Symaptic: os/kernelhwsrv/kernel/eka/drivers/pbus/pccard/spccard.cpp@260cb5ec6c19 (annotated)

sl@0	1	// Copyright (c) 1998-2009 Nokia Corporation and/or its subsidiary(-ies).
sl@0	2	// All rights reserved.
sl@0	3	// This component and the accompanying materials are made available
sl@0	4	// under the terms of the License "Eclipse Public License v1.0"
sl@0	5	// which accompanies this distribution, and is available
sl@0	6	// at the URL "http://www.eclipse.org/legal/epl-v10.html".
sl@0	7	//
sl@0	8	// Initial Contributors:
sl@0	9	// Nokia Corporation - initial contribution.
sl@0	10	//
sl@0	11	// Contributors:
sl@0	12	//
sl@0	13	// Description:
sl@0	14	// e32\drivers\pbus\pccard\spccard.cpp
sl@0	15	//
sl@0	16	//
sl@0	17
sl@0	18	#include <pccard.h>
sl@0	19	#include "cis.h"
sl@0	20
sl@0	21	LOCAL_D const TPccdAccessSpeed CisDevSpeedTable[8] =
sl@0	22	{EAcSpeedInValid,EAcSpeed250nS,EAcSpeed200nS,EAcSpeed150nS,
sl@0	23	EAcSpeed100nS,EAcSpeedInValid,EAcSpeedInValid,EAcSpeedInValid};
sl@0	24	LOCAL_D const TUint32 CisDevSizeInBytesTable[8] =
sl@0	25	{0x00000200,0x00000800,0x00002000,0x00008000,0x00020000,0x00080000,0x00200000,0};
sl@0	26	LOCAL_D const TInt CisMantisaTable[0x10] =
sl@0	27	{10,12,13,15,20,25,30,35,40,45,50,55,60,70,80,90};
sl@0	28	LOCAL_D const TInt CisSpeedExponentTable[8] =
sl@0	29	{0,1,10,100,1000,10000,100000,1000000};
sl@0	30
sl@0	31	GLDEF_C void PcCardPanic(TPcCardPanic aPanic)
sl@0	32	{
sl@0	33	Kern::Fault("PCCARD",aPanic);
sl@0	34	}
sl@0	35
sl@0	36	LOCAL_C TPccdAccessSpeed DevSpeedFromExtended(TInt aSpeedInNanoSecs)
sl@0	37	{
sl@0	38
sl@0	39	if (aSpeedInNanoSecs<=100) return(EAcSpeed100nS);
sl@0	40	if (aSpeedInNanoSecs<=150) return(EAcSpeed150nS);
sl@0	41	if (aSpeedInNanoSecs<=200) return(EAcSpeed200nS);
sl@0	42	if (aSpeedInNanoSecs<=250) return(EAcSpeed250nS);
sl@0	43	if (aSpeedInNanoSecs<=300) return(EAcSpeed300nS);
sl@0	44	if (aSpeedInNanoSecs<=450) return(EAcSpeed450nS);
sl@0	45	if (aSpeedInNanoSecs<=600) return(EAcSpeed600nS);
sl@0	46	if (aSpeedInNanoSecs<=750) return(EAcSpeed750nS);
sl@0	47	return(EAcSpeedExtended);
sl@0	48	}
sl@0	49
sl@0	50	LOCAL_C TMemDeviceType DevType(TInt aTypeCode)
sl@0	51	{
sl@0	52	if ( aTypeCode>=KTpDiDTypeNull && aTypeCode<=KTpDiDTypeDram )
sl@0	53	return( (TMemDeviceType)aTypeCode );
sl@0	54	else if (aTypeCode>=KTpDiDTypeFuncSpec)
sl@0	55	return(EDeviceFunSpec);
sl@0	56	else
sl@0	57	return(EDeviceInvalid);
sl@0	58	}
sl@0	59
sl@0	60	LOCAL_C TInt ExtendedSpeedToNanoSeconds(TUint8 aVal)
sl@0	61	//
sl@0	62	// Converts extended device speed field to speed in nS.
sl@0	63	//
sl@0	64	{
sl@0	65
sl@0	66	TInt mant=(aVal&KCisTplMantM)>>KCisTplMantFO;
sl@0	67	TInt s=(mant==0)?0:CisMantisaTable[mant-1];
sl@0	68	s*=CisSpeedExponentTable[aVal&KCisTplExponM];
sl@0	69	return(s);
sl@0	70	}
sl@0	71
sl@0	72	LOCAL_C TInt PwrTplToMicroAmps(TUint aVal,TUint anExt)
sl@0	73	//
sl@0	74	// Converts a power tuple into an integer value - units uA.
sl@0	75	//
sl@0	76	{
sl@0	77	TInt p=CisMantisaTable[(aVal&KCisTplMantM)>>KCisTplMantFO];
sl@0	78	p*=10;
sl@0	79	if (anExt<=99)
sl@0	80	p+=anExt; // Add on the extension
sl@0	81	switch ( aVal&KCisTplExponM )
sl@0	82	{
sl@0	83	case 7: return(p=10000); case 6: return(p=1000);
sl@0	84	case 5: return(p=100); case 4: return(p=10);
sl@0	85	case 3: return(p); case 2: return(p/=10);
sl@0	86	case 1: return(p/=100);
sl@0	87	default: return(0); // Anything else is too small to worry about
sl@0	88	}
sl@0	89	}
sl@0	90
sl@0	91	LOCAL_C TInt PwrTplToMilliVolts(TUint aVal,TUint anExt)
sl@0	92	//
sl@0	93	// Converts a power tuple into a integer value - units mV.
sl@0	94	//
sl@0	95	{
sl@0	96	return(PwrTplToMicroAmps(aVal,anExt)/10);
sl@0	97	}
sl@0	98
sl@0	99	LOCAL_C TInt ParseConfigTuple(TDes8 &configTpl,TPcCardConfig &anInfo,TInt &aLastEntry)
sl@0	100	//
sl@0	101	// Parse a KCisTplConfig tuple.
sl@0	102	// (Always alters iConfigBaseAddr and iRegPresent).
sl@0	103	//
sl@0	104	{
sl@0	105
sl@0	106	anInfo.iConfigBaseAddr=0;
sl@0	107	anInfo.iRegPresent=0;
sl@0	108
sl@0	109	// Get the sizes of the ConfReg base addr & ConfReg present fields
sl@0	110	TInt rasz=((configTpl[2]&KTpCcRaszM)>>KTpCcRaszFO)+1;
sl@0	111	TInt rmsz=((configTpl[2]&KTpCcRmszM)>>KTpCcRmszFO)+1;
sl@0	112	if ( (configTpl.Size()-4) < (rasz+rmsz) )
sl@0	113	return(KErrNotSupported); // Size of fields longer than tuple length.
sl@0	114	aLastEntry=configTpl[3];
sl@0	115
sl@0	116	// Read Config. Reg. base address.
sl@0	117	TInt i;
sl@0	118	for (i=0;i<rasz;i++)
sl@0	119	anInfo.iConfigBaseAddr += (configTpl[4+i]<<(8*i));
sl@0	120
sl@0	121	// Read Config. Reg. present mask
sl@0	122	if (rmsz>4) rmsz=4; // We only have 32bit field
sl@0	123	for (i=0;i<rmsz;i++)
sl@0	124	anInfo.iRegPresent += (configTpl[4+rasz+i]<<(8*i));
sl@0	125	return(KErrNone); // Ignore custom interface subtuples
sl@0	126	}
sl@0	127
sl@0	128	LOCAL_C TInt ParsePowerEntry(const TUint8 aTplPtr,TInt aVMax,TInt aVMin,TInt aPeakI,TInt *aPdwnI)
sl@0	129	//
sl@0	130	// Parse a Power descriptor in a KCisTplCfTableEntry tuple. Returns the
sl@0	131	// number of bytes we have parsed.
sl@0	132	//
sl@0	133	{
sl@0	134	const TUint8 *initPtr = aTplPtr;
sl@0	135	TUint8 present = *aTplPtr++;
sl@0	136	TBuf8<16> pwr;
sl@0	137	pwr.FillZ(16); // Important
sl@0	138
sl@0	139	TInt i;
sl@0	140	for (i=0;i<16;i+=2,present>>=1)
sl@0	141	{
sl@0	142	if (present&0x01)
sl@0	143	{
sl@0	144	pwr[i]=(TUint8)((*aTplPtr)&(~KCisTplExt));
sl@0	145	if (*aTplPtr++ & KCisTplExt)
sl@0	146	{
sl@0	147	pwr[i+1]=(TUint8)((*aTplPtr)&(~KCisTplExt)); // Extension tuple
sl@0	148	while( *aTplPtr++ & KCisTplExt ); // Jump past any more extensions
sl@0	149	}
sl@0	150	}
sl@0	151	}
sl@0	152
sl@0	153	if (aVMin && aVMax)
sl@0	154	{
sl@0	155	if (pwr[0]) // NomV (assume +/-5%)
sl@0	156	{
sl@0	157	(aVMin)=(aVMax)=PwrTplToMilliVolts(pwr[0],pwr[1]);
sl@0	158	(aVMin) = ((aVMin)*95)/100;
sl@0	159	(aVMax) = ((aVMax)*105)/100;
sl@0	160	}
sl@0	161	if (pwr[2]) // MinV
sl@0	162	*aVMin=PwrTplToMilliVolts(pwr[2],pwr[3]);
sl@0	163	if (pwr[4]) // MaxV
sl@0	164	*aVMax=PwrTplToMilliVolts(pwr[4],pwr[5]);
sl@0	165	}
sl@0	166	// We'll settle for average/static if no peak.
sl@0	167	if (aPeakI && (pwr[10]\|\|pwr[8]\|\|pwr[6]) )
sl@0	168	{
sl@0	169	if (pwr[6])
sl@0	170	*aPeakI = PwrTplToMicroAmps(pwr[6],pwr[7]);
sl@0	171	if (pwr[8])
sl@0	172	*aPeakI = PwrTplToMicroAmps(pwr[8],pwr[9]);
sl@0	173	if (pwr[10])
sl@0	174	*aPeakI = PwrTplToMicroAmps(pwr[10],pwr[11]); // Last one overides others
sl@0	175	}
sl@0	176	if (aPdwnI && pwr[12])
sl@0	177	*aPdwnI = PwrTplToMicroAmps(pwr[12],pwr[13]);
sl@0	178
sl@0	179	return(aTplPtr-initPtr);
sl@0	180	}
sl@0	181
sl@0	182	LOCAL_C TInt ParseTimingEntry(const TUint8 *aTplPtr)
sl@0	183	//
sl@0	184	// Parse a timing descriptor in a KCisTplCfTableEntry tuple. Returns the
sl@0	185	// number of bytes we have parsed.
sl@0	186	//
sl@0	187	{
sl@0	188	// We ignore this information - just jump past this field
sl@0	189	const TUint8 *initPtr=aTplPtr;
sl@0	190
sl@0	191	TUint8 present=*aTplPtr++; // First the timing present field
sl@0	192
sl@0	193	if ((present & KTpCeTimWaitM) != KTpCeTimWaitM)
sl@0	194	while( *aTplPtr++ & KCisTplExt ); // Wait time (jump past any extensions)
sl@0	195	if ((present & KTpCeTimRdyM) != KTpCeTimRdyM)
sl@0	196	while( *aTplPtr++ & KCisTplExt ); // Ready time (jump past any extensions)
sl@0	197	if ((present & KTpCeTimResM) != KTpCeTimResM)
sl@0	198	while( *aTplPtr++ & KCisTplExt ); // Reserved time (jump past any extensions)
sl@0	199	return(aTplPtr-initPtr);
sl@0	200	}
sl@0	201
sl@0	202	LOCAL_C TInt ParseIoEntry(const TUint8 aTplPtr,TPccdChnk aChnk,TInt &aNextChnkNum)
sl@0	203	//
sl@0	204	// Parse an IO space descriptor in a KCisTplCfTableEntry tuple. Returns the
sl@0	205	// number of bytes we have parsed (or a negative error value). Also returns the
sl@0	206	// number of config chunk entries used ('aNextChunkNum').
sl@0	207	//
sl@0	208	{
sl@0	209	TPccdMemType memType;
sl@0	210	TInt bytesParsed = 1; // Must be a minimum of a single byte descriptor here.
sl@0	211
sl@0	212	// Always at least one I/O space descriptor
sl@0	213	switch( (*aTplPtr & KTpCeBus16_8M) >> KTpCeBus16_8FO )
sl@0	214	{
sl@0	215	case 1: case 2:
sl@0	216	memType = EPccdIo8Mem; // Card supports 8bit I/O only.
sl@0	217	break;
sl@0	218	case 3:
sl@0	219	memType = EPccdIo16Mem; // Card supports 8 & 16 bit I/O.
sl@0	220	break;
sl@0	221	default:
sl@0	222	return(KErrCorrupt);
sl@0	223	}
sl@0	224	TUint ioLines = (*aTplPtr & KTpCeIoLinesM) >> KTpCeIoLinesFO;
sl@0	225
sl@0	226	TInt ranges=1; // We always specify one chunk even if no range descriptors follow
sl@0	227	TInt addrInBytes=0;
sl@0	228	TInt lenInBytes=0;
sl@0	229	// Are there any IO Range description bytes to follow
sl@0	230	if (*aTplPtr++ & KTpCeRangePresM)
sl@0	231	{
sl@0	232	ranges = ((*aTplPtr & KTpCeIoRangesM) >> KTpCeIoRangesFO)+1;
sl@0	233	addrInBytes = (*aTplPtr & KTpCeIoAddrSzM) >> KTpCeIoAddrSzFO;
sl@0	234	lenInBytes = (*aTplPtr & KTpCeIoAddrLenM) >> KTpCeIoAddrLenFO;
sl@0	235	aTplPtr++;
sl@0	236
sl@0	237	// There could be multiple range descriptors
sl@0	238	if ((ranges+aNextChnkNum)<=KMaxChunksPerConfig)
sl@0	239	bytesParsed += (ranges * (addrInBytes + lenInBytes))+1;
sl@0	240	else
sl@0	241	return(KErrNotSupported); // Too many descriptors for us
sl@0	242	}
sl@0	243
sl@0	244	aChnk+=aNextChnkNum;
sl@0	245	for (;ranges>0;ranges--,aChnk++,aNextChnkNum++)
sl@0	246	{
sl@0	247	TInt j;
sl@0	248	aChnk->iMemType=memType; // I/O memory type
sl@0	249
sl@0	250	// Lets get the IO start address
sl@0	251	aChnk->iMemBaseAddr=0;
sl@0	252	if (addrInBytes)
sl@0	253	{
sl@0	254	for (j=0;j<addrInBytes;j++)
sl@0	255	aChnk->iMemBaseAddr += (aTplPtr++) << (8j);
sl@0	256	}
sl@0	257
sl@0	258	// Finally, lets get the IO length
sl@0	259	if (lenInBytes)
sl@0	260	{
sl@0	261	for (j=0,aChnk->iMemLen=0;j<lenInBytes;j++)
sl@0	262	aChnk->iMemLen += (aTplPtr++) << (8j);
sl@0	263	(aChnk->iMemLen)++;
sl@0	264	}
sl@0	265	else
sl@0	266	{
sl@0	267	if (ioLines)
sl@0	268	aChnk->iMemLen = 0x01<<ioLines;
sl@0	269	else
sl@0	270	return(KErrCorrupt); // No ioLines and no length, it's invalid.
sl@0	271	}
sl@0	272	}
sl@0	273	return(bytesParsed);
sl@0	274	}
sl@0	275
sl@0	276	LOCAL_C TInt ParseMemEntry(const TUint8 aTplPtr,TInt aFeatureVal,TPccdChnk aChnk,TInt &aNextChnkNum)
sl@0	277	//
sl@0	278	// Parse a memory space descriptor in a KCisTplCfTableEntry tuple. Returns
sl@0	279	// the number of bytes we have parsed (or a negative error value). Also returns the
sl@0	280	// number of config chunk entries used ('aNextChunkNum').
sl@0	281	//
sl@0	282	{
sl@0	283
sl@0	284	const TUint8 *initPtr=aTplPtr;
sl@0	285	TInt windows=0;
sl@0	286	TInt lenInBytes=0;
sl@0	287	TInt addrInBytes=0;
sl@0	288	TBool hostAddr=EFalse;
sl@0	289	switch (aFeatureVal)
sl@0	290	{
sl@0	291	case 3: // Memory space descriptor
sl@0	292	windows=(*aTplPtr & KTpCeMemWindowsM)+1;
sl@0	293	lenInBytes=(*aTplPtr & KTpCeMemLenSzM) >> KTpCeMemLenSzFO;
sl@0	294	addrInBytes=(*aTplPtr & KTpCeMemAddrSzM) >> KTpCeMemAddrSzFO;
sl@0	295	hostAddr=(*aTplPtr & KTpCeMemHostAddrM);
sl@0	296	aTplPtr++;
sl@0	297	break;
sl@0	298	case 2: // Length(2byte) and base address(2byte) specified.
sl@0	299	addrInBytes=2;
sl@0	300	case 1: // Single 2-byte length specified.
sl@0	301	lenInBytes=2;
sl@0	302	windows=1;
sl@0	303	break;
sl@0	304	}
sl@0	305
sl@0	306	if ((windows+aNextChnkNum)>KMaxChunksPerConfig)
sl@0	307	return(KErrNotSupported); // Too many descriptors for us
sl@0	308
sl@0	309	aChnk+=aNextChnkNum;
sl@0	310	TInt i;
sl@0	311	for (;windows>0;windows--,aChnk++,aNextChnkNum++)
sl@0	312	{
sl@0	313	aChnk->iMemType=EPccdCommon16Mem;
sl@0	314	aChnk->iMemLen=0;
sl@0	315	if (lenInBytes)
sl@0	316	{
sl@0	317	for (i=0;i<lenInBytes;i++)
sl@0	318	aChnk->iMemLen += (aTplPtr++) << ((8i)+8); // in 256 byte pages
sl@0	319	}
sl@0	320	aChnk->iMemBaseAddr=0;
sl@0	321	if (addrInBytes)
sl@0	322	{
sl@0	323	for (i=0;i<addrInBytes;i++)
sl@0	324	aChnk->iMemBaseAddr += (aTplPtr++) << ((8i)+8);// in 256 byte pages
sl@0	325	}
sl@0	326	if (hostAddr)
sl@0	327	{
sl@0	328	for (i=0;i<addrInBytes;i++)
sl@0	329	aTplPtr++; // Dont record this, just advance the tuple pointer
sl@0	330	}
sl@0	331	}
sl@0	332	return(aTplPtr-initPtr);
sl@0	333	}
sl@0	334
sl@0	335	LOCAL_C TInt ParseMiscEntry(const TUint8 *aTplPtr, TBool &aPwrDown)
sl@0	336	//
sl@0	337	// Parse a miscellaneous features field in a KCisTplCfTableEntry tuple.
sl@0	338	// Returns the number of bytes we have parsed.
sl@0	339	//
sl@0	340	{
sl@0	341	aPwrDown=(*aTplPtr&KTpCePwrDownM);
sl@0	342
sl@0	343	TInt i;
sl@0	344	for (i=1;*aTplPtr & KCisTplExt;i++,aTplPtr++);
sl@0	345	return(i);
sl@0	346	}
sl@0	347
sl@0	348	LOCAL_C TInt ParseConfigEntTuple(TDes8 &cTpl,TPcCardConfig &anInfo)
sl@0	349	//
sl@0	350	// Parse a KCisTplCfTableEntry tuple. anInfo contains default values on
sl@0	351	// entry so this routine only adds data it finds in the tuple.
sl@0	352	//
sl@0	353	{
sl@0	354
sl@0	355	// Parse the Index byte.
sl@0	356	const TUint8 *tplPtr=cTpl.Ptr()+2; // First tuple after link
sl@0	357	anInfo.iConfigOption=(*tplPtr & KTpCeOptionM);
sl@0	358	anInfo.iIsDefault=(*tplPtr & KTpCeIsDefaultM);
sl@0	359
sl@0	360	// Check if there is an interface description field to follow
sl@0	361	if (*tplPtr++ & KTpCeIntfPresM)
sl@0	362	{
sl@0	363	anInfo.iIsIoAndMem=(*tplPtr&KTpCeIntfTypeM);
sl@0	364	anInfo.iActiveSignals=*tplPtr&(KTpCeBvdM\|KTpCeWpM\|KTpCeReadyM\|KTpCeWaitM);
sl@0	365	tplPtr++;
sl@0	366	}
sl@0	367
sl@0	368	// Next byte should be the feature selection byte.
sl@0	369	TUint8 features=*tplPtr++;
sl@0	370
sl@0	371	// Next might be 0-3 power description structures. 1st one is always VCC info.
sl@0	372	TInt entry=(features & KTpCePwrPresM)>>KTpCePwrPresFO;
sl@0	373	if (entry)
sl@0	374	{
sl@0	375	tplPtr += ParsePowerEntry(tplPtr,&anInfo.iVccMaxInMilliVolts,&anInfo.iVccMinInMilliVolts,
sl@0	376	&anInfo.iOperCurrentInMicroAmps,&anInfo.iPwrDwnCurrentInMicroAmps);
sl@0	377	entry--;
sl@0	378	}
sl@0	379
sl@0	380	// We only support a single Vpp supply. However we need to parse both (Vpp1+Vpp2)
sl@0	381	// in order to advance the tuple pointer.
sl@0	382	while ( entry-- )
sl@0	383	tplPtr += ParsePowerEntry(tplPtr,&anInfo.iVppMaxInMilliVolts,&anInfo.iVppMinInMilliVolts,NULL,NULL);
sl@0	384
sl@0	385	// Next might be timing info.
sl@0	386	if (features & KTpCeTimPresM)
sl@0	387	tplPtr += ParseTimingEntry(tplPtr);
sl@0	388
sl@0	389	// Next might be IO space description.
sl@0	390	TInt ret;
sl@0	391	TInt nextFreeChunk=0;
sl@0	392	if (features & KTpCeIoPresM)
sl@0	393	{
sl@0	394	if((ret=ParseIoEntry(tplPtr,&(anInfo.iChnk[0]),nextFreeChunk))<0)
sl@0	395	return(ret);
sl@0	396	anInfo.iValidChunks=nextFreeChunk;
sl@0	397	tplPtr += ret;
sl@0	398	}
sl@0	399
sl@0	400	// Next might be IRQ description.
sl@0	401	if (features & KTpCeIrqPresM)
sl@0	402	{
sl@0	403	anInfo.iInterruptInfo=*tplPtr&(KPccdIntShare\|KPccdIntPulse\|KPccdIntLevel);
sl@0	404	tplPtr+=(*tplPtr&KTpCeIrqMaskM)?3:1; // Ignore mask bytes if present
sl@0	405	}
sl@0	406
sl@0	407	// Next might be memory space description.
sl@0	408	entry=((features & KTpCeMemPresM) >> KTpCeMemPresFO);
sl@0	409	if (entry)
sl@0	410	{
sl@0	411	if ((ret=ParseMemEntry(tplPtr,entry,&(anInfo.iChnk[0]),nextFreeChunk))<0)
sl@0	412	return(ret);
sl@0	413	anInfo.iValidChunks=nextFreeChunk;
sl@0	414	tplPtr+=ret;
sl@0	415	}
sl@0	416
sl@0	417	// And finally there might be a miscellaneous features field
sl@0	418	if (features & KTpCeMiscPresM)
sl@0	419	tplPtr+=ParseMiscEntry(tplPtr,anInfo.iPwrDown);
sl@0	420
sl@0	421	// Check that we haven't been reading beyond the tuple.
sl@0	422	if ((tplPtr-cTpl.Ptr()) > (cTpl[1]+2))
sl@0	423	return(KErrCorrupt);
sl@0	424
sl@0	425	return(KErrNone);
sl@0	426	}
sl@0	427
sl@0	428	LOCAL_C TInt ParseDeviceInfo(const TUint8 *aTplPtr,TPcCardRegion &anInfo)
sl@0	429	//
sl@0	430	// Parse a device info field in a KCisTplDeviceX tuple.
sl@0	431	// Returns the number of bytes we have parsed (or a negative error value).
sl@0	432	//
sl@0	433	{
sl@0	434
sl@0	435	const TUint8 *initPtr=aTplPtr;
sl@0	436	TInt val;
sl@0	437	// Device ID - device type field
sl@0	438	val=((*aTplPtr & KTpDiDTypeM) >> KTpDiDTypeFO);
sl@0	439	if (val==KTpDiDTypeExtend)
sl@0	440	return(KErrNotSupported); // Don't support extended device type
sl@0	441	anInfo.iDeviceType=DevType(val);
sl@0	442
sl@0	443	// Device ID - write protect field
sl@0	444	if (!(*aTplPtr&KTpDiWpsM))
sl@0	445	anInfo.iActiveSignals\|=KSigWpActive;
sl@0	446
sl@0	447	// Device ID - device speed field
sl@0	448	val=(*aTplPtr & KTpDiDSpeedM);
sl@0	449	if (val==KTpDiDSpeedExt)
sl@0	450	{
sl@0	451	aTplPtr++;
sl@0	452	anInfo.iExtendedAccSpeedInNanoSecs=ExtendedSpeedToNanoSeconds(*aTplPtr);
sl@0	453	anInfo.iAccessSpeed=DevSpeedFromExtended(anInfo.iExtendedAccSpeedInNanoSecs);
sl@0	454	while(*aTplPtr++ & KCisTplExt); // Jump past any (further) extended speed fields
sl@0	455	}
sl@0	456	else
sl@0	457	{
sl@0	458	anInfo.iExtendedAccSpeedInNanoSecs=0;
sl@0	459	anInfo.iAccessSpeed=CisDevSpeedTable[val];
sl@0	460	aTplPtr++;
sl@0	461	}
sl@0	462
sl@0	463	// Now the Device size
sl@0	464	TInt size,numUnits;
sl@0	465	size=((*aTplPtr & KTpDiDSizeM) >> KTpDiDSizeFO);
sl@0	466	numUnits=((*aTplPtr++ & KTpDiDUnitsM) >> KTpDiDUnitsFO)+1;
sl@0	467	if (size>KTpDiDSize2M)
sl@0	468	return(KErrCorrupt);
sl@0	469	anInfo.iChnk.iMemLen=numUnits*CisDevSizeInBytesTable[size];
sl@0	470	return(aTplPtr-initPtr);
sl@0	471	}
sl@0	472	/*
sl@0	473	LOCAL_C TInt SocketIsInRange(TSocket aSocket)
sl@0	474	//
sl@0	475	// Check socket is valid for this machine
sl@0	476	//
sl@0	477	{
sl@0	478
sl@0	479	// return(aSocket>=0&&aSocket<ThePcCardController->TotalSupportedBuses());
sl@0	480	return (aSocket>=0 && aSocket<KMaxPBusSockets && TheSockets[aSocket]!=NULL);
sl@0	481	}
sl@0	482	*/
sl@0	483	EXPORT_C TCisReader::TCisReader()
sl@0	484	//
sl@0	485	// Constructor.
sl@0	486	//
sl@0	487	: iFunc(0),iCisOffset(0),iLinkOffset(0),iMemType(EPccdAttribMem),
sl@0	488	iLinkFlags(0),iRestarted(EFalse),iRegionCount(0),
sl@0	489	iConfigCount(0)
sl@0	490	{
sl@0	491	iSocket=NULL;
sl@0	492	}
sl@0	493
sl@0	494	EXPORT_C TInt TCisReader::SelectCis(TSocket aSocket,TInt aCardFunc)
sl@0	495	//
sl@0	496	// Assign the CIS reader to a socket and function.
sl@0	497	//
sl@0	498	{
sl@0	499	// We need to have read the CIS format
sl@0	500	__KTRACE_OPT(KPBUS1,Kern::Printf(">CisReader:SelectCis(S:%d F:%d)",aSocket,aCardFunc));
sl@0	501	DPcCardSocket* pS=(DPcCardSocket*)TheSockets[aSocket];
sl@0	502	if (pS->CardIsReadyAndVerified()!=KErrNone)
sl@0	503	return KErrNotReady;
sl@0	504	iSocket=pS;
sl@0	505	return(DoSelectCis(aCardFunc));
sl@0	506	}
sl@0	507
sl@0	508	TInt TCisReader::DoSelectCis(TInt aCardFunc)
sl@0	509	//
sl@0	510	// Actually assign the CIS reader to a socket and function.
sl@0	511	//
sl@0	512	{
sl@0	513
sl@0	514	// Check that the function is valid
sl@0	515	TInt r;
sl@0	516	if (!iSocket->IsValidCardFunc(aCardFunc))
sl@0	517	{
sl@0	518	iSocket=NULL;
sl@0	519	r=KErrNotFound;
sl@0	520	}
sl@0	521	else
sl@0	522	{
sl@0	523	iFunc=aCardFunc;
sl@0	524	DoRestart();
sl@0	525	iConfigCount=0;
sl@0	526	r=KErrNone;
sl@0	527	}
sl@0	528	__KTRACE_OPT(KPBUS1,Kern::Printf("<CisReader:DoSelectCis(F:%d)-%d",aCardFunc,r));
sl@0	529	return(r);
sl@0	530	}
sl@0	531
sl@0	532	EXPORT_C TInt TCisReader::Restart()
sl@0	533	//
sl@0	534	// Restart the CIS reader back to the start of the CIS, and re-initialise
sl@0	535	// config entry parsing.
sl@0	536	//
sl@0	537	{
sl@0	538	if (iSocket==NULL)
sl@0	539	return(KErrGeneral);
sl@0	540	DoRestart();
sl@0	541	iConfigCount=0;
sl@0	542	return(KErrNone);
sl@0	543	}
sl@0	544
sl@0	545	void TCisReader::DoRestart()
sl@0	546	//
sl@0	547	// Restart the CIS reader back to the start of the CIS
sl@0	548	//
sl@0	549	{
sl@0	550
sl@0	551	TPcCardFunction *func=iSocket->CardFunc(iFunc);
sl@0	552	iCisOffset=func->InitCisOffset();
sl@0	553	iLinkOffset=0;
sl@0	554	iMemType=func->InitCisMemType();
sl@0	555	iLinkFlags=0;
sl@0	556	iRestarted=ETrue;
sl@0	557	iRegionCount=0;
sl@0	558	__KTRACE_OPT(KPBUS1,Kern::Printf("<CisReader:DoRestart"));
sl@0	559	}
sl@0	560
sl@0	561	EXPORT_C TInt TCisReader::FindReadTuple(TUint8 aDesiredTpl,TDes8 &aDes,TUint aFlag)
sl@0	562	//
sl@0	563	// Find a specified tuple from the CIS and read it.
sl@0	564	//
sl@0	565	{
sl@0	566	__ASSERT_ALWAYS(iSocket!=NULL,PcCardPanic(EPcCardCisReaderUnInit));
sl@0	567
sl@0	568	// We're going to read the card itself so it must be ready.
sl@0	569	if ( iSocket->CardIsReadyAndVerified()!=KErrNone )
sl@0	570	return(KErrNotReady);
sl@0	571
sl@0	572	return(DoFindReadTuple(aDesiredTpl,aDes,aFlag));
sl@0	573	}
sl@0	574
sl@0	575	TInt TCisReader::DoFindReadTuple(TUint8 aDesiredTpl,TDes8 &aDes,TUint aFlag)
sl@0	576	//
sl@0	577	// Actually find a specified tuple from the CIS and read it.
sl@0	578	//
sl@0	579	{
sl@0	580
sl@0	581	__KTRACE_OPT(KPBUS1,Kern::Printf(">CisReader:DoFindReadTuple(T:%xH)",aDesiredTpl));
sl@0	582
sl@0	583	TBuf8<KSmallTplBufSize> tpl;
sl@0	584	TBuf8<KSmallTplBufSize> linkAddr;
sl@0	585	TInt i,j,err;
sl@0	586
sl@0	587	// Read the previous tuple
sl@0	588	if ((err=iSocket->ReadCis(iMemType,iCisOffset,tpl,2))!=KErrNone)
sl@0	589	return(err);
sl@0	590
sl@0	591	for (j=0;j<KMaxTuplesPerCis;j++)
sl@0	592	{
sl@0	593	// Adjust CIS offset beyond last tuple read (unless we've just restarted)
sl@0	594	if (iRestarted)
sl@0	595	iRestarted=EFalse;
sl@0	596	else
sl@0	597	{
sl@0	598	if (tpl[0]!=KCisTplEnd && tpl[1]!=0xff)
sl@0	599	iCisOffset+=(tpl[0]==KCisTplNull)?1:(tpl[1]+2); // A null tuple has no link field
sl@0	600	else
sl@0	601	{
sl@0	602	// End of chain tuple
sl@0	603	if ((err=FollowLink(aFlag&KPccdReportErrors))!=KErrNone)
sl@0	604	return(err);
sl@0	605	}
sl@0	606	}
sl@0	607
sl@0	608	// Read the next tuple
sl@0	609	if ((err=iSocket->ReadCis(iMemType,iCisOffset,tpl,2))!=KErrNone)
sl@0	610	return(err);
sl@0	611
sl@0	612	// Check for a link tuple (need to store next chain addr. for later)
sl@0	613	switch(tpl[0])
sl@0	614	{
sl@0	615	case KCisTplLongLinkA:
sl@0	616	iLinkFlags \|= KPccdLinkA;
sl@0	617	if ((err= iSocket->ReadCis(iMemType,iCisOffset+2,linkAddr,4)) != KErrNone)
sl@0	618	return(err);
sl@0	619	for (iLinkOffset=0,i=0 ; i<4 ; i++)
sl@0	620	iLinkOffset += linkAddr[i] << (8*i);
sl@0	621	break;
sl@0	622	case KCisTplLongLinkC:
sl@0	623	iLinkFlags \|= KPccdLinkC;
sl@0	624	if ((err= iSocket->ReadCis(iMemType,iCisOffset+2,linkAddr,4)) != KErrNone)
sl@0	625	return(err);
sl@0	626	for (iLinkOffset=0,i=0 ; i<4 ; i++)
sl@0	627	iLinkOffset += linkAddr[i] << (8*i);
sl@0	628	break;
sl@0	629	case KCisTplLongLinkMfc:
sl@0	630	iLinkFlags \|= KPccdLinkMFC;
sl@0	631	break;
sl@0	632	case KCisTplNoLink:
sl@0	633	iLinkFlags \|= KPccdNoLink;
sl@0	634	default:
sl@0	635	break;
sl@0	636	}
sl@0	637
sl@0	638	// Check if we have found the specified tuple
sl@0	639	if (aDesiredTpl==KPccdNonSpecificTpl \|\| aDesiredTpl==tpl[0])
sl@0	640	{
sl@0	641	// The following are ignored unless KPccdReturnLinkTpl is set.
sl@0	642	if ((tpl[0]==KCisTplNull)\|\|
sl@0	643	(tpl[0]==KCisTplEnd)\|\|
sl@0	644	(tpl[0]==KCisTplLongLinkA)\|\|
sl@0	645	(tpl[0]==KCisTplLongLinkC)\|\|
sl@0	646	(tpl[0]==KCisTplLongLinkMfc)\|\|
sl@0	647	(tpl[0]==KCisTplNoLink)\|\|
sl@0	648	(tpl[0]==KCisTplLinkTarget))
sl@0	649	{
sl@0	650	if (aFlag&KPccdReturnLinkTpl)
sl@0	651	break;
sl@0	652	}
sl@0	653	else
sl@0	654	break;
sl@0	655	}
sl@0	656	}
sl@0	657
sl@0	658	// We got a result (or we've wandered off into the weeds)
sl@0	659	if (j>=KMaxTuplesPerCis)
sl@0	660	return( (aFlag&KPccdReportErrors)?KErrCorrupt:KErrNotFound );
sl@0	661	else
sl@0	662	return((aFlag&KPccdFindOnly)?KErrNone:DoReadTuple(aDes));
sl@0	663	}
sl@0	664
sl@0	665	EXPORT_C TInt TCisReader::ReadTuple(TDes8 &aDes)
sl@0	666	//
sl@0	667	// Read the tuple at the current CIS offset.
sl@0	668	//
sl@0	669	{
sl@0	670	__ASSERT_ALWAYS(iSocket!=NULL,PcCardPanic(EPcCardCisReaderUnInit));
sl@0	671
sl@0	672	// We're going to read the card itself so it must be ready.
sl@0	673	if ( iSocket->CardIsReadyAndVerified()!=KErrNone )
sl@0	674	return(KErrNotReady);
sl@0	675
sl@0	676	return(DoReadTuple(aDes));
sl@0	677	}
sl@0	678
sl@0	679	TInt TCisReader::DoReadTuple(TDes8 &aDes)
sl@0	680	//
sl@0	681	// Actually read the tuple at the current CIS offset.
sl@0	682	//
sl@0	683	{
sl@0	684
sl@0	685	__KTRACE_OPT(KPBUS1,Kern::Printf(">CisReader:DoReadTuple"));
sl@0	686	TInt err;
sl@0	687
sl@0	688	// Read the tuple type and link
sl@0	689	TBuf8<KSmallTplBufSize> tpl;
sl@0	690	if ((err= iSocket->ReadCis(iMemType,iCisOffset,tpl,2)) != KErrNone)
sl@0	691	return(err);
sl@0	692
sl@0	693	TInt tplLen ;
sl@0	694	if ((tpl[0] == KCisTplNull) \|\| (tpl[0] == KCisTplEnd))
sl@0	695	tplLen = 1 ; // These tuples dont have a link.
sl@0	696	else
sl@0	697	tplLen = (tpl[1]+2) ;
sl@0	698	if ( tplLen>aDes.MaxLength() ) // We dont want a panic if aDes too small
sl@0	699	return(KErrArgument);
sl@0	700
sl@0	701	// Lets copy the tuple
sl@0	702	if ((err= iSocket->ReadCis(iMemType,iCisOffset,aDes,tplLen)) != KErrNone)
sl@0	703	return(err);
sl@0	704	else
sl@0	705	return(KErrNone);
sl@0	706	}
sl@0	707
sl@0	708	TInt TCisReader::FollowLink(TUint aFullErrorReport)
sl@0	709	//
sl@0	710	// Called at the end of a tuple chain, this moves CIS pointer to the next
sl@0	711	// CIS chain if a long link has been detected.
sl@0	712	//
sl@0	713	{
sl@0	714
sl@0	715	TInt err;
sl@0	716	switch (iLinkFlags)
sl@0	717	{
sl@0	718	case 0: // Haven't found anything so assume longlink to 0 in common.
sl@0	719	iLinkOffset=0;
sl@0	720	case KPccdLinkC:
sl@0	721	iCisOffset=iLinkOffset;
sl@0	722	iMemType=EPccdCommon8Mem;
sl@0	723	iLinkOffset=0;
sl@0	724	if ((err=VerifyLinkTarget())!=KErrNone)
sl@0	725	{
sl@0	726	DoRestart(); // Leave pointers somewhere safe.
sl@0	727	if (iLinkFlags==0\|\|!aFullErrorReport)
sl@0	728	err=KErrNotFound; // Above assumption wrong
sl@0	729	}
sl@0	730	break;
sl@0	731	case KPccdLinkA:
sl@0	732	iCisOffset=iLinkOffset;
sl@0	733	iMemType=EPccdAttribMem;
sl@0	734	iLinkOffset=0;
sl@0	735	if ((err=VerifyLinkTarget())!=KErrNone)
sl@0	736	{
sl@0	737	iCisOffset>>=1; // Check if the link offset is wrong
sl@0	738	if (VerifyLinkTarget()!=KErrNone)
sl@0	739	{
sl@0	740	DoRestart(); // Leave pointers somewhere safe.
sl@0	741	if (!aFullErrorReport)
sl@0	742	err=KErrNotFound;
sl@0	743	}
sl@0	744	else
sl@0	745	err=KErrNone;
sl@0	746	}
sl@0	747	break;
sl@0	748	case KPccdNoLink:
sl@0	749	case KPccdLinkMFC: // Can't follow a multi-function link
sl@0	750	DoRestart(); // Leave pointers somewhere safe.
sl@0	751	err=KErrNotFound;
sl@0	752	break;
sl@0	753	default: // Shouldn't have more than 1 link per chain
sl@0	754	DoRestart(); // Leave pointers somewhere safe.
sl@0	755	err=(aFullErrorReport)?KErrCorrupt:KErrNotFound;
sl@0	756	}
sl@0	757	iLinkFlags=0;
sl@0	758	return(err);
sl@0	759	}
sl@0	760
sl@0	761	TInt TCisReader::VerifyLinkTarget()
sl@0	762	//
sl@0	763	// Verify a new tuple chain starts with a valid link target tuple
sl@0	764	//
sl@0	765	{
sl@0	766	TBuf8<KSmallTplBufSize> tpl;
sl@0	767	TInt err;
sl@0	768	if ((err=iSocket->ReadCis(iMemType,iCisOffset,tpl,5))!=KErrNone)
sl@0	769	return(err);
sl@0	770	if ( (tpl[0]!=KCisTplLinkTarget) \|\| (tpl[1]<3) \|\| (tpl.Find(_L8("CIS"))!=2) )
sl@0	771	return(KErrCorrupt);
sl@0	772	return(KErrNone);
sl@0	773	}
sl@0	774
sl@0	775	EXPORT_C TInt TCisReader::FindReadRegion(TPccdSocketVcc aSocketVcc,TPcCardRegion &anInfo,TUint8 aDesiredTpl)
sl@0	776	//
sl@0	777	// Read region info from the CIS on the specified Socket/Function. Can
sl@0	778	// be called multiple times to read all regions (eventually
sl@0	779	// returns KErrNotFound).
sl@0	780	// If the function returns an error value then ignore anInfo.
sl@0	781	//
sl@0	782	{
sl@0	783
sl@0	784	if (!aDesiredTpl)
sl@0	785	aDesiredTpl=(aSocketVcc==EPccdSocket_5V0)?KCisTplDevice:KCisTplDeviceOC;
sl@0	786	__KTRACE_OPT(KPBUS1,Kern::Printf(">CisReader:FindReadRegion(TPL:%xH)",aDesiredTpl));
sl@0	787
sl@0	788	TInt ret;
sl@0	789	TBuf8<KLargeTplBufSize> devTpl;
sl@0	790	if (!iRegionCount) // Count of regions processed in tuple
sl@0	791	ret=FindReadTuple(aDesiredTpl,devTpl);
sl@0	792	else
sl@0	793	ret=ReadTuple(devTpl);
sl@0	794	if (ret!=KErrNone)
sl@0	795	return(ret);
sl@0	796	const TUint8 *tplPtr=devTpl.Ptr();
sl@0	797	const TUint8 *tplE=tplPtr+devTpl.Length();
sl@0	798	tplPtr+=2; // First tuple after link
sl@0	799
sl@0	800	if (aDesiredTpl==KCisTplDeviceOC\|\|aDesiredTpl==KCisTplDeviceOA)
sl@0	801	{
sl@0	802	// Process the Other Conditions info.
sl@0	803	anInfo.iChnk.iMemType=(aDesiredTpl==KCisTplDeviceOA)?EPccdAttribMem:EPccdCommon16Mem;
sl@0	804	anInfo.iActiveSignals=(*tplPtr & KTpDoMWaitM)?KSigWaitRequired:0;
sl@0	805	switch( (*tplPtr & KTpDoVccUsedM) >> KTpDoVccUsedFO )
sl@0	806	{
sl@0	807	case 3: anInfo.iVcc=EPccdSocket_yVy; break;
sl@0	808	case 2: anInfo.iVcc=EPccdSocket_xVx; break;
sl@0	809	case 1: anInfo.iVcc=EPccdSocket_3V3; break;
sl@0	810	default: anInfo.iVcc=EPccdSocket_5V0; break;
sl@0	811	}
sl@0	812	while (*tplPtr++ & KCisTplExt); // Ignore any extensions
sl@0	813	}
sl@0	814	else
sl@0	815	{ // KCisTplDevice
sl@0	816	anInfo.iChnk.iMemType=(aDesiredTpl==KCisTplDeviceA)?EPccdAttribMem:EPccdCommon16Mem;
sl@0	817	anInfo.iVcc=EPccdSocket_5V0;
sl@0	818	anInfo.iActiveSignals=0;
sl@0	819	}
sl@0	820
sl@0	821	// Now start on the Device Info fields
sl@0	822	anInfo.iAccessSpeed=EAcSpeedInValid;
sl@0	823	anInfo.iChnk.iMemBaseAddr = anInfo.iChnk.iMemLen = 0;
sl@0	824	for (TInt regions=1;*tplPtr!=0xFF&&tplPtr<tplE;tplPtr+=ret,regions++)
sl@0	825	{
sl@0	826	// Add length of previous region to give new base address.
sl@0	827	anInfo.iChnk.iMemBaseAddr+=anInfo.iChnk.iMemLen;
sl@0	828
sl@0	829	if ((ret=ParseDeviceInfo(tplPtr,anInfo)) < 0)
sl@0	830	return(ret);
sl@0	831
sl@0	832	// Check if we have new region to report (dont report null regions)
sl@0	833	if (anInfo.iDeviceType!=EDeviceNull && regions>iRegionCount)
sl@0	834	{
sl@0	835	iRegionCount=regions; // Save for next time
sl@0	836	return(KErrNone);
sl@0	837	}
sl@0	838	}
sl@0	839	return(KErrNotFound);
sl@0	840	}
sl@0	841
sl@0	842	EXPORT_C TInt TCisReader::FindReadConfig(TPcCardConfig &anInfo)
sl@0	843	//
sl@0	844	// Read configuration info from the CIS on the specified Socket/Function. Can
sl@0	845	// be called multiple times to read all configuration options (eventually
sl@0	846	// returns KErrNotFound). Uses previous configuration option value to mark
sl@0	847	// where we are in a configuration table.
sl@0	848	// If the function returns an error value then ignore anInfo.
sl@0	849	//
sl@0	850	{
sl@0	851
sl@0	852	__KTRACE_OPT(KPBUS1,Kern::Printf(">CisReader:FindReadConfig(%d)",iConfigCount));
sl@0	853	__ASSERT_ALWAYS(iSocket!=NULL,PcCardPanic(EPcCardCisReaderUnInit));
sl@0	854
sl@0	855	DoRestart(); // Start from beginning of CIS each time (dont reset iConfigCount though).
sl@0	856
sl@0	857	// Create an initial default configuration
sl@0	858	TPcCardConfig defaultConfInfo;
sl@0	859	defaultConfInfo.iVccMaxInMilliVolts=5250; // 5V+5%
sl@0	860	defaultConfInfo.iVccMinInMilliVolts=4750; // 5V-5%
sl@0	861	defaultConfInfo.iAccessSpeed=DEF_IO_ACSPEED;
sl@0	862	defaultConfInfo.iActiveSignals=0;
sl@0	863
sl@0	864	TBuf8<KLargeTplBufSize> configTpl;
sl@0	865	TInt lastEntryIndex;
sl@0	866	TBool foundLast=EFalse;
sl@0	867	TInt err;
sl@0	868	TInt i=0;
sl@0	869	if (
sl@0	870	(err=FindReadTuple(KCisTplConfig,configTpl))==KErrNone &&
sl@0	871	(err=ParseConfigTuple(configTpl,defaultConfInfo,lastEntryIndex))==KErrNone
sl@0	872	)
sl@0	873	{
sl@0	874	// Start of new configuration table
sl@0	875	for (; (err=FindReadTuple(KCisTplCfTableEntry,configTpl))==KErrNone && i<KMaxCfEntriesPerCis ; i++)
sl@0	876	{
sl@0	877	anInfo=defaultConfInfo; // Entries assume values from last default entry
sl@0	878	err=ParseConfigEntTuple(configTpl,anInfo);
sl@0	879	if (anInfo.iConfigOption==lastEntryIndex)
sl@0	880	foundLast=ETrue;
sl@0	881	else
sl@0	882	{
sl@0	883	if (foundLast)
sl@0	884	{
sl@0	885	err=KErrNotFound; // We've passed the last entry
sl@0	886	break;
sl@0	887	}
sl@0	888	}
sl@0	889	if (iConfigCount==i)
sl@0	890	break;
sl@0	891	if (err==KErrNone && anInfo.iIsDefault)
sl@0	892	defaultConfInfo=anInfo;
sl@0	893	}
sl@0	894	}
sl@0	895	if (i>=KMaxCfEntriesPerCis)
sl@0	896	err=KErrCorrupt;
sl@0	897	if (err==KErrNone)
sl@0	898	iConfigCount++;
sl@0	899	__KTRACE_OPT(KPBUS1,Kern::Printf("<CisReader:FindReadConfig-%d",err));
sl@0	900	return(err);
sl@0	901	}
sl@0	902
sl@0	903	TPcCardFunction::TPcCardFunction(TUint32 anOffset,TPccdMemType aMemType)
sl@0	904	//
sl@0	905	// Constructor
sl@0	906	//
sl@0	907	: iFuncType(EUnknownCard),iInitCisOffset(anOffset),iInitCisMemType(aMemType),
sl@0	908	iConfigBaseAddr(0),iConfigRegMask(0),iConfigIndex(KInvalidConfOpt),iConfigFlags(0)
sl@0	909	{
sl@0	910	iClientID=NULL;
sl@0	911	}
sl@0	912
sl@0	913	void TPcCardFunction::SetConfigOption(TInt anIndex,DBase *aClientID,TUint aConfigFlags)
sl@0	914	//
sl@0	915	// Save configuration index and client ID
sl@0	916	//
sl@0	917	{
sl@0	918
sl@0	919	iConfigIndex=anIndex;
sl@0	920	iClientID=aClientID;
sl@0	921	iConfigFlags=aConfigFlags;
sl@0	922	}
sl@0	923
sl@0	924	TInt TPcCardFunction::ConfigRegAddress(TInt aRegOffset,TInt &anAddr)
sl@0	925	//
sl@0	926	// Provide the specified configuration register address.
sl@0	927	//
sl@0	928	{
sl@0	929
sl@0	930	// Must be configured or we wont have the ConfigReg base address
sl@0	931	if (!IsConfigured())
sl@0	932	return(KErrGeneral);
sl@0	933	anAddr=(iConfigBaseAddr + (aRegOffset<<1));
sl@0	934
sl@0	935	// Return an error if the register isn't present
sl@0	936	if ( !(iConfigRegMask & (0x01<<aRegOffset)) )
sl@0	937	return(KErrNotSupported);
sl@0	938	else
sl@0	939	return(KErrNone);
sl@0	940	}
sl@0	941
sl@0	942	EXPORT_C TPccdChnk::TPccdChnk()
sl@0	943	//
sl@0	944	// Constructor
sl@0	945	//
sl@0	946	: iMemType(EPccdAttribMem),iMemBaseAddr(0),iMemLen(0)
sl@0	947	{}
sl@0	948
sl@0	949	EXPORT_C TPccdChnk::TPccdChnk(TPccdMemType aType,TUint32 aBaseAddr,TUint32 aLen)
sl@0	950	//
sl@0	951	// Constructor
sl@0	952	//
sl@0	953	: iMemType(aType),iMemBaseAddr(aBaseAddr),iMemLen(aLen)
sl@0	954	{}
sl@0	955
sl@0	956	EXPORT_C TPcCardConfig::TPcCardConfig()
sl@0	957	//
sl@0	958	// Constructor (iConfigOption to KInvalidConfOpt guarentees that we start with
sl@0	959	// 1st configuration entry).
sl@0	960	//
sl@0	961	: iAccessSpeed(EAcSpeedInValid),iActiveSignals(0),iVccMaxInMilliVolts(0),
sl@0	962	iVccMinInMilliVolts(0),iValidChunks(0),iIsIoAndMem(FALSE),iIsDefault(FALSE),
sl@0	963	iPwrDown(FALSE),iVppMaxInMilliVolts(0),iVppMinInMilliVolts(0),iOperCurrentInMicroAmps(0),
sl@0	964	iPwrDwnCurrentInMicroAmps(0),iInterruptInfo(0),iConfigOption(KInvalidConfOpt),iConfigBaseAddr(0),
sl@0	965	iRegPresent(0)
sl@0	966	{}
sl@0	967
sl@0	968	EXPORT_C TBool TPcCardConfig::IsMachineCompatible(TSocket aSocket,TInt aFlag)
sl@0	969	//
sl@0	970	// Return ETrue if this configuration is compatible with this machine
sl@0	971	//
sl@0	972	{
sl@0	973
sl@0	974	DPcCardSocket* pS=(DPcCardSocket*)TheSockets[aSocket];
sl@0	975	DPcCardVcc* pV=(DPcCardVcc*)pS->iVcc;
sl@0	976	TInt nomSocketVcc=DPcCardVcc::SocketVccToMilliVolts(pV->VoltageSetting());
sl@0	977	if (!(aFlag&KPccdCompatNoVccCheck))
sl@0	978	{
sl@0	979	// Check Vcc level compatibility
sl@0	980	if (iVccMaxInMilliVolts<nomSocketVcc\|\|iVccMinInMilliVolts>nomSocketVcc)
sl@0	981	{
sl@0	982	__KTRACE_OPT(KPBUS1,Kern::Printf("MachineCompatible-Bad Vcc"));
sl@0	983	return(EFalse);
sl@0	984	}
sl@0	985	}
sl@0	986
sl@0	987	TPcCardSocketInfo si;
sl@0	988	pS->SocketInfo(si);
sl@0	989	if (!(aFlag&KPccdCompatNoVppCheck))
sl@0	990	{
sl@0	991	// Check Vpp level compatibility
sl@0	992	if (iVppMaxInMilliVolts<si.iNomVppInMilliVolts\|\|iVppMinInMilliVolts>si.iNomVppInMilliVolts)
sl@0	993	{
sl@0	994	__KTRACE_OPT(KPBUS1,Kern::Printf("MachineCompatible-Bad Vpp"));
sl@0	995	return(EFalse);
sl@0	996	}
sl@0	997	}
sl@0	998
sl@0	999	if (!(aFlag&KPccdCompatNoPwrCheck))
sl@0	1000	{
sl@0	1001	// Check the configurations power requirements can be supported
sl@0	1002	if (iOperCurrentInMicroAmps>pV->MaxCurrentInMicroAmps())
sl@0	1003	{
sl@0	1004	__KTRACE_OPT(KPBUS1,Kern::Printf("MachineCompatible-Bad Pwr"));
sl@0	1005	return(EFalse);
sl@0	1006	}
sl@0	1007	}
sl@0	1008
sl@0	1009	// If wait requested then check its supported
sl@0	1010	if ((iActiveSignals&KSigWaitRequired)&&!(si.iSupportedSignals&KSigWaitSupported))
sl@0	1011	{
sl@0	1012	__KTRACE_OPT(KPBUS1,Kern::Printf("MachineCompatible-Bad Wait-sig"));
sl@0	1013	return(EFalse);
sl@0	1014	}
sl@0	1015	// Dealt with WAIT - mask out any other signls which aren't supported - not reason to reject though
sl@0	1016	iActiveSignals&=si.iSupportedSignals;
sl@0	1017	return(ETrue);
sl@0	1018	}
sl@0	1019
sl@0	1020	EXPORT_C TPcCardRegion::TPcCardRegion()
sl@0	1021	//
sl@0	1022	// Constructor (iDeviceType to EDeviceInvalid guarentees that we start with
sl@0	1023	// 1st device information entry).
sl@0	1024	//
sl@0	1025	: iAccessSpeed(EAcSpeedInValid),iActiveSignals(0),iVcc(EPccdSocket_Invalid),
sl@0	1026	iDeviceType(EDeviceInvalid),iExtendedAccSpeedInNanoSecs(0)
sl@0	1027	{}
sl@0	1028
sl@0	1029	EXPORT_C TBool TPcCardRegion::IsMachineCompatible(TSocket aSocket)
sl@0	1030	//
sl@0	1031	// Return ETrue if this configuration is compatible with this machine
sl@0	1032	//
sl@0	1033	{
sl@0	1034
sl@0	1035	DPcCardSocket* pS=(DPcCardSocket*)TheSockets[aSocket];
sl@0	1036	TPccdSocketVcc vcc=pS->VccSetting();
sl@0	1037	// Check Vcc level compatibility
sl@0	1038	if (iVcc!=vcc)
sl@0	1039	{
sl@0	1040	__KTRACE_OPT(KPBUS1,Kern::Printf("MachineCompatible-Bad Vcc"));
sl@0	1041	return(EFalse);
sl@0	1042	}
sl@0	1043
sl@0	1044	// If wait requested then check its supported
sl@0	1045	TPcCardSocketInfo si;
sl@0	1046	pS->SocketInfo(si);
sl@0	1047	TBool waitReq=(iActiveSignals&KSigWaitRequired);
sl@0	1048	if (waitReq&&!(si.iSupportedSignals&KSigWaitSupported))
sl@0	1049	{
sl@0	1050	__KTRACE_OPT(KPBUS1,Kern::Printf("MachineCompatible-Bad Wait-sig"));
sl@0	1051	return(EFalse);
sl@0	1052	}
sl@0	1053	// Dealt with WAIT - mask out any other signls which aren't supported - not reason to reject though
sl@0	1054	iActiveSignals&=si.iSupportedSignals;
sl@0	1055
sl@0	1056	// Check requested access speed (ie not too slow for us)
sl@0	1057	TPccdAccessSpeed as=__IS_ATTRIB_MEM(iChnk.iMemType)?si.iMaxAttribAccSpeed:si.iMaxCommonIoAccSpeed;
sl@0	1058	if (iAccessSpeed>as && !waitReq)
sl@0	1059	{
sl@0	1060	__KTRACE_OPT(KPBUS1,Kern::Printf("MachineCompatible-Bad speed"));
sl@0	1061	return(EFalse);
sl@0	1062	}
sl@0	1063	return(ETrue);
sl@0	1064	}
sl@0	1065
sl@0	1066	EXPORT_C TPccdType::TPccdType()
sl@0	1067	//
sl@0	1068	// Constructor
sl@0	1069	//
sl@0	1070	: iFuncCount(0)
sl@0	1071	{
sl@0	1072	for (TInt i=0;i<(TInt)KMaxFuncPerCard;i++)
sl@0	1073	iFuncType[i]=EUnknownCard;
sl@0	1074	}
sl@0	1075
sl@0	1076

author	sl
	Tue, 10 Jun 2014 14:32:02 +0200
changeset 1	260cb5ec6c19
permissions	-rw-r--r--