/*++ Copyright (c) 1997-2000 Microsoft Corporation Module Name: id.c Abstract: This module contains functions used in the generation of responses to a IRP_MN_QUERY_ID IRP. Author: Peter Johnston (peterj) 08-Mar-1997 Revision History: --*/ #include "pcip.h" //++ // // PciQueryId returns UNICODE strings when the ID type is DeviceID // or InstanceID. For HardwareIDs and CompatibleIDs it returns a // a zero terminated list of zero terminated UNICODE strings (MULTI_SZ). // // The normal process of converting a string to a unicode string involves // taking it's length, allocating pool memory for the new string and // calling RtlAnsiStringToUnicodeString to do the conversion. The following // is an attempt to be a little more efficient in terms of both size and // speed by keeping track of the relevant string data as it goes past in // the process of creating the set of strings. // //-- #define MAX_ANSI_STRINGS 8 #define MAX_ANSI_BUFFER 256 typedef struct _PCI_ID_BUFFER { ULONG Count; // number of ansi strings ANSI_STRING AnsiStrings[MAX_ANSI_STRINGS]; USHORT UnicodeSZSize[MAX_ANSI_STRINGS]; USHORT UnicodeBufferSize; PUCHAR NextFree; // first unused byte in buffer UCHAR Bytes[MAX_ANSI_BUFFER];// buffer start address } PCI_ID_BUFFER, *PPCI_ID_BUFFER; // // All functins in this module are pageable. // // Define prototypes for module local functions. // VOID PciIdPrintf( IN PPCI_ID_BUFFER IdBuffer, PCCHAR Format, ... ); VOID PciIdPrintfAppend( IN PPCI_ID_BUFFER IdBuffer, PCCHAR Format, ... ); VOID PciInitIdBuffer( IN PPCI_ID_BUFFER IdBuffer ); #ifdef ALLOC_PRAGMA #pragma alloc_text(PAGE, PciGetDeviceDescriptionMessage) #pragma alloc_text(PAGE, PciIdPrintf) #pragma alloc_text(PAGE, PciIdPrintfAppend) #pragma alloc_text(PAGE, PciInitIdBuffer) #pragma alloc_text(PAGE, PciQueryId) #pragma alloc_text(PAGE, PciQueryDeviceText) #endif VOID PciInitIdBuffer( IN PPCI_ID_BUFFER IdBuffer ) { IdBuffer->NextFree = IdBuffer->Bytes; IdBuffer->UnicodeBufferSize = 0; IdBuffer->Count = 0; } VOID PciIdPrintf( IN PPCI_ID_BUFFER IdBuffer, PCCHAR Format, ... ) { LONG length; ULONG index; PUCHAR buffer; LONG maxLength; va_list ap; PANSI_STRING ansiString; ASSERT(IdBuffer->Count < MAX_ANSI_STRINGS); // // Make my life easier, keep repeated values in locals. // index = IdBuffer->Count; buffer = IdBuffer->NextFree; maxLength = MAX_ANSI_BUFFER - (LONG)(buffer - IdBuffer->Bytes); ansiString = &IdBuffer->AnsiStrings[index]; // // Pass the format string and subsequent data into (effectively) // sprintf. // va_start(ap, Format); length = _vsnprintf(buffer, maxLength, Format, ap); va_end(ap); ASSERT(length < maxLength); // // RtlInitAnsiString without the strlen. // ansiString->Buffer = buffer; ansiString->Length = (USHORT)length; ansiString->MaximumLength = (USHORT)length; // // Get the length of this string in a unicode world and record it // for later when the whole set of strings gets converted (keep // the total size also). // IdBuffer->UnicodeSZSize[index] = (USHORT)RtlAnsiStringToUnicodeSize(ansiString); IdBuffer->UnicodeBufferSize += IdBuffer->UnicodeSZSize[index]; // // Bump buffer pointer for next iteration and the count. // IdBuffer->NextFree += length + 1; IdBuffer->Count++; } VOID PciIdPrintfAppend( IN PPCI_ID_BUFFER IdBuffer, PCCHAR Format, ... ) { LONG length; ULONG index; PUCHAR buffer; LONG maxLength; va_list ap; PANSI_STRING ansiString; ASSERT(IdBuffer->Count); // // Make my life easier, keep repeated values in locals. // index = IdBuffer->Count - 1; buffer = IdBuffer->NextFree - 1; maxLength = MAX_ANSI_BUFFER - (LONG)(buffer - IdBuffer->Bytes); ansiString = &IdBuffer->AnsiStrings[index]; // // Pass the format string and subsequent data into (effectively) // sprintf. // va_start(ap, Format); length = _vsnprintf(buffer, maxLength, Format, ap); va_end(ap); ASSERT(length < maxLength); // // Increase the ansi string length by the length of the new // portion of the string. // ansiString->Length += (USHORT)length; ansiString->MaximumLength += (USHORT)length; // // Get the length of this string in a unicode world and record it // for later when the whole set of strings gets converted (keep // the total size also). // IdBuffer->UnicodeSZSize[index] = (USHORT)RtlAnsiStringToUnicodeSize(ansiString); IdBuffer->UnicodeBufferSize += IdBuffer->UnicodeSZSize[index]; // // Bump buffer pointer for next iteration. // IdBuffer->NextFree += length; } NTSTATUS PciQueryId( IN PPCI_PDO_EXTENSION PdoExtension, IN BUS_QUERY_ID_TYPE IdType, IN OUT PWSTR *BusQueryId ) { PCI_ID_BUFFER idBuffer; UCHAR venDevString[sizeof("PCI\\VEN_vvvv&DEV_dddd")]; NTSTATUS status; UNICODE_STRING unicodeId; PVOID unicodeBuffer; ULONG i; ULONG subsystem; PPCI_PDO_EXTENSION current; PAGED_CODE(); *BusQueryId = NULL; // // In all the following we want PCI\VEN_vvvv&DEV_dddd. // sprintf(venDevString, "PCI\\VEN_%04X&DEV_%04X", PdoExtension->VendorId, PdoExtension->DeviceId); PciInitIdBuffer(&idBuffer); subsystem = (PdoExtension->SubsystemId << 16) | PdoExtension->SubsystemVendorId; switch (IdType) { case BusQueryInstanceID: // // Caller wants an instance ID for this device. The PCI // driver reports that it does NOT generate unique IDs for // devices so PnP Manager will prepend bus information. // // The instance ID is of the form- // // AABBCCDDEEFF...XXYYZZ // // Where AA is the slot number (device/function) of the device // on the bus, BB, CC,... XX, YY, ZZ are the slot number of the // PCI-to-PCI bridges on their parent busses all the way up to // the root. A device on the root bus will have only one entry, // AA. // current = PdoExtension; // // Initialize empty buffer. // PciIdPrintf(&idBuffer,""); for (;;) { PciIdPrintfAppend(&idBuffer, "%02X", PCI_DEVFUNC(current) ); if (PCI_PDO_ON_ROOT(current)) { break; } current = PCI_PARENT_PDO(current)->DeviceExtension; } break; case BusQueryHardwareIDs: case BusQueryDeviceID: // // Hardware and Compatible IDs are generated as specified // in the ACPI spec (section 6.1.2 in version 0.9). // // Hardware IDs are a list of identifiers of the form // // PCI\VEN_vvvv&DEV_dddd&SUBSYS_ssssssss&REV_rr // PCI\VEN_vvvv&DEV_dddd&SUBSYS_ssssssss // PCI\VEN_vvvv&DEV_dddd&REV_rr // PCI\VEN_vvvv&DEV_dddd // // Where vvvv is the Vendor ID from config space, // dddd is the Device ID, // ssssssss is the Subsystem ID/Subsystem Vendor ID, and // rr is the Revision ID. // // Device ID is the same as the first Hardware ID (ie most // specific of all possible IDs). // PciIdPrintf(&idBuffer, "%s&SUBSYS_%08X&REV_%02X", venDevString, subsystem, PdoExtension->RevisionId); if (IdType == BusQueryDeviceID) { break; } PciIdPrintf(&idBuffer, "%s&SUBSYS_%08X", venDevString, subsystem); // // Fall thru. // case BusQueryCompatibleIDs: // // If the subsystem is non-zero, the second two are compatible // IDs, otherwise they are hardware IDs. // if (((subsystem == 0) && (IdType == BusQueryHardwareIDs)) || ((subsystem != 0) && (IdType == BusQueryCompatibleIDs))) { PciIdPrintf(&idBuffer, "%s&REV_%02X", venDevString, PdoExtension->RevisionId); // // Device ID is PCI\VEN_vvvv&DEV_dddd // PciIdPrintf(&idBuffer, "%s", venDevString); } if (IdType == BusQueryHardwareIDs) { // // The comment in the Memphis code says "Add // special Intel entry". Odd that these entries // are absent from the spec. They are added for // PIIX4 which has the same vendor and device IDs // for two different sub class codes. // // These two entries are // // PCI\VEN_vvvv&DEV_dddd&CC_ccsspp // PCI\VEN_vvvv&DEV_dddd&CC_ccss // // (See below for cc, ss and pp explanaitions). // PciIdPrintf(&idBuffer, "%s&CC_%02X%02X%02X", venDevString, PdoExtension->BaseClass, PdoExtension->SubClass, PdoExtension->ProgIf); PciIdPrintf(&idBuffer, "%s&CC_%02X%02X", venDevString, PdoExtension->BaseClass, PdoExtension->SubClass); } if (IdType == BusQueryCompatibleIDs) { // // The Compatible IDs list, consists of the above plus // // PCI\VEN_vvvv&CC_ccsspp // PCI\VEN_vvvv&CC_ccss // PCI\VEN_vvvv // PCI\CC_ccsspp // PCI\CC_ccss // // Where cc is the Class Code from config space, // ss is the Sub-Class Code, and // pp is the programming interface. // // WARNING: Revise the size of the buffer if you increase // the above list. // PciIdPrintf(&idBuffer, "PCI\\VEN_%04X&CC_%02X%02X%02X", PdoExtension->VendorId, PdoExtension->BaseClass, PdoExtension->SubClass, PdoExtension->ProgIf); PciIdPrintf(&idBuffer, "PCI\\VEN_%04X&CC_%02X%02X", PdoExtension->VendorId, PdoExtension->BaseClass, PdoExtension->SubClass); PciIdPrintf(&idBuffer, "PCI\\VEN_%04X", PdoExtension->VendorId); PciIdPrintf(&idBuffer, "PCI\\CC_%02X%02X%02X", PdoExtension->BaseClass, PdoExtension->SubClass, PdoExtension->ProgIf); PciIdPrintf(&idBuffer, "PCI\\CC_%02X%02X", PdoExtension->BaseClass, PdoExtension->SubClass); } // // HardwareIDs and CompatibleIDs are MULTI_SZ, add a // NULL list to terminate it all. // PciIdPrintf(&idBuffer, ""); break; default: PciDebugPrint(PciDbgVerbose, "PciQueryId expected ID type = %d\n", IdType); //ASSERT(0 && "Unexpected BUS_QUERY_ID_TYPE"); return STATUS_NOT_SUPPORTED; } ASSERT(idBuffer.Count > 0); // // What we have is a (bunch of) ansi strings. What we need is a // (bunch of) unicode strings. // unicodeBuffer = ExAllocatePool(PagedPool | POOL_COLD_ALLOCATION, idBuffer.UnicodeBufferSize); if (unicodeBuffer == NULL) { return STATUS_INSUFFICIENT_RESOURCES; } // // Build the (possibly MULTI_SZ) unicode string(s). // PciDebugPrint(PciDbgPrattling, "PciQueryId(%d)\n", IdType); unicodeId.Buffer = unicodeBuffer; unicodeId.MaximumLength = idBuffer.UnicodeBufferSize; for (i = 0; i < idBuffer.Count; i++) { PciDebugPrint(PciDbgPrattling, " <- \"%s\"\n", idBuffer.AnsiStrings[i].Buffer); status = RtlAnsiStringToUnicodeString(&unicodeId, &idBuffer.AnsiStrings[i], FALSE); if (!NT_SUCCESS(status)) { ASSERT(NT_SUCCESS(status)); ExFreePool(unicodeBuffer); return status; } // // Bump the base pointer and decrement the max length for the // next trip thru the loop. // (ULONG_PTR)unicodeId.Buffer += idBuffer.UnicodeSZSize[i]; unicodeId.MaximumLength -= idBuffer.UnicodeSZSize[i]; } *BusQueryId = unicodeBuffer; return status; } PWSTR PciGetDescriptionMessage( IN ULONG MessageNumber ) { PWSTR description = NULL; NTSTATUS status; PMESSAGE_RESOURCE_ENTRY messageEntry; status = RtlFindMessage(PciDriverObject->DriverStart, 11, // <-- I wonder what this is. LANG_NEUTRAL, MessageNumber, &messageEntry); if (NT_SUCCESS(status)) { if (messageEntry->Flags & MESSAGE_RESOURCE_UNICODE) { // // Our caller wants a copy they can free, also we need to // strip the trailing CR/LF. The Length field of the // message structure includes both the header and the // actual text. // // Note: The message resource entry length will always be a // multiple of 4 bytes in length. The 2 byte null terminator // could be in either the last or second last WCHAR position. // ULONG textLength; textLength = messageEntry->Length - FIELD_OFFSET(MESSAGE_RESOURCE_ENTRY, Text) - 2 * sizeof(WCHAR); description = (PWSTR)(messageEntry->Text); if (description[textLength / sizeof(WCHAR)] == 0) { textLength -= sizeof(WCHAR); } ASSERT((LONG)textLength > 1); ASSERT(description[textLength / sizeof(WCHAR)] == 0x000a); description = ExAllocatePool(PagedPool | POOL_COLD_ALLOCATION, textLength); if (description) { // // Copy the text except for the CR/LF/NULL // textLength -= sizeof(WCHAR); RtlCopyMemory(description, messageEntry->Text, textLength); // // New NULL terminator. // description[textLength / sizeof(WCHAR)] = 0; } } else { // // RtlFindMessage returns a string? Wierd. // ANSI_STRING ansiDescription; UNICODE_STRING unicodeDescription; RtlInitAnsiString(&ansiDescription, messageEntry->Text); // // Strip CR/LF off the end of the string. // ansiDescription.Length -= 2; // // Turn it all into a unicode string so we can grab the buffer // and return that to our caller. // status = RtlAnsiStringToUnicodeString( &unicodeDescription, &ansiDescription, TRUE ); description = unicodeDescription.Buffer; } } return description; } PWSTR PciGetDeviceDescriptionMessage( IN UCHAR BaseClass, IN UCHAR SubClass ) { PWSTR deviceDescription = NULL; ULONG messageNumber; messageNumber = (BaseClass << 8) | SubClass; deviceDescription = PciGetDescriptionMessage(messageNumber); if (!deviceDescription) { #define TEMP_DESCRIPTION L"PCI Device" deviceDescription = ExAllocatePool(PagedPool, sizeof(TEMP_DESCRIPTION)); if (deviceDescription) { RtlCopyMemory(deviceDescription, TEMP_DESCRIPTION, sizeof(TEMP_DESCRIPTION)); } } return deviceDescription; } NTSTATUS PciQueryDeviceText( IN PPCI_PDO_EXTENSION PdoExtension, IN DEVICE_TEXT_TYPE TextType, IN LCID LocaleId, IN OUT PWSTR *DeviceText ) { PWSTR locationFormat; ULONG textLength; PAGED_CODE(); switch (TextType) { case DeviceTextDescription: *DeviceText = PciGetDeviceDescriptionMessage(PdoExtension->BaseClass, PdoExtension->SubClass); if (*DeviceText) { return STATUS_SUCCESS; } return STATUS_NOT_SUPPORTED; case DeviceTextLocationInformation: locationFormat = PciGetDescriptionMessage(PCI_LOCATION_TEXT); if (locationFormat) { // Compute max size for location information string textLength = wcslen(locationFormat) + 2 + 2 + 2 + 1; *DeviceText = ExAllocatePool(PagedPool | POOL_COLD_ALLOCATION, textLength * sizeof(WCHAR)); if (*DeviceText) { swprintf(*DeviceText, locationFormat, (ULONG) PdoExtension->ParentFdoExtension->BaseBus, (ULONG) PdoExtension->Slot.u.bits.DeviceNumber, (ULONG) PdoExtension->Slot.u.bits.FunctionNumber); } ExFreePool(locationFormat); if (*DeviceText) { return STATUS_SUCCESS; } else { return STATUS_INSUFFICIENT_RESOURCES; } } // fall thru if we couldn't get format string default: return STATUS_NOT_SUPPORTED; } }