPLATE
));
1220 if ((XhcDequeue
& (~0x0F)) != (PhyAddr
& (~0x0F))) {
1222 // Some 3rd party XHCI external cards don't support single 64-bytes width register access,
1223 // So divide it to two 32-bytes width register access.
1225 XhcWriteRuntimeReg (Xhc
, XHC_ERDP_OFFSET
, XHC_LOW_32BIT (PhyAddr
) | BIT3
);
1226 XhcWriteRuntimeReg (Xhc
, XHC_ERDP_OFFSET
+ 4, XHC_HIGH_32BIT (PhyAddr
));
1229 return Urb
->Finished
;
1234 Execute the transfer by polling the URB. This is a synchronous operation.
1236 @param Xhc The XHCI Instance.
1237 @param CmdTransfer The executed URB is for cmd transfer or not.
1238 @param Urb The URB to execute.
1239 @param Timeout The time to wait before abort, in millisecond.
1241 @return EFI_DEVICE_ERROR The transfer failed due to transfer error.
1242 @return EFI_TIMEOUT The transfer failed due to time out.
1243 @return EFI_SUCCESS The transfer finished OK.
1248 IN USB_XHCI_INSTANCE
*Xhc
,
1249 IN BOOLEAN CmdTransfer
,
1265 SlotId
= XhcBusDevAddrToSlotId (Xhc
, Urb
->Ep
.BusAddr
);
1267 return EFI_DEVICE_ERROR
;
1269 Dci
= XhcEndpointToDci (Urb
->Ep
.EpAddr
, (UINT8
)(Urb
->Ep
.Direction
));
1273 Status
= EFI_SUCCESS
;
1274 Loop
= Timeout
* XHC_1_MILLISECOND
;
1279 XhcRingDoorBell (Xhc
, SlotId
, Dci
);
1281 for (Index
= 0; Index
< Loop
; Index
++) {
1282 Finished
= XhcCheckUrbResult (Xhc
, Urb
);
1286 gBS
->Stall (XHC_1_MICROSECOND
);
1289 if (Index
== Loop
) {
1290 Urb
->Result
= EFI_USB_ERR_TIMEOUT
;
1291 Status
= EFI_TIMEOUT
;
1292 } else if (Urb
->Result
!= EFI_USB_NOERROR
) {
1293 Status
= EFI_DEVICE_ERROR
;
1300 Delete a single asynchronous interrupt transfer for
1301 the device and endpoint.
1303 @param Xhc The XHCI Instance.
1304 @param BusAddr The logical device address assigned by UsbBus driver.
1305 @param EpNum The endpoint of the target.
1307 @retval EFI_SUCCESS An asynchronous transfer is removed.
1308 @retval EFI_NOT_FOUND No transfer for the device is found.
1312 XhciDelAsyncIntTransfer (
1313 IN USB_XHCI_INSTANCE
*Xhc
,
1321 EFI_USB_DATA_DIRECTION Direction
;
1323 Direction
= ((EpNum
& 0x80) != 0) ? EfiUsbDataIn
: EfiUsbDataOut
;
1328 EFI_LIST_FOR_EACH_SAFE (Entry
, Next
, &Xhc
->AsyncIntTransfers
) {
1329 Urb
= EFI_LIST_CONTAINER (Entry
, URB
, UrbList
);
1330 if ((Urb
->Ep
.BusAddr
== BusAddr
) &&
1331 (Urb
->Ep
.EpAddr
== EpNum
) &&
1332 (Urb
->Ep
.Direction
== Direction
)) {
1333 RemoveEntryList (&Urb
->UrbList
);
1334 FreePool (Urb
->Data
);
1335 XhcFreeUrb (Xhc
, Urb
);
1340 return EFI_NOT_FOUND
;
1344 Remove all the asynchronous interrutp transfers.
1346 @param Xhc The XHCI Instance.
1350 XhciDelAllAsyncIntTransfers (
1351 IN USB_XHCI_INSTANCE
*Xhc
1358 EFI_LIST_FOR_EACH_SAFE (Entry
, Next
, &Xhc
->AsyncIntTransfers
) {
1359 Urb
= EFI_LIST_CONTAINER (Entry
, URB
, UrbList
);
1360 RemoveEntryList (&Urb
->UrbList
);
1361 FreePool (Urb
->Data
);
1362 XhcFreeUrb (Xhc
, Urb
);
1367 Update the queue head for next round of asynchronous transfer
1369 @param Xhc The XHCI Instance.
1370 @param Urb The URB to update
1374 XhcUpdateAsyncRequest (
1375 IN USB_XHCI_INSTANCE
*Xhc
,
1381 if (Urb
->Result
== EFI_USB_NOERROR
) {
1382 Status
= XhcCreateTransferTrb (Xhc
, Urb
);
1383 if (EFI_ERROR (Status
)) {
1386 Status
= RingIntTransferDoorBell (Xhc
, Urb
);
1387 if (EFI_ERROR (Status
)) {
1394 Flush data from PCI controller specific address to mapped system
1397 @param Xhc The XHCI device.
1398 @param Urb The URB to unmap.
1400 @retval EFI_SUCCESS Success to flush data to mapped system memory.
1401 @retval EFI_DEVICE_ERROR Fail to flush data to mapped system memory.
1405 XhcFlushAsyncIntMap (
1406 IN USB_XHCI_INSTANCE
*Xhc
,
1411 EFI_PHYSICAL_ADDRESS PhyAddr
;
1412 EFI_PCI_IO_PROTOCOL_OPERATION MapOp
;
1413 EFI_PCI_IO_PROTOCOL
*PciIo
;
1420 if (Urb
->Ep
.Direction
== EfiUsbDataIn
) {
1421 MapOp
= EfiPciIoOperationBusMasterWrite
;
1423 MapOp
= EfiPciIoOperationBusMasterRead
;
1426 if (Urb
->DataMap
!= NULL
) {
1427 Status
= PciIo
->Unmap (PciIo
, Urb
->DataMap
);
1428 if (EFI_ERROR (Status
)) {
1433 Urb
->DataMap
= NULL
;
1435 Status
= PciIo
->Map (PciIo
, MapOp
, Urb
->Data
, &Len
, &PhyAddr
, &Map
);
1436 if (EFI_ERROR (Status
) || (Len
!= Urb
->DataLen
)) {
1440 Urb
->DataPhy
= (VOID
*) ((UINTN
) PhyAddr
);
1445 return EFI_DEVICE_ERROR
;
1449 Interrupt transfer periodic check handler.
1451 @param Event Interrupt event.
1452 @param Context Pointer to USB_XHCI_INSTANCE.
1457 XhcMonitorAsyncRequests (
1462 USB_XHCI_INSTANCE
*Xhc
;
1471 OldTpl
= gBS
->RaiseTPL (XHC_TPL
);
1473 Xhc
= (USB_XHCI_INSTANCE
*) Context
;
1475 EFI_LIST_FOR_EACH_SAFE (Entry
, Next
, &Xhc
->AsyncIntTransfers
) {
1476 Urb
= EFI_LIST_CONTAINER (Entry
, URB
, UrbList
);
1479 // Make sure that the device is available before every check.
1481 SlotId
= XhcBusDevAddrToSlotId (Xhc
, Urb
->Ep
.BusAddr
);
1487 // Check the result of URB execution. If it is still
1488 // active, check the next one.
1490 XhcCheckUrbResult (Xhc
, Urb
);
1492 if (!Urb
->Finished
) {
1497 // Flush any PCI posted write transactions from a PCI host
1498 // bridge to system memory.
1500 Status
= XhcFlushAsyncIntMap (Xhc
, Urb
);
1501 if (EFI_ERROR (Status
)) {
1502 DEBUG ((EFI_D_ERROR
, "XhcMonitorAsyncRequests: Fail to Flush AsyncInt Mapped Memeory\n"));
1506 // Allocate a buffer then copy the transferred data for user.
1507 // If failed to allocate the buffer, update the URB for next
1508 // round of transfer. Ignore the data of this round.
1511 if (Urb
->Result
== EFI_USB_NOERROR
) {
1512 ASSERT (Urb
->Completed
<= Urb
->DataLen
);
1514 ProcBuf
= AllocateZeroPool (Urb
->Completed
);
1516 if (ProcBuf
== NULL
) {
1517 XhcUpdateAsyncRequest (Xhc
, Urb
);
1521 CopyMem (ProcBuf
, Urb
->Data
, Urb
->Completed
);
1525 // Leave error recovery to its related device driver. A
1526 // common case of the error recovery is to re-submit the
1527 // interrupt transfer which is linked to the head of the
1528 // list. This function scans from head to tail. So the
1529 // re-submitted interrupt transfer's callback function
1530 // will not be called again in this round. Don't touch this
1531 // URB after the callback, it may have been removed by the
1534 if (Urb
->Callback
!= NULL
) {
1536 // Restore the old TPL, USB bus maybe connect device in
1537 // his callback. Some drivers may has a lower TPL restriction.
1539 gBS
->RestoreTPL (OldTpl
);
1540 (Urb
->Callback
) (ProcBuf
, Urb
->Completed
, Urb
->Context
, Urb
->Result
);
1541 OldTpl
= gBS
->RaiseTPL (XHC_TPL
);
1544 if (ProcBuf
!= NULL
) {
1545 gBS
->FreePool (ProcBuf
);
1548 XhcUpdateAsyncRequest (Xhc
, Urb
);
1550 gBS
->RestoreTPL (OldTpl
);
1554 Monitor the port status change. Enable/Disable device slot if there is a device attached/detached.
1556 @param Xhc The XHCI Instance.
1557 @param ParentRouteChart The route string pointed to the parent device if it exists.
1558 @param Port The port to be polled.
1559 @param PortState The port state.
1561 @retval EFI_SUCCESS Successfully enable/disable device slot according to port state.
1562 @retval Others Should not appear.
1567 XhcPollPortStatusChange (
1568 IN USB_XHCI_INSTANCE
*Xhc
,
1569 IN USB_DEV_ROUTE ParentRouteChart
,
1571 IN EFI_USB_PORT_STATUS
*PortState
1577 USB_DEV_ROUTE RouteChart
;
1579 Status
= EFI_SUCCESS
;
1581 if ((PortState
->PortChangeStatus
& (USB_PORT_STAT_C_CONNECTION
| USB_PORT_STAT_C_ENABLE
| USB_PORT_STAT_C_OVERCURRENT
| USB_PORT_STAT_C_RESET
)) == 0) {
1585 if (ParentRouteChart
.Dword
== 0) {
1586 RouteChart
.Route
.RouteString
= 0;
1587 RouteChart
.Route
.RootPortNum
= Port
+ 1;
1588 RouteChart
.Route
.TierNum
= 1;
1591 RouteChart
.Route
.RouteString
= ParentRouteChart
.Route
.RouteString
| (Port
<< (4 * (ParentRouteChart
.Route
.TierNum
- 1)));
1593 RouteChart
.Route
.RouteString
= ParentRouteChart
.Route
.RouteString
| (15 << (4 * (ParentRouteChart
.Route
.TierNum
- 1)));
1595 RouteChart
.Route
.RootPortNum
= ParentRouteChart
.Route
.RootPortNum
;
1596 RouteChart
.Route
.TierNum
= ParentRouteChart
.Route
.TierNum
+ 1;
1599 SlotId
= XhcRouteStringToSlotId (Xhc
, RouteChart
);
1601 if (Xhc
->HcCParams
.Data
.Csz
== 0) {
1602 Status
= XhcDisableSlotCmd (Xhc
, SlotId
);
1604 Status
= XhcDisableSlotCmd64 (Xhc
, SlotId
);
1608 if (((PortState
->PortStatus
& USB_PORT_STAT_ENABLE
) != 0) &&
1609 ((PortState
->PortStatus
& USB_PORT_STAT_CONNECTION
) != 0)) {
1611 // Has a device attached, Identify device speed after port is enabled.
1613 Speed
= EFI_USB_SPEED_FULL
;
1614 if ((PortState
->PortStatus
& USB_PORT_STAT_LOW_SPEED
) != 0) {
1615 Speed
= EFI_USB_SPEED_LOW
;
1616 } else if ((PortState
->PortStatus
& USB_PORT_STAT_HIGH_SPEED
) != 0) {
1617 Speed
= EFI_USB_SPEED_HIGH
;
1618 } else if ((PortState
->PortStatus
& USB_PORT_STAT_SUPER_SPEED
) != 0) {
1619 Speed
= EFI_USB_SPEED_SUPER
;
1622 // Execute Enable_Slot cmd for attached device, initialize device context and assign device address.
1624 SlotId
= XhcRouteStringToSlotId (Xhc
, RouteChart
);
1625 if ((SlotId
== 0) && ((PortState
->PortChangeStatus
& USB_PORT_STAT_C_RESET
) != 0)) {
1626 if (Xhc
->HcCParams
.Data
.Csz
== 0) {
1627 Status
= XhcInitializeDeviceSlot (Xhc
, ParentRouteChart
, Port
, RouteChart
, Speed
);
1629 Status
= XhcInitializeDeviceSlot64 (Xhc
, ParentRouteChart
, Port
, RouteChart
, Speed
);
1639 Calculate the device context index by endpoint address and direction.
1641 @param EpAddr The target endpoint number.
1642 @param Direction The direction of the target endpoint.
1644 @return The device context index of endpoint.
1658 Index
= (UINT8
) (2 * EpAddr
);
1659 if (Direction
== EfiUsbDataIn
) {
1667 Find out the actual device address according to the requested device address from UsbBus.
1669 @param Xhc The XHCI Instance.
1670 @param BusDevAddr The requested device address by UsbBus upper driver.
1672 @return The actual device address assigned to the device.
1677 XhcBusDevAddrToSlotId (
1678 IN USB_XHCI_INSTANCE
*Xhc
,
1684 for (Index
= 0; Index
< 255; Index
++) {
1685 if (Xhc
->UsbDevContext
[Index
+ 1].Enabled
&&
1686 (Xhc
->UsbDevContext
[Index
+ 1].SlotId
!= 0) &&
1687 (Xhc
->UsbDevContext
[Index
+ 1].BusDevAddr
== BusDevAddr
)) {
1696 return Xhc
->UsbDevContext
[Index
+ 1].SlotId
;
1700 Find out the slot id according to the device's route string.
1702 @param Xhc The XHCI Instance.
1703 @param RouteString The route string described the device location.
1705 @return The slot id used by the device.
1710 XhcRouteStringToSlotId (
1711 IN USB_XHCI_INSTANCE
*Xhc
,
1712 IN USB_DEV_ROUTE RouteString
1717 for (Index
= 0; Index
< 255; Index
++) {
1718 if (Xhc
->UsbDevContext
[Index
+ 1].Enabled
&&
1719 (Xhc
->UsbDevContext
[Index
+ 1].SlotId
!= 0) &&
1720 (Xhc
->UsbDevContext
[Index
+ 1].RouteString
.Dword
== RouteString
.Dword
)) {
1729 return Xhc
->UsbDevContext
[Index
+ 1].SlotId
;
1733 Synchronize the specified event ring to update the enqueue and dequeue pointer.
1735 @param Xhc The XHCI Instance.
1736 @param EvtRing The event ring to sync.
1738 @retval EFI_SUCCESS The event ring is synchronized successfully.
1744 IN USB_XHCI_INSTANCE
*Xhc
,
1745 IN EVENT_RING
*EvtRing
1749 TRB_TEMPLATE
*EvtTrb1
;
1751 ASSERT (EvtRing
!= NULL
);
1754 // Calculate the EventRingEnqueue and EventRingCCS.
1755 // Note: only support single Segment
1757 EvtTrb1
= EvtRing
->EventRingDequeue
;
1759 for (Index
= 0; Index
< EvtRing
->TrbNumber
; Index
++) {
1760 if (EvtTrb1
->CycleBit
!= EvtRing
->EventRingCCS
) {
1766 if ((UINTN
)EvtTrb1
>= ((UINTN
) EvtRing
->EventRingSeg0
+ sizeof (TRB_TEMPLATE
) * EvtRing
->TrbNumber
)) {
1767 EvtTrb1
= EvtRing
->EventRingSeg0
;
1768 EvtRing
->EventRingCCS
= (EvtRing
->EventRingCCS
) ? 0 : 1;
1772 if (Index
< EvtRing
->TrbNumber
) {
1773 EvtRing
->EventRingEnqueue
= EvtTrb1
;
1782 Synchronize the specified transfer ring to update the enqueue and dequeue pointer.
1784 @param Xhc The XHCI Instance.
1785 @param TrsRing The transfer ring to sync.
1787 @retval EFI_SUCCESS The transfer ring is synchronized successfully.
1793 IN USB_XHCI_INSTANCE
*Xhc
,
1794 IN TRANSFER_RING
*TrsRing
1798 TRB_TEMPLATE
*TrsTrb
;
1800 ASSERT (TrsRing
!= NULL
);
1802 // Calculate the latest RingEnqueue and RingPCS
1804 TrsTrb
= TrsRing
->RingEnqueue
;
1805 ASSERT (TrsTrb
!= NULL
);
1807 for (Index
= 0; Index
< TrsRing
->TrbNumber
; Index
++) {
1808 if (TrsTrb
->CycleBit
!= (TrsRing
->RingPCS
& BIT0
)) {
1812 if ((UINT8
) TrsTrb
->Type
== TRB_TYPE_LINK
) {
1813 ASSERT (((LINK_TRB
*)TrsTrb
)->TC
!= 0);
1815 // set cycle bit in Link TRB as normal
1817 ((LINK_TRB
*)TrsTrb
)->CycleBit
= TrsRing
->RingPCS
& BIT0
;
1819 // Toggle PCS maintained by software
1821 TrsRing
->RingPCS
= (TrsRing
->RingPCS
& BIT0
) ? 0 : 1;
1822 TrsTrb
= (TRB_TEMPLATE
*) TrsRing
->RingSeg0
; // Use host address
1826 ASSERT (Index
!= TrsRing
->TrbNumber
);
1828 if (TrsTrb
!= TrsRing
->RingEnqueue
) {
1829 TrsRing
->RingEnqueue
= TrsTrb
;
1833 // Clear the Trb context for enqueue, but reserve the PCS bit
1835 TrsTrb
->Parameter1
= 0;
1836 TrsTrb
->Parameter2
= 0;
1840 TrsTrb
->Control
= 0;
1846 Check if there is a new generated event.
1848 @param Xhc The XHCI Instance.
1849 @param EvtRing The event ring to check.
1850 @param NewEvtTrb The new event TRB found.
1852 @retval EFI_SUCCESS Found a new event TRB at the event ring.
1853 @retval EFI_NOT_READY The event ring has no new event.
1859 IN USB_XHCI_INSTANCE
*Xhc
,
1860 IN EVENT_RING
*EvtRing
,
1861 OUT TRB_TEMPLATE
**NewEvtTrb
1864 ASSERT (EvtRing
!= NULL
);
1866 *NewEvtTrb
= EvtRing
->EventRingDequeue
;
1868 if (EvtRing
->EventRingDequeue
== EvtRing
->EventRingEnqueue
) {
1869 return EFI_NOT_READY
;
1872 EvtRing
->EventRingDequeue
++;
1874 // If the dequeue pointer is beyond the ring, then roll-back it to the begining of the ring.
1876 if ((UINTN
)EvtRing
->EventRingDequeue
>= ((UINTN
) EvtRing
->EventRingSeg0
+ sizeof (TRB_TEMPLATE
) * EvtRing
->TrbNumber
)) {
1877 EvtRing
->EventRingDequeue
= EvtRing
->EventRingSeg0
;
1884 Ring the door bell to notify XHCI there is a transaction to be executed.
1886 @param Xhc The XHCI Instance.
1887 @param SlotId The slot id of the target device.
1888 @param Dci The device context index of the target slot or endpoint.
1890 @retval EFI_SUCCESS Successfully ring the door bell.
1896 IN USB_XHCI_INSTANCE
*Xhc
,
1902 XhcWriteDoorBellReg (Xhc
, 0, 0);
1904 XhcWriteDoorBellReg (Xhc
, SlotId
* sizeof (UINT32
), Dci
);
1911 Ring the door bell to notify XHCI there is a transaction to be executed through URB.
1913 @param Xhc The XHCI Instance.
1914 @param Urb The URB to be rung.
1916 @retval EFI_SUCCESS Successfully ring the door bell.
1920 RingIntTransferDoorBell (
1921 IN USB_XHCI_INSTANCE
*Xhc
,
1928 SlotId
= XhcBusDevAddrToSlotId (Xhc
, Urb
->Ep
.BusAddr
);
1929 Dci
= XhcEndpointToDci (Urb
->Ep
.EpAddr
, (UINT8
)(Urb
->Ep
.Direction
));
1930 XhcRingDoorBell (Xhc
, SlotId
, Dci
);
1935 Assign and initialize the device slot for a new device.
1937 @param Xhc The XHCI Instance.
1938 @param ParentRouteChart The route string pointed to the parent device.
1939 @param ParentPort The port at which the device is located.
1940 @param RouteChart The route string pointed to the device.
1941 @param DeviceSpeed The device speed.
1943 @retval EFI_SUCCESS Successfully assign a slot to the device and assign an address to it.
1948 XhcInitializeDeviceSlot (
1949 IN USB_XHCI_INSTANCE
*Xhc
,
1950 IN USB_DEV_ROUTE ParentRouteChart
,
1951 IN UINT16 ParentPort
,
1952 IN USB_DEV_ROUTE RouteChart
,
1953 IN UINT8 DeviceSpeed
1957 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
1958 INPUT_CONTEXT
*InputContext
;
1959 DEVICE_CONTEXT
*OutputContext
;
1960 TRANSFER_RING
*EndpointTransferRing
;
1961 CMD_TRB_ADDRESS_DEVICE CmdTrbAddr
;
1962 UINT8 DeviceAddress
;
1963 CMD_TRB_ENABLE_SLOT CmdTrb
;
1966 DEVICE_CONTEXT
*ParentDeviceContext
;
1967 EFI_PHYSICAL_ADDRESS PhyAddr
;
1969 ZeroMem (&CmdTrb
, sizeof (CMD_TRB_ENABLE_SLOT
));
1970 CmdTrb
.CycleBit
= 1;
1971 CmdTrb
.Type
= TRB_TYPE_EN_SLOT
;
1973 Status
= XhcCmdTransfer (
1975 (TRB_TEMPLATE
*) (UINTN
) &CmdTrb
,
1976 XHC_GENERIC_TIMEOUT
,
1977 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
1979 if (EFI_ERROR (Status
)) {
1980 DEBUG ((EFI_D_ERROR
, "XhcInitializeDeviceSlot: Enable Slot Failed, Status = %r\n", Status
));
1983 ASSERT (EvtTrb
->SlotId
<= Xhc
->MaxSlotsEn
);
1984 DEBUG ((EFI_D_INFO
, "Enable Slot Successfully, The Slot ID = 0x%x\n", EvtTrb
->SlotId
));
1985 SlotId
= (UINT8
)EvtTrb
->SlotId
;
1986 ASSERT (SlotId
!= 0);
1988 ZeroMem (&Xhc
->UsbDevContext
[SlotId
], sizeof (USB_DEV_CONTEXT
));
1989 Xhc
->UsbDevContext
[SlotId
].Enabled
= TRUE
;
1990 Xhc
->UsbDevContext
[SlotId
].SlotId
= SlotId
;
1991 Xhc
->UsbDevContext
[SlotId
].RouteString
.Dword
= RouteChart
.Dword
;
1992 Xhc
->UsbDevContext
[SlotId
].ParentRouteString
.Dword
= ParentRouteChart
.Dword
;
1995 // 4.3.3 Device Slot Initialization
1996 // 1) Allocate an Input Context data structure (6.2.5) and initialize all fields to '0'.
1998 InputContext
= UsbHcAllocateMem (Xhc
->MemPool
, sizeof (INPUT_CONTEXT
));
1999 ASSERT (InputContext
!= NULL
);
2000 ASSERT (((UINTN
) InputContext
& 0x3F) == 0);
2001 ZeroMem (InputContext
, sizeof (INPUT_CONTEXT
));
2003 Xhc
->UsbDevContext
[SlotId
].InputContext
= (VOID
*) InputContext
;
2006 // 2) Initialize the Input Control Context (6.2.5.1) of the Input Context by setting the A0 and A1
2007 // flags to '1'. These flags indicate that the Slot Context and the Endpoint 0 Context of the Input
2008 // Context are affected by the command.
2010 InputContext
->InputControlContext
.Dword2
|= (BIT0
| BIT1
);
2013 // 3) Initialize the Input Slot Context data structure
2015 InputContext
->Slot
.RouteString
= RouteChart
.Route
.RouteString
;
2016 InputContext
->Slot
.Speed
= DeviceSpeed
+ 1;
2017 InputContext
->Slot
.ContextEntries
= 1;
2018 InputContext
->Slot
.RootHubPortNum
= RouteChart
.Route
.RootPortNum
;
2020 if (RouteChart
.Route
.RouteString
) {
2022 // The device is behind of hub device.
2024 ParentSlotId
= XhcRouteStringToSlotId(Xhc
, ParentRouteChart
);
2025 ASSERT (ParentSlotId
!= 0);
2027 //if the Full/Low device attached to a High Speed Hub, Init the TTPortNum and TTHubSlotId field of slot context
2029 ParentDeviceContext
= (DEVICE_CONTEXT
*)Xhc
->UsbDevContext
[ParentSlotId
].OutputContext
;
2030 if ((ParentDeviceContext
->Slot
.TTPortNum
== 0) &&
2031 (ParentDeviceContext
->Slot
.TTHubSlotId
== 0)) {
2032 if ((ParentDeviceContext
->Slot
.Speed
== (EFI_USB_SPEED_HIGH
+ 1)) && (DeviceSpeed
< EFI_USB_SPEED_HIGH
)) {
2034 // Full/Low device attached to High speed hub port that isolates the high speed signaling
2035 // environment from Full/Low speed signaling environment for a device
2037 InputContext
->Slot
.TTPortNum
= ParentPort
;
2038 InputContext
->Slot
.TTHubSlotId
= ParentSlotId
;
2042 // Inherit the TT parameters from parent device.
2044 InputContext
->Slot
.TTPortNum
= ParentDeviceContext
->Slot
.TTPortNum
;
2045 InputContext
->Slot
.TTHubSlotId
= ParentDeviceContext
->Slot
.TTHubSlotId
;
2047 // If the device is a High speed device then down the speed to be the same as its parent Hub
2049 if (DeviceSpeed
== EFI_USB_SPEED_HIGH
) {
2050 InputContext
->Slot
.Speed
= ParentDeviceContext
->Slot
.Speed
;
2056 // 4) Allocate and initialize the Transfer Ring for the Default Control Endpoint.
2058 EndpointTransferRing
= AllocateZeroPool (sizeof (TRANSFER_RING
));
2059 Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[0] = EndpointTransferRing
;
2060 CreateTransferRing(Xhc
, TR_RING_TRB_NUMBER
, (TRANSFER_RING
*)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[0]);
2062 // 5) Initialize the Input default control Endpoint 0 Context (6.2.3).
2064 InputContext
->EP
[0].EPType
= ED_CONTROL_BIDIR
;
2066 if (DeviceSpeed
== EFI_USB_SPEED_SUPER
) {
2067 InputContext
->EP
[0].MaxPacketSize
= 512;
2068 } else if (DeviceSpeed
== EFI_USB_SPEED_HIGH
) {
2069 InputContext
->EP
[0].MaxPacketSize
= 64;
2071 InputContext
->EP
[0].MaxPacketSize
= 8;
2074 // Initial value of Average TRB Length for Control endpoints would be 8B, Interrupt endpoints
2075 // 1KB, and Bulk and Isoch endpoints 3KB.
2077 InputContext
->EP
[0].AverageTRBLength
= 8;
2078 InputContext
->EP
[0].MaxBurstSize
= 0;
2079 InputContext
->EP
[0].Interval
= 0;
2080 InputContext
->EP
[0].MaxPStreams
= 0;
2081 InputContext
->EP
[0].Mult
= 0;
2082 InputContext
->EP
[0].CErr
= 3;
2085 // Init the DCS(dequeue cycle state) as the transfer ring's CCS
2087 PhyAddr
= UsbHcGetPciAddrForHostAddr (
2089 ((TRANSFER_RING
*)(UINTN
)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[0])->RingSeg0
,
2090 sizeof (TRB_TEMPLATE
) * TR_RING_TRB_NUMBER
2092 InputContext
->EP
[0].PtrLo
= XHC_LOW_32BIT (PhyAddr
) | BIT0
;
2093 InputContext
->EP
[0].PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
2096 // 6) Allocate the Output Device Context data structure (6.2.1) and initialize it to '0'.
2098 OutputContext
= UsbHcAllocateMem (Xhc
->MemPool
, sizeof (DEVICE_CONTEXT
));
2099 ASSERT (OutputContext
!= NULL
);
2100 ASSERT (((UINTN
) OutputContext
& 0x3F) == 0);
2101 ZeroMem (OutputContext
, sizeof (DEVICE_CONTEXT
));
2103 Xhc
->UsbDevContext
[SlotId
].OutputContext
= OutputContext
;
2105 // 7) Load the appropriate (Device Slot ID) entry in the Device Context Base Address Array (5.4.6) with
2106 // a pointer to the Output Device Context data structure (6.2.1).
2108 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, OutputContext
, sizeof (DEVICE_CONTEXT
));
2110 // Fill DCBAA with PCI device address
2112 Xhc
->DCBAA
[SlotId
] = (UINT64
) (UINTN
) PhyAddr
;
2115 // 8) Issue an Address Device Command for the Device Slot, where the command points to the Input
2116 // Context data structure described above.
2118 ZeroMem (&CmdTrbAddr
, sizeof (CmdTrbAddr
));
2119 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, Xhc
->UsbDevContext
[SlotId
].InputContext
, sizeof (INPUT_CONTEXT
));
2120 CmdTrbAddr
.PtrLo
= XHC_LOW_32BIT (PhyAddr
);
2121 CmdTrbAddr
.PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
2122 CmdTrbAddr
.CycleBit
= 1;
2123 CmdTrbAddr
.Type
= TRB_TYPE_ADDRESS_DEV
;
2124 CmdTrbAddr
.SlotId
= Xhc
->UsbDevContext
[SlotId
].SlotId
;
2125 Status
= XhcCmdTransfer (
2127 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbAddr
,
2128 XHC_GENERIC_TIMEOUT
,
2129 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
2131 if (!EFI_ERROR (Status
)) {
2132 DeviceAddress
= (UINT8
) ((DEVICE_CONTEXT
*) OutputContext
)->Slot
.DeviceAddress
;
2133 DEBUG ((EFI_D_INFO
, " Address %d assigned successfully\n", DeviceAddress
));
2134 Xhc
->UsbDevContext
[SlotId
].XhciDevAddr
= DeviceAddress
;
2141 Assign and initialize the device slot for a new device.
2143 @param Xhc The XHCI Instance.
2144 @param ParentRouteChart The route string pointed to the parent device.
2145 @param ParentPort The port at which the device is located.
2146 @param RouteChart The route string pointed to the device.
2147 @param DeviceSpeed The device speed.
2149 @retval EFI_SUCCESS Successfully assign a slot to the device and assign an address to it.
2154 XhcInitializeDeviceSlot64 (
2155 IN USB_XHCI_INSTANCE
*Xhc
,
2156 IN USB_DEV_ROUTE ParentRouteChart
,
2157 IN UINT16 ParentPort
,
2158 IN USB_DEV_ROUTE RouteChart
,
2159 IN UINT8 DeviceSpeed
2163 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
2164 INPUT_CONTEXT_64
*InputContext
;
2165 DEVICE_CONTEXT_64
*OutputContext
;
2166 TRANSFER_RING
*EndpointTransferRing
;
2167 CMD_TRB_ADDRESS_DEVICE CmdTrbAddr
;
2168 UINT8 DeviceAddress
;
2169 CMD_TRB_ENABLE_SLOT CmdTrb
;
2172 DEVICE_CONTEXT_64
*ParentDeviceContext
;
2173 EFI_PHYSICAL_ADDRESS PhyAddr
;
2175 ZeroMem (&CmdTrb
, sizeof (CMD_TRB_ENABLE_SLOT
));
2176 CmdTrb
.CycleBit
= 1;
2177 CmdTrb
.Type
= TRB_TYPE_EN_SLOT
;
2179 Status
= XhcCmdTransfer (
2181 (TRB_TEMPLATE
*) (UINTN
) &CmdTrb
,
2182 XHC_GENERIC_TIMEOUT
,
2183 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
2185 if (EFI_ERROR (Status
)) {
2186 DEBUG ((EFI_D_ERROR
, "XhcInitializeDeviceSlot64: Enable Slot Failed, Status = %r\n", Status
));
2189 ASSERT (EvtTrb
->SlotId
<= Xhc
->MaxSlotsEn
);
2190 DEBUG ((EFI_D_INFO
, "Enable Slot Successfully, The Slot ID = 0x%x\n", EvtTrb
->SlotId
));
2191 SlotId
= (UINT8
)EvtTrb
->SlotId
;
2192 ASSERT (SlotId
!= 0);
2194 ZeroMem (&Xhc
->UsbDevContext
[SlotId
], sizeof (USB_DEV_CONTEXT
));
2195 Xhc
->UsbDevContext
[SlotId
].Enabled
= TRUE
;
2196 Xhc
->UsbDevContext
[SlotId
].SlotId
= SlotId
;
2197 Xhc
->UsbDevContext
[SlotId
].RouteString
.Dword
= RouteChart
.Dword
;
2198 Xhc
->UsbDevContext
[SlotId
].ParentRouteString
.Dword
= ParentRouteChart
.Dword
;
2201 // 4.3.3 Device Slot Initialization
2202 // 1) Allocate an Input Context data structure (6.2.5) and initialize all fields to '0'.
2204 InputContext
= UsbHcAllocateMem (Xhc
->MemPool
, sizeof (INPUT_CONTEXT_64
));
2205 ASSERT (InputContext
!= NULL
);
2206 ASSERT (((UINTN
) InputContext
& 0x3F) == 0);
2207 ZeroMem (InputContext
, sizeof (INPUT_CONTEXT_64
));
2209 Xhc
->UsbDevContext
[SlotId
].InputContext
= (VOID
*) InputContext
;
2212 // 2) Initialize the Input Control Context (6.2.5.1) of the Input Context by setting the A0 and A1
2213 // flags to '1'. These flags indicate that the Slot Context and the Endpoint 0 Context of the Input
2214 // Context are affected by the command.
2216 InputContext
->InputControlContext
.Dword2
|= (BIT0
| BIT1
);
2219 // 3) Initialize the Input Slot Context data structure
2221 InputContext
->Slot
.RouteString
= RouteChart
.Route
.RouteString
;
2222 InputContext
->Slot
.Speed
= DeviceSpeed
+ 1;
2223 InputContext
->Slot
.ContextEntries
= 1;
2224 InputContext
->Slot
.RootHubPortNum
= RouteChart
.Route
.RootPortNum
;
2226 if (RouteChart
.Route
.RouteString
) {
2228 // The device is behind of hub device.
2230 ParentSlotId
= XhcRouteStringToSlotId(Xhc
, ParentRouteChart
);
2231 ASSERT (ParentSlotId
!= 0);
2233 //if the Full/Low device attached to a High Speed Hub, Init the TTPortNum and TTHubSlotId field of slot context
2235 ParentDeviceContext
= (DEVICE_CONTEXT_64
*)Xhc
->UsbDevContext
[ParentSlotId
].OutputContext
;
2236 if ((ParentDeviceContext
->Slot
.TTPortNum
== 0) &&
2237 (ParentDeviceContext
->Slot
.TTHubSlotId
== 0)) {
2238 if ((ParentDeviceContext
->Slot
.Speed
== (EFI_USB_SPEED_HIGH
+ 1)) && (DeviceSpeed
< EFI_USB_SPEED_HIGH
)) {
2240 // Full/Low device attached to High speed hub port that isolates the high speed signaling
2241 // environment from Full/Low speed signaling environment for a device
2243 InputContext
->Slot
.TTPortNum
= ParentPort
;
2244 InputContext
->Slot
.TTHubSlotId
= ParentSlotId
;
2248 // Inherit the TT parameters from parent device.
2250 InputContext
->Slot
.TTPortNum
= ParentDeviceContext
->Slot
.TTPortNum
;
2251 InputContext
->Slot
.TTHubSlotId
= ParentDeviceContext
->Slot
.TTHubSlotId
;
2253 // If the device is a High speed device then down the speed to be the same as its parent Hub
2255 if (DeviceSpeed
== EFI_USB_SPEED_HIGH
) {
2256 InputContext
->Slot
.Speed
= ParentDeviceContext
->Slot
.Speed
;
2262 // 4) Allocate and initialize the Transfer Ring for the Default Control Endpoint.
2264 EndpointTransferRing
= AllocateZeroPool (sizeof (TRANSFER_RING
));
2265 Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[0] = EndpointTransferRing
;
2266 CreateTransferRing(Xhc
, TR_RING_TRB_NUMBER
, (TRANSFER_RING
*)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[0]);
2268 // 5) Initialize the Input default control Endpoint 0 Context (6.2.3).
2270 InputContext
->EP
[0].EPType
= ED_CONTROL_BIDIR
;
2272 if (DeviceSpeed
== EFI_USB_SPEED_SUPER
) {
2273 InputContext
->EP
[0].MaxPacketSize
= 512;
2274 } else if (DeviceSpeed
== EFI_USB_SPEED_HIGH
) {
2275 InputContext
->EP
[0].MaxPacketSize
= 64;
2277 InputContext
->EP
[0].MaxPacketSize
= 8;
2280 // Initial value of Average TRB Length for Control endpoints would be 8B, Interrupt endpoints
2281 // 1KB, and Bulk and Isoch endpoints 3KB.
2283 InputContext
->EP
[0].AverageTRBLength
= 8;
2284 InputContext
->EP
[0].MaxBurstSize
= 0;
2285 InputContext
->EP
[0].Interval
= 0;
2286 InputContext
->EP
[0].MaxPStreams
= 0;
2287 InputContext
->EP
[0].Mult
= 0;
2288 InputContext
->EP
[0].CErr
= 3;
2291 // Init the DCS(dequeue cycle state) as the transfer ring's CCS
2293 PhyAddr
= UsbHcGetPciAddrForHostAddr (
2295 ((TRANSFER_RING
*)(UINTN
)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[0])->RingSeg0
,
2296 sizeof (TRB_TEMPLATE
) * TR_RING_TRB_NUMBER
2298 InputContext
->EP
[0].PtrLo
= XHC_LOW_32BIT (PhyAddr
) | BIT0
;
2299 InputContext
->EP
[0].PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
2302 // 6) Allocate the Output Device Context data structure (6.2.1) and initialize it to '0'.
2304 OutputContext
= UsbHcAllocateMem (Xhc
->MemPool
, sizeof (DEVICE_CONTEXT_64
));
2305 ASSERT (OutputContext
!= NULL
);
2306 ASSERT (((UINTN
) OutputContext
& 0x3F) == 0);
2307 ZeroMem (OutputContext
, sizeof (DEVICE_CONTEXT_64
));
2309 Xhc
->UsbDevContext
[SlotId
].OutputContext
= OutputContext
;
2311 // 7) Load the appropriate (Device Slot ID) entry in the Device Context Base Address Array (5.4.6) with
2312 // a pointer to the Output Device Context data structure (6.2.1).
2314 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, OutputContext
, sizeof (DEVICE_CONTEXT_64
));
2316 // Fill DCBAA with PCI device address
2318 Xhc
->DCBAA
[SlotId
] = (UINT64
) (UINTN
) PhyAddr
;
2321 // 8) Issue an Address Device Command for the Device Slot, where the command points to the Input
2322 // Context data structure described above.
2324 ZeroMem (&CmdTrbAddr
, sizeof (CmdTrbAddr
));
2325 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, Xhc
->UsbDevContext
[SlotId
].InputContext
, sizeof (INPUT_CONTEXT_64
));
2326 CmdTrbAddr
.PtrLo
= XHC_LOW_32BIT (PhyAddr
);
2327 CmdTrbAddr
.PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
2328 CmdTrbAddr
.CycleBit
= 1;
2329 CmdTrbAddr
.Type
= TRB_TYPE_ADDRESS_DEV
;
2330 CmdTrbAddr
.SlotId
= Xhc
->UsbDevContext
[SlotId
].SlotId
;
2331 Status
= XhcCmdTransfer (
2333 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbAddr
,
2334 XHC_GENERIC_TIMEOUT
,
2335 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
2337 if (!EFI_ERROR (Status
)) {
2338 DeviceAddress
= (UINT8
) ((DEVICE_CONTEXT_64
*) OutputContext
)->Slot
.DeviceAddress
;
2339 DEBUG ((EFI_D_INFO
, " Address %d assigned successfully\n", DeviceAddress
));
2340 Xhc
->UsbDevContext
[SlotId
].XhciDevAddr
= DeviceAddress
;
2347 Disable the specified device slot.
2349 @param Xhc The XHCI Instance.
2350 @param SlotId The slot id to be disabled.
2352 @retval EFI_SUCCESS Successfully disable the device slot.
2358 IN USB_XHCI_INSTANCE
*Xhc
,
2363 TRB_TEMPLATE
*EvtTrb
;
2364 CMD_TRB_DISABLE_SLOT CmdTrbDisSlot
;
2369 // Disable the device slots occupied by these devices on its downstream ports.
2370 // Entry 0 is reserved.
2372 for (Index
= 0; Index
< 255; Index
++) {
2373 if (!Xhc
->UsbDevContext
[Index
+ 1].Enabled
||
2374 (Xhc
->UsbDevContext
[Index
+ 1].SlotId
== 0) ||
2375 (Xhc
->UsbDevContext
[Index
+ 1].ParentRouteString
.Dword
!= Xhc
->UsbDevContext
[SlotId
].RouteString
.Dword
)) {
2379 Status
= XhcDisableSlotCmd (Xhc
, Xhc
->UsbDevContext
[Index
+ 1].SlotId
);
2381 if (EFI_ERROR (Status
)) {
2382 DEBUG ((EFI_D_ERROR
, "XhcDisableSlotCmd: failed to disable child, ignore error\n"));
2383 Xhc
->UsbDevContext
[Index
+ 1].SlotId
= 0;
2388 // Construct the disable slot command
2390 DEBUG ((EFI_D_INFO
, "Disable device slot %d!\n", SlotId
));
2392 ZeroMem (&CmdTrbDisSlot
, sizeof (CmdTrbDisSlot
));
2393 CmdTrbDisSlot
.CycleBit
= 1;
2394 CmdTrbDisSlot
.Type
= TRB_TYPE_DIS_SLOT
;
2395 CmdTrbDisSlot
.SlotId
= SlotId
;
2396 Status
= XhcCmdTransfer (
2398 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbDisSlot
,
2399 XHC_GENERIC_TIMEOUT
,
2400 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
2402 if (EFI_ERROR (Status
)) {
2403 DEBUG ((EFI_D_ERROR
, "XhcDisableSlotCmd: Disable Slot Command Failed, Status = %r\n", Status
));
2407 // Free the slot's device context entry
2409 Xhc
->DCBAA
[SlotId
] = 0;
2412 // Free the slot related data structure
2414 for (Index
= 0; Index
< 31; Index
++) {
2415 if (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Index
] != NULL
) {
2416 RingSeg
= ((TRANSFER_RING
*)(UINTN
)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Index
])->RingSeg0
;
2417 if (RingSeg
!= NULL
) {
2418 UsbHcFreeMem (Xhc
->MemPool
, RingSeg
, sizeof (TRB_TEMPLATE
) * TR_RING_TRB_NUMBER
);
2420 FreePool (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Index
]);
2421 Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Index
] = NULL
;
2425 for (Index
= 0; Index
< Xhc
->UsbDevContext
[SlotId
].DevDesc
.NumConfigurations
; Index
++) {
2426 if (Xhc
->UsbDevContext
[SlotId
].ConfDesc
[Index
] != NULL
) {
2427 FreePool (Xhc
->UsbDevContext
[SlotId
].ConfDesc
[Index
]);
2431 if (Xhc
->UsbDevContext
[SlotId
].ActiveAlternateSetting
!= NULL
) {
2432 FreePool (Xhc
->UsbDevContext
[SlotId
].ActiveAlternateSetting
);
2435 if (Xhc
->UsbDevContext
[SlotId
].InputContext
!= NULL
) {
2436 UsbHcFreeMem (Xhc
->MemPool
, Xhc
->UsbDevContext
[SlotId
].InputContext
, sizeof (INPUT_CONTEXT
));
2439 if (Xhc
->UsbDevContext
[SlotId
].OutputContext
!= NULL
) {
2440 UsbHcFreeMem (Xhc
->MemPool
, Xhc
->UsbDevContext
[SlotId
].OutputContext
, sizeof (DEVICE_CONTEXT
));
2443 // Doesn't zero the entry because XhcAsyncInterruptTransfer() may be invoked to remove the established
2444 // asynchronous interrupt pipe after the device is disabled. It needs the device address mapping info to
2445 // remove urb from XHCI's asynchronous transfer list.
2447 Xhc
->UsbDevContext
[SlotId
].Enabled
= FALSE
;
2448 Xhc
->UsbDevContext
[SlotId
].SlotId
= 0;
2454 Disable the specified device slot.
2456 @param Xhc The XHCI Instance.
2457 @param SlotId The slot id to be disabled.
2459 @retval EFI_SUCCESS Successfully disable the device slot.
2464 XhcDisableSlotCmd64 (
2465 IN USB_XHCI_INSTANCE
*Xhc
,
2470 TRB_TEMPLATE
*EvtTrb
;
2471 CMD_TRB_DISABLE_SLOT CmdTrbDisSlot
;
2476 // Disable the device slots occupied by these devices on its downstream ports.
2477 // Entry 0 is reserved.
2479 for (Index
= 0; Index
< 255; Index
++) {
2480 if (!Xhc
->UsbDevContext
[Index
+ 1].Enabled
||
2481 (Xhc
->UsbDevContext
[Index
+ 1].SlotId
== 0) ||
2482 (Xhc
->UsbDevContext
[Index
+ 1].ParentRouteString
.Dword
!= Xhc
->UsbDevContext
[SlotId
].RouteString
.Dword
)) {
2486 Status
= XhcDisableSlotCmd64 (Xhc
, Xhc
->UsbDevContext
[Index
+ 1].SlotId
);
2488 if (EFI_ERROR (Status
)) {
2489 DEBUG ((EFI_D_ERROR
, "XhcDisableSlotCmd: failed to disable child, ignore error\n"));
2490 Xhc
->UsbDevContext
[Index
+ 1].SlotId
= 0;
2495 // Construct the disable slot command
2497 DEBUG ((EFI_D_INFO
, "Disable device slot %d!\n", SlotId
));
2499 ZeroMem (&CmdTrbDisSlot
, sizeof (CmdTrbDisSlot
));
2500 CmdTrbDisSlot
.CycleBit
= 1;
2501 CmdTrbDisSlot
.Type
= TRB_TYPE_DIS_SLOT
;
2502 CmdTrbDisSlot
.SlotId
= SlotId
;
2503 Status
= XhcCmdTransfer (
2505 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbDisSlot
,
2506 XHC_GENERIC_TIMEOUT
,
2507 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
2509 if (EFI_ERROR (Status
)) {
2510 DEBUG ((EFI_D_ERROR
, "XhcDisableSlotCmd: Disable Slot Command Failed, Status = %r\n", Status
));
2514 // Free the slot's device context entry
2516 Xhc
->DCBAA
[SlotId
] = 0;
2519 // Free the slot related data structure
2521 for (Index
= 0; Index
< 31; Index
++) {
2522 if (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Index
] != NULL
) {
2523 RingSeg
= ((TRANSFER_RING
*)(UINTN
)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Index
])->RingSeg0
;
2524 if (RingSeg
!= NULL
) {
2525 UsbHcFreeMem (Xhc
->MemPool
, RingSeg
, sizeof (TRB_TEMPLATE
) * TR_RING_TRB_NUMBER
);
2527 FreePool (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Index
]);
2528 Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Index
] = NULL
;
2532 for (Index
= 0; Index
< Xhc
->UsbDevContext
[SlotId
].DevDesc
.NumConfigurations
; Index
++) {
2533 if (Xhc
->UsbDevContext
[SlotId
].ConfDesc
[Index
] != NULL
) {
2534 FreePool (Xhc
->UsbDevContext
[SlotId
].ConfDesc
[Index
]);
2538 if (Xhc
->UsbDevContext
[SlotId
].ActiveAlternateSetting
!= NULL
) {
2539 FreePool (Xhc
->UsbDevContext
[SlotId
].ActiveAlternateSetting
);
2542 if (Xhc
->UsbDevContext
[SlotId
].InputContext
!= NULL
) {
2543 UsbHcFreeMem (Xhc
->MemPool
, Xhc
->UsbDevContext
[SlotId
].InputContext
, sizeof (INPUT_CONTEXT_64
));
2546 if (Xhc
->UsbDevContext
[SlotId
].OutputContext
!= NULL
) {
2547 UsbHcFreeMem (Xhc
->MemPool
, Xhc
->UsbDevContext
[SlotId
].OutputContext
, sizeof (DEVICE_CONTEXT_64
));
2550 // Doesn't zero the entry because XhcAsyncInterruptTransfer() may be invoked to remove the established
2551 // asynchronous interrupt pipe after the device is disabled. It needs the device address mapping info to
2552 // remove urb from XHCI's asynchronous transfer list.
2554 Xhc
->UsbDevContext
[SlotId
].Enabled
= FALSE
;
2555 Xhc
->UsbDevContext
[SlotId
].SlotId
= 0;
2561 Initialize endpoint context in input context.
2563 @param Xhc The XHCI Instance.
2564 @param SlotId The slot id to be configured.
2565 @param DeviceSpeed The device's speed.
2566 @param InputContext The pointer to the input context.
2567 @param IfDesc The pointer to the usb device interface descriptor.
2569 @return The maximum device context index of endpoint.
2574 XhcInitializeEndpointContext (
2575 IN USB_XHCI_INSTANCE
*Xhc
,
2577 IN UINT8 DeviceSpeed
,
2578 IN INPUT_CONTEXT
*InputContext
,
2579 IN USB_INTERFACE_DESCRIPTOR
*IfDesc
2582 USB_ENDPOINT_DESCRIPTOR
*EpDesc
;
2589 EFI_PHYSICAL_ADDRESS PhyAddr
;
2591 TRANSFER_RING
*EndpointTransferRing
;
2595 NumEp
= IfDesc
->NumEndpoints
;
2597 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)(IfDesc
+ 1);
2598 for (EpIndex
= 0; EpIndex
< NumEp
; EpIndex
++) {
2599 while (EpDesc
->DescriptorType
!= USB_DESC_TYPE_ENDPOINT
) {
2600 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
2603 if (EpDesc
->Length
< sizeof (USB_ENDPOINT_DESCRIPTOR
)) {
2604 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
2608 EpAddr
= (UINT8
)(EpDesc
->EndpointAddress
& 0x0F);
2609 Direction
= (UINT8
)((EpDesc
->EndpointAddress
& 0x80) ? EfiUsbDataIn
: EfiUsbDataOut
);
2611 Dci
= XhcEndpointToDci (EpAddr
, Direction
);
2617 InputContext
->InputControlContext
.Dword2
|= (BIT0
<< Dci
);
2618 InputContext
->EP
[Dci
-1].MaxPacketSize
= EpDesc
->MaxPacketSize
;
2620 if (DeviceSpeed
== EFI_USB_SPEED_SUPER
) {
2622 // 6.2.3.4, shall be set to the value defined in the bMaxBurst field of the SuperSpeed Endpoint Companion Descriptor.
2624 InputContext
->EP
[Dci
-1].MaxBurstSize
= 0x0;
2626 InputContext
->EP
[Dci
-1].MaxBurstSize
= 0x0;
2629 switch (EpDesc
->Attributes
& USB_ENDPOINT_TYPE_MASK
) {
2630 case USB_ENDPOINT_BULK
:
2631 if (Direction
== EfiUsbDataIn
) {
2632 InputContext
->EP
[Dci
-1].CErr
= 3;
2633 InputContext
->EP
[Dci
-1].EPType
= ED_BULK_IN
;
2635 InputContext
->EP
[Dci
-1].CErr
= 3;
2636 InputContext
->EP
[Dci
-1].EPType
= ED_BULK_OUT
;
2639 InputContext
->EP
[Dci
-1].AverageTRBLength
= 0x1000;
2640 if (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1] == NULL
) {
2641 EndpointTransferRing
= AllocateZeroPool(sizeof (TRANSFER_RING
));
2642 Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1] = (VOID
*) EndpointTransferRing
;
2643 CreateTransferRing(Xhc
, TR_RING_TRB_NUMBER
, (TRANSFER_RING
*)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1]);
2647 case USB_ENDPOINT_ISO
:
2648 if (Direction
== EfiUsbDataIn
) {
2649 InputContext
->EP
[Dci
-1].CErr
= 0;
2650 InputContext
->EP
[Dci
-1].EPType
= ED_ISOCH_IN
;
2652 InputContext
->EP
[Dci
-1].CErr
= 0;
2653 InputContext
->EP
[Dci
-1].EPType
= ED_ISOCH_OUT
;
2656 // Do not support isochronous transfer now.
2658 DEBUG ((EFI_D_INFO
, "XhcInitializeEndpointContext: Unsupport ISO EP found, Transfer ring is not allocated.\n"));
2659 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
2661 case USB_ENDPOINT_INTERRUPT
:
2662 if (Direction
== EfiUsbDataIn
) {
2663 InputContext
->EP
[Dci
-1].CErr
= 3;
2664 InputContext
->EP
[Dci
-1].EPType
= ED_INTERRUPT_IN
;
2666 InputContext
->EP
[Dci
-1].CErr
= 3;
2667 InputContext
->EP
[Dci
-1].EPType
= ED_INTERRUPT_OUT
;
2669 InputContext
->EP
[Dci
-1].AverageTRBLength
= 0x1000;
2670 InputContext
->EP
[Dci
-1].MaxESITPayload
= EpDesc
->MaxPacketSize
;
2672 // Get the bInterval from descriptor and init the the interval field of endpoint context
2674 if ((DeviceSpeed
== EFI_USB_SPEED_FULL
) || (DeviceSpeed
== EFI_USB_SPEED_LOW
)) {
2675 Interval
= EpDesc
->Interval
;
2677 // Calculate through the bInterval field of Endpoint descriptor.
2679 ASSERT (Interval
!= 0);
2680 InputContext
->EP
[Dci
-1].Interval
= (UINT32
)HighBitSet32((UINT32
)Interval
) + 3;
2681 } else if ((DeviceSpeed
== EFI_USB_SPEED_HIGH
) || (DeviceSpeed
== EFI_USB_SPEED_SUPER
)) {
2682 Interval
= EpDesc
->Interval
;
2683 ASSERT (Interval
>= 1 && Interval
<= 16);
2685 // Refer to XHCI 1.0 spec section 6.2.3.6, table 61
2687 InputContext
->EP
[Dci
-1].Interval
= Interval
- 1;
2688 InputContext
->EP
[Dci
-1].AverageTRBLength
= 0x1000;
2689 InputContext
->EP
[Dci
-1].MaxESITPayload
= 0x0002;
2690 InputContext
->EP
[Dci
-1].MaxBurstSize
= 0x0;
2691 InputContext
->EP
[Dci
-1].CErr
= 3;
2694 if (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1] == NULL
) {
2695 EndpointTransferRing
= AllocateZeroPool(sizeof (TRANSFER_RING
));
2696 Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1] = (VOID
*) EndpointTransferRing
;
2697 CreateTransferRing(Xhc
, TR_RING_TRB_NUMBER
, (TRANSFER_RING
*)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1]);
2701 case USB_ENDPOINT_CONTROL
:
2703 // Do not support control transfer now.
2705 DEBUG ((EFI_D_INFO
, "XhcInitializeEndpointContext: Unsupport Control EP found, Transfer ring is not allocated.\n"));
2707 DEBUG ((EFI_D_INFO
, "XhcInitializeEndpointContext: Unknown EP found, Transfer ring is not allocated.\n"));
2708 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
2712 PhyAddr
= UsbHcGetPciAddrForHostAddr (
2714 ((TRANSFER_RING
*)(UINTN
)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1])->RingSeg0
,
2715 sizeof (TRB_TEMPLATE
) * TR_RING_TRB_NUMBER
2717 PhyAddr
&= ~((EFI_PHYSICAL_ADDRESS
)0x0F);
2718 PhyAddr
|= (EFI_PHYSICAL_ADDRESS
)((TRANSFER_RING
*)(UINTN
)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1])->RingPCS
;
2719 InputContext
->EP
[Dci
-1].PtrLo
= XHC_LOW_32BIT (PhyAddr
);
2720 InputContext
->EP
[Dci
-1].PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
2722 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
2729 Initialize endpoint context in input context.
2731 @param Xhc The XHCI Instance.
2732 @param SlotId The slot id to be configured.
2733 @param DeviceSpeed The device's speed.
2734 @param InputContext The pointer to the input context.
2735 @param IfDesc The pointer to the usb device interface descriptor.
2737 @return The maximum device context index of endpoint.
2742 XhcInitializeEndpointContext64 (
2743 IN USB_XHCI_INSTANCE
*Xhc
,
2745 IN UINT8 DeviceSpeed
,
2746 IN INPUT_CONTEXT_64
*InputContext
,
2747 IN USB_INTERFACE_DESCRIPTOR
*IfDesc
2750 USB_ENDPOINT_DESCRIPTOR
*EpDesc
;
2757 EFI_PHYSICAL_ADDRESS PhyAddr
;
2759 TRANSFER_RING
*EndpointTransferRing
;
2763 NumEp
= IfDesc
->NumEndpoints
;
2765 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)(IfDesc
+ 1);
2766 for (EpIndex
= 0; EpIndex
< NumEp
; EpIndex
++) {
2767 while (EpDesc
->DescriptorType
!= USB_DESC_TYPE_ENDPOINT
) {
2768 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
2771 if (EpDesc
->Length
< sizeof (USB_ENDPOINT_DESCRIPTOR
)) {
2772 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
2776 EpAddr
= (UINT8
)(EpDesc
->EndpointAddress
& 0x0F);
2777 Direction
= (UINT8
)((EpDesc
->EndpointAddress
& 0x80) ? EfiUsbDataIn
: EfiUsbDataOut
);
2779 Dci
= XhcEndpointToDci (EpAddr
, Direction
);
2785 InputContext
->InputControlContext
.Dword2
|= (BIT0
<< Dci
);
2786 InputContext
->EP
[Dci
-1].MaxPacketSize
= EpDesc
->MaxPacketSize
;
2788 if (DeviceSpeed
== EFI_USB_SPEED_SUPER
) {
2790 // 6.2.3.4, shall be set to the value defined in the bMaxBurst field of the SuperSpeed Endpoint Companion Descriptor.
2792 InputContext
->EP
[Dci
-1].MaxBurstSize
= 0x0;
2794 InputContext
->EP
[Dci
-1].MaxBurstSize
= 0x0;
2797 switch (EpDesc
->Attributes
& USB_ENDPOINT_TYPE_MASK
) {
2798 case USB_ENDPOINT_BULK
:
2799 if (Direction
== EfiUsbDataIn
) {
2800 InputContext
->EP
[Dci
-1].CErr
= 3;
2801 InputContext
->EP
[Dci
-1].EPType
= ED_BULK_IN
;
2803 InputContext
->EP
[Dci
-1].CErr
= 3;
2804 InputContext
->EP
[Dci
-1].EPType
= ED_BULK_OUT
;
2807 InputContext
->EP
[Dci
-1].AverageTRBLength
= 0x1000;
2808 if (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1] == NULL
) {
2809 EndpointTransferRing
= AllocateZeroPool(sizeof (TRANSFER_RING
));
2810 Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1] = (VOID
*) EndpointTransferRing
;
2811 CreateTransferRing(Xhc
, TR_RING_TRB_NUMBER
, (TRANSFER_RING
*)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1]);
2815 case USB_ENDPOINT_ISO
:
2816 if (Direction
== EfiUsbDataIn
) {
2817 InputContext
->EP
[Dci
-1].CErr
= 0;
2818 InputContext
->EP
[Dci
-1].EPType
= ED_ISOCH_IN
;
2820 InputContext
->EP
[Dci
-1].CErr
= 0;
2821 InputContext
->EP
[Dci
-1].EPType
= ED_ISOCH_OUT
;
2824 // Do not support isochronous transfer now.
2826 DEBUG ((EFI_D_INFO
, "XhcInitializeEndpointContext64: Unsupport ISO EP found, Transfer ring is not allocated.\n"));
2827 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
2829 case USB_ENDPOINT_INTERRUPT
:
2830 if (Direction
== EfiUsbDataIn
) {
2831 InputContext
->EP
[Dci
-1].CErr
= 3;
2832 InputContext
->EP
[Dci
-1].EPType
= ED_INTERRUPT_IN
;
2834 InputContext
->EP
[Dci
-1].CErr
= 3;
2835 InputContext
->EP
[Dci
-1].EPType
= ED_INTERRUPT_OUT
;
2837 InputContext
->EP
[Dci
-1].AverageTRBLength
= 0x1000;
2838 InputContext
->EP
[Dci
-1].MaxESITPayload
= EpDesc
->MaxPacketSize
;
2840 // Get the bInterval from descriptor and init the the interval field of endpoint context
2842 if ((DeviceSpeed
== EFI_USB_SPEED_FULL
) || (DeviceSpeed
== EFI_USB_SPEED_LOW
)) {
2843 Interval
= EpDesc
->Interval
;
2845 // Calculate through the bInterval field of Endpoint descriptor.
2847 ASSERT (Interval
!= 0);
2848 InputContext
->EP
[Dci
-1].Interval
= (UINT32
)HighBitSet32((UINT32
)Interval
) + 3;
2849 } else if ((DeviceSpeed
== EFI_USB_SPEED_HIGH
) || (DeviceSpeed
== EFI_USB_SPEED_SUPER
)) {
2850 Interval
= EpDesc
->Interval
;
2851 ASSERT (Interval
>= 1 && Interval
<= 16);
2853 // Refer to XHCI 1.0 spec section 6.2.3.6, table 61
2855 InputContext
->EP
[Dci
-1].Interval
= Interval
- 1;
2856 InputContext
->EP
[Dci
-1].AverageTRBLength
= 0x1000;
2857 InputContext
->EP
[Dci
-1].MaxESITPayload
= 0x0002;
2858 InputContext
->EP
[Dci
-1].MaxBurstSize
= 0x0;
2859 InputContext
->EP
[Dci
-1].CErr
= 3;
2862 if (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1] == NULL
) {
2863 EndpointTransferRing
= AllocateZeroPool(sizeof (TRANSFER_RING
));
2864 Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1] = (VOID
*) EndpointTransferRing
;
2865 CreateTransferRing(Xhc
, TR_RING_TRB_NUMBER
, (TRANSFER_RING
*)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1]);
2869 case USB_ENDPOINT_CONTROL
:
2871 // Do not support control transfer now.
2873 DEBUG ((EFI_D_INFO
, "XhcInitializeEndpointContext64: Unsupport Control EP found, Transfer ring is not allocated.\n"));
2875 DEBUG ((EFI_D_INFO
, "XhcInitializeEndpointContext64: Unknown EP found, Transfer ring is not allocated.\n"));
2876 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
2880 PhyAddr
= UsbHcGetPciAddrForHostAddr (
2882 ((TRANSFER_RING
*)(UINTN
)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1])->RingSeg0
,
2883 sizeof (TRB_TEMPLATE
) * TR_RING_TRB_NUMBER
2885 PhyAddr
&= ~((EFI_PHYSICAL_ADDRESS
)0x0F);
2886 PhyAddr
|= (EFI_PHYSICAL_ADDRESS
)((TRANSFER_RING
*)(UINTN
)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
-1])->RingPCS
;
2887 InputContext
->EP
[Dci
-1].PtrLo
= XHC_LOW_32BIT (PhyAddr
);
2888 InputContext
->EP
[Dci
-1].PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
2890 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
2897 Configure all the device endpoints through XHCI's Configure_Endpoint cmd.
2899 @param Xhc The XHCI Instance.
2900 @param SlotId The slot id to be configured.
2901 @param DeviceSpeed The device's speed.
2902 @param ConfigDesc The pointer to the usb device configuration descriptor.
2904 @retval EFI_SUCCESS Successfully configure all the device endpoints.
2910 IN USB_XHCI_INSTANCE
*Xhc
,
2912 IN UINT8 DeviceSpeed
,
2913 IN USB_CONFIG_DESCRIPTOR
*ConfigDesc
2917 USB_INTERFACE_DESCRIPTOR
*IfDesc
;
2921 EFI_PHYSICAL_ADDRESS PhyAddr
;
2923 CMD_TRB_CONFIG_ENDPOINT CmdTrbCfgEP
;
2924 INPUT_CONTEXT
*InputContext
;
2925 DEVICE_CONTEXT
*OutputContext
;
2926 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
2928 // 4.6.6 Configure Endpoint
2930 InputContext
= Xhc
->UsbDevContext
[SlotId
].InputContext
;
2931 OutputContext
= Xhc
->UsbDevContext
[SlotId
].OutputContext
;
2932 ZeroMem (InputContext
, sizeof (INPUT_CONTEXT
));
2933 CopyMem (&InputContext
->Slot
, &OutputContext
->Slot
, sizeof (SLOT_CONTEXT
));
2935 ASSERT (ConfigDesc
!= NULL
);
2939 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)(ConfigDesc
+ 1);
2940 for (Index
= 0; Index
< ConfigDesc
->NumInterfaces
; Index
++) {
2941 while ((IfDesc
->DescriptorType
!= USB_DESC_TYPE_INTERFACE
) || (IfDesc
->AlternateSetting
!= 0)) {
2942 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)((UINTN
)IfDesc
+ IfDesc
->Length
);
2945 if (IfDesc
->Length
< sizeof (USB_INTERFACE_DESCRIPTOR
)) {
2946 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)((UINTN
)IfDesc
+ IfDesc
->Length
);
2950 Dci
= XhcInitializeEndpointContext (Xhc
, SlotId
, DeviceSpeed
, InputContext
, IfDesc
);
2955 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)((UINTN
)IfDesc
+ IfDesc
->Length
);
2958 InputContext
->InputControlContext
.Dword2
|= BIT0
;
2959 InputContext
->Slot
.ContextEntries
= MaxDci
;
2961 // configure endpoint
2963 ZeroMem (&CmdTrbCfgEP
, sizeof (CmdTrbCfgEP
));
2964 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, InputContext
, sizeof (INPUT_CONTEXT
));
2965 CmdTrbCfgEP
.PtrLo
= XHC_LOW_32BIT (PhyAddr
);
2966 CmdTrbCfgEP
.PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
2967 CmdTrbCfgEP
.CycleBit
= 1;
2968 CmdTrbCfgEP
.Type
= TRB_TYPE_CON_ENDPOINT
;
2969 CmdTrbCfgEP
.SlotId
= Xhc
->UsbDevContext
[SlotId
].SlotId
;
2970 DEBUG ((EFI_D_INFO
, "Configure Endpoint\n"));
2971 Status
= XhcCmdTransfer (
2973 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbCfgEP
,
2974 XHC_GENERIC_TIMEOUT
,
2975 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
2977 if (EFI_ERROR (Status
)) {
2978 DEBUG ((EFI_D_ERROR
, "XhcSetConfigCmd: Config Endpoint Failed, Status = %r\n", Status
));
2980 Xhc
->UsbDevContext
[SlotId
].ActiveConfiguration
= ConfigDesc
->ConfigurationValue
;
2987 Configure all the device endpoints through XHCI's Configure_Endpoint cmd.
2989 @param Xhc The XHCI Instance.
2990 @param SlotId The slot id to be configured.
2991 @param DeviceSpeed The device's speed.
2992 @param ConfigDesc The pointer to the usb device configuration descriptor.
2994 @retval EFI_SUCCESS Successfully configure all the device endpoints.
3000 IN USB_XHCI_INSTANCE
*Xhc
,
3002 IN UINT8 DeviceSpeed
,
3003 IN USB_CONFIG_DESCRIPTOR
*ConfigDesc
3007 USB_INTERFACE_DESCRIPTOR
*IfDesc
;
3011 EFI_PHYSICAL_ADDRESS PhyAddr
;
3013 CMD_TRB_CONFIG_ENDPOINT CmdTrbCfgEP
;
3014 INPUT_CONTEXT_64
*InputContext
;
3015 DEVICE_CONTEXT_64
*OutputContext
;
3016 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
3018 // 4.6.6 Configure Endpoint
3020 InputContext
= Xhc
->UsbDevContext
[SlotId
].InputContext
;
3021 OutputContext
= Xhc
->UsbDevContext
[SlotId
].OutputContext
;
3022 ZeroMem (InputContext
, sizeof (INPUT_CONTEXT_64
));
3023 CopyMem (&InputContext
->Slot
, &OutputContext
->Slot
, sizeof (SLOT_CONTEXT_64
));
3025 ASSERT (ConfigDesc
!= NULL
);
3029 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)(ConfigDesc
+ 1);
3030 for (Index
= 0; Index
< ConfigDesc
->NumInterfaces
; Index
++) {
3031 while ((IfDesc
->DescriptorType
!= USB_DESC_TYPE_INTERFACE
) || (IfDesc
->AlternateSetting
!= 0)) {
3032 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)((UINTN
)IfDesc
+ IfDesc
->Length
);
3035 if (IfDesc
->Length
< sizeof (USB_INTERFACE_DESCRIPTOR
)) {
3036 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)((UINTN
)IfDesc
+ IfDesc
->Length
);
3040 Dci
= XhcInitializeEndpointContext64 (Xhc
, SlotId
, DeviceSpeed
, InputContext
, IfDesc
);
3045 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)((UINTN
)IfDesc
+ IfDesc
->Length
);
3048 InputContext
->InputControlContext
.Dword2
|= BIT0
;
3049 InputContext
->Slot
.ContextEntries
= MaxDci
;
3051 // configure endpoint
3053 ZeroMem (&CmdTrbCfgEP
, sizeof (CmdTrbCfgEP
));
3054 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, InputContext
, sizeof (INPUT_CONTEXT_64
));
3055 CmdTrbCfgEP
.PtrLo
= XHC_LOW_32BIT (PhyAddr
);
3056 CmdTrbCfgEP
.PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
3057 CmdTrbCfgEP
.CycleBit
= 1;
3058 CmdTrbCfgEP
.Type
= TRB_TYPE_CON_ENDPOINT
;
3059 CmdTrbCfgEP
.SlotId
= Xhc
->UsbDevContext
[SlotId
].SlotId
;
3060 DEBUG ((EFI_D_INFO
, "Configure Endpoint\n"));
3061 Status
= XhcCmdTransfer (
3063 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbCfgEP
,
3064 XHC_GENERIC_TIMEOUT
,
3065 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
3067 if (EFI_ERROR (Status
)) {
3068 DEBUG ((EFI_D_ERROR
, "XhcSetConfigCmd64: Config Endpoint Failed, Status = %r\n", Status
));
3070 Xhc
->UsbDevContext
[SlotId
].ActiveConfiguration
= ConfigDesc
->ConfigurationValue
;
3077 Stop endpoint through XHCI's Stop_Endpoint cmd.
3079 @param Xhc The XHCI Instance.
3080 @param SlotId The slot id to be configured.
3081 @param Dci The device context index of endpoint.
3083 @retval EFI_SUCCESS Stop endpoint successfully.
3084 @retval Others Failed to stop endpoint.
3090 IN USB_XHCI_INSTANCE
*Xhc
,
3096 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
3097 CMD_TRB_STOP_ENDPOINT CmdTrbStopED
;
3099 DEBUG ((EFI_D_INFO
, "XhcStopEndpoint: Slot = 0x%x, Dci = 0x%x\n", SlotId
, Dci
));
3102 // Send stop endpoint command to transit Endpoint from running to stop state
3104 ZeroMem (&CmdTrbStopED
, sizeof (CmdTrbStopED
));
3105 CmdTrbStopED
.CycleBit
= 1;
3106 CmdTrbStopED
.Type
= TRB_TYPE_STOP_ENDPOINT
;
3107 CmdTrbStopED
.EDID
= Dci
;
3108 CmdTrbStopED
.SlotId
= SlotId
;
3109 Status
= XhcCmdTransfer (
3111 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbStopED
,
3112 XHC_GENERIC_TIMEOUT
,
3113 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
3115 if (EFI_ERROR(Status
)) {
3116 DEBUG ((EFI_D_ERROR
, "XhcStopEndpoint: Stop Endpoint Failed, Status = %r\n", Status
));
3123 Reset endpoint through XHCI's Reset_Endpoint cmd.
3125 @param Xhc The XHCI Instance.
3126 @param SlotId The slot id to be configured.
3127 @param Dci The device context index of endpoint.
3129 @retval EFI_SUCCESS Reset endpoint successfully.
3130 @retval Others Failed to reset endpoint.
3136 IN USB_XHCI_INSTANCE
*Xhc
,
3142 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
3143 CMD_TRB_RESET_ENDPOINT CmdTrbResetED
;
3145 DEBUG ((EFI_D_INFO
, "XhcResetEndpoint: Slot = 0x%x, Dci = 0x%x\n", SlotId
, Dci
));
3148 // Send stop endpoint command to transit Endpoint from running to stop state
3150 ZeroMem (&CmdTrbResetED
, sizeof (CmdTrbResetED
));
3151 CmdTrbResetED
.CycleBit
= 1;
3152 CmdTrbResetED
.Type
= TRB_TYPE_RESET_ENDPOINT
;
3153 CmdTrbResetED
.EDID
= Dci
;
3154 CmdTrbResetED
.SlotId
= SlotId
;
3155 Status
= XhcCmdTransfer (
3157 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbResetED
,
3158 XHC_GENERIC_TIMEOUT
,
3159 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
3161 if (EFI_ERROR(Status
)) {
3162 DEBUG ((EFI_D_ERROR
, "XhcResetEndpoint: Reset Endpoint Failed, Status = %r\n", Status
));
3169 Set transfer ring dequeue pointer through XHCI's Set_Tr_Dequeue_Pointer cmd.
3171 @param Xhc The XHCI Instance.
3172 @param SlotId The slot id to be configured.
3173 @param Dci The device context index of endpoint.
3174 @param Urb The dequeue pointer of the transfer ring specified
3175 by the urb to be updated.
3177 @retval EFI_SUCCESS Set transfer ring dequeue pointer succeeds.
3178 @retval Others Failed to set transfer ring dequeue pointer.
3183 XhcSetTrDequeuePointer (
3184 IN USB_XHCI_INSTANCE
*Xhc
,
3191 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
3192 CMD_SET_TR_DEQ_POINTER CmdSetTRDeq
;
3193 EFI_PHYSICAL_ADDRESS PhyAddr
;
3195 DEBUG ((EFI_D_INFO
, "XhcSetTrDequeuePointer: Slot = 0x%x, Dci = 0x%x, Urb = 0x%x\n", SlotId
, Dci
, Urb
));
3198 // Send stop endpoint command to transit Endpoint from running to stop state
3200 ZeroMem (&CmdSetTRDeq
, sizeof (CmdSetTRDeq
));
3201 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, Urb
->Ring
->RingEnqueue
, sizeof (CMD_SET_TR_DEQ_POINTER
));
3202 CmdSetTRDeq
.PtrLo
= XHC_LOW_32BIT (PhyAddr
) | Urb
->Ring
->RingPCS
;
3203 CmdSetTRDeq
.PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
3204 CmdSetTRDeq
.CycleBit
= 1;
3205 CmdSetTRDeq
.Type
= TRB_TYPE_SET_TR_DEQUE
;
3206 CmdSetTRDeq
.Endpoint
= Dci
;
3207 CmdSetTRDeq
.SlotId
= SlotId
;
3208 Status
= XhcCmdTransfer (
3210 (TRB_TEMPLATE
*) (UINTN
) &CmdSetTRDeq
,
3211 XHC_GENERIC_TIMEOUT
,
3212 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
3214 if (EFI_ERROR(Status
)) {
3215 DEBUG ((EFI_D_ERROR
, "XhcSetTrDequeuePointer: Set TR Dequeue Pointer Failed, Status = %r\n", Status
));
3222 Set interface through XHCI's Configure_Endpoint cmd.
3224 @param Xhc The XHCI Instance.
3225 @param SlotId The slot id to be configured.
3226 @param DeviceSpeed The device's speed.
3227 @param ConfigDesc The pointer to the usb device configuration descriptor.
3228 @param Request USB device request to send.
3230 @retval EFI_SUCCESS Successfully set interface.
3236 IN USB_XHCI_INSTANCE
*Xhc
,
3238 IN UINT8 DeviceSpeed
,
3239 IN USB_CONFIG_DESCRIPTOR
*ConfigDesc
,
3240 IN EFI_USB_DEVICE_REQUEST
*Request
3244 USB_INTERFACE_DESCRIPTOR
*IfDescActive
;
3245 USB_INTERFACE_DESCRIPTOR
*IfDescSet
;
3246 USB_INTERFACE_DESCRIPTOR
*IfDesc
;
3247 USB_ENDPOINT_DESCRIPTOR
*EpDesc
;
3254 EFI_PHYSICAL_ADDRESS PhyAddr
;
3257 CMD_TRB_CONFIG_ENDPOINT CmdTrbCfgEP
;
3258 INPUT_CONTEXT
*InputContext
;
3259 DEVICE_CONTEXT
*OutputContext
;
3260 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
3262 Status
= EFI_SUCCESS
;
3264 InputContext
= Xhc
->UsbDevContext
[SlotId
].InputContext
;
3265 OutputContext
= Xhc
->UsbDevContext
[SlotId
].OutputContext
;
3267 // XHCI 4.6.6 Configure Endpoint
3268 // When this command is used to "Set an Alternate Interface on a device", software shall set the Drop
3269 // Context and Add Context flags as follows:
3270 // 1) If an endpoint is not modified by the Alternate Interface setting, then software shall set the Drop
3271 // Context and Add Context flags to '0'.
3273 // Except the interface indicated by Reqeust->Index, no impact to other interfaces.
3274 // So the default Drop Context and Add Context flags can be '0' to cover 1).
3276 ZeroMem (InputContext
, sizeof (INPUT_CONTEXT
));
3277 CopyMem (&InputContext
->Slot
, &OutputContext
->Slot
, sizeof (SLOT_CONTEXT
));
3279 ASSERT (ConfigDesc
!= NULL
);
3283 IfDescActive
= NULL
;
3286 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)(ConfigDesc
+ 1);
3287 while ((UINTN
) IfDesc
< ((UINTN
) ConfigDesc
+ ConfigDesc
->TotalLength
)) {
3288 if ((IfDesc
->DescriptorType
== USB_DESC_TYPE_INTERFACE
) && (IfDesc
->Length
>= sizeof (USB_INTERFACE_DESCRIPTOR
))) {
3289 if (IfDesc
->InterfaceNumber
== (UINT8
) Request
->Index
) {
3290 if (IfDesc
->AlternateSetting
== Xhc
->UsbDevContext
[SlotId
].ActiveAlternateSetting
[IfDesc
->InterfaceNumber
]) {
3292 // Find out the active interface descriptor.
3294 IfDescActive
= IfDesc
;
3295 } else if (IfDesc
->AlternateSetting
== (UINT8
) Request
->Value
) {
3297 // Find out the interface descriptor to set.
3303 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)((UINTN
)IfDesc
+ IfDesc
->Length
);
3307 // XHCI 4.6.6 Configure Endpoint
3308 // When this command is used to "Set an Alternate Interface on a device", software shall set the Drop
3309 // Context and Add Context flags as follows:
3310 // 2) If an endpoint previously disabled, is enabled by the Alternate Interface setting, then software shall set
3311 // the Drop Context flag to '0' and Add Context flag to '1', and initialize the Input Endpoint Context.
3312 // 3) If an endpoint previously enabled, is disabled by the Alternate Interface setting, then software shall set
3313 // the Drop Context flag to '1' and Add Context flag to '0'.
3314 // 4) If a parameter of an enabled endpoint is modified by an Alternate Interface setting, the Drop Context
3315 // and Add Context flags shall be set to '1'.
3317 // Below codes are to cover 2), 3) and 4).
3320 if ((IfDescActive
!= NULL
) && (IfDescSet
!= NULL
)) {
3321 NumEp
= IfDescActive
->NumEndpoints
;
3322 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*) (IfDescActive
+ 1);
3323 for (EpIndex
= 0; EpIndex
< NumEp
; EpIndex
++) {
3324 while (EpDesc
->DescriptorType
!= USB_DESC_TYPE_ENDPOINT
) {
3325 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
3328 if (EpDesc
->Length
< sizeof (USB_ENDPOINT_DESCRIPTOR
)) {
3329 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
3333 EpAddr
= (UINT8
) (EpDesc
->EndpointAddress
& 0x0F);
3334 Direction
= (UINT8
) ((EpDesc
->EndpointAddress
& 0x80) ? EfiUsbDataIn
: EfiUsbDataOut
);
3336 Dci
= XhcEndpointToDci (EpAddr
, Direction
);
3342 // XHCI 4.3.6 - Setting Alternate Interfaces
3343 // 1) Stop any Running Transfer Rings affected by the Alternate Interface setting.
3345 Status
= XhcStopEndpoint (Xhc
, SlotId
, Dci
);
3346 if (EFI_ERROR (Status
)) {
3350 // XHCI 4.3.6 - Setting Alternate Interfaces
3351 // 2) Free Transfer Rings of all endpoints that will be affected by the Alternate Interface setting.
3353 if (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
- 1] != NULL
) {
3354 RingSeg
= ((TRANSFER_RING
*)(UINTN
)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
- 1])->RingSeg0
;
3355 if (RingSeg
!= NULL
) {
3356 UsbHcFreeMem (Xhc
->MemPool
, RingSeg
, sizeof (TRB_TEMPLATE
) * TR_RING_TRB_NUMBER
);
3358 FreePool (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
- 1]);
3359 Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
- 1] = NULL
;
3363 // Set the Drop Context flag to '1'.
3365 InputContext
->InputControlContext
.Dword1
|= (BIT0
<< Dci
);
3367 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
3371 // XHCI 4.3.6 - Setting Alternate Interfaces
3372 // 3) Clear all the Endpoint Context fields of each endpoint that will be disabled by the Alternate
3373 // Interface setting, to '0'.
3375 // The step 3) has been covered by the ZeroMem () to InputContext at the start of the function.
3379 // XHCI 4.3.6 - Setting Alternate Interfaces
3380 // 4) For each endpoint enabled by the Configure Endpoint Command:
3381 // a. Allocate a Transfer Ring.
3382 // b. Initialize the Transfer Ring Segment(s) by clearing all fields of all TRBs to '0'.
3383 // c. Initialize the Endpoint Context data structure.
3385 Dci
= XhcInitializeEndpointContext (Xhc
, SlotId
, DeviceSpeed
, InputContext
, IfDescSet
);
3390 InputContext
->InputControlContext
.Dword2
|= BIT0
;
3391 InputContext
->Slot
.ContextEntries
= MaxDci
;
3393 // XHCI 4.3.6 - Setting Alternate Interfaces
3394 // 5) Issue and successfully complete a Configure Endpoint Command.
3396 ZeroMem (&CmdTrbCfgEP
, sizeof (CmdTrbCfgEP
));
3397 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, InputContext
, sizeof (INPUT_CONTEXT
));
3398 CmdTrbCfgEP
.PtrLo
= XHC_LOW_32BIT (PhyAddr
);
3399 CmdTrbCfgEP
.PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
3400 CmdTrbCfgEP
.CycleBit
= 1;
3401 CmdTrbCfgEP
.Type
= TRB_TYPE_CON_ENDPOINT
;
3402 CmdTrbCfgEP
.SlotId
= Xhc
->UsbDevContext
[SlotId
].SlotId
;
3403 DEBUG ((EFI_D_INFO
, "SetInterface: Configure Endpoint\n"));
3404 Status
= XhcCmdTransfer (
3406 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbCfgEP
,
3407 XHC_GENERIC_TIMEOUT
,
3408 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
3410 if (EFI_ERROR (Status
)) {
3411 DEBUG ((EFI_D_ERROR
, "SetInterface: Config Endpoint Failed, Status = %r\n", Status
));
3414 // Update the active AlternateSetting.
3416 Xhc
->UsbDevContext
[SlotId
].ActiveAlternateSetting
[(UINT8
) Request
->Index
] = (UINT8
) Request
->Value
;
3424 Set interface through XHCI's Configure_Endpoint cmd.
3426 @param Xhc The XHCI Instance.
3427 @param SlotId The slot id to be configured.
3428 @param DeviceSpeed The device's speed.
3429 @param ConfigDesc The pointer to the usb device configuration descriptor.
3430 @param Request USB device request to send.
3432 @retval EFI_SUCCESS Successfully set interface.
3438 IN USB_XHCI_INSTANCE
*Xhc
,
3440 IN UINT8 DeviceSpeed
,
3441 IN USB_CONFIG_DESCRIPTOR
*ConfigDesc
,
3442 IN EFI_USB_DEVICE_REQUEST
*Request
3446 USB_INTERFACE_DESCRIPTOR
*IfDescActive
;
3447 USB_INTERFACE_DESCRIPTOR
*IfDescSet
;
3448 USB_INTERFACE_DESCRIPTOR
*IfDesc
;
3449 USB_ENDPOINT_DESCRIPTOR
*EpDesc
;
3456 EFI_PHYSICAL_ADDRESS PhyAddr
;
3459 CMD_TRB_CONFIG_ENDPOINT CmdTrbCfgEP
;
3460 INPUT_CONTEXT_64
*InputContext
;
3461 DEVICE_CONTEXT_64
*OutputContext
;
3462 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
3464 Status
= EFI_SUCCESS
;
3466 InputContext
= Xhc
->UsbDevContext
[SlotId
].InputContext
;
3467 OutputContext
= Xhc
->UsbDevContext
[SlotId
].OutputContext
;
3469 // XHCI 4.6.6 Configure Endpoint
3470 // When this command is used to "Set an Alternate Interface on a device", software shall set the Drop
3471 // Context and Add Context flags as follows:
3472 // 1) If an endpoint is not modified by the Alternate Interface setting, then software shall set the Drop
3473 // Context and Add Context flags to '0'.
3475 // Except the interface indicated by Reqeust->Index, no impact to other interfaces.
3476 // So the default Drop Context and Add Context flags can be '0' to cover 1).
3478 ZeroMem (InputContext
, sizeof (INPUT_CONTEXT_64
));
3479 CopyMem (&InputContext
->Slot
, &OutputContext
->Slot
, sizeof (SLOT_CONTEXT_64
));
3481 ASSERT (ConfigDesc
!= NULL
);
3485 IfDescActive
= NULL
;
3488 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)(ConfigDesc
+ 1);
3489 while ((UINTN
) IfDesc
< ((UINTN
) ConfigDesc
+ ConfigDesc
->TotalLength
)) {
3490 if ((IfDesc
->DescriptorType
== USB_DESC_TYPE_INTERFACE
) && (IfDesc
->Length
>= sizeof (USB_INTERFACE_DESCRIPTOR
))) {
3491 if (IfDesc
->InterfaceNumber
== (UINT8
) Request
->Index
) {
3492 if (IfDesc
->AlternateSetting
== Xhc
->UsbDevContext
[SlotId
].ActiveAlternateSetting
[IfDesc
->InterfaceNumber
]) {
3494 // Find out the active interface descriptor.
3496 IfDescActive
= IfDesc
;
3497 } else if (IfDesc
->AlternateSetting
== (UINT8
) Request
->Value
) {
3499 // Find out the interface descriptor to set.
3505 IfDesc
= (USB_INTERFACE_DESCRIPTOR
*)((UINTN
)IfDesc
+ IfDesc
->Length
);
3509 // XHCI 4.6.6 Configure Endpoint
3510 // When this command is used to "Set an Alternate Interface on a device", software shall set the Drop
3511 // Context and Add Context flags as follows:
3512 // 2) If an endpoint previously disabled, is enabled by the Alternate Interface setting, then software shall set
3513 // the Drop Context flag to '0' and Add Context flag to '1', and initialize the Input Endpoint Context.
3514 // 3) If an endpoint previously enabled, is disabled by the Alternate Interface setting, then software shall set
3515 // the Drop Context flag to '1' and Add Context flag to '0'.
3516 // 4) If a parameter of an enabled endpoint is modified by an Alternate Interface setting, the Drop Context
3517 // and Add Context flags shall be set to '1'.
3519 // Below codes are to cover 2), 3) and 4).
3522 if ((IfDescActive
!= NULL
) && (IfDescSet
!= NULL
)) {
3523 NumEp
= IfDescActive
->NumEndpoints
;
3524 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*) (IfDescActive
+ 1);
3525 for (EpIndex
= 0; EpIndex
< NumEp
; EpIndex
++) {
3526 while (EpDesc
->DescriptorType
!= USB_DESC_TYPE_ENDPOINT
) {
3527 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
3530 if (EpDesc
->Length
< sizeof (USB_ENDPOINT_DESCRIPTOR
)) {
3531 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
3535 EpAddr
= (UINT8
) (EpDesc
->EndpointAddress
& 0x0F);
3536 Direction
= (UINT8
) ((EpDesc
->EndpointAddress
& 0x80) ? EfiUsbDataIn
: EfiUsbDataOut
);
3538 Dci
= XhcEndpointToDci (EpAddr
, Direction
);
3544 // XHCI 4.3.6 - Setting Alternate Interfaces
3545 // 1) Stop any Running Transfer Rings affected by the Alternate Interface setting.
3547 Status
= XhcStopEndpoint (Xhc
, SlotId
, Dci
);
3548 if (EFI_ERROR (Status
)) {
3552 // XHCI 4.3.6 - Setting Alternate Interfaces
3553 // 2) Free Transfer Rings of all endpoints that will be affected by the Alternate Interface setting.
3555 if (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
- 1] != NULL
) {
3556 RingSeg
= ((TRANSFER_RING
*)(UINTN
)Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
- 1])->RingSeg0
;
3557 if (RingSeg
!= NULL
) {
3558 UsbHcFreeMem (Xhc
->MemPool
, RingSeg
, sizeof (TRB_TEMPLATE
) * TR_RING_TRB_NUMBER
);
3560 FreePool (Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
- 1]);
3561 Xhc
->UsbDevContext
[SlotId
].EndpointTransferRing
[Dci
- 1] = NULL
;
3565 // Set the Drop Context flag to '1'.
3567 InputContext
->InputControlContext
.Dword1
|= (BIT0
<< Dci
);
3569 EpDesc
= (USB_ENDPOINT_DESCRIPTOR
*)((UINTN
)EpDesc
+ EpDesc
->Length
);
3573 // XHCI 4.3.6 - Setting Alternate Interfaces
3574 // 3) Clear all the Endpoint Context fields of each endpoint that will be disabled by the Alternate
3575 // Interface setting, to '0'.
3577 // The step 3) has been covered by the ZeroMem () to InputContext at the start of the function.
3581 // XHCI 4.3.6 - Setting Alternate Interfaces
3582 // 4) For each endpoint enabled by the Configure Endpoint Command:
3583 // a. Allocate a Transfer Ring.
3584 // b. Initialize the Transfer Ring Segment(s) by clearing all fields of all TRBs to '0'.
3585 // c. Initialize the Endpoint Context data structure.
3587 Dci
= XhcInitializeEndpointContext64 (Xhc
, SlotId
, DeviceSpeed
, InputContext
, IfDescSet
);
3592 InputContext
->InputControlContext
.Dword2
|= BIT0
;
3593 InputContext
->Slot
.ContextEntries
= MaxDci
;
3595 // XHCI 4.3.6 - Setting Alternate Interfaces
3596 // 5) Issue and successfully complete a Configure Endpoint Command.
3598 ZeroMem (&CmdTrbCfgEP
, sizeof (CmdTrbCfgEP
));
3599 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, InputContext
, sizeof (INPUT_CONTEXT_64
));
3600 CmdTrbCfgEP
.PtrLo
= XHC_LOW_32BIT (PhyAddr
);
3601 CmdTrbCfgEP
.PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
3602 CmdTrbCfgEP
.CycleBit
= 1;
3603 CmdTrbCfgEP
.Type
= TRB_TYPE_CON_ENDPOINT
;
3604 CmdTrbCfgEP
.SlotId
= Xhc
->UsbDevContext
[SlotId
].SlotId
;
3605 DEBUG ((EFI_D_INFO
, "SetInterface64: Configure Endpoint\n"));
3606 Status
= XhcCmdTransfer (
3608 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbCfgEP
,
3609 XHC_GENERIC_TIMEOUT
,
3610 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
3612 if (EFI_ERROR (Status
)) {
3613 DEBUG ((EFI_D_ERROR
, "SetInterface64: Config Endpoint Failed, Status = %r\n", Status
));
3616 // Update the active AlternateSetting.
3618 Xhc
->UsbDevContext
[SlotId
].ActiveAlternateSetting
[(UINT8
) Request
->Index
] = (UINT8
) Request
->Value
;
3626 Evaluate the endpoint 0 context through XHCI's Evaluate_Context cmd.
3628 @param Xhc The XHCI Instance.
3629 @param SlotId The slot id to be evaluated.
3630 @param MaxPacketSize The max packet size supported by the device control transfer.
3632 @retval EFI_SUCCESS Successfully evaluate the device endpoint 0.
3637 XhcEvaluateContext (
3638 IN USB_XHCI_INSTANCE
*Xhc
,
3640 IN UINT32 MaxPacketSize
3644 CMD_TRB_EVALUATE_CONTEXT CmdTrbEvalu
;
3645 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
3646 INPUT_CONTEXT
*InputContext
;
3647 EFI_PHYSICAL_ADDRESS PhyAddr
;
3649 ASSERT (Xhc
->UsbDevContext
[SlotId
].SlotId
!= 0);
3652 // 4.6.7 Evaluate Context
3654 InputContext
= Xhc
->UsbDevContext
[SlotId
].InputContext
;
3655 ZeroMem (InputContext
, sizeof (INPUT_CONTEXT
));
3657 InputContext
->InputControlContext
.Dword2
|= BIT1
;
3658 InputContext
->EP
[0].MaxPacketSize
= MaxPacketSize
;
3660 ZeroMem (&CmdTrbEvalu
, sizeof (CmdTrbEvalu
));
3661 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, InputContext
, sizeof (INPUT_CONTEXT
));
3662 CmdTrbEvalu
.PtrLo
= XHC_LOW_32BIT (PhyAddr
);
3663 CmdTrbEvalu
.PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
3664 CmdTrbEvalu
.CycleBit
= 1;
3665 CmdTrbEvalu
.Type
= TRB_TYPE_EVALU_CONTXT
;
3666 CmdTrbEvalu
.SlotId
= Xhc
->UsbDevContext
[SlotId
].SlotId
;
3667 DEBUG ((EFI_D_INFO
, "Evaluate context\n"));
3668 Status
= XhcCmdTransfer (
3670 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbEvalu
,
3671 XHC_GENERIC_TIMEOUT
,
3672 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
3674 if (EFI_ERROR (Status
)) {
3675 DEBUG ((EFI_D_ERROR
, "XhcEvaluateContext: Evaluate Context Failed, Status = %r\n", Status
));
3681 Evaluate the endpoint 0 context through XHCI's Evaluate_Context cmd.
3683 @param Xhc The XHCI Instance.
3684 @param SlotId The slot id to be evaluated.
3685 @param MaxPacketSize The max packet size supported by the device control transfer.
3687 @retval EFI_SUCCESS Successfully evaluate the device endpoint 0.
3692 XhcEvaluateContext64 (
3693 IN USB_XHCI_INSTANCE
*Xhc
,
3695 IN UINT32 MaxPacketSize
3699 CMD_TRB_EVALUATE_CONTEXT CmdTrbEvalu
;
3700 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
3701 INPUT_CONTEXT_64
*InputContext
;
3702 EFI_PHYSICAL_ADDRESS PhyAddr
;
3704 ASSERT (Xhc
->UsbDevContext
[SlotId
].SlotId
!= 0);
3707 // 4.6.7 Evaluate Context
3709 InputContext
= Xhc
->UsbDevContext
[SlotId
].InputContext
;
3710 ZeroMem (InputContext
, sizeof (INPUT_CONTEXT_64
));
3712 InputContext
->InputControlContext
.Dword2
|= BIT1
;
3713 InputContext
->EP
[0].MaxPacketSize
= MaxPacketSize
;
3715 ZeroMem (&CmdTrbEvalu
, sizeof (CmdTrbEvalu
));
3716 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, InputContext
, sizeof (INPUT_CONTEXT_64
));
3717 CmdTrbEvalu
.PtrLo
= XHC_LOW_32BIT (PhyAddr
);
3718 CmdTrbEvalu
.PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
3719 CmdTrbEvalu
.CycleBit
= 1;
3720 CmdTrbEvalu
.Type
= TRB_TYPE_EVALU_CONTXT
;
3721 CmdTrbEvalu
.SlotId
= Xhc
->UsbDevContext
[SlotId
].SlotId
;
3722 DEBUG ((EFI_D_INFO
, "Evaluate context\n"));
3723 Status
= XhcCmdTransfer (
3725 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbEvalu
,
3726 XHC_GENERIC_TIMEOUT
,
3727 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
3729 if (EFI_ERROR (Status
)) {
3730 DEBUG ((EFI_D_ERROR
, "XhcEvaluateContext64: Evaluate Context Failed, Status = %r\n", Status
));
3737 Evaluate the slot context for hub device through XHCI's Configure_Endpoint cmd.
3739 @param Xhc The XHCI Instance.
3740 @param SlotId The slot id to be configured.
3741 @param PortNum The total number of downstream port supported by the hub.
3742 @param TTT The TT think time of the hub device.
3743 @param MTT The multi-TT of the hub device.
3745 @retval EFI_SUCCESS Successfully configure the hub device's slot context.
3749 XhcConfigHubContext (
3750 IN USB_XHCI_INSTANCE
*Xhc
,
3758 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
3759 INPUT_CONTEXT
*InputContext
;
3760 DEVICE_CONTEXT
*OutputContext
;
3761 CMD_TRB_CONFIG_ENDPOINT CmdTrbCfgEP
;
3762 EFI_PHYSICAL_ADDRESS PhyAddr
;
3764 ASSERT (Xhc
->UsbDevContext
[SlotId
].SlotId
!= 0);
3765 InputContext
= Xhc
->UsbDevContext
[SlotId
].InputContext
;
3766 OutputContext
= Xhc
->UsbDevContext
[SlotId
].OutputContext
;
3769 // 4.6.7 Evaluate Context
3771 ZeroMem (InputContext
, sizeof (INPUT_CONTEXT
));
3773 InputContext
->InputControlContext
.Dword2
|= BIT0
;
3776 // Copy the slot context from OutputContext to Input context
3778 CopyMem(&(InputContext
->Slot
), &(OutputContext
->Slot
), sizeof (SLOT_CONTEXT
));
3779 InputContext
->Slot
.Hub
= 1;
3780 InputContext
->Slot
.PortNum
= PortNum
;
3781 InputContext
->Slot
.TTT
= TTT
;
3782 InputContext
->Slot
.MTT
= MTT
;
3784 ZeroMem (&CmdTrbCfgEP
, sizeof (CmdTrbCfgEP
));
3785 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, InputContext
, sizeof (INPUT_CONTEXT
));
3786 CmdTrbCfgEP
.PtrLo
= XHC_LOW_32BIT (PhyAddr
);
3787 CmdTrbCfgEP
.PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
3788 CmdTrbCfgEP
.CycleBit
= 1;
3789 CmdTrbCfgEP
.Type
= TRB_TYPE_CON_ENDPOINT
;
3790 CmdTrbCfgEP
.SlotId
= Xhc
->UsbDevContext
[SlotId
].SlotId
;
3791 DEBUG ((EFI_D_INFO
, "Configure Hub Slot Context\n"));
3792 Status
= XhcCmdTransfer (
3794 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbCfgEP
,
3795 XHC_GENERIC_TIMEOUT
,
3796 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
3798 if (EFI_ERROR (Status
)) {
3799 DEBUG ((EFI_D_ERROR
, "XhcConfigHubContext: Config Endpoint Failed, Status = %r\n", Status
));
3805 Evaluate the slot context for hub device through XHCI's Configure_Endpoint cmd.
3807 @param Xhc The XHCI Instance.
3808 @param SlotId The slot id to be configured.
3809 @param PortNum The total number of downstream port supported by the hub.
3810 @param TTT The TT think time of the hub device.
3811 @param MTT The multi-TT of the hub device.
3813 @retval EFI_SUCCESS Successfully configure the hub device's slot context.
3817 XhcConfigHubContext64 (
3818 IN USB_XHCI_INSTANCE
*Xhc
,
3826 EVT_TRB_COMMAND_COMPLETION
*EvtTrb
;
3827 INPUT_CONTEXT_64
*InputContext
;
3828 DEVICE_CONTEXT_64
*OutputContext
;
3829 CMD_TRB_CONFIG_ENDPOINT CmdTrbCfgEP
;
3830 EFI_PHYSICAL_ADDRESS PhyAddr
;
3832 ASSERT (Xhc
->UsbDevContext
[SlotId
].SlotId
!= 0);
3833 InputContext
= Xhc
->UsbDevContext
[SlotId
].InputContext
;
3834 OutputContext
= Xhc
->UsbDevContext
[SlotId
].OutputContext
;
3837 // 4.6.7 Evaluate Context
3839 ZeroMem (InputContext
, sizeof (INPUT_CONTEXT_64
));
3841 InputContext
->InputControlContext
.Dword2
|= BIT0
;
3844 // Copy the slot context from OutputContext to Input context
3846 CopyMem(&(InputContext
->Slot
), &(OutputContext
->Slot
), sizeof (SLOT_CONTEXT_64
));
3847 InputContext
->Slot
.Hub
= 1;
3848 InputContext
->Slot
.PortNum
= PortNum
;
3849 InputContext
->Slot
.TTT
= TTT
;
3850 InputContext
->Slot
.MTT
= MTT
;
3852 ZeroMem (&CmdTrbCfgEP
, sizeof (CmdTrbCfgEP
));
3853 PhyAddr
= UsbHcGetPciAddrForHostAddr (Xhc
->MemPool
, InputContext
, sizeof (INPUT_CONTEXT_64
));
3854 CmdTrbCfgEP
.PtrLo
= XHC_LOW_32BIT (PhyAddr
);
3855 CmdTrbCfgEP
.PtrHi
= XHC_HIGH_32BIT (PhyAddr
);
3856 CmdTrbCfgEP
.CycleBit
= 1;
3857 CmdTrbCfgEP
.Type
= TRB_TYPE_CON_ENDPOINT
;
3858 CmdTrbCfgEP
.SlotId
= Xhc
->UsbDevContext
[SlotId
].SlotId
;
3859 DEBUG ((EFI_D_INFO
, "Configure Hub Slot Context\n"));
3860 Status
= XhcCmdTransfer (
3862 (TRB_TEMPLATE
*) (UINTN
) &CmdTrbCfgEP
,
3863 XHC_GENERIC_TIMEOUT
,
3864 (TRB_TEMPLATE
**) (UINTN
) &EvtTrb
3866 if (EFI_ERROR (Status
)) {
3867 DEBUG ((EFI_D_ERROR
, "XhcConfigHubContext64: Config Endpoint Failed, Status = %r\n", Status
));