/** @file OVMF ACPI support using QEMU's fw-cfg interface Copyright (c) 2008 - 2014, Intel Corporation. All rights reserved.
Copyright (C) 2012-2014, Red Hat, Inc. SPDX-License-Identifier: BSD-2-Clause-Patent **/ #include "AcpiPlatform.h" #include "QemuLoader.h" #include #include #include #include #include #include #include #include // // The user structure for the ordered collection that will track the fw_cfg // blobs under processing. // typedef struct { UINT8 File[QEMU_LOADER_FNAME_SIZE]; // NUL-terminated name of the fw_cfg // blob. This is the ordering / search // key. UINTN Size; // The number of bytes in this blob. UINT8 *Base; // Pointer to the blob data. BOOLEAN HostsOnlyTableData; // TRUE iff the blob has been found to // only contain data that is directly // part of ACPI tables. } BLOB; /** Compare a standalone key against a user structure containing an embedded key. @param[in] StandaloneKey Pointer to the bare key. @param[in] UserStruct Pointer to the user structure with the embedded key. @retval <0 If StandaloneKey compares less than UserStruct's key. @retval 0 If StandaloneKey compares equal to UserStruct's key. @retval >0 If StandaloneKey compares greater than UserStruct's key. **/ STATIC INTN EFIAPI BlobKeyCompare ( IN CONST VOID *StandaloneKey, IN CONST VOID *UserStruct ) { CONST BLOB *Blob; Blob = UserStruct; return AsciiStrCmp (StandaloneKey, (CONST CHAR8 *)Blob->File); } /** Comparator function for two user structures. @param[in] UserStruct1 Pointer to the first user structure. @param[in] UserStruct2 Pointer to the second user structure. @retval <0 If UserStruct1 compares less than UserStruct2. @retval 0 If UserStruct1 compares equal to UserStruct2. @retval >0 If UserStruct1 compares greater than UserStruct2. **/ STATIC INTN EFIAPI BlobCompare ( IN CONST VOID *UserStruct1, IN CONST VOID *UserStruct2 ) { CONST BLOB *Blob1; Blob1 = UserStruct1; return BlobKeyCompare (Blob1->File, UserStruct2); } /** Comparator function for two opaque pointers, ordering on (unsigned) pointer value itself. Can be used as both Key and UserStruct comparator. @param[in] Pointer1 First pointer. @param[in] Pointer2 Second pointer. @retval <0 If Pointer1 compares less than Pointer2. @retval 0 If Pointer1 compares equal to Pointer2. @retval >0 If Pointer1 compares greater than Pointer2. **/ STATIC INTN EFIAPI PointerCompare ( IN CONST VOID *Pointer1, IN CONST VOID *Pointer2 ) { if (Pointer1 == Pointer2) { return 0; } if ((UINTN)Pointer1 < (UINTN)Pointer2) { return -1; } return 1; } /** Comparator function for two ASCII strings. Can be used as both Key and UserStruct comparator. This function exists solely so we can avoid casting &AsciiStrCmp to ORDERED_COLLECTION_USER_COMPARE and ORDERED_COLLECTION_KEY_COMPARE. @param[in] AsciiString1 Pointer to the first ASCII string. @param[in] AsciiString2 Pointer to the second ASCII string. @return The return value of AsciiStrCmp (AsciiString1, AsciiString2). **/ STATIC INTN EFIAPI AsciiStringCompare ( IN CONST VOID *AsciiString1, IN CONST VOID *AsciiString2 ) { return AsciiStrCmp (AsciiString1, AsciiString2); } /** Release the ORDERED_COLLECTION structure populated by CollectAllocationsRestrictedTo32Bit() (below). This function may be called by CollectAllocationsRestrictedTo32Bit() itself, on the error path. @param[in] AllocationsRestrictedTo32Bit The ORDERED_COLLECTION structure to release. **/ STATIC VOID ReleaseAllocationsRestrictedTo32Bit ( IN ORDERED_COLLECTION *AllocationsRestrictedTo32Bit ) { ORDERED_COLLECTION_ENTRY *Entry, *Entry2; for (Entry = OrderedCollectionMin (AllocationsRestrictedTo32Bit); Entry != NULL; Entry = Entry2) { Entry2 = OrderedCollectionNext (Entry); OrderedCollectionDelete (AllocationsRestrictedTo32Bit, Entry, NULL); } OrderedCollectionUninit (AllocationsRestrictedTo32Bit); } /** Iterate over the linker/loader script, and collect the names of the fw_cfg blobs that are referenced by QEMU_LOADER_ADD_POINTER.PointeeFile fields, such that QEMU_LOADER_ADD_POINTER.PointerSize is less than 8. This means that the pointee blob's address will have to be patched into a narrower-than-8 byte pointer field, hence the pointee blob must not be allocated from 64-bit address space. @param[out] AllocationsRestrictedTo32Bit The ORDERED_COLLECTION structure linking (not copying / owning) such QEMU_LOADER_ADD_POINTER.PointeeFile fields that name the blobs restricted from 64-bit allocation. @param[in] LoaderStart Points to the first entry in the linker/loader script. @param[in] LoaderEnd Points one past the last entry in the linker/loader script. @retval EFI_SUCCESS AllocationsRestrictedTo32Bit has been populated. @retval EFI_OUT_OF_RESOURCES Memory allocation failed. @retval EFI_PROTOCOL_ERROR Invalid linker/loader script contents. **/ STATIC EFI_STATUS CollectAllocationsRestrictedTo32Bit ( OUT ORDERED_COLLECTION **AllocationsRestrictedTo32Bit, IN CONST QEMU_LOADER_ENTRY *LoaderStart, IN CONST QEMU_LOADER_ENTRY *LoaderEnd ) { ORDERED_COLLECTION *Collection; CONST QEMU_LOADER_ENTRY *LoaderEntry; EFI_STATUS Status; Collection = OrderedCollectionInit (AsciiStringCompare, AsciiStringCompare); if (Collection == NULL) { return EFI_OUT_OF_RESOURCES; } for (LoaderEntry = LoaderStart; LoaderEntry < LoaderEnd; ++LoaderEntry) { CONST QEMU_LOADER_ADD_POINTER *AddPointer; if (LoaderEntry->Type != QemuLoaderCmdAddPointer) { continue; } AddPointer = &LoaderEntry->Command.AddPointer; if (AddPointer->PointerSize >= 8) { continue; } if (AddPointer->PointeeFile[QEMU_LOADER_FNAME_SIZE - 1] != '\0') { DEBUG ((DEBUG_ERROR, "%a: malformed file name\n", __FUNCTION__)); Status = EFI_PROTOCOL_ERROR; goto RollBack; } Status = OrderedCollectionInsert ( Collection, NULL, // Entry (VOID *)AddPointer->PointeeFile ); switch (Status) { case EFI_SUCCESS: DEBUG (( DEBUG_VERBOSE, "%a: restricting blob \"%a\" from 64-bit allocation\n", __FUNCTION__, AddPointer->PointeeFile )); break; case EFI_ALREADY_STARTED: // // The restriction has been recorded already. // break; case EFI_OUT_OF_RESOURCES: goto RollBack; default: ASSERT (FALSE); } } *AllocationsRestrictedTo32Bit = Collection; return EFI_SUCCESS; RollBack: ReleaseAllocationsRestrictedTo32Bit (Collection); return Status; } /** Process a QEMU_LOADER_ALLOCATE command. @param[in] Allocate The QEMU_LOADER_ALLOCATE command to process. @param[in,out] Tracker The ORDERED_COLLECTION tracking the BLOB user structures created thus far. @param[in] AllocationsRestrictedTo32Bit The ORDERED_COLLECTION populated by the function CollectAllocationsRestrictedTo32Bit, naming the fw_cfg blobs that must not be allocated from 64-bit address space. @retval EFI_SUCCESS An area of whole AcpiNVS pages has been allocated for the blob contents, and the contents have been saved. A BLOB object (user structure) has been allocated from pool memory, referencing the blob contents. The BLOB user structure has been linked into Tracker. @retval EFI_PROTOCOL_ERROR Malformed fw_cfg file name has been found in Allocate, or the Allocate command references a file that is already known by Tracker. @retval EFI_UNSUPPORTED Unsupported alignment request has been found in Allocate. @retval EFI_OUT_OF_RESOURCES Pool allocation failed. @return Error codes from QemuFwCfgFindFile() and gBS->AllocatePages(). **/ STATIC EFI_STATUS EFIAPI ProcessCmdAllocate ( IN CONST QEMU_LOADER_ALLOCATE *Allocate, IN OUT ORDERED_COLLECTION *Tracker, IN ORDERED_COLLECTION *AllocationsRestrictedTo32Bit ) { FIRMWARE_CONFIG_ITEM FwCfgItem; UINTN FwCfgSize; EFI_STATUS Status; UINTN NumPages; EFI_PHYSICAL_ADDRESS Address; BLOB *Blob; if (Allocate->File[QEMU_LOADER_FNAME_SIZE - 1] != '\0') { DEBUG ((DEBUG_ERROR, "%a: malformed file name\n", __FUNCTION__)); return EFI_PROTOCOL_ERROR; } if (Allocate->Alignment > EFI_PAGE_SIZE) { DEBUG ((DEBUG_ERROR, "%a: unsupported alignment 0x%x\n", __FUNCTION__, Allocate->Alignment)); return EFI_UNSUPPORTED; } Status = QemuFwCfgFindFile ((CHAR8 *)Allocate->File, &FwCfgItem, &FwCfgSize); if (EFI_ERROR (Status)) { DEBUG ((DEBUG_ERROR, "%a: QemuFwCfgFindFile(\"%a\"): %r\n", __FUNCTION__, Allocate->File, Status)); return Status; } NumPages = EFI_SIZE_TO_PAGES (FwCfgSize); Address = MAX_UINT64; if (OrderedCollectionFind ( AllocationsRestrictedTo32Bit, Allocate->File ) != NULL) { Address = MAX_UINT32; } Status = gBS->AllocatePages (AllocateMaxAddress, EfiACPIMemoryNVS, NumPages, &Address); if (EFI_ERROR (Status)) { return Status; } Blob = AllocatePool (sizeof *Blob); if (Blob == NULL) { Status = EFI_OUT_OF_RESOURCES; goto FreePages; } CopyMem (Blob->File, Allocate->File, QEMU_LOADER_FNAME_SIZE); Blob->Size = FwCfgSize; Blob->Base = (VOID *)(UINTN)Address; Blob->HostsOnlyTableData = TRUE; Status = OrderedCollectionInsert (Tracker, NULL, Blob); if (Status == RETURN_ALREADY_STARTED) { DEBUG ((DEBUG_ERROR, "%a: duplicated file \"%a\"\n", __FUNCTION__, Allocate->File)); Status = EFI_PROTOCOL_ERROR; } if (EFI_ERROR (Status)) { goto FreeBlob; } QemuFwCfgSelectItem (FwCfgItem); QemuFwCfgReadBytes (FwCfgSize, Blob->Base); ZeroMem (Blob->Base + Blob->Size, EFI_PAGES_TO_SIZE (NumPages) - Blob->Size); DEBUG ((DEBUG_VERBOSE, "%a: File=\"%a\" Alignment=0x%x Zone=%d Size=0x%Lx " "Address=0x%Lx\n", __FUNCTION__, Allocate->File, Allocate->Alignment, Allocate->Zone, (UINT64)Blob->Size, (UINT64)(UINTN)Blob->Base)); return EFI_SUCCESS; FreeBlob: FreePool (Blob); FreePages: gBS->FreePages (Address, NumPages); return Status; } /** Process a QEMU_LOADER_ADD_POINTER command. @param[in] AddPointer The QEMU_LOADER_ADD_POINTER command to process. @param[in] Tracker The ORDERED_COLLECTION tracking the BLOB user structures created thus far. @retval EFI_PROTOCOL_ERROR Malformed fw_cfg file name(s) have been found in AddPointer, or the AddPointer command references a file unknown to Tracker, or the pointer to relocate has invalid location, size, or value, or the relocated pointer value is not representable in the given pointer size. @retval EFI_SUCCESS The pointer field inside the pointer blob has been relocated. **/ STATIC EFI_STATUS EFIAPI ProcessCmdAddPointer ( IN CONST QEMU_LOADER_ADD_POINTER *AddPointer, IN CONST ORDERED_COLLECTION *Tracker ) { ORDERED_COLLECTION_ENTRY *TrackerEntry, *TrackerEntry2; BLOB *Blob, *Blob2; UINT8 *PointerField; UINT64 PointerValue; if (AddPointer->PointerFile[QEMU_LOADER_FNAME_SIZE - 1] != '\0' || AddPointer->PointeeFile[QEMU_LOADER_FNAME_SIZE - 1] != '\0') { DEBUG ((DEBUG_ERROR, "%a: malformed file name\n", __FUNCTION__)); return EFI_PROTOCOL_ERROR; } TrackerEntry = OrderedCollectionFind (Tracker, AddPointer->PointerFile); TrackerEntry2 = OrderedCollectionFind (Tracker, AddPointer->PointeeFile); if (TrackerEntry == NULL || TrackerEntry2 == NULL) { DEBUG ((DEBUG_ERROR, "%a: invalid blob reference(s) \"%a\" / \"%a\"\n", __FUNCTION__, AddPointer->PointerFile, AddPointer->PointeeFile)); return EFI_PROTOCOL_ERROR; } Blob = OrderedCollectionUserStruct (TrackerEntry); Blob2 = OrderedCollectionUserStruct (TrackerEntry2); if ((AddPointer->PointerSize != 1 && AddPointer->PointerSize != 2 && AddPointer->PointerSize != 4 && AddPointer->PointerSize != 8) || Blob->Size < AddPointer->PointerSize || Blob->Size - AddPointer->PointerSize < AddPointer->PointerOffset) { DEBUG ((DEBUG_ERROR, "%a: invalid pointer location or size in \"%a\"\n", __FUNCTION__, AddPointer->PointerFile)); return EFI_PROTOCOL_ERROR; } PointerField = Blob->Base + AddPointer->PointerOffset; PointerValue = 0; CopyMem (&PointerValue, PointerField, AddPointer->PointerSize); if (PointerValue >= Blob2->Size) { DEBUG ((DEBUG_ERROR, "%a: invalid pointer value in \"%a\"\n", __FUNCTION__, AddPointer->PointerFile)); return EFI_PROTOCOL_ERROR; } // // The memory allocation system ensures that the address of the byte past the // last byte of any allocated object is expressible (no wraparound). // ASSERT ((UINTN)Blob2->Base <= MAX_ADDRESS - Blob2->Size); PointerValue += (UINT64)(UINTN)Blob2->Base; if (AddPointer->PointerSize < 8 && RShiftU64 (PointerValue, AddPointer->PointerSize * 8) != 0) { DEBUG ((DEBUG_ERROR, "%a: relocated pointer value unrepresentable in " "\"%a\"\n", __FUNCTION__, AddPointer->PointerFile)); return EFI_PROTOCOL_ERROR; } CopyMem (PointerField, &PointerValue, AddPointer->PointerSize); DEBUG ((DEBUG_VERBOSE, "%a: PointerFile=\"%a\" PointeeFile=\"%a\" " "PointerOffset=0x%x PointerSize=%d\n", __FUNCTION__, AddPointer->PointerFile, AddPointer->PointeeFile, AddPointer->PointerOffset, AddPointer->PointerSize)); return EFI_SUCCESS; } /** Process a QEMU_LOADER_ADD_CHECKSUM command. @param[in] AddChecksum The QEMU_LOADER_ADD_CHECKSUM command to process. @param[in] Tracker The ORDERED_COLLECTION tracking the BLOB user structures created thus far. @retval EFI_PROTOCOL_ERROR Malformed fw_cfg file name has been found in AddChecksum, or the AddChecksum command references a file unknown to Tracker, or the range to checksum is invalid. @retval EFI_SUCCESS The requested range has been checksummed. **/ STATIC EFI_STATUS EFIAPI ProcessCmdAddChecksum ( IN CONST QEMU_LOADER_ADD_CHECKSUM *AddChecksum, IN CONST ORDERED_COLLECTION *Tracker ) { ORDERED_COLLECTION_ENTRY *TrackerEntry; BLOB *Blob; if (AddChecksum->File[QEMU_LOADER_FNAME_SIZE - 1] != '\0') { DEBUG ((DEBUG_ERROR, "%a: malformed file name\n", __FUNCTION__)); return EFI_PROTOCOL_ERROR; } TrackerEntry = OrderedCollectionFind (Tracker, AddChecksum->File); if (TrackerEntry == NULL) { DEBUG ((DEBUG_ERROR, "%a: invalid blob reference \"%a\"\n", __FUNCTION__, AddChecksum->File)); return EFI_PROTOCOL_ERROR; } Blob = OrderedCollectionUserStruct (TrackerEntry); if (Blob->Size <= AddChecksum->ResultOffset || Blob->Size < AddChecksum->Length || Blob->Size - AddChecksum->Length < AddChecksum->Start) { DEBUG ((DEBUG_ERROR, "%a: invalid checksum range in \"%a\"\n", __FUNCTION__, AddChecksum->File)); return EFI_PROTOCOL_ERROR; } Blob->Base[AddChecksum->ResultOffset] = CalculateCheckSum8 ( Blob->Base + AddChecksum->Start, AddChecksum->Length ); DEBUG ((DEBUG_VERBOSE, "%a: File=\"%a\" ResultOffset=0x%x Start=0x%x " "Length=0x%x\n", __FUNCTION__, AddChecksum->File, AddChecksum->ResultOffset, AddChecksum->Start, AddChecksum->Length)); return EFI_SUCCESS; } /** Process a QEMU_LOADER_WRITE_POINTER command. @param[in] WritePointer The QEMU_LOADER_WRITE_POINTER command to process. @param[in] Tracker The ORDERED_COLLECTION tracking the BLOB user structures created thus far. @param[in,out] S3Context The S3_CONTEXT object capturing the fw_cfg actions of successfully processed QEMU_LOADER_WRITE_POINTER commands, to be replayed at S3 resume. S3Context may be NULL if S3 is disabled. @retval EFI_PROTOCOL_ERROR Malformed fw_cfg file name(s) have been found in WritePointer. Or, the WritePointer command references a file unknown to Tracker or the fw_cfg directory. Or, the pointer object to rewrite has invalid location, size, or initial relative value. Or, the pointer value to store does not fit in the given pointer size. @retval EFI_SUCCESS The pointer object inside the writeable fw_cfg file has been written. If S3Context is not NULL, then WritePointer has been condensed into S3Context. @return Error codes propagated from SaveCondensedWritePointerToS3Context(). The pointer object inside the writeable fw_cfg file has not been written. **/ STATIC EFI_STATUS ProcessCmdWritePointer ( IN CONST QEMU_LOADER_WRITE_POINTER *WritePointer, IN CONST ORDERED_COLLECTION *Tracker, IN OUT S3_CONTEXT *S3Context OPTIONAL ) { RETURN_STATUS Status; FIRMWARE_CONFIG_ITEM PointerItem; UINTN PointerItemSize; ORDERED_COLLECTION_ENTRY *PointeeEntry; BLOB *PointeeBlob; UINT64 PointerValue; if (WritePointer->PointerFile[QEMU_LOADER_FNAME_SIZE - 1] != '\0' || WritePointer->PointeeFile[QEMU_LOADER_FNAME_SIZE - 1] != '\0') { DEBUG ((DEBUG_ERROR, "%a: malformed file name\n", __FUNCTION__)); return EFI_PROTOCOL_ERROR; } Status = QemuFwCfgFindFile ((CONST CHAR8 *)WritePointer->PointerFile, &PointerItem, &PointerItemSize); PointeeEntry = OrderedCollectionFind (Tracker, WritePointer->PointeeFile); if (RETURN_ERROR (Status) || PointeeEntry == NULL) { DEBUG ((DEBUG_ERROR, "%a: invalid fw_cfg file or blob reference \"%a\" / \"%a\"\n", __FUNCTION__, WritePointer->PointerFile, WritePointer->PointeeFile)); return EFI_PROTOCOL_ERROR; } if ((WritePointer->PointerSize != 1 && WritePointer->PointerSize != 2 && WritePointer->PointerSize != 4 && WritePointer->PointerSize != 8) || (PointerItemSize < WritePointer->PointerSize) || (PointerItemSize - WritePointer->PointerSize < WritePointer->PointerOffset)) { DEBUG ((DEBUG_ERROR, "%a: invalid pointer location or size in \"%a\"\n", __FUNCTION__, WritePointer->PointerFile)); return EFI_PROTOCOL_ERROR; } PointeeBlob = OrderedCollectionUserStruct (PointeeEntry); PointerValue = WritePointer->PointeeOffset; if (PointerValue >= PointeeBlob->Size) { DEBUG ((DEBUG_ERROR, "%a: invalid PointeeOffset\n", __FUNCTION__)); return EFI_PROTOCOL_ERROR; } // // The memory allocation system ensures that the address of the byte past the // last byte of any allocated object is expressible (no wraparound). // ASSERT ((UINTN)PointeeBlob->Base <= MAX_ADDRESS - PointeeBlob->Size); PointerValue += (UINT64)(UINTN)PointeeBlob->Base; if (WritePointer->PointerSize < 8 && RShiftU64 (PointerValue, WritePointer->PointerSize * 8) != 0) { DEBUG ((DEBUG_ERROR, "%a: pointer value unrepresentable in \"%a\"\n", __FUNCTION__, WritePointer->PointerFile)); return EFI_PROTOCOL_ERROR; } // // If S3 is enabled, we have to capture the below fw_cfg actions in condensed // form, to be replayed during S3 resume. // if (S3Context != NULL) { EFI_STATUS SaveStatus; SaveStatus = SaveCondensedWritePointerToS3Context ( S3Context, (UINT16)PointerItem, WritePointer->PointerSize, WritePointer->PointerOffset, PointerValue ); if (EFI_ERROR (SaveStatus)) { return SaveStatus; } } QemuFwCfgSelectItem (PointerItem); QemuFwCfgSkipBytes (WritePointer->PointerOffset); QemuFwCfgWriteBytes (WritePointer->PointerSize, &PointerValue); // // Because QEMU has now learned PointeeBlob->Base, we must mark PointeeBlob // as unreleasable, for the case when the whole linker/loader script is // handled successfully. // PointeeBlob->HostsOnlyTableData = FALSE; DEBUG ((DEBUG_VERBOSE, "%a: PointerFile=\"%a\" PointeeFile=\"%a\" " "PointerOffset=0x%x PointeeOffset=0x%x PointerSize=%d\n", __FUNCTION__, WritePointer->PointerFile, WritePointer->PointeeFile, WritePointer->PointerOffset, WritePointer->PointeeOffset, WritePointer->PointerSize)); return EFI_SUCCESS; } /** Undo a QEMU_LOADER_WRITE_POINTER command. This function revokes (zeroes out) a guest memory reference communicated to QEMU earlier. The caller is responsible for invoking this function only on such QEMU_LOADER_WRITE_POINTER commands that have been successfully processed by ProcessCmdWritePointer(). @param[in] WritePointer The QEMU_LOADER_WRITE_POINTER command to undo. **/ STATIC VOID UndoCmdWritePointer ( IN CONST QEMU_LOADER_WRITE_POINTER *WritePointer ) { RETURN_STATUS Status; FIRMWARE_CONFIG_ITEM PointerItem; UINTN PointerItemSize; UINT64 PointerValue; Status = QemuFwCfgFindFile ((CONST CHAR8 *)WritePointer->PointerFile, &PointerItem, &PointerItemSize); ASSERT_RETURN_ERROR (Status); PointerValue = 0; QemuFwCfgSelectItem (PointerItem); QemuFwCfgSkipBytes (WritePointer->PointerOffset); QemuFwCfgWriteBytes (WritePointer->PointerSize, &PointerValue); DEBUG ((DEBUG_VERBOSE, "%a: PointerFile=\"%a\" PointerOffset=0x%x PointerSize=%d\n", __FUNCTION__, WritePointer->PointerFile, WritePointer->PointerOffset, WritePointer->PointerSize)); } // // We'll be saving the keys of installed tables so that we can roll them back // in case of failure. 128 tables should be enough for anyone (TM). // #define INSTALLED_TABLES_MAX 128 /** Process a QEMU_LOADER_ADD_POINTER command in order to see if its target byte array is an ACPI table, and if so, install it. This function assumes that the entire QEMU linker/loader command file has been processed successfully in a prior first pass. @param[in] AddPointer The QEMU_LOADER_ADD_POINTER command to process. @param[in] Tracker The ORDERED_COLLECTION tracking the BLOB user structures. @param[in] AcpiProtocol The ACPI table protocol used to install tables. @param[in,out] InstalledKey On input, an array of INSTALLED_TABLES_MAX UINTN elements, allocated by the caller. On output, the function will have stored (appended) the AcpiProtocol-internal key of the ACPI table that the function has installed, if the AddPointer command identified an ACPI table that is different from RSDT and XSDT. @param[in,out] NumInstalled On input, the number of entries already used in InstalledKey; it must be in [0, INSTALLED_TABLES_MAX] inclusive. On output, the parameter is incremented if the AddPointer command identified an ACPI table that is different from RSDT and XSDT. @param[in,out] SeenPointers The ORDERED_COLLECTION tracking the absolute target addresses that have been pointed-to by QEMU_LOADER_ADD_POINTER commands thus far. If a target address is encountered for the first time, and it identifies an ACPI table that is different from RDST and XSDT, the table is installed. If a target address is seen for the second or later times, it is skipped without taking any action. @retval EFI_INVALID_PARAMETER NumInstalled was outside the allowed range on input. @retval EFI_OUT_OF_RESOURCES The AddPointer command identified an ACPI table different from RSDT and XSDT, but there was no more room in InstalledKey. @retval EFI_SUCCESS AddPointer has been processed. Either its absolute target address has been encountered before, or an ACPI table different from RSDT and XSDT has been installed (reflected by InstalledKey and NumInstalled), or RSDT or XSDT has been identified but not installed, or the fw_cfg blob pointed-into by AddPointer has been marked as hosting something else than just direct ACPI table contents. @return Error codes returned by AcpiProtocol->InstallAcpiTable(). **/ STATIC EFI_STATUS EFIAPI Process2ndPassCmdAddPointer ( IN CONST QEMU_LOADER_ADD_POINTER *AddPointer, IN CONST ORDERED_COLLECTION *Tracker, IN EFI_ACPI_TABLE_PROTOCOL *AcpiProtocol, IN OUT UINTN InstalledKey[INSTALLED_TABLES_MAX], IN OUT INT32 *NumInstalled, IN OUT ORDERED_COLLECTION *SeenPointers ) { CONST ORDERED_COLLECTION_ENTRY *TrackerEntry; CONST ORDERED_COLLECTION_ENTRY *TrackerEntry2; ORDERED_COLLECTION_ENTRY *SeenPointerEntry; CONST BLOB *Blob; BLOB *Blob2; CONST UINT8 *PointerField; UINT64 PointerValue; UINTN Blob2Remaining; UINTN TableSize; CONST EFI_ACPI_1_0_FIRMWARE_ACPI_CONTROL_STRUCTURE *Facs; CONST EFI_ACPI_DESCRIPTION_HEADER *Header; EFI_STATUS Status; if (*NumInstalled < 0 || *NumInstalled > INSTALLED_TABLES_MAX) { return EFI_INVALID_PARAMETER; } TrackerEntry = OrderedCollectionFind (Tracker, AddPointer->PointerFile); TrackerEntry2 = OrderedCollectionFind (Tracker, AddPointer->PointeeFile); Blob = OrderedCollectionUserStruct (TrackerEntry); Blob2 = OrderedCollectionUserStruct (TrackerEntry2); PointerField = Blob->Base + AddPointer->PointerOffset; PointerValue = 0; CopyMem (&PointerValue, PointerField, AddPointer->PointerSize); // // We assert that PointerValue falls inside Blob2's contents. This is ensured // by the Blob2->Size check and later checks in ProcessCmdAddPointer(). // Blob2Remaining = (UINTN)Blob2->Base; ASSERT(PointerValue >= Blob2Remaining); Blob2Remaining += Blob2->Size; ASSERT (PointerValue < Blob2Remaining); Status = OrderedCollectionInsert ( SeenPointers, &SeenPointerEntry, // for reverting insertion in error case (VOID *)(UINTN)PointerValue ); if (EFI_ERROR (Status)) { if (Status == RETURN_ALREADY_STARTED) { // // Already seen this pointer, don't try to process it again. // DEBUG (( DEBUG_VERBOSE, "%a: PointerValue=0x%Lx already processed, skipping.\n", __FUNCTION__, PointerValue )); Status = EFI_SUCCESS; } return Status; } Blob2Remaining -= (UINTN) PointerValue; DEBUG ((DEBUG_VERBOSE, "%a: checking for ACPI header in \"%a\" at 0x%Lx " "(remaining: 0x%Lx): ", __FUNCTION__, AddPointer->PointeeFile, PointerValue, (UINT64)Blob2Remaining)); TableSize = 0; // // To make our job simple, the FACS has a custom header. Sigh. // if (sizeof *Facs <= Blob2Remaining) { Facs = (EFI_ACPI_1_0_FIRMWARE_ACPI_CONTROL_STRUCTURE *)(UINTN)PointerValue; if (Facs->Length >= sizeof *Facs && Facs->Length <= Blob2Remaining && Facs->Signature == EFI_ACPI_1_0_FIRMWARE_ACPI_CONTROL_STRUCTURE_SIGNATURE) { DEBUG ((DEBUG_VERBOSE, "found \"%-4.4a\" size 0x%x\n", (CONST CHAR8 *)&Facs->Signature, Facs->Length)); TableSize = Facs->Length; } } // // check for the uniform tables // if (TableSize == 0 && sizeof *Header <= Blob2Remaining) { Header = (EFI_ACPI_DESCRIPTION_HEADER *)(UINTN)PointerValue; if (Header->Length >= sizeof *Header && Header->Length <= Blob2Remaining && CalculateSum8 ((CONST UINT8 *)Header, Header->Length) == 0) { // // This looks very much like an ACPI table from QEMU: // - Length field consistent with both ACPI and containing blob size // - checksum is correct // DEBUG ((DEBUG_VERBOSE, "found \"%-4.4a\" size 0x%x\n", (CONST CHAR8 *)&Header->Signature, Header->Length)); TableSize = Header->Length; // // Skip RSDT and XSDT because those are handled by // EFI_ACPI_TABLE_PROTOCOL automatically. if (Header->Signature == EFI_ACPI_1_0_ROOT_SYSTEM_DESCRIPTION_TABLE_SIGNATURE || Header->Signature == EFI_ACPI_2_0_EXTENDED_SYSTEM_DESCRIPTION_TABLE_SIGNATURE) { return EFI_SUCCESS; } } } if (TableSize == 0) { DEBUG ((DEBUG_VERBOSE, "not found; marking fw_cfg blob as opaque\n")); Blob2->HostsOnlyTableData = FALSE; return EFI_SUCCESS; } if (*NumInstalled == INSTALLED_TABLES_MAX) { DEBUG ((DEBUG_ERROR, "%a: can't install more than %d tables\n", __FUNCTION__, INSTALLED_TABLES_MAX)); Status = EFI_OUT_OF_RESOURCES; goto RollbackSeenPointer; } Status = AcpiProtocol->InstallAcpiTable (AcpiProtocol, (VOID *)(UINTN)PointerValue, TableSize, &InstalledKey[*NumInstalled]); if (EFI_ERROR (Status)) { DEBUG ((DEBUG_ERROR, "%a: InstallAcpiTable(): %r\n", __FUNCTION__, Status)); goto RollbackSeenPointer; } ++*NumInstalled; return EFI_SUCCESS; RollbackSeenPointer: OrderedCollectionDelete (SeenPointers, SeenPointerEntry, NULL); return Status; } /** Download, process, and install ACPI table data from the QEMU loader interface. @param[in] AcpiProtocol The ACPI table protocol used to install tables. @retval EFI_UNSUPPORTED Firmware configuration is unavailable, or QEMU loader command with unsupported parameters has been found. @retval EFI_NOT_FOUND The host doesn't export the required fw_cfg files. @retval EFI_OUT_OF_RESOURCES Memory allocation failed, or more than INSTALLED_TABLES_MAX tables found. @retval EFI_PROTOCOL_ERROR Found invalid fw_cfg contents. @return Status codes returned by AcpiProtocol->InstallAcpiTable(). **/ EFI_STATUS EFIAPI InstallQemuFwCfgTables ( IN EFI_ACPI_TABLE_PROTOCOL *AcpiProtocol ) { EFI_STATUS Status; FIRMWARE_CONFIG_ITEM FwCfgItem; UINTN FwCfgSize; QEMU_LOADER_ENTRY *LoaderStart; CONST QEMU_LOADER_ENTRY *LoaderEntry, *LoaderEnd; CONST QEMU_LOADER_ENTRY *WritePointerSubsetEnd; ORIGINAL_ATTRIBUTES *OriginalPciAttributes; UINTN OriginalPciAttributesCount; ORDERED_COLLECTION *AllocationsRestrictedTo32Bit; S3_CONTEXT *S3Context; ORDERED_COLLECTION *Tracker; UINTN *InstalledKey; INT32 Installed; ORDERED_COLLECTION_ENTRY *TrackerEntry, *TrackerEntry2; ORDERED_COLLECTION *SeenPointers; ORDERED_COLLECTION_ENTRY *SeenPointerEntry, *SeenPointerEntry2; Status = QemuFwCfgFindFile ("etc/table-loader", &FwCfgItem, &FwCfgSize); if (EFI_ERROR (Status)) { return Status; } if (FwCfgSize % sizeof *LoaderEntry != 0) { DEBUG ((DEBUG_ERROR, "%a: \"etc/table-loader\" has invalid size 0x%Lx\n", __FUNCTION__, (UINT64)FwCfgSize)); return EFI_PROTOCOL_ERROR; } LoaderStart = AllocatePool (FwCfgSize); if (LoaderStart == NULL) { return EFI_OUT_OF_RESOURCES; } EnablePciDecoding (&OriginalPciAttributes, &OriginalPciAttributesCount); QemuFwCfgSelectItem (FwCfgItem); QemuFwCfgReadBytes (FwCfgSize, LoaderStart); RestorePciDecoding (OriginalPciAttributes, OriginalPciAttributesCount); LoaderEnd = LoaderStart + FwCfgSize / sizeof *LoaderEntry; AllocationsRestrictedTo32Bit = NULL; Status = CollectAllocationsRestrictedTo32Bit ( &AllocationsRestrictedTo32Bit, LoaderStart, LoaderEnd ); if (EFI_ERROR (Status)) { goto FreeLoader; } S3Context = NULL; if (QemuFwCfgS3Enabled ()) { // // Size the allocation pessimistically, assuming that all commands in the // script are QEMU_LOADER_WRITE_POINTER commands. // Status = AllocateS3Context (&S3Context, LoaderEnd - LoaderStart); if (EFI_ERROR (Status)) { goto FreeAllocationsRestrictedTo32Bit; } } Tracker = OrderedCollectionInit (BlobCompare, BlobKeyCompare); if (Tracker == NULL) { Status = EFI_OUT_OF_RESOURCES; goto FreeS3Context; } // // first pass: process the commands // // "WritePointerSubsetEnd" points one past the last successful // QEMU_LOADER_WRITE_POINTER command. Now when we're about to start the first // pass, no such command has been encountered yet. // WritePointerSubsetEnd = LoaderStart; for (LoaderEntry = LoaderStart; LoaderEntry < LoaderEnd; ++LoaderEntry) { switch (LoaderEntry->Type) { case QemuLoaderCmdAllocate: Status = ProcessCmdAllocate ( &LoaderEntry->Command.Allocate, Tracker, AllocationsRestrictedTo32Bit ); break; case QemuLoaderCmdAddPointer: Status = ProcessCmdAddPointer (&LoaderEntry->Command.AddPointer, Tracker); break; case QemuLoaderCmdAddChecksum: Status = ProcessCmdAddChecksum (&LoaderEntry->Command.AddChecksum, Tracker); break; case QemuLoaderCmdWritePointer: Status = ProcessCmdWritePointer (&LoaderEntry->Command.WritePointer, Tracker, S3Context); if (!EFI_ERROR (Status)) { WritePointerSubsetEnd = LoaderEntry + 1; } break; default: DEBUG ((DEBUG_VERBOSE, "%a: unknown loader command: 0x%x\n", __FUNCTION__, LoaderEntry->Type)); break; } if (EFI_ERROR (Status)) { goto RollbackWritePointersAndFreeTracker; } } InstalledKey = AllocatePool (INSTALLED_TABLES_MAX * sizeof *InstalledKey); if (InstalledKey == NULL) { Status = EFI_OUT_OF_RESOURCES; goto RollbackWritePointersAndFreeTracker; } SeenPointers = OrderedCollectionInit (PointerCompare, PointerCompare); if (SeenPointers == NULL) { Status = EFI_OUT_OF_RESOURCES; goto FreeKeys; } // // second pass: identify and install ACPI tables // Installed = 0; for (LoaderEntry = LoaderStart; LoaderEntry < LoaderEnd; ++LoaderEntry) { if (LoaderEntry->Type == QemuLoaderCmdAddPointer) { Status = Process2ndPassCmdAddPointer ( &LoaderEntry->Command.AddPointer, Tracker, AcpiProtocol, InstalledKey, &Installed, SeenPointers ); if (EFI_ERROR (Status)) { goto UninstallAcpiTables; } } } // // Translating the condensed QEMU_LOADER_WRITE_POINTER commands to ACPI S3 // Boot Script opcodes has to be the last operation in this function, because // if it succeeds, it cannot be undone. // if (S3Context != NULL) { Status = TransferS3ContextToBootScript (S3Context); if (EFI_ERROR (Status)) { goto UninstallAcpiTables; } // // Ownership of S3Context has been transferred. // S3Context = NULL; } UninstallAcpiTables: if (EFI_ERROR (Status)) { // // roll back partial installation // while (Installed > 0) { --Installed; AcpiProtocol->UninstallAcpiTable (AcpiProtocol, InstalledKey[Installed]); } } else { DEBUG ((DEBUG_INFO, "%a: installed %d tables\n", __FUNCTION__, Installed)); } for (SeenPointerEntry = OrderedCollectionMin (SeenPointers); SeenPointerEntry != NULL; SeenPointerEntry = SeenPointerEntry2) { SeenPointerEntry2 = OrderedCollectionNext (SeenPointerEntry); OrderedCollectionDelete (SeenPointers, SeenPointerEntry, NULL); } OrderedCollectionUninit (SeenPointers); FreeKeys: FreePool (InstalledKey); RollbackWritePointersAndFreeTracker: // // In case of failure, revoke any allocation addresses that were communicated // to QEMU previously, before we release all the blobs. // if (EFI_ERROR (Status)) { LoaderEntry = WritePointerSubsetEnd; while (LoaderEntry > LoaderStart) { --LoaderEntry; if (LoaderEntry->Type == QemuLoaderCmdWritePointer) { UndoCmdWritePointer (&LoaderEntry->Command.WritePointer); } } } // // Tear down the tracker infrastructure. Each fw_cfg blob will be left in // place only if we're exiting with success and the blob hosts data that is // not directly part of some ACPI table. // for (TrackerEntry = OrderedCollectionMin (Tracker); TrackerEntry != NULL; TrackerEntry = TrackerEntry2) { VOID *UserStruct; BLOB *Blob; TrackerEntry2 = OrderedCollectionNext (TrackerEntry); OrderedCollectionDelete (Tracker, TrackerEntry, &UserStruct); Blob = UserStruct; if (EFI_ERROR (Status) || Blob->HostsOnlyTableData) { DEBUG ((DEBUG_VERBOSE, "%a: freeing \"%a\"\n", __FUNCTION__, Blob->File)); gBS->FreePages ((UINTN)Blob->Base, EFI_SIZE_TO_PAGES (Blob->Size)); } FreePool (Blob); } OrderedCollectionUninit (Tracker); FreeS3Context: if (S3Context != NULL) { ReleaseS3Context (S3Context); } FreeAllocationsRestrictedTo32Bit: ReleaseAllocationsRestrictedTo32Bit (AllocationsRestrictedTo32Bit); FreeLoader: FreePool (LoaderStart); return Status; }