/** @file PEIM to produce gPeiUsb2HostControllerPpiGuid based on gPeiUsbControllerPpiGuid which is used to enable recovery function from USB Drivers. Copyright (c) 2010 - 2018, Intel Corporation. All rights reserved.
SPDX-License-Identifier: BSD-2-Clause-Patent **/ #include "EhcPeim.h" /** Delete a single asynchronous interrupt transfer for the device and endpoint. @param Ehc The EHCI device. @param Data Current data not associated with a QTD. @param DataLen The length of the data. @param PktId Packet ID to use in the QTD. @param Toggle Data toggle to use in the QTD. @param MaxPacket Maximu packet length of the endpoint. @retval the pointer to the created QTD or NULL if failed to create one. **/ PEI_EHC_QTD * EhcCreateQtd ( IN PEI_USB2_HC_DEV *Ehc, IN UINT8 *Data, IN UINTN DataLen, IN UINT8 PktId, IN UINT8 Toggle, IN UINTN MaxPacket ) { PEI_EHC_QTD *Qtd; QTD_HW *QtdHw; UINTN Index; UINTN Len; UINTN ThisBufLen; ASSERT (Ehc != NULL); Qtd = UsbHcAllocateMem (Ehc, Ehc->MemPool, sizeof (PEI_EHC_QTD)); if (Qtd == NULL) { return NULL; } Qtd->Signature = EHC_QTD_SIG; Qtd->Data = Data; Qtd->DataLen = 0; InitializeListHead (&Qtd->QtdList); QtdHw = &Qtd->QtdHw; QtdHw->NextQtd = QTD_LINK (NULL, TRUE); QtdHw->AltNext = QTD_LINK (NULL, TRUE); QtdHw->Status = QTD_STAT_ACTIVE; QtdHw->Pid = PktId; QtdHw->ErrCnt = QTD_MAX_ERR; QtdHw->Ioc = 0; QtdHw->TotalBytes = 0; QtdHw->DataToggle = Toggle; // // Fill in the buffer points // if (Data != NULL) { Len = 0; for (Index = 0; Index <= QTD_MAX_BUFFER; Index++) { // // Set the buffer point (Check page 41 EHCI Spec 1.0). No need to // compute the offset and clear Reserved fields. This is already // done in the data point. // QtdHw->Page[Index] = EHC_LOW_32BIT (Data); QtdHw->PageHigh[Index] = EHC_HIGH_32BIT (Data); ThisBufLen = QTD_BUF_LEN - (EHC_LOW_32BIT (Data) & QTD_BUF_MASK); if (Len + ThisBufLen >= DataLen) { Len = DataLen; break; } Len += ThisBufLen; Data += ThisBufLen; } // // Need to fix the last pointer if the Qtd can't hold all the // user's data to make sure that the length is in the unit of // max packets. If it can hold all the data, there is no such // need. // if (Len < DataLen) { Len = Len - Len % MaxPacket; } QtdHw->TotalBytes = (UINT32) Len; Qtd->DataLen = Len; } return Qtd; } /** Initialize the queue head for interrupt transfer, that is, initialize the following three fields: 1. SplitXState in the Status field. 2. Microframe S-mask. 3. Microframe C-mask. @param Ep The queue head's related endpoint. @param QhHw The queue head to initialize. **/ VOID EhcInitIntQh ( IN USB_ENDPOINT *Ep, IN QH_HW *QhHw ) { // // Because UEFI interface can't utilitize an endpoint with // poll rate faster than 1ms, only need to set one bit in // the queue head. simple. But it may be changed later. If // sub-1ms interrupt is supported, need to update the S-Mask // here // if (Ep->DevSpeed == EFI_USB_SPEED_HIGH) { QhHw->SMask = QH_MICROFRAME_0; return ; } // // For low/full speed device, the transfer must go through // the split transaction. Need to update three fields // 1. SplitXState in the status // 2. Microframe S-Mask // 3. Microframe C-Mask // UEFI USB doesn't exercise admission control. It simplely // schedule the high speed transactions in microframe 0, and // full/low speed transactions at microframe 1. This also // avoid the use of FSTN. // QhHw->SMask = QH_MICROFRAME_1; QhHw->CMask = QH_MICROFRAME_3 | QH_MICROFRAME_4 | QH_MICROFRAME_5; } /** Allocate and initialize a EHCI queue head. @param Ehci The EHCI device. @param Ep The endpoint to create queue head for. @retval the pointer to the created queue head or NULL if failed to create one. **/ PEI_EHC_QH * EhcCreateQh ( IN PEI_USB2_HC_DEV *Ehci, IN USB_ENDPOINT *Ep ) { PEI_EHC_QH *Qh; QH_HW *QhHw; Qh = UsbHcAllocateMem (Ehci, Ehci->MemPool, sizeof (PEI_EHC_QH)); if (Qh == NULL) { return NULL; } Qh->Signature = EHC_QH_SIG; Qh->NextQh = NULL; Qh->Interval = Ep->PollRate; InitializeListHead (&Qh->Qtds); QhHw = &Qh->QhHw; QhHw->HorizonLink = QH_LINK (NULL, 0, TRUE); QhHw->DeviceAddr = Ep->DevAddr; QhHw->Inactive = 0; QhHw->EpNum = Ep->EpAddr; QhHw->EpSpeed = Ep->DevSpeed; QhHw->DtCtrl = 0; QhHw->ReclaimHead = 0; QhHw->MaxPacketLen = (UINT32) Ep->MaxPacket; QhHw->CtrlEp = 0; QhHw->NakReload = QH_NAK_RELOAD; QhHw->HubAddr = Ep->HubAddr; QhHw->PortNum = Ep->HubPort; QhHw->Multiplier = 1; QhHw->DataToggle = Ep->Toggle; if (Ep->DevSpeed != EFI_USB_SPEED_HIGH) { QhHw->Status |= QTD_STAT_DO_SS; } switch (Ep->Type) { case EHC_CTRL_TRANSFER: // // Special initialization for the control transfer: // 1. Control transfer initialize data toggle from each QTD // 2. Set the Control Endpoint Flag (C) for low/full speed endpoint. // QhHw->DtCtrl = 1; if (Ep->DevSpeed != EFI_USB_SPEED_HIGH) { QhHw->CtrlEp = 1; } break; case EHC_INT_TRANSFER_ASYNC: case EHC_INT_TRANSFER_SYNC: // // Special initialization for the interrupt transfer // to set the S-Mask and C-Mask // QhHw->NakReload = 0; EhcInitIntQh (Ep, QhHw); break; case EHC_BULK_TRANSFER: if ((Ep->DevSpeed == EFI_USB_SPEED_HIGH) && (Ep->Direction == EfiUsbDataOut)) { QhHw->Status |= QTD_STAT_DO_PING; } break; } return Qh; } /** Convert the poll interval from application to that be used by EHCI interface data structure. Only need to get the max 2^n that is less than interval. UEFI can't support high speed endpoint with a interval less than 8 microframe because interval is specified in the unit of ms (millisecond). @param Interval The interval to convert. @retval The converted interval. **/ UINTN EhcConvertPollRate ( IN UINTN Interval ) { UINTN BitCount; if (Interval == 0) { return 1; } // // Find the index (1 based) of the highest non-zero bit // BitCount = 0; while (Interval != 0) { Interval >>= 1; BitCount++; } return (UINTN)1 << (BitCount - 1); } /** Free a list of QTDs. @param Ehc The EHCI device. @param Qtds The list head of the QTD. **/ VOID EhcFreeQtds ( IN PEI_USB2_HC_DEV *Ehc, IN EFI_LIST_ENTRY *Qtds ) { EFI_LIST_ENTRY *Entry; EFI_LIST_ENTRY *Next; PEI_EHC_QTD *Qtd; EFI_LIST_FOR_EACH_SAFE (Entry, Next, Qtds) { Qtd = EFI_LIST_CONTAINER (Entry, PEI_EHC_QTD, QtdList); RemoveEntryList (&Qtd->QtdList); UsbHcFreeMem (Ehc, Ehc->MemPool, Qtd, sizeof (PEI_EHC_QTD)); } } /** Free an allocated URB. It is possible for it to be partially inited. @param Ehc The EHCI device. @param Urb The URB to free. **/ VOID EhcFreeUrb ( IN PEI_USB2_HC_DEV *Ehc, IN PEI_URB *Urb ) { if (Urb->RequestPhy != NULL) { IoMmuUnmap (Ehc->IoMmu, Urb->RequestMap); } if (Urb->DataMap != NULL) { IoMmuUnmap (Ehc->IoMmu, Urb->DataMap); } if (Urb->Qh != NULL) { // // Ensure that this queue head has been unlinked from the // schedule data structures. Free all the associated QTDs // EhcFreeQtds (Ehc, &Urb->Qh->Qtds); UsbHcFreeMem (Ehc, Ehc->MemPool, Urb->Qh, sizeof (PEI_EHC_QH)); } } /** Create a list of QTDs for the URB. @param Ehc The EHCI device. @param Urb The URB to create QTDs for. @retval EFI_OUT_OF_RESOURCES Failed to allocate resource for QTD. @retval EFI_SUCCESS The QTDs are allocated for the URB. **/ EFI_STATUS EhcCreateQtds ( IN PEI_USB2_HC_DEV *Ehc, IN PEI_URB *Urb ) { USB_ENDPOINT *Ep; PEI_EHC_QH *Qh; PEI_EHC_QTD *Qtd; PEI_EHC_QTD *StatusQtd; PEI_EHC_QTD *NextQtd; EFI_LIST_ENTRY *Entry; UINT32 AlterNext; UINT8 Toggle; UINTN Len; UINT8 Pid; ASSERT ((Urb != NULL) && (Urb->Qh != NULL)); // // EHCI follows the alternet next QTD pointer if it meets // a short read and the AlterNext pointer is valid. UEFI // EHCI driver should terminate the transfer except the // control transfer. // Toggle = 0; Qh = Urb->Qh; Ep = &Urb->Ep; StatusQtd = NULL; AlterNext = QTD_LINK (NULL, TRUE); if (Ep->Direction == EfiUsbDataIn) { AlterNext = QTD_LINK (Ehc->ShortReadStop, FALSE); } // // Build the Setup and status packets for control transfer // if (Urb->Ep.Type == EHC_CTRL_TRANSFER) { Len = sizeof (EFI_USB_DEVICE_REQUEST); Qtd = EhcCreateQtd (Ehc, Urb->RequestPhy, Len, QTD_PID_SETUP, 0, Ep->MaxPacket); if (Qtd == NULL) { return EFI_OUT_OF_RESOURCES; } InsertTailList (&Qh->Qtds, &Qtd->QtdList); // // Create the status packet now. Set the AlterNext to it. So, when // EHCI meets a short control read, it can resume at the status stage. // Use the opposite direction of the data stage, or IN if there is // no data stage. // if (Ep->Direction == EfiUsbDataIn) { Pid = QTD_PID_OUTPUT; } else { Pid = QTD_PID_INPUT; } StatusQtd = EhcCreateQtd (Ehc, NULL, 0, Pid, 1, Ep->MaxPacket); if (StatusQtd == NULL) { goto ON_ERROR; } if (Ep->Direction == EfiUsbDataIn) { AlterNext = QTD_LINK (StatusQtd, FALSE); } Toggle = 1; } // // Build the data packets for all the transfers // if (Ep->Direction == EfiUsbDataIn) { Pid = QTD_PID_INPUT; } else { Pid = QTD_PID_OUTPUT; } Qtd = NULL; Len = 0; while (Len < Urb->DataLen) { Qtd = EhcCreateQtd ( Ehc, (UINT8 *) Urb->DataPhy + Len, Urb->DataLen - Len, Pid, Toggle, Ep->MaxPacket ); if (Qtd == NULL) { goto ON_ERROR; } Qtd->QtdHw.AltNext = AlterNext; InsertTailList (&Qh->Qtds, &Qtd->QtdList); // // Switch the Toggle bit if odd number of packets are included in the QTD. // if (((Qtd->DataLen + Ep->MaxPacket - 1) / Ep->MaxPacket) % 2) { Toggle = (UINT8) (1 - Toggle); } Len += Qtd->DataLen; } // // Insert the status packet for control transfer // if (Ep->Type == EHC_CTRL_TRANSFER) { InsertTailList (&Qh->Qtds, &StatusQtd->QtdList); } // // OK, all the QTDs needed are created. Now, fix the NextQtd point // EFI_LIST_FOR_EACH (Entry, &Qh->Qtds) { Qtd = EFI_LIST_CONTAINER (Entry, PEI_EHC_QTD, QtdList); // // break if it is the last entry on the list // if (Entry->ForwardLink == &Qh->Qtds) { break; } NextQtd = EFI_LIST_CONTAINER (Entry->ForwardLink, PEI_EHC_QTD, QtdList); Qtd->QtdHw.NextQtd = QTD_LINK (NextQtd, FALSE); } // // Link the QTDs to the queue head // NextQtd = EFI_LIST_CONTAINER (Qh->Qtds.ForwardLink, PEI_EHC_QTD, QtdList); Qh->QhHw.NextQtd = QTD_LINK (NextQtd, FALSE); return EFI_SUCCESS; ON_ERROR: EhcFreeQtds (Ehc, &Qh->Qtds); return EFI_OUT_OF_RESOURCES; } /** Create a new URB and its associated QTD. @param Ehc The EHCI device. @param DevAddr The device address. @param EpAddr Endpoint addrress & its direction. @param DevSpeed The device speed. @param Toggle Initial data toggle to use. @param MaxPacket The max packet length of the endpoint. @param Hub The transaction translator to use. @param Type The transaction type. @param Request The standard USB request for control transfer. @param Data The user data to transfer. @param DataLen The length of data buffer. @param Callback The function to call when data is transferred. @param Context The context to the callback. @param Interval The interval for interrupt transfer. @retval the pointer to the created URB or NULL. **/ PEI_URB * EhcCreateUrb ( IN PEI_USB2_HC_DEV *Ehc, IN UINT8 DevAddr, IN UINT8 EpAddr, IN UINT8 DevSpeed, IN UINT8 Toggle, IN UINTN MaxPacket, IN EFI_USB2_HC_TRANSACTION_TRANSLATOR *Hub, IN UINTN Type, IN EFI_USB_DEVICE_REQUEST *Request, IN VOID *Data, IN UINTN DataLen, IN EFI_ASYNC_USB_TRANSFER_CALLBACK Callback, IN VOID *Context, IN UINTN Interval ) { USB_ENDPOINT *Ep; EFI_PHYSICAL_ADDRESS PhyAddr; EDKII_IOMMU_OPERATION MapOp; EFI_STATUS Status; UINTN Len; PEI_URB *Urb; VOID *Map; Urb = Ehc->Urb; Urb->Signature = EHC_URB_SIG; InitializeListHead (&Urb->UrbList); Ep = &Urb->Ep; Ep->DevAddr = DevAddr; Ep->EpAddr = (UINT8) (EpAddr & 0x0F); Ep->Direction = (((EpAddr & 0x80) != 0) ? EfiUsbDataIn : EfiUsbDataOut); Ep->DevSpeed = DevSpeed; Ep->MaxPacket = MaxPacket; Ep->HubAddr = 0; Ep->HubPort = 0; if (DevSpeed != EFI_USB_SPEED_HIGH) { ASSERT (Hub != NULL); Ep->HubAddr = Hub->TranslatorHubAddress; Ep->HubPort = Hub->TranslatorPortNumber; } Ep->Toggle = Toggle; Ep->Type = Type; Ep->PollRate = EhcConvertPollRate (Interval); Urb->Request = Request; Urb->Data = Data; Urb->DataLen = DataLen; Urb->Callback = Callback; Urb->Context = Context; Urb->Qh = EhcCreateQh (Ehc, &Urb->Ep); if (Urb->Qh == NULL) { goto ON_ERROR; } Urb->RequestPhy = NULL; Urb->RequestMap = NULL; Urb->DataPhy = NULL; Urb->DataMap = NULL; // // Map the request and user data // if (Request != NULL) { Len = sizeof (EFI_USB_DEVICE_REQUEST); MapOp = EdkiiIoMmuOperationBusMasterRead; Status = IoMmuMap (Ehc->IoMmu, MapOp, Request, &Len, &PhyAddr, &Map); if (EFI_ERROR (Status) || (Len != sizeof (EFI_USB_DEVICE_REQUEST))) { goto ON_ERROR; } Urb->RequestPhy = (VOID *) ((UINTN) PhyAddr); Urb->RequestMap = Map; } if (Data != NULL) { Len = DataLen; if (Ep->Direction == EfiUsbDataIn) { MapOp = EdkiiIoMmuOperationBusMasterWrite; } else { MapOp = EdkiiIoMmuOperationBusMasterRead; } Status = IoMmuMap (Ehc->IoMmu, MapOp, Data, &Len, &PhyAddr, &Map); if (EFI_ERROR (Status) || (Len != DataLen)) { goto ON_ERROR; } Urb->DataPhy = (VOID *) ((UINTN) PhyAddr); Urb->DataMap = Map; } Status = EhcCreateQtds (Ehc, Urb); if (EFI_ERROR (Status)) { goto ON_ERROR; } return Urb; ON_ERROR: EhcFreeUrb (Ehc, Urb); return NULL; }