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// Copyright (c) 2000-2009 Nokia Corporation and/or its subsidiary(-ies).
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// All rights reserved.
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// This component and the accompanying materials are made available
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// under the terms of the License "Eclipse Public License v1.0"
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// which accompanies this distribution, and is available
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// at the URL "http://www.eclipse.org/legal/epl-v10.html".
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//
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// Initial Contributors:
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// Nokia Corporation - initial contribution.
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//
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// Contributors:
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//
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// Description:
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// e32/drivers/usbcc/misc.cpp
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// Platform independent layer (PIL) of the USB Device controller driver:
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// Implementations of misc. classes defined in usbc.h.
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//
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//
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/**
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@file misc.cpp
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@internalTechnology
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*/
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#include <drivers/usbc.h>
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/** Helper function for logical endpoints and endpoint descriptors:
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Split single Ep size into separate FS/HS sizes.
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This function modifies its arguments.
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*/
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TInt TUsbcEndpointInfo::AdjustEpSizes(TInt& aEpSize_Fs, TInt& aEpSize_Hs) const
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{
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if (iType == KUsbEpTypeBulk)
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{
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// FS: [8|16|32|64] HS: 512
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if (iSize < 64)
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{
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aEpSize_Fs = iSize;
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}
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else
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{
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aEpSize_Fs = 64;
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}
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aEpSize_Hs = 512;
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}
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else if (iType == KUsbEpTypeInterrupt)
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{
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// FS: [0..64] HS: [0..1024]
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if (iSize < 64)
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{
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aEpSize_Fs = iSize;
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}
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else
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{
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aEpSize_Fs = 64;
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}
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aEpSize_Hs = iSize;
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}
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else if (iType == KUsbEpTypeIsochronous)
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{
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// FS: [0..1023] HS: [0..1024]
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if (iSize < 1023)
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{
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aEpSize_Fs = iSize;
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}
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else
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{
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aEpSize_Fs = 1023;
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}
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aEpSize_Hs = iSize;
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}
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else if (iType == KUsbEpTypeControl)
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{
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// FS: [8|16|32|64] HS: 64
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if (iSize < 64)
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{
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aEpSize_Fs = iSize;
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}
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else
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{
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aEpSize_Fs = 64;
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}
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aEpSize_Hs = 64;
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}
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else
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{
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aEpSize_Fs = aEpSize_Hs = 0;
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return KErrGeneral;
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}
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// For the reason of the following checks see Table 9-14. "Allowed wMaxPacketSize
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// Values for Different Numbers of Transactions per Microframe".
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if ((iType == KUsbEpTypeInterrupt) || (iType == KUsbEpTypeIsochronous))
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{
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if (iTransactions == 1)
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{
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if (aEpSize_Hs < 513)
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{
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__KTRACE_OPT(KPANIC, Kern::Printf(" Warning: Ep size too small: %d < 513. Correcting...",
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aEpSize_Hs));
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aEpSize_Hs = 513;
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}
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}
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else if (iTransactions == 2)
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{
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if (aEpSize_Hs < 683)
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{
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__KTRACE_OPT(KPANIC, Kern::Printf(" Warning: Ep size too small: %d < 683. Correcting...",
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aEpSize_Hs));
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aEpSize_Hs = 683;
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}
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}
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}
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return KErrNone;
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}
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/** Helper function for logical endpoints and endpoint descriptors:
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If not set, assign a valid and meaningful value to iInterval_Hs, deriving from iInterval.
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This function modifies the objects's data member(s).
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*/
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TInt TUsbcEndpointInfo::AdjustPollInterval()
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{
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if (iInterval_Hs != -1)
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{
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// Already done.
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return KErrNone;
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}
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if ((iType == KUsbEpTypeBulk) || (iType == KUsbEpTypeControl))
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{
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// Valid range: 0..255 (maximum NAK rate).
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// (The host controller will probably ignore this value though -
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// see the last sentence of section 9.6.6 for details.)
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iInterval_Hs = 255;
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}
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else if (iType == KUsbEpTypeInterrupt)
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{
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// HS interval = 2^(iInterval_Hs-1) with a valid iInterval_Hs range of 1..16.
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// The following table shows the mapping of HS values to actual intervals (and
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// thus FS values) for the range of possible FS values (1..255).
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// There is not always a 1:1 mapping possible, but we want at least to make sure
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// that the HS polling interval is never longer than the FS one (except for 255).
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//
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// 1 = 1
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// 2 = 2
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// 3 = 4
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// 4 = 8
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// 5 = 16
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// 6 = 32
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// 7 = 64
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// 8 = 128
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// 9 = 256
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if (iInterval == 255)
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iInterval_Hs = 9;
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else if (iInterval >= 128)
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iInterval_Hs = 8;
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else if (iInterval >= 64)
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iInterval_Hs = 7;
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else if (iInterval >= 32)
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iInterval_Hs = 6;
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else if (iInterval >= 16)
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iInterval_Hs = 5;
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else if (iInterval >= 8)
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iInterval_Hs = 4;
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else if (iInterval >= 4)
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iInterval_Hs = 3;
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else if (iInterval >= 2)
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iInterval_Hs = 2;
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else if (iInterval == 1)
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iInterval_Hs = 1;
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else
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{
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// iInterval wasn't set properly by the user
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iInterval_Hs = 1;
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return KErrGeneral;
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}
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}
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else if (iType == KUsbEpTypeIsochronous)
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{
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// Interpretation is the same for FS and HS.
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iInterval_Hs = iInterval;
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}
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else
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{
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// '1' is a valid value for all endpoint types...
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iInterval_Hs = 1;
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return KErrGeneral;
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}
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return KErrNone;
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}
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TUsbcPhysicalEndpoint::TUsbcPhysicalEndpoint()
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: iEndpointAddr(0), iIfcNumber(NULL), iLEndpoint(NULL), iSettingReserve(EFalse), iHalt(EFalse)
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{
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__KTRACE_OPT(KUSB, Kern::Printf("TUsbcPhysicalEndpoint::TUsbcPhysicalEndpoint"));
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}
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TInt TUsbcPhysicalEndpoint::TypeAvailable(TUint aType) const
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{
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__KTRACE_OPT(KUSB, Kern::Printf("TUsbcPhysicalEndpoint::TypeAvailable"));
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switch (aType)
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{
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case KUsbEpTypeControl:
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return (iCaps.iTypesAndDir & KUsbEpTypeControl);
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case KUsbEpTypeIsochronous:
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return (iCaps.iTypesAndDir & KUsbEpTypeIsochronous);
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case KUsbEpTypeBulk:
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return (iCaps.iTypesAndDir & KUsbEpTypeBulk);
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case KUsbEpTypeInterrupt:
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return (iCaps.iTypesAndDir & KUsbEpTypeInterrupt);
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default:
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__KTRACE_OPT(KPANIC, Kern::Printf(" Error: invalid EP type: %d", aType));
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return 0;
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}
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}
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TInt TUsbcPhysicalEndpoint::DirAvailable(TUint aDir) const
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{
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__KTRACE_OPT(KUSB, Kern::Printf("TUsbcPhysicalEndpoint::DirAvailable"));
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switch (aDir)
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{
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case KUsbEpDirIn:
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return (iCaps.iTypesAndDir & KUsbEpDirIn);
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case KUsbEpDirOut:
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return (iCaps.iTypesAndDir & KUsbEpDirOut);
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default:
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__KTRACE_OPT(KPANIC, Kern::Printf(" Error: invalid EP direction: %d", aDir));
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return 0;
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}
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}
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TInt TUsbcPhysicalEndpoint::EndpointSuitable(const TUsbcEndpointInfo* aEpInfo, TInt aIfcNumber) const
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{
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__KTRACE_OPT(KUSB, Kern::Printf("TUsbcPhysicalEndpoint::EndpointSuitable"));
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__KTRACE_OPT(KUSB, Kern::Printf(" looking for EP: type=0x%x dir=0x%x size=%d (ifc_num=%d)",
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aEpInfo->iType, aEpInfo->iDir, aEpInfo->iSize, aIfcNumber));
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if (iSettingReserve)
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{
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__KTRACE_OPT(KUSB, Kern::Printf(" -> setting conflict"));
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return 0;
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}
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// (aIfcNumber == -1) means the ep is for a new default interface setting
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else if (iIfcNumber && (*iIfcNumber != aIfcNumber))
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{
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// If this endpoint has already been claimed (iIfcNumber != NULL),
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// but by a different interface(-set) than the currently looking one
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// (*iIfcNumber != aIfcNumber), then it's not available.
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// This works because we can assign the same physical endpoint
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// to different alternate settings of the *same* interface, and
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// because we check for available endpoints for every alternate setting
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// as a whole.
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__KTRACE_OPT(KUSB, Kern::Printf(" -> ifc conflict"));
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return 0;
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}
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else if (!TypeAvailable(aEpInfo->iType))
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{
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__KTRACE_OPT(KUSB, Kern::Printf(" -> type conflict"));
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return 0;
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}
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else if (!DirAvailable(aEpInfo->iDir))
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{
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__KTRACE_OPT(KUSB, Kern::Printf(" -> direction conflict"));
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return 0;
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}
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else if (!(iCaps.iSizes & PacketSize2Mask(aEpInfo->iSize)) && !(iCaps.iSizes & KUsbEpSizeCont))
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{
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__KTRACE_OPT(KUSB, Kern::Printf(" -> size conflict"));
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return 0;
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}
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else
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return 1;
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}
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TUsbcPhysicalEndpoint::~TUsbcPhysicalEndpoint()
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{
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__KTRACE_OPT(KUSB, Kern::Printf("TUsbcPhysicalEndpoint::~TUsbcPhysicalEndpoint()"));
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iLEndpoint = NULL;
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}
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TUsbcLogicalEndpoint::TUsbcLogicalEndpoint(DUsbClientController* aController, TUint aEndpointNum,
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const TUsbcEndpointInfo& aEpInfo, TUsbcInterface* aInterface,
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TUsbcPhysicalEndpoint* aPEndpoint)
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: iController(aController), iLEndpointNum(aEndpointNum), iInfo(aEpInfo), iInterface(aInterface),
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iPEndpoint(aPEndpoint)
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{
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__KTRACE_OPT(KUSB, Kern::Printf("TUsbcLogicalEndpoint::TUsbcLogicalEndpoint()"));
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// Adjust FS/HS endpoint sizes
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if (iInfo.AdjustEpSizes(iEpSize_Fs, iEpSize_Hs) != KErrNone)
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{
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__KTRACE_OPT(KPANIC, Kern::Printf(" Error: Unknown endpoint type: %d", iInfo.iType));
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}
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__KTRACE_OPT(KUSB, Kern::Printf(" Now set: iEpSize_Fs=%d iEpSize_Hs=%d (iInfo.iSize=%d)",
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iEpSize_Fs, iEpSize_Hs, iInfo.iSize));
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// Adjust HS polling interval
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if (iInfo.AdjustPollInterval() != KErrNone)
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{
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__KTRACE_OPT(KPANIC, Kern::Printf(" Error: Unknown ep type (%d) or invalid interval value (%d)",
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iInfo.iType, iInfo.iInterval));
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}
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__KTRACE_OPT(KUSB, Kern::Printf(" Now set: iInfo.iInterval=%d iInfo.iInterval_Hs=%d",
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iInfo.iInterval, iInfo.iInterval_Hs));
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// Additional transactions requested on a non High Bandwidth ep?
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if ((iInfo.iTransactions > 0) && !aPEndpoint->iCaps.iHighBandwidth)
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{
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__KTRACE_OPT(KPANIC,
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Kern::Printf(" Warning: Additional transactions requested but not a High Bandwidth ep"));
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}
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}
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TUsbcLogicalEndpoint::~TUsbcLogicalEndpoint()
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{
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__KTRACE_OPT(KUSB, Kern::Printf("TUsbcLogicalEndpoint::~TUsbcLogicalEndpoint: #%d", iLEndpointNum));
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// If the real endpoint this endpoint points to is also used by
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// any other logical endpoint in any other setting of this interface
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// then we leave the real endpoint marked as used. Otherwise we mark
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324 |
// it as available (set its ifc number pointer to NULL).
|
sl@0
|
325 |
const TInt n = iInterface->iInterfaceSet->iInterfaces.Count();
|
sl@0
|
326 |
for (TInt i = 0; i < n; ++i)
|
sl@0
|
327 |
{
|
sl@0
|
328 |
const TUsbcInterface* const ifc = iInterface->iInterfaceSet->iInterfaces[i];
|
sl@0
|
329 |
const TInt m = ifc->iEndpoints.Count();
|
sl@0
|
330 |
for (TInt j = 0; j < m; ++j)
|
sl@0
|
331 |
{
|
sl@0
|
332 |
const TUsbcLogicalEndpoint* const ep = ifc->iEndpoints[j];
|
sl@0
|
333 |
if ((ep->iPEndpoint == iPEndpoint) && (ep != this))
|
sl@0
|
334 |
{
|
sl@0
|
335 |
__KTRACE_OPT(KUSB, Kern::Printf(" Physical endpoint still in use -> we leave it as is"));
|
sl@0
|
336 |
return;
|
sl@0
|
337 |
}
|
sl@0
|
338 |
}
|
sl@0
|
339 |
}
|
sl@0
|
340 |
__KTRACE_OPT(KUSB, Kern::Printf(" Closing DMA channel"));
|
sl@0
|
341 |
const TInt idx = iController->EpAddr2Idx(iPEndpoint->iEndpointAddr);
|
sl@0
|
342 |
// If the endpoint doesn't support DMA (now or ever) the next operation will be a no-op.
|
sl@0
|
343 |
iController->CloseDmaChannel(idx);
|
sl@0
|
344 |
__KTRACE_OPT(KUSB, Kern::Printf(" Setting physical ep 0x%02x ifc number to NULL (was %d)",
|
sl@0
|
345 |
iPEndpoint->iEndpointAddr, *iPEndpoint->iIfcNumber));
|
sl@0
|
346 |
iPEndpoint->iIfcNumber = NULL;
|
sl@0
|
347 |
}
|
sl@0
|
348 |
|
sl@0
|
349 |
|
sl@0
|
350 |
TUsbcInterface::TUsbcInterface(TUsbcInterfaceSet* aIfcSet, TUint8 aSetting, TBool aNoEp0Requests)
|
sl@0
|
351 |
: iEndpoints(2), iInterfaceSet(aIfcSet), iSettingCode(aSetting), iNoEp0Requests(aNoEp0Requests)
|
sl@0
|
352 |
{
|
sl@0
|
353 |
__KTRACE_OPT(KUSB, Kern::Printf("TUsbcInterface::TUsbcInterface()"));
|
sl@0
|
354 |
}
|
sl@0
|
355 |
|
sl@0
|
356 |
|
sl@0
|
357 |
TUsbcInterface::~TUsbcInterface()
|
sl@0
|
358 |
{
|
sl@0
|
359 |
__KTRACE_OPT(KUSB, Kern::Printf("TUsbcInterface::~TUsbcInterface()"));
|
sl@0
|
360 |
iEndpoints.ResetAndDestroy();
|
sl@0
|
361 |
}
|
sl@0
|
362 |
|
sl@0
|
363 |
|
sl@0
|
364 |
TUsbcInterfaceSet::TUsbcInterfaceSet(const DBase* aClientId, TUint8 aIfcNum)
|
sl@0
|
365 |
: iInterfaces(2), iClientId(aClientId), iInterfaceNumber(aIfcNum), iCurrentInterface(0)
|
sl@0
|
366 |
{
|
sl@0
|
367 |
__KTRACE_OPT(KUSB, Kern::Printf("TUsbcInterfaceSet::TUsbcInterfaceSet()"));
|
sl@0
|
368 |
}
|
sl@0
|
369 |
|
sl@0
|
370 |
|
sl@0
|
371 |
TUsbcInterfaceSet::~TUsbcInterfaceSet()
|
sl@0
|
372 |
{
|
sl@0
|
373 |
__KTRACE_OPT(KUSB, Kern::Printf("TUsbcInterfaceSet::~TUsbcInterfaceSet()"));
|
sl@0
|
374 |
iInterfaces.ResetAndDestroy();
|
sl@0
|
375 |
}
|
sl@0
|
376 |
|
sl@0
|
377 |
|
sl@0
|
378 |
TUsbcConfiguration::TUsbcConfiguration(TUint8 aConfigVal)
|
sl@0
|
379 |
: iInterfaceSets(1), iConfigValue(aConfigVal) // iInterfaceSets(1): granularity
|
sl@0
|
380 |
{
|
sl@0
|
381 |
__KTRACE_OPT(KUSB, Kern::Printf("TUsbcConfiguration::TUsbcConfiguration()"));
|
sl@0
|
382 |
}
|
sl@0
|
383 |
|
sl@0
|
384 |
|
sl@0
|
385 |
TUsbcConfiguration::~TUsbcConfiguration()
|
sl@0
|
386 |
{
|
sl@0
|
387 |
__KTRACE_OPT(KUSB, Kern::Printf("TUsbcConfiguration::~TUsbcConfiguration()"));
|
sl@0
|
388 |
iInterfaceSets.ResetAndDestroy();
|
sl@0
|
389 |
}
|
sl@0
|
390 |
|
sl@0
|
391 |
|
sl@0
|
392 |
_LIT(KDriverName, "Usbcc");
|
sl@0
|
393 |
|
sl@0
|
394 |
DUsbcPowerHandler::DUsbcPowerHandler(DUsbClientController* aController)
|
sl@0
|
395 |
: DPowerHandler(KDriverName), iController(aController)
|
sl@0
|
396 |
{}
|
sl@0
|
397 |
|
sl@0
|
398 |
|
sl@0
|
399 |
void DUsbcPowerHandler::PowerUp()
|
sl@0
|
400 |
{
|
sl@0
|
401 |
if (iController)
|
sl@0
|
402 |
iController->iPowerUpDfc.Enque();
|
sl@0
|
403 |
}
|
sl@0
|
404 |
|
sl@0
|
405 |
|
sl@0
|
406 |
void DUsbcPowerHandler::PowerDown(TPowerState)
|
sl@0
|
407 |
{
|
sl@0
|
408 |
if (iController)
|
sl@0
|
409 |
iController->iPowerDownDfc.Enque();
|
sl@0
|
410 |
}
|
sl@0
|
411 |
|
sl@0
|
412 |
|
sl@0
|
413 |
// -eof-
|