Source code of Windows XP (NT5)
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45 KiB

/*++
Copyright (c) 1997 Microsoft Corporation
Module Name:
mts.c
Abstract:
MikeTs's little KD extension.
Author:
Michael Tsang (mikets) 18-November-1997
Environment:
User Mode.
Revision History:
--*/
#include "precomp.h"
#include "pcskthw.h"
#include "pci.h"
#pragma hdrstop
BOOL
ReadPci (
IN PPCI_TYPE1_CFG_BITS PciCfg1,
OUT PUCHAR Buffer,
IN ULONG Offset,
IN ULONG Length
);
BOOLEAN
WritePci (
IN PPCI_TYPE1_CFG_BITS PciCfg1,
IN PUCHAR Buffer,
IN ULONG Offset,
IN ULONG Length
);
typedef struct _PCI_BRIDBG_CTRL_REG {
USHORT PERRREnable:1;
USHORT SERREnable:1;
USHORT ISAEnable:1;
USHORT VGAEnable:1;
USHORT Reserved:1;
USHORT MasterAbort:1;
USHORT CBRst:1;
USHORT IRQRoutingEnable:1;
USHORT Mem0Prefetch:1;
USHORT Mem1Prefetch:1;
USHORT WritePostEnable:1;
USHORT Reserved1:5;
} PCI_BRIDBG_CTRL_REG;
VOID PrintClassInfo(PBYTE pb, DWORD dwReg);
void PrintPciStatusReg(
USHORT Status
)
{
if (Status & PCI_STATUS_CAPABILITIES_LIST) {
dprintf("CapList ");
}
if (Status & PCI_STATUS_66MHZ_CAPABLE) {
dprintf("66MHzCapable ");
}
if (Status & PCI_STATUS_UDF_SUPPORTED) {
dprintf("UDFSupported ");
}
if (Status & PCI_STATUS_FAST_BACK_TO_BACK) {
dprintf("FB2BCapable ");
}
if (Status & PCI_STATUS_DATA_PARITY_DETECTED) {
dprintf("DataPERR ");
}
if (Status & PCI_STATUS_SIGNALED_TARGET_ABORT) {
dprintf("TargetDevAbort ");
}
if (Status & PCI_STATUS_RECEIVED_TARGET_ABORT) {
dprintf("TargetAbort ");
}
if (Status & PCI_STATUS_RECEIVED_MASTER_ABORT) {
dprintf("InitiatorAbort ");
}
if (Status & PCI_STATUS_SIGNALED_SYSTEM_ERROR) {
dprintf("SERR ");
}
if (Status & PCI_STATUS_DETECTED_PARITY_ERROR) {
dprintf("PERR ");
}
if (Status & PCI_STATUS_DEVSEL) {
dprintf("DEVSELTiming:%lx",(Status & PCI_STATUS_DEVSEL) >> 9);
}
dprintf("\n");
}
void PrintPciBridgeCtrlReg(
USHORT Bridge
)
{
PCI_BRIDBG_CTRL_REG bReg = *((PCI_BRIDBG_CTRL_REG *) &Bridge);
if (bReg.PERRREnable) {
dprintf("PERRREnable ");
}
if (bReg.SERREnable) {
dprintf("SERREnable ");
}
if (bReg.ISAEnable) {
dprintf("ISAEnable ");
}
if (bReg.MasterAbort) {
dprintf("MasterAbort ");
}
if (bReg.CBRst) {
dprintf("CBRst ");
}
if (bReg.IRQRoutingEnable) {
dprintf("IRQRoutingEnable ");
}
if (bReg.Mem0Prefetch) {
dprintf("Mem0Prefetch ");
}
if (bReg.Mem1Prefetch) {
dprintf("Mem1Prefetch ");
}
if (bReg.WritePostEnable) {
dprintf("WritePostEnable ");
}
dprintf("\n");
}
BOOL
PrintCommonConfigSpace(
PCI_COMMON_CONFIG *pCmnCfg,
PCHAR Pad
)
{
if (!Pad) {
Pad = "";
}
dprintf("%sVendorID %04lx\n", Pad, pCmnCfg->VendorID);
dprintf("%sDeviceID %04lx\n", Pad, pCmnCfg->DeviceID);
dprintf("%sCommand ", Pad);
if (pCmnCfg->Command & PCI_ENABLE_IO_SPACE) {
dprintf("IOSpaceEnable ");
}
if (pCmnCfg->Command & PCI_ENABLE_MEMORY_SPACE) {
dprintf("MemSpaceEnable ");
}
if (pCmnCfg->Command & PCI_ENABLE_BUS_MASTER) {
dprintf("BusInitiate ");
}
if (pCmnCfg->Command & PCI_ENABLE_SPECIAL_CYCLES) {
dprintf("SpecialCycle ");
}
if (pCmnCfg->Command & PCI_ENABLE_WRITE_AND_INVALIDATE) {
dprintf("MemWriteEnable ");
}
if (pCmnCfg->Command & PCI_ENABLE_VGA_COMPATIBLE_PALETTE) {
dprintf("VGASnoop ");
}
if (pCmnCfg->Command & PCI_ENABLE_PARITY) {
dprintf("PERREnable ");
}
if (pCmnCfg->Command & PCI_ENABLE_WAIT_CYCLE) {
dprintf("WaitCycle ");
}
if (pCmnCfg->Command & PCI_ENABLE_SERR) {
dprintf("SERREnable ");
}
if (pCmnCfg->Command & PCI_ENABLE_FAST_BACK_TO_BACK) {
dprintf("FB2BEnable ");
}
dprintf("\n");
dprintf("%sStatus ", Pad);
PrintPciStatusReg(pCmnCfg->Status);
dprintf("%sRevisionID %02lx\n%sProgIF %02lx",
Pad,
pCmnCfg->RevisionID,
Pad,
pCmnCfg->ProgIf);
PrintClassInfo((PBYTE) pCmnCfg, FIELD_OFFSET(PCI_COMMON_CONFIG, ProgIf));
dprintf("%sSubClass %02lx", Pad,
pCmnCfg->SubClass);
PrintClassInfo((PBYTE) pCmnCfg, FIELD_OFFSET(PCI_COMMON_CONFIG, SubClass));
dprintf("%sBaseClass %02lx", Pad,
pCmnCfg->BaseClass);
PrintClassInfo((PBYTE) pCmnCfg, FIELD_OFFSET(PCI_COMMON_CONFIG, BaseClass));
dprintf("%sCacheLineSize %04lx", Pad, pCmnCfg->CacheLineSize);
if (pCmnCfg->CacheLineSize & 0xf0) {
dprintf("BurstDisabled ");
}
if (pCmnCfg->CacheLineSize & 0xf) {
dprintf("Burst4DW");
}
dprintf("\n");
dprintf("%sLatencyTimer %02lx\n", Pad, pCmnCfg->LatencyTimer);
dprintf("%sHeaderType %02lx\n", Pad, pCmnCfg->HeaderType);
dprintf("%sBIST %02lx\n", Pad, pCmnCfg->BIST);
return TRUE;
}
BOOL
PrintCfgSpaceType0(
PCI_COMMON_CONFIG *pCmnCfg,
PCHAR Pad
)
{
int i;
if (!Pad) {
Pad = "";
}
for (i=0; i<PCI_TYPE0_ADDRESSES; ++i) {
dprintf("%sBAR%x %08lx\n", Pad, i, pCmnCfg->u.type0.BaseAddresses[i]);
}
dprintf("%sCBCISPtr %08lx\n", Pad, pCmnCfg->u.type0.CIS);
dprintf("%sSubSysVenID %04lx\n", Pad, pCmnCfg->u.type0.SubVendorID);
dprintf("%sSubSysID %04lx\n", Pad, pCmnCfg->u.type0.SubSystemID);
dprintf("%sROMBAR %08lx\n", Pad, pCmnCfg->u.type0.ROMBaseAddress);
dprintf("%sCapPtr %02lx\n", Pad, pCmnCfg->u.type0.CapabilitiesPtr);
dprintf("%sIntLine %02lx\n", Pad, pCmnCfg->u.type0.InterruptLine);
dprintf("%sIntPin %02lx\n", Pad, pCmnCfg->u.type0.InterruptPin);
dprintf("%sMinGnt %02lx\n", Pad, pCmnCfg->u.type0.MinimumGrant);
dprintf("%sMaxLat %02lx\n", Pad, pCmnCfg->u.type0.MaximumLatency);
return TRUE;
}
BOOL
PrintCfgSpaceType1(
PCI_COMMON_CONFIG *pCmnCfg,
PCHAR Pad
)
{
int i;
if (!Pad) {
Pad = "";
}
for (i=0; i<PCI_TYPE1_ADDRESSES; ++i) {
dprintf("%sBAR%x %08lx\n", Pad, i, pCmnCfg->u.type1.BaseAddresses[i]);
}
dprintf("%sPriBusNum %02lx\n", Pad, pCmnCfg->u.type1.PrimaryBus);
dprintf("%sSecBusNum %02lx\n", Pad, pCmnCfg->u.type1.SecondaryBus);
dprintf("%sSubBusNum %02lx\n", Pad, pCmnCfg->u.type1.SubordinateBus);
dprintf("%sSecLatencyTmr %02lx\n", Pad, pCmnCfg->u.type1.SecondaryLatency);
dprintf("%sIOBase %02lx\n", Pad, pCmnCfg->u.type1.IOBase);
dprintf("%sIOLimit %02lx\n", Pad, pCmnCfg->u.type1.IOLimit);
dprintf("%sSecStatus ",Pad);
PrintPciStatusReg(pCmnCfg->u.type1.SecondaryStatus);
dprintf("%sMemBase %04lx\n", Pad, pCmnCfg->u.type1.MemoryBase);
dprintf("%sMemLimit %04lx\n", Pad, pCmnCfg->u.type1.MemoryLimit);
dprintf("%sPrefMemBase %04lx\n", Pad, pCmnCfg->u.type1.PrefetchBase);
dprintf("%sPrefMemLimit %04lx\n", Pad, pCmnCfg->u.type1.PrefetchLimit);
dprintf("%sPrefBaseHi %08lx\n", Pad, pCmnCfg->u.type1.PrefetchBaseUpper32);
dprintf("%sPrefLimitHi %08lx\n", Pad, pCmnCfg->u.type1.PrefetchLimitUpper32);
dprintf("%sIOBaseHi %04lx\n", Pad, pCmnCfg->u.type1.IOBaseUpper16);
dprintf("%sIOLimitHi %04lx\n", Pad, pCmnCfg->u.type1.IOLimitUpper16);
dprintf("%sCapPtr %02lx\n", Pad, pCmnCfg->u.type1.CapabilitiesPtr);
dprintf("%sROMBAR %08lx\n", Pad, pCmnCfg->u.type1.ROMBaseAddress);
dprintf("%sIntLine %02lx\n", Pad, pCmnCfg->u.type1.InterruptLine);
dprintf("%sIntPin %02lx\n", Pad, pCmnCfg->u.type1.InterruptPin);
dprintf("%sBridgeCtrl %04lx\n", Pad, pCmnCfg->u.type1.BridgeControl);
return TRUE;
}
BOOL
PrintCfgSpaceType2(
PCI_COMMON_CONFIG *pCmnCfg,
PCHAR Pad
)
{
int i;
if (!Pad) {
Pad = "";
}
dprintf("%sRegBaseAddr %08lx\n", Pad, pCmnCfg->u.type2.SocketRegistersBaseAddress);
dprintf("%sCapPtr %02lx\n", Pad, pCmnCfg->u.type2.CapabilitiesPtr);
dprintf("%sSecStatus ", Pad);
PrintPciStatusReg(pCmnCfg->u.type2.SecondaryStatus);
dprintf("%sPCIBusNum %02lx\n", Pad, pCmnCfg->u.type2.PrimaryBus);
dprintf("%sCBBusNum %02lx\n", Pad, pCmnCfg->u.type2.SecondaryBus);
dprintf("%sSubBusNum %02lx\n", Pad, pCmnCfg->u.type2.SubordinateBus);
dprintf("%sCBLatencyTimer %02lx\n", Pad, pCmnCfg->u.type2.SecondaryLatency);
for (i=0; i< PCI_TYPE2_ADDRESSES; ++i) {
dprintf("%sRange[%lx].Base %08lx\n", Pad, i, pCmnCfg->u.type2.Range[i].Base);
dprintf("%sRange[%lx].Limit %08lx\n", Pad, i, pCmnCfg->u.type2.Range[i].Limit);
}
dprintf("%sIntLine %02lx\n", Pad, pCmnCfg->u.type2.InterruptLine);
dprintf("%sIntPin %02lx\n", Pad, pCmnCfg->u.type2.InterruptPin);
dprintf("%sBridgeCtrl %02lx\n", Pad);
PrintPciBridgeCtrlReg(pCmnCfg->u.type2.BridgeControl);
#if 0
// Not part of type2 typedef, but were present in old !dcs
{"SubSysVenID=", (PFMTHDR)&fmtHexWord, NULL},
{"SubSysID=", (PFMTHDR)&fmtHexWord, NULL},
{"LegacyBaseAddr=",(PFMTHDR)&fmtHexDWord, NULL},
#endif
return TRUE;
}
void
PrintDataRange(
PCHAR pData,
ULONG nDwords,
ULONG base,
PCHAR Pad
)
{
unsigned int i;
unsigned int j;
PULONG pRange;
pRange = (PULONG) pData;
if (!Pad) {
Pad = "";
}
for (i=0; i<((nDwords+3)/4); i++) {
dprintf("%s%02lx:", Pad, base + i*16);
for (j=0; (j < 4) && (i*4+j < nDwords); j++) {
dprintf(" %08lx", pRange[i*4+j]);
}
dprintf("\n");
}
}
BOOL
PrintPciCapHeader(
PCI_CAPABILITIES_HEADER *pCapHdr,
PCHAR Pad
)
{
if (!Pad) Pad = "";
dprintf("%sCapID ", Pad);
if (pCapHdr->CapabilityID & PCI_CAPABILITY_ID_POWER_MANAGEMENT) {
dprintf("PwrMgmt ");
}
if (pCapHdr->CapabilityID & PCI_CAPABILITY_ID_AGP) {
dprintf("AGP ");
}
if (pCapHdr->CapabilityID & PCI_CAPABILITY_ID_MSI) {
dprintf("MSI ");
}
dprintf("\n");
dprintf("%sNextPtr %02lx\n", Pad, pCapHdr->Next);
return TRUE;
}
void
PrintPciPwrMgmtCaps(
USHORT Capabilities
)
{
PCI_PMC pmc;
pmc = *((PCI_PMC *) &Capabilities);
if (pmc.PMEClock) {
dprintf("PMECLK ");
}
if (pmc.Rsvd1) {
dprintf("AUXPWR ");
}
if (pmc.DeviceSpecificInitialization) {
dprintf("DSI ");
}
if (pmc.Support.D1) {
dprintf("D1Support ");
}
if (pmc.Support.D2) {
dprintf("D2Support ");
}
if (pmc.Support.PMED0) {
dprintf("PMED0 ");
}
if (pmc.Support.PMED1) {
dprintf("PMED1 ");
}
if (pmc.Support.PMED2) {
dprintf("PMED2 ");
}
if (pmc.Support.PMED3Hot) {
dprintf("PMED3Hot ");
}
if (pmc.Support.PMED3Cold) {
dprintf("PMED3Cold ");
}
dprintf("Version=%lx\n", pmc.Version);
}
BOOL
PrintPciPowerManagement(
PCHAR pData,
PCHAR Pad
)
{
PPCI_PM_CAPABILITY pPmC;
int i;
pPmC = (PPCI_PM_CAPABILITY) pData;
if (!Pad) {
Pad = "";
}
dprintf("%sPwrMgmtCap ", Pad);
PrintPciPwrMgmtCaps(pPmC->PMC.AsUSHORT);
dprintf("%sPwrMgmtCtrl ", Pad);
PCI_PMCSR CtrlStatus = pPmC->PMCSR.ControlStatus;
if (CtrlStatus.PMEEnable) {
dprintf("PMEEnable ");
}
if (CtrlStatus.PMEStatus) {
dprintf("PMESTAT ");
}
dprintf("DataScale:%lx ", CtrlStatus.DataScale);
dprintf("DataSel:%lx ", CtrlStatus.DataSelect);
dprintf("D%lx%s", CtrlStatus.PowerState, (CtrlStatus.PowerState == 3) ? "Hot " : " ");
dprintf("\n");
dprintf("%sPwrMgmtBridge ", Pad);
if (pPmC->PMCSR_BSE.BridgeSupport.D3HotSupportsStopClock) {
dprintf("D3HotStopClock ");
}
if (pPmC->PMCSR_BSE.BridgeSupport.BusPowerClockControlEnabled) {
dprintf("BPCCEnable ");
}
dprintf("\n");
return TRUE;
}
BOOL
PrintPciAGP(
PCHAR pData,
PCHAR Pad
)
{
PPCI_AGP_CAPABILITY pAGP;
int i;
pAGP = (PPCI_AGP_CAPABILITY) pData;
if (!Pad) {
Pad = "";
}
dprintf("%sVersion Major %lx, Minor %lx\n",
Pad,
pAGP->Major,
pAGP->Minor);
dprintf("%sStatus MaxRQDepth:%lx",
Pad,
pAGP->AGPStatus.RequestQueueDepthMaximum);
if (pAGP->AGPStatus.SideBandAddressing) {
dprintf(" SBA");
}
dprintf(" Rate:%lx\n", pAGP->AGPStatus.Rate);
dprintf("%sCommand ", Pad);
if (pAGP->AGPCommand.SBAEnable) {
dprintf("SBAEnable ");
}
if (pAGP->AGPCommand.AGPEnable) {
dprintf("AGPEnable ");
}
dprintf("RQDepth:%lx ", pAGP->AGPCommand.RequestQueueDepth);
dprintf("Rate:%lx ", pAGP->AGPCommand.Rate);
dprintf("\n");
return TRUE;
}
BOOL
PrintPciMSICaps(
PCHAR pData,
PCHAR Pad
)
{
PPCI_PCI_CAPABILITY pMsiCap;
pMsiCap = (PPCI_PCI_CAPABILITY) pData;
if (!Pad) {
Pad = "";
}
dprintf("%sMsgCtrl ", Pad);
if (pMsiCap->MessageControl.CapableOf64Bits) {
dprintf("64BitCapable ");
}
if (pMsiCap->MessageControl.MSIEnable) {
dprintf("MSIEnable ");
}
dprintf("MultipleMsgEnable:%lx ", pMsiCap->MessageControl.MultipleMessageEnable);
dprintf("MultipleMsgCapable:%lx ", pMsiCap->MessageControl.MultipleMessageCapable);
dprintf("%sMsgAddr %lx\n", Pad, pMsiCap->MessageAddress.Raw);
if (pMsiCap->MessageControl.CapableOf64Bits) {
dprintf("%sMsgAddrHi %lx\n", pMsiCap->Data.Bit64.MessageUpperAddress);
dprintf("%sMsData %lx\n", pMsiCap->Data.Bit64.MessageData);
} else {
dprintf("%sMsData %lx\n", pMsiCap->Data.Bit32.MessageData);
}
return TRUE;
}
/*** CardBus Registers
*/
void
PrintCBSktEventReg(
UCHAR Register
)
{
dprintf("%lx ", Register);
if (Register & SKTEVENT_CSTSCHG) {
dprintf("CSTSCHG ");
}
if (Register & SKTEVENT_CCD1) {
dprintf("/CCD1 ");
}
if (Register & SKTEVENT_CCD2) {
dprintf("/CCD2 ");
}
if (Register & SKTEVENT_POWERCYCLE) {
dprintf("PowerCycle ");
}
}
//Socket Mask Register
void
PrintCBSktMaskReg(
UCHAR Register
)
{
dprintf("%lx ", Register);
if (Register & SKTMSK_POWERCYCLE) {
dprintf("PowerCycle ");
}
if (Register & SKTMSK_CSTSCHG) {
dprintf("CSTSCHG ");
}
if ((Register & SKTMSK_CCD) == 0) {
dprintf("CSCDisabled ");
} else if ((Register & SKTMSK_CCD) == SKTMSK_CCD) {
dprintf("CSCEnabled ");
} else {
dprintf("Undefined ");
}
}
//Socket Present State Register
void
PrintCBSktStateReg(
ULONG Register
)
{
dprintf("%08lx ", Register);
if (Register & SKTSTATE_CSTSCHG) {
dprintf("CSTSCHG ");
}
if (Register & SKTSTATE_POWERCYCLE) {
dprintf("PowerCycle ");
}
if (Register & SKTSTATE_CARDTYPE_MASK) {
dprintf("");
}
if (Register & SKTSTATE_R2CARD) {
dprintf("R2Card ");
}
if (Register & SKTSTATE_CBCARD) {
dprintf("CBCard ");
}
if (Register & SKTSTATE_OPTI_DOCK) {
dprintf("OptiDock ");
}
if (Register & SKTSTATE_CARDINT) {
dprintf("CardInt ");
}
if (Register & SKTSTATE_NOTACARD) {
dprintf("NotACard ");
}
if (Register & SKTSTATE_DATALOST) {
dprintf("DataLoss ");
}
if (Register & SKTSTATE_BADVCCREQ) {
dprintf("BadVccReq ");
}
if (Register & SKTSTATE_5VCARD) {
dprintf("5VCard ");
}
if (Register & SKTSTATE_3VCARD) {
dprintf("3VCard ");
}
if (Register & SKTSTATE_XVCARD) {
dprintf("XVCard ");
}
if (Register & SKTSTATE_YVCARD) {
dprintf("YVCard ");
}
if (Register & SKTSTATE_5VSOCKET) {
dprintf("5VSkt ");
}
if (Register & SKTSTATE_3VSOCKET) {
dprintf("3VSkt ");
}
if (Register & SKTSTATE_XVSOCKET) {
dprintf("XVSkt ");
}
if (Register & SKTSTATE_YVSOCKET) {
dprintf("YVSkt ");
}
if ((Register & SKTSTATE_CCD_MASK) == 0) {
dprintf("CardPresent ");
} else if ((Register & SKTSTATE_CCD_MASK) == SKTSTATE_CCD_MASK) {
dprintf("NoCard ");
} else {
dprintf("CardMayPresent ");
}
}
//Socket Control Register
void PrintCBSktCtrlReg(
ULONG Register
)
{
ULONG Ctrl;
dprintf("%08lx ", Register);
Ctrl = Register & SKTPOWER_VPP_CONTROL;
dprintf("Vpp:");
switch (Ctrl) {
case SKTPOWER_VPP_OFF:
dprintf("Off");
break;
case SKTPOWER_VPP_120V:
dprintf("12V");
break;
case SKTPOWER_VPP_050V:
dprintf("5V");
break;
case SKTPOWER_VPP_033V:
dprintf("3.3V");
break;
case SKTPOWER_VPP_0XXV:
dprintf("X.XV");
break;
case SKTPOWER_VPP_0YYV:
dprintf("Y.YV");
break;
}
dprintf(" Vcc:");
switch (Register & SKTPOWER_VCC_CONTROL) {
case SKTPOWER_VCC_OFF:
dprintf("Off");
break;
case SKTPOWER_VCC_050V:
dprintf("5V");
break;
case SKTPOWER_VCC_033V:
dprintf("3.3V");
break;
case SKTPOWER_VCC_0XXV:
dprintf("X.XV");
break;
case SKTPOWER_VCC_0YYV:
dprintf("Y.YV");
break;
}
if (Register & SKTPOWER_STOPCLOCK) {
dprintf(" ClockStopEnabled ");
}
}
BOOL
PrintCBRegs(
PCHAR pData,
PCHAR Pad
)
{
ULONG Off=0;
dprintf("%s%02lx: SktEvent ", Pad, Off);
PrintCBSktEventReg(*pData);
dprintf("\n");
pData+=4; Off+=4;
dprintf("%s%02lx: SktMask ", Pad, Off);
PrintCBSktMaskReg(*pData);
dprintf("\n");
pData+=4; Off+=4;
dprintf("%s%02lx: SktState ", Pad, Off);
PrintCBSktStateReg(*((PULONG)pData));
dprintf("\n");
pData+=4; Off+=4;
dprintf("%s%02lx: SktForce %08lx\n", Pad, Off, *((PULONG)pData));
pData+=4; Off+=4;
dprintf("%s%02lx: SktCtrl ", Pad, Off);
PrintCBSktEventReg(*(pData));
dprintf("\n");
return FALSE;
}
/*** ExCA Registers
*/
void
PrintExCARegs(
PEXCAREGS pExCARegs
)
{
struct _MEMWIN_EXCA {
USHORT Start;
USHORT Stop;
USHORT Offset;
USHORT Reserved;
} MemWin, *pMemWin;
dprintf("%02lx: IDRev %02lx", FIELD_OFFSET(EXCAREGS, bIDRev),pExCARegs->bIDRev);
if ((pExCARegs->bIDRev & IDREV_IFID_MASK) == IDREV_IFID_IO) {
dprintf(" IOOnly");
}
else if ((pExCARegs->bIDRev & IDREV_IFID_MASK) == IDREV_IFID_MEM) {
dprintf(" MemOnly");
} else if ((pExCARegs->bIDRev & IDREV_IFID_MASK) == IDREV_IFID_IOMEM) {
dprintf(" IO&Mem");
}
dprintf(" Rev: %02lx\n", pExCARegs->bIDRev & IDREV_REV_MASK);
dprintf("%02lx: IFStatus %02lx",
FIELD_OFFSET(EXCAREGS, bInterfaceStatus),
pExCARegs->bInterfaceStatus);
if (pExCARegs->bInterfaceStatus & IFS_BVD1) {
dprintf(" BVD1");
}
if (pExCARegs->bInterfaceStatus & IFS_BVD2) {
dprintf(" BVD2");
}
if (pExCARegs->bInterfaceStatus & IFS_CD1) {
dprintf(" CD1");
}
if (pExCARegs->bInterfaceStatus & IFS_CD2) {
dprintf(" CD2");
}
if (pExCARegs->bInterfaceStatus & IFS_WP) {
dprintf(" WP");
}
if (pExCARegs->bInterfaceStatus & IFS_RDYBSY) {
dprintf(" Ready");
}
if (pExCARegs->bInterfaceStatus & IFS_CARDPWR_ACTIVE) {
dprintf(" PowerActive");
}
if (pExCARegs->bInterfaceStatus & IFS_VPP_VALID) {
dprintf(" VppValid");
}
dprintf("\n");
dprintf("%02lx: PwrCtrl %02lx", FIELD_OFFSET(EXCAREGS, bPowerControl), pExCARegs->bPowerControl);
dprintf(" Vpp1=");
switch (pExCARegs->bPowerControl & PC_VPP1_MASK) {
case PC_VPP_NO_CONNECT:
dprintf("Off");
break;
case PC_VPP_SETTO_VCC:
dprintf("Vcc");
break;
case PC_VPP_SETTO_VPP:
dprintf("Vpp");
break;
}
dprintf(" Vpp2=");
switch ((pExCARegs->bPowerControl & PC_VPP2_MASK) >> 4) {
case PC_VPP_NO_CONNECT:
dprintf("Off");
break;
case PC_VPP_SETTO_VCC:
dprintf("Vcc");
break;
case PC_VPP_SETTO_VPP:
dprintf("Vpp");
break;
}
if (pExCARegs->bPowerControl & PC_CARDPWR_ENABLE) {
dprintf(" PwrEnable");
}
if (pExCARegs->bPowerControl & PC_AUTOPWR_ENABLE) {
dprintf(" AutoPwrEnabled");
}
if (pExCARegs->bPowerControl & PC_RESETDRV_DISABLE) {
dprintf(" RESETDRVDisabled");
}
if (pExCARegs->bPowerControl & PC_OUTPUT_ENABLE) {
dprintf(" OutputEnable");
}
dprintf("\n");
dprintf("%02lx: IntGenCtrl %02lx",
FIELD_OFFSET(EXCAREGS, bIntGenControl),
pExCARegs->bIntGenControl);
switch (pExCARegs->bIntGenControl & ~IGC_IRQ_MASK) {
case IGC_INTR_ENABLE:
dprintf(" INTREnable");
break;
case IGC_PCCARD_IO:
dprintf(" IOCard");
break;
case IGC_PCCARD_RESETLO:
dprintf(" ResetOff");
break;
case IGC_RINGIND_ENABLE:
dprintf(" RingIndEnable");
break;
}
dprintf(" CardIRQ:%lx\n", pExCARegs->bIntGenControl & IGC_IRQ_MASK);
dprintf("%02lx: CardStatChange %02lx", FIELD_OFFSET(EXCAREGS, bCardStatusChange), pExCARegs->bCardStatusChange);
if (pExCARegs->bCardStatusChange & CSC_BATT_DEAD) {
dprintf(" BATTDEAD");
}
if (pExCARegs->bCardStatusChange & CSC_BATT_WARNING) {
dprintf(" BATTWARN");
}
if (pExCARegs->bCardStatusChange & CSC_READY_CHANGE) {
dprintf(" RDYC");
}
if (pExCARegs->bCardStatusChange & CSC_CD_CHANGE) {
dprintf(" CDC");
}
dprintf("\n");
dprintf("%02lx: IntConfig %02lx",
FIELD_OFFSET(EXCAREGS, bCardStatusIntConfig),
pExCARegs->bCardStatusIntConfig);
if (pExCARegs->bCardStatusIntConfig & CSCFG_BATT_DEAD) {
dprintf(" BattDeadEnable");
}
if (pExCARegs->bCardStatusIntConfig & CSCFG_BATT_WARNING) {
dprintf(" BattWarnEnable");
}
if (pExCARegs->bCardStatusIntConfig & CSCFG_READY_ENABLE) {
dprintf(" RDYEnable");
}
if (pExCARegs->bCardStatusIntConfig & CSCFG_CD_ENABLE) {
dprintf(" CDEnable");
}
dprintf(" CSCIRQ:%lx\n",(pExCARegs->bCardStatusIntConfig & CSCFG_IRQ_MASK));
dprintf("%02lx: WinEnable %02lx",
FIELD_OFFSET(EXCAREGS, bWindowEnable),
pExCARegs->bWindowEnable);
if (pExCARegs->bWindowEnable & WE_MEM0_ENABLE) {
dprintf(" Mem0Enable");
}
if (pExCARegs->bWindowEnable & WE_MEM1_ENABLE) {
dprintf(" Mem1Enable");
}
if (pExCARegs->bWindowEnable & WE_MEM2_ENABLE) {
dprintf(" Mem2Enable");
}
if (pExCARegs->bWindowEnable & WE_MEM3_ENABLE) {
dprintf(" Mem3Enable");
}
if (pExCARegs->bWindowEnable & WE_MEM4_ENABLE) {
dprintf(" Mem4Enable");
}
if (pExCARegs->bWindowEnable & WE_MEMCS16_DECODE) {
dprintf(" DecodeA23-A12");
}
if (pExCARegs->bWindowEnable & WE_IO0_ENABLE) {
dprintf(" IO0Enable");
}
if (pExCARegs->bWindowEnable & WE_IO1_ENABLE) {
dprintf(" IO1Enable");
}
dprintf("\n");
dprintf("%02lx: IOWinCtrl %02lx",
FIELD_OFFSET(EXCAREGS, bIOControl),
pExCARegs->bIOControl);
if (pExCARegs->bIOControl & IOC_IO0_DATASIZE) {
dprintf(" IO0CardIOCS");
}
if (pExCARegs->bIOControl & IOC_IO0_IOCS16) {
dprintf(" IO016Bit");
}
if (pExCARegs->bIOControl & IOC_IO0_ZEROWS) {
dprintf(" IO0ZeroWS");
}
if (pExCARegs->bIOControl & IOC_IO0_WAITSTATE) {
dprintf(" IO0WS");
}
if (pExCARegs->bIOControl & IOC_IO1_DATASIZE) {
dprintf(" IO1CardIOCS");
}
if (pExCARegs->bIOControl & IOC_IO1_IOCS16) {
dprintf(" IO116Bit");
}
if (pExCARegs->bIOControl & IOC_IO1_ZEROWS) {
dprintf(" IO1ZeroWS");
}
if (pExCARegs->bIOControl & IOC_IO1_WAITSTATE) {
dprintf(" IO1WS");
}
dprintf("\n");
dprintf("%02lx: IOWin0Start %02lx %02lx\n",
FIELD_OFFSET(EXCAREGS, bIO0StartLo),
pExCARegs->bIO0StartHi, pExCARegs->bIO0StartLo);
dprintf("%02lx: IOWin0Stop %02lx %02lx\n",
FIELD_OFFSET(EXCAREGS, bIO0StopLo),
pExCARegs->bIO0StopHi, pExCARegs->bIO0StopLo);
dprintf("%02lx: IOWin1Start %02lx %02lx\n",
FIELD_OFFSET(EXCAREGS, bIO1StartLo),
pExCARegs->bIO1StartHi, pExCARegs->bIO1StartLo);
dprintf("%02lx: IOWin1Stop %02lx %02lx\n",
FIELD_OFFSET(EXCAREGS, bIO1StopLo),
pExCARegs->bIO1StopHi, pExCARegs->bIO1StopLo);
pMemWin = (struct _MEMWIN_EXCA*) &pExCARegs->bMem0StartLo;
for (int i=0;
i<5;
i++, pMemWin++) {
dprintf("%02lx: MemWin%lxStart %04lx",
FIELD_OFFSET(EXCAREGS, bMem0StartLo) + i*sizeof(_MEMWIN_EXCA),
i, pMemWin->Start & MEMBASE_ADDR_MASK);
if (pMemWin->Start & MEMBASE_ZEROWS) {
dprintf(" ZeroWs");
} else if (pMemWin->Start & MEMBASE_16BIT) {
dprintf(" 16Bit");
}
dprintf("\n");
dprintf("%02lx: MemWin%lxStop %04lx, WaitState:%lx\n",
FIELD_OFFSET(EXCAREGS, bMem0StopLo) + i*sizeof(_MEMWIN_EXCA),
i,
(pMemWin->Stop & MEMEND_ADDR_MASK),
(pMemWin->Stop & MEMEND_WS_MASK));
dprintf("%02lx: MemWin%lxOffset %04lx %s%s\n",
FIELD_OFFSET(EXCAREGS, bMem0OffsetLo) + i*sizeof(_MEMWIN_EXCA),
i,
(pMemWin->Offset & MEMOFF_ADDR_MASK),
((pMemWin->Offset & MEMOFF_REG_ACTIVE) ? " RegActive" : ""),
((pMemWin->Offset & MEMOFF_WP) ? " WP" : "")
);
}
}
void
PrintExCAHiRegs(
PUCHAR pExCaReg,
PCHAR Pad
)
{
ULONG Off = sizeof(EXCAREGS);
dprintf("%s%02lx: MemWin0High %02lx\n", Pad, Off++, *(pExCaReg++));
dprintf("%s%02lx: MemWin1High %02lx\n", Pad, Off++, *(pExCaReg++));
dprintf("%s%02lx: MemWin2High %02lx\n", Pad, Off++, *(pExCaReg++));
dprintf("%s%02lx: MemWin3High %02lx\n", Pad, Off++, *(pExCaReg++));
dprintf("%s%02lx: MemWin4High %02lx\n", Pad, Off++, *(pExCaReg++));
dprintf("%s%02lx: CLIOWin0High %02lx\n", Pad, Off++, *(pExCaReg++));
dprintf("%s%02lx: CLIOWin1High %02lx\n", Pad, Off++, *(pExCaReg++));
}
/***LP ReadExCAByte - Read ExCA byte register
*
* ENTRY
* dwBaseAddr - Base port address
* dwReg - register offset
*
* EXIT
* returns data read
*/
BYTE ReadExCAByte(ULONG64 dwBaseAddr, DWORD dwReg)
{
BYTE bData=0;
ULONG ulSize;
ulSize = sizeof(BYTE);
WriteIoSpace64(dwBaseAddr, dwReg, &ulSize);
ulSize = sizeof(BYTE);
ReadIoSpace64(dwBaseAddr + 1, (PULONG)&bData, &ulSize);
return bData;
} //ReadExCAByte
/***LP GetClassDesc - Get class description string
*
* ENTRY
* bBaseClass - Base Class code
* bSubClass - Sub Class code
* bProgIF - Program Interface code
*
* EXIT-SUCCESS
* returns pointer to description string
* EXIT-FAILURE
* returns NULL
*/
PSZ GetClassDesc(BYTE bBaseClass, BYTE bSubClass, BYTE bProgIF)
{
char *psz = NULL;
int i;
static struct classtab_s
{
BYTE bBaseClass;
BYTE bSubClass;
BYTE bProgIF;
PSZ pszDesc;
} ClassTable[] =
{
{0x00, 0xff, 0xff, "Legacy controller"},
{0x00, 0x00, 0x00, "All legacy controller except VGA"},
{0x00, 0x01, 0x00, "All legacy VGA device"},
{0x01, 0xff, 0xff, "Mass storage controller"},
{0x01, 0x00, 0x00, "SCSI bus controller"},
{0x01, 0x01, 0xff, "IDE controller"},
{0x01, 0x02, 0x00, "Floppy disk controller"},
{0x01, 0x03, 0x00, "IPI bus controller"},
{0x01, 0x04, 0x00, "RAID controller"},
{0x01, 0x80, 0x00, "Other mass storage controller"},
{0x02, 0xff, 0xff, "Network controller"},
{0x02, 0x00, 0x00, "Ethernet controller"},
{0x02, 0x01, 0x00, "Token ring controller"},
{0x02, 0x02, 0x00, "FDDI controller"},
{0x02, 0x03, 0x00, "ATM controller"},
{0x02, 0x80, 0x00, "Other network controller"},
{0x03, 0xff, 0xff, "Display controller"},
{0x03, 0x00, 0x00, "VGA compatible controller"},
{0x03, 0x00, 0x01, "8514 compatible controller"},
{0x03, 0x01, 0x00, "XGA controller"},
{0x03, 0x80, 0x00, "Other display controller"},
{0x04, 0xff, 0xff, "Multimedia device"},
{0x04, 0x00, 0x00, "Video device"},
{0x04, 0x01, 0x00, "Audio device"},
{0x04, 0x80, 0x00, "Other multimedia device"},
{0x05, 0xff, 0xff, "Memory controller"},
{0x05, 0x00, 0x00, "RAM controller"},
{0x05, 0x01, 0x00, "Flash controller"},
{0x05, 0x80, 0x00, "Other memory controller"},
{0x06, 0xff, 0xff, "Bridge device"},
{0x06, 0x00, 0x00, "Host bridge"},
{0x06, 0x01, 0x00, "ISA bridge"},
{0x06, 0x02, 0x00, "EISA bridge"},
{0x06, 0x03, 0x00, "MCA bridge"},
{0x06, 0x04, 0x00, "PCI-PCI bridge"},
{0x06, 0x05, 0x00, "PCMCIA bridge"},
{0x06, 0x06, 0x00, "NuBus bridge"},
{0x06, 0x07, 0x00, "CardBus bridge"},
{0x06, 0x80, 0x00, "Other bridge device"},
{0x07, 0xff, 0xff, "Simple com device"},
{0x07, 0x00, 0x00, "Generic XT compatible serial controller"},
{0x07, 0x00, 0x01, "16450 compatible serial controller"},
{0x07, 0x00, 0x02, "16550 compatible serial controller"},
{0x07, 0x01, 0x00, "Parallel port"},
{0x07, 0x01, 0x01, "Bidirectional parallel port"},
{0x07, 0x01, 0x02, "ECP 1.X compliant parallel port"},
{0x07, 0x80, 0x00, "Other communication device"},
{0x08, 0xff, 0xff, "Base system peripherals"},
{0x08, 0x00, 0x00, "Generic 8259 PIC"},
{0x08, 0x00, 0x01, "ISA PIC"},
{0x08, 0x00, 0x02, "EISA PIC"},
{0x08, 0x01, 0x00, "Generic 8237 DMA controller"},
{0x08, 0x01, 0x01, "ISA DMA controller"},
{0x08, 0x01, 0x02, "EISA DMA controller"},
{0x08, 0x02, 0x00, "Generic 8254 system timer"},
{0x08, 0x02, 0x01, "ISA system timer"},
{0x08, 0x02, 0x02, "EISA system timer"},
{0x08, 0x03, 0x00, "Generic RTC controller"},
{0x08, 0x03, 0x01, "ISA RTC controller"},
{0x08, 0x80, 0x00, "Other system peripheral"},
{0x09, 0xff, 0xff, "Input device"},
{0x09, 0x00, 0x00, "Keyboard controller"},
{0x09, 0x01, 0x00, "Digitizer (pen)"},
{0x09, 0x02, 0x00, "Mouse controller"},
{0x09, 0x80, 0x00, "Other input controller"},
{0x0a, 0xff, 0xff, "Docking station"},
{0x0a, 0x00, 0x00, "Generic docking station"},
{0x0a, 0x80, 0x00, "Other type of docking station"},
{0x0b, 0xff, 0xff, "Processor"},
{0x0b, 0x00, 0x00, "386"},
{0x0b, 0x01, 0x00, "486"},
{0x0b, 0x02, 0x00, "Pentium"},
{0x0b, 0x10, 0x00, "Alpha"},
{0x0b, 0x20, 0x00, "PowerPC"},
{0x0b, 0x40, 0x00, "Co-processor"},
{0x0c, 0xff, 0xff, "Serial bus controller"},
{0x0c, 0x00, 0x00, "FireWire (IEEE 1394)"},
{0x0c, 0x01, 0x00, "ACCESS bus"},
{0x0c, 0x02, 0x00, "SSA"},
{0x0c, 0x03, 0x00, "Universal Serial Bus (USB)"},
{0x0c, 0x04, 0x00, "Fibre Channel"},
{0xff, 0xff, 0xff, "Unknown"},
{0x00, 0x00, 0x00, NULL}
};
for (i = 0; ClassTable[i].pszDesc != NULL; ++i)
{
if ((ClassTable[i].bBaseClass == bBaseClass) &&
(ClassTable[i].bSubClass == bSubClass) &&
(ClassTable[i].bProgIF == bProgIF))
{
psz = ClassTable[i].pszDesc;
}
}
return psz;
} //GetClassDesc
/***LP PrintClassInfo - Print device class info.
*
* ENTRY
* pb -> ConfigSpace
* dwReg - ConfigSpace register
*
* EXIT
* None
*/
VOID PrintClassInfo(PBYTE pb, DWORD dwReg)
{
PPCI_COMMON_CONFIG pcc = (PPCI_COMMON_CONFIG) pb;
BYTE bBaseClass, bSubClass, bProgIF;
PSZ psz;
if (dwReg == FIELD_OFFSET(PCI_COMMON_CONFIG ,BaseClass))
{
bBaseClass = pcc->BaseClass;
bSubClass = 0xff;
bProgIF = 0xff;
}
else if (dwReg == FIELD_OFFSET(PCI_COMMON_CONFIG ,SubClass))
{
bBaseClass = pcc->BaseClass;
bSubClass = pcc->SubClass;
bProgIF = 0xff;
}
else //must be CFGSPACE_CLASSCODE_PI
{
bBaseClass = pcc->BaseClass;
bSubClass = pcc->SubClass;
bProgIF = pcc->ProgIf;
}
if ((psz = GetClassDesc(bBaseClass, bSubClass, bProgIF)) != NULL)
dprintf(" (%s)", psz);
else if ((bBaseClass == 0x01) && (bSubClass == 0x01) && (bProgIF != 0xff) &&
(bProgIF != 0x00))
{
dprintf(" (");
if (bProgIF & 0x80)
dprintf("MasterIDE ");
if (bProgIF & 0x02)
dprintf("PriNativeCapable ");
if (bProgIF & 0x01)
dprintf("PriNativeMode ");
if (bProgIF & 0x08)
dprintf("SecNativeCapable ");
if (bProgIF & 0x04)
dprintf("SecNativeMode");
dprintf(")");
}
dprintf("\n");
} //PrintClassInfo
VOID
DumpCfgSpace (
IN PPCI_COMMON_CONFIG pcs
)
{
BYTE bHeaderType = pcs->HeaderType & ~PCI_MULTIFUNCTION;
DWORD dwOffset;
PSZ pszDataFmt = "%02x: ";
dwOffset = 0;
if (PrintCommonConfigSpace(pcs, " ")) {
switch (bHeaderType)
{
case PCI_DEVICE_TYPE:
dprintf(" DeviceType (@%02lx):\n", FIELD_OFFSET(PCI_COMMON_CONFIG,u));
PrintCfgSpaceType0(pcs, " ");
break;
case PCI_BRIDGE_TYPE:
dprintf(" BridgeType (@%02lx):\n", FIELD_OFFSET(PCI_COMMON_CONFIG,u));
PrintCfgSpaceType1(pcs, " ");
break;
case PCI_CARDBUS_BRIDGE_TYPE:
dprintf(" CardBusBridgeType (@%02lx):\n", FIELD_OFFSET(PCI_COMMON_CONFIG,u));
PrintCfgSpaceType2(pcs, " ");
break;
default:
dprintf(" TypeUnknown:\n");
PrintDataRange((PCHAR) &pcs->u, 12, FIELD_OFFSET(PCI_COMMON_CONFIG, u), " ");
}
if ((pcs->Status & PCI_STATUS_CAPABILITIES_LIST)) {
if (bHeaderType == PCI_DEVICE_TYPE) {
dwOffset = pcs->u.type0.CapabilitiesPtr;
}
else if (bHeaderType == PCI_BRIDGE_TYPE) {
dwOffset = pcs->u.type1.CapabilitiesPtr;
}
else if (bHeaderType == PCI_CARDBUS_BRIDGE_TYPE) {
dwOffset = pcs->u.type2.CapabilitiesPtr;
}
else {
dwOffset = 0;
}
dprintf(" Capabilities (@%02lx):\n", dwOffset);
while ((dwOffset != 0)) {
PPCI_CAPABILITIES_HEADER pCap;
pCap = (PPCI_CAPABILITIES_HEADER)&((PBYTE)pcs)[dwOffset];
if (PrintPciCapHeader(pCap, " ")) {
switch (pCap->CapabilityID) {
case PCI_CAPABILITY_ID_POWER_MANAGEMENT:
PrintPciPowerManagement(((PCHAR)pCap), " ");
break;
case PCI_CAPABILITY_ID_AGP:
PrintPciAGP(((PCHAR)pCap), " ");
break;
case PCI_CAPABILITY_ID_MSI:
PrintPciMSICaps(((PCHAR)pCap), " ");
break;
}
dwOffset = pCap->Next;
} else {
break;
}
}
}
}
PrintDataRange((PCHAR) pcs, sizeof(PCI_COMMON_CONFIG)/4, 0, " ");
}
/***LP DumpCBRegs - Dump CardBus registers
*
* ENTRY
* pbBuff -> register base
*
* EXIT
* None
*/
VOID DumpCBRegs(PBYTE pbBuff)
{
PrintCBRegs((PCHAR) pbBuff, "");
} //DumpCBRegs
/***LP DumpExCARegs - Dump ExCA registers
*
* ENTRY
* pbBuff -> buffer
* dwSize - size of buffer
*
* EXIT
* None
*/
VOID DumpExCARegs(PBYTE pbBuff, DWORD dwSize)
{
DWORD dwOffset = 0;
char *pszDataFmt = "%02x: ";
PrintExCARegs((PEXCAREGS) pbBuff);
PrintExCAHiRegs(pbBuff + sizeof(EXCAREGS), "");
} //DumpExCARegs
DECLARE_API( dcs )
/*++
Routine Description:
Dumps PCI ConfigSpace
Arguments:
args - Supplies the Bus.Dev.Fn numbers
Return Value:
None
--*/
{
LONG lcArgs;
DWORD dwBus = 0;
DWORD dwDev = 0;
DWORD dwFn = 0;
lcArgs = sscanf(args, "%lx.%lx.%lx", &dwBus, &dwDev, &dwFn);
dprintf("!dcs now integrated into !pci 1xx (flag 100).\n"
"Use !pci 100 %lx %lx %lx to dump PCI config space.\n",
dwBus, dwDev, dwFn);
return E_INVALIDARG;
if (lcArgs != 3)
{
dprintf("invalid command syntax\n"
"Usage: dcs <Bus>.<Dev>.<Func>\n");
}
else
{
PCI_TYPE1_CFG_BITS PciCfg1;
PCI_COMMON_CONFIG cs;
PciCfg1.u.AsULONG = 0;
PciCfg1.u.bits.BusNumber = dwBus;
PciCfg1.u.bits.DeviceNumber = dwDev;
PciCfg1.u.bits.FunctionNumber = dwFn;
PciCfg1.u.bits.Enable = TRUE;
ReadPci(&PciCfg1, (PUCHAR)&cs, 0, sizeof(cs));
DumpCfgSpace(&cs);
}
return S_OK;
}
DECLARE_API( ecs )
/*++
Routine Description:
Edit PCI ConfigSpace
Arguments:
args - Bus.Dev.Fn
Dword Offset
Data
Return Value:
None
--*/
{
dprintf("Edit PCI ConfigSpace - must use one of the following:\n"
"!ecd - edit dword\n"
"!ecw - edit word\n"
"!ecb - edit byte\n");
return S_OK;
}
DECLARE_API( ecb )
/*++
Routine Description:
Edit PCI ConfigSpace BYTE
Arguments:
args - Bus.Dev.Fn Offset Data
Return Value:
None
--*/
{
LONG lcArgs;
DWORD bus = 0, dev = 0, fn = 0;
DWORD offset = 0, data = 0;
PCI_TYPE1_CFG_BITS pcicfg;
lcArgs = sscanf(args, "%lx.%lx.%lx %lx %lx", &bus, &dev, &fn, &offset, &data);
if (lcArgs != 5)
{
dprintf("invalid command syntax\n"
"Usage: ecb <Bus>.<Dev>.<Func> Offset Data\n");
}else{
//
// Init for PCI config.
//
pcicfg.u.AsULONG = 0;
pcicfg.u.bits.BusNumber = bus;
pcicfg.u.bits.DeviceNumber = dev;
pcicfg.u.bits.FunctionNumber = fn;
pcicfg.u.bits.Enable = TRUE;
if (!(WritePci (&pcicfg, (PUCHAR)&data, offset, sizeof(UCHAR)))){
dprintf("write operation failed!\n");
return S_FALSE;
}
}
return S_OK;
}
DECLARE_API( ecw )
/*++
Routine Description:
Edit PCI ConfigSpace WORD
Arguments:
args - Bus.Dev.Fn Offset Data
Return Value:
None
--*/
{
LONG lcArgs;
DWORD bus = 0, dev = 0, fn = 0;
DWORD offset = 0, data = 0;
PCI_TYPE1_CFG_BITS pcicfg;
lcArgs = sscanf(args, "%lx.%lx.%lx %lx %lx", &bus, &dev, &fn, &offset, &data);
if (lcArgs != 5)
{
dprintf("invalid command syntax\n"
"Usage: ecw <Bus>.<Dev>.<Func> Offset Data\n");
}else{
if ((offset & 0x1) || (offset > 0xfe)) {
//
// not word aligned.
//
dprintf("offset must be word aligned and no greater than 0xfe\n");
return S_OK;
}
//
// Init for PCI config.
//
pcicfg.u.AsULONG = 0;
pcicfg.u.bits.BusNumber = bus;
pcicfg.u.bits.DeviceNumber = dev;
pcicfg.u.bits.FunctionNumber = fn;
pcicfg.u.bits.Enable = TRUE;
if (!(WritePci (&pcicfg, (PUCHAR)&data, offset, sizeof(USHORT)))){
dprintf("write operation failed!\n");
return S_FALSE;
}
}
return S_OK;
}
DECLARE_API( ecd )
/*++
Routine Description:
Edit PCI ConfigSpace DWORD
Arguments:
args - Bus.Dev.Fn Offset Data
Return Value:
None
--*/
{
LONG lcArgs;
DWORD bus = 0, dev = 0, fn = 0;
DWORD offset = 0, data = 0;
PCI_TYPE1_CFG_BITS pcicfg;
lcArgs = sscanf(args, "%lx.%lx.%lx %lx %lx", &bus, &dev, &fn, &offset, &data);
if (lcArgs != 5)
{
dprintf("invalid command syntax\n"
"Usage: ecd <Bus>.<Dev>.<Func> Offset Data\n");
}else{
if ((offset & 0x3) || (offset > 0xfc)) {
//
// not dword aligned.
//
dprintf("offset must be dword aligned and no greater than 0xfc\n");
return S_OK;
}
//
// Init for PCI config.
//
pcicfg.u.AsULONG = 0;
pcicfg.u.bits.BusNumber = bus;
pcicfg.u.bits.DeviceNumber = dev;
pcicfg.u.bits.FunctionNumber = fn;
pcicfg.u.bits.Enable = TRUE;
if (!(WritePci (&pcicfg, (PUCHAR)&data, offset, sizeof(ULONG)))){
dprintf("write operation failed!\n");
return S_FALSE;
}
}
return S_OK;
}
DECLARE_API( cbreg )
/*++
Routine Description:
Dumps CardBus registers
Arguments:
args - Supplies the address in hex.
Return Value:
None
--*/
{
BOOL rc = TRUE;
LONG lcArgs;
BOOL fPhysical = FALSE;
DWORD dwAddr = 0;
if (args == NULL)
{
dprintf("invalid command syntax\n"
"Usage: cbreg <RegBaseAddr>\n");
rc = FALSE;
}
else if ((args[0] == '%') && (args[1] == '%'))
{
lcArgs = sscanf(&args[2], "%lx", &dwAddr);
fPhysical = TRUE;
}
else
{
lcArgs = sscanf(args, "%lx", &dwAddr);
}
if ((rc == TRUE) && (lcArgs == 1))
{
BYTE abCBRegs[0x14];
BYTE abExCARegs[0x47];
DWORD dwSize;
if (fPhysical)
{
ULONG64 phyaddr = 0;
phyaddr = dwAddr;
ReadPhysical(phyaddr, abCBRegs, sizeof(abCBRegs), &dwSize);
if (dwSize != sizeof(abCBRegs))
{
dprintf("failed to read physical CBRegs (SizeRead=%x)\n",
dwSize);
rc = FALSE;
}
else
{
phyaddr += 0x800;
ReadPhysical(phyaddr, abExCARegs, sizeof(abExCARegs), &dwSize);
if (dwSize != sizeof(abExCARegs))
{
dprintf("failed to read physical ExCARegs (SizeRead=%x)\n",
dwSize);
rc = FALSE;
}
}
}
else if (!ReadMemory(dwAddr, abCBRegs, sizeof(abCBRegs), &dwSize) ||
(dwSize != sizeof(abCBRegs)))
{
dprintf("failed to read CBRegs (SizeRead=%x)\n", dwSize);
rc = FALSE;
}
else if (!ReadMemory(dwAddr + 0x800, abExCARegs, sizeof(abExCARegs),
&dwSize) ||
(dwSize != sizeof(abExCARegs)))
{
dprintf("failed to read CBRegs (SizeRead=%x)\n", dwSize);
rc = FALSE;
}
if (rc == TRUE)
{
dprintf("\nCardBus Registers:\n");
DumpCBRegs(abCBRegs);
dprintf("\nExCA Registers:\n");
DumpExCARegs(abExCARegs, sizeof(abExCARegs));
}
}
return S_OK;
}
DECLARE_API( exca )
/*++
Routine Description:
Dumps CardBus ExCA registers
Arguments:
args - Supplies <BasePort>.<SktNum>
Return Value:
None
--*/
{
LONG lcArgs;
DWORD dwBasePort = 0;
DWORD dwSktNum = 0;
if (TargetMachine != IMAGE_FILE_MACHINE_I386) {
dprintf("X86 target only API.\n");
return E_INVALIDARG;
}
lcArgs = sscanf(args, "%lx.%lx", &dwBasePort, &dwSktNum);
if (lcArgs != 2)
{
dprintf("invalid command syntax\n"
"Usage: exca <BasePort>.<SocketNum>\n");
}
else
{
int i;
BYTE abExCARegs[0x40];
for (i = 0; i < sizeof(abExCARegs); ++i)
{
abExCARegs[i] = ReadExCAByte(dwBasePort,
(ULONG)(dwSktNum*0x40 + i));
}
DumpExCARegs(abExCARegs, sizeof(abExCARegs));
}
return S_OK;
}