/** @file Rewrite the BootOrder NvVar based on QEMU's "bootorder" fw_cfg file. Copyright (C) 2012 - 2013, Red Hat, Inc. This program and the accompanying materials are licensed and made available under the terms and conditions of the BSD License which accompanies this distribution. The full text of the license may be found at http://opensource.org/licenses/bsd-license.php THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. **/ #include #include #include #include #include #include #include #include #include #include /** OpenFirmware to UEFI device path translation output buffer size in CHAR16's. **/ #define TRANSLATION_OUTPUT_SIZE 0x100 /** Numbers of nodes in OpenFirmware device paths that are required and examined. **/ #define REQUIRED_OFW_NODES 2 #define EXAMINED_OFW_NODES 4 /** Simple character classification routines, corresponding to POSIX class names and ASCII encoding. **/ STATIC BOOLEAN IsAlnum ( IN CHAR8 Chr ) { return (('0' <= Chr && Chr <= '9') || ('A' <= Chr && Chr <= 'Z') || ('a' <= Chr && Chr <= 'z') ); } STATIC BOOLEAN IsDriverNamePunct ( IN CHAR8 Chr ) { return (Chr == ',' || Chr == '.' || Chr == '_' || Chr == '+' || Chr == '-' ); } STATIC BOOLEAN IsPrintNotDelim ( IN CHAR8 Chr ) { return (32 <= Chr && Chr <= 126 && Chr != '/' && Chr != '@' && Chr != ':'); } /** Utility types and functions. **/ typedef struct { CONST CHAR8 *Ptr; // not necessarily NUL-terminated UINTN Len; // number of non-NUL characters } SUBSTRING; /** Check if Substring and String have identical contents. The function relies on the restriction that a SUBSTRING cannot have embedded NULs either. @param[in] Substring The SUBSTRING input to the comparison. @param[in] String The ASCII string input to the comparison. @return Whether the inputs have identical contents. **/ STATIC BOOLEAN SubstringEq ( IN SUBSTRING Substring, IN CONST CHAR8 *String ) { UINTN Pos; CONST CHAR8 *Chr; Pos = 0; Chr = String; while (Pos < Substring.Len && Substring.Ptr[Pos] == *Chr) { ++Pos; ++Chr; } return (BOOLEAN)(Pos == Substring.Len && *Chr == '\0'); } /** Parse a comma-separated list of hexadecimal integers into the elements of an UINT32 array. Whitespace, "0x" prefixes, leading or trailing commas, sequences of commas, or an empty string are not allowed; they are rejected. The function relies on ASCII encoding. @param[in] UnitAddress The substring to parse. @param[out] Result The array, allocated by the caller, to receive the parsed values. This parameter may be NULL if NumResults is zero on input. @param[in out] NumResults On input, the number of elements allocated for Result. On output, the number of elements it has taken (or would have taken) to parse the string fully. @retval RETURN_SUCCESS UnitAddress has been fully parsed. NumResults is set to the number of parsed values; the corresponding elements have been set in Result. The rest of Result's elements are unchanged. @retval RETURN_BUFFER_TOO_SMALL UnitAddress has been fully parsed. NumResults is set to the number of parsed values, but elements have been stored only up to the input value of NumResults, which is less than what has been parsed. @retval RETURN_INVALID_PARAMETER Parse error. The contents of Results is indeterminate. NumResults has not been changed. **/ STATIC RETURN_STATUS ParseUnitAddressHexList ( IN SUBSTRING UnitAddress, OUT UINT32 *Result, IN OUT UINTN *NumResults ) { UINTN Entry; // number of entry currently being parsed UINT32 EntryVal; // value being constructed for current entry CHAR8 PrevChr; // UnitAddress character previously checked UINTN Pos; // current position within UnitAddress RETURN_STATUS Status; Entry = 0; EntryVal = 0; PrevChr = ','; for (Pos = 0; Pos < UnitAddress.Len; ++Pos) { CHAR8 Chr; INT8 Val; Chr = UnitAddress.Ptr[Pos]; Val = ('a' <= Chr && Chr <= 'f') ? (Chr - 'a' + 10) : ('A' <= Chr && Chr <= 'F') ? (Chr - 'A' + 10) : ('0' <= Chr && Chr <= '9') ? (Chr - '0' ) : -1; if (Val >= 0) { if (EntryVal > 0xFFFFFFF) { return RETURN_INVALID_PARAMETER; } EntryVal = (EntryVal << 4) | Val; } else if (Chr == ',') { if (PrevChr == ',') { return RETURN_INVALID_PARAMETER; } if (Entry < *NumResults) { Result[Entry] = EntryVal; } ++Entry; EntryVal = 0; } else { return RETURN_INVALID_PARAMETER; } PrevChr = Chr; } if (PrevChr == ',') { return RETURN_INVALID_PARAMETER; } if (Entry < *NumResults) { Result[Entry] = EntryVal; Status = RETURN_SUCCESS; } else { Status = RETURN_BUFFER_TOO_SMALL; } ++Entry; *NumResults = Entry; return Status; } /** A simple array of Boot Option ID's. **/ typedef struct { UINT16 *Data; UINTN Allocated; UINTN Produced; } BOOT_ORDER; /** Append BootOptionId to BootOrder, reallocating the latter if needed. @param[in out] BootOrder The structure pointing to the array and holding allocation and usage counters. @param[in] BootOptionId The value to append to the array. @retval RETURN_SUCCESS BootOptionId appended. @retval RETURN_OUT_OF_RESOURCES Memory reallocation failed. **/ STATIC RETURN_STATUS BootOrderAppend ( IN OUT BOOT_ORDER *BootOrder, IN UINT16 BootOptionId ) { if (BootOrder->Produced == BootOrder->Allocated) { UINTN AllocatedNew; UINT16 *DataNew; ASSERT (BootOrder->Allocated > 0); AllocatedNew = BootOrder->Allocated * 2; DataNew = ReallocatePool ( BootOrder->Allocated * sizeof (*BootOrder->Data), AllocatedNew * sizeof (*DataNew), BootOrder->Data ); if (DataNew == NULL) { return RETURN_OUT_OF_RESOURCES; } BootOrder->Allocated = AllocatedNew; BootOrder->Data = DataNew; } BootOrder->Data[BootOrder->Produced++] = BootOptionId; return RETURN_SUCCESS; } /** OpenFirmware device path node **/ typedef struct { SUBSTRING DriverName; SUBSTRING UnitAddress; SUBSTRING DeviceArguments; } OFW_NODE; /** Parse an OpenFirmware device path node into the caller-allocated OFW_NODE structure, and advance in the input string. The node format is mostly parsed after IEEE 1275-1994, 3.2.1.1 "Node names" (a leading slash is expected and not returned): /driver-name@unit-address[:device-arguments][] A single trailing character is consumed but not returned. A trailing or NUL character terminates the device path. The function relies on ASCII encoding. @param[in out] Ptr Address of the pointer pointing to the start of the node string. After successful parsing *Ptr is set to the byte immediately following the consumed characters. On error it points to the byte that caused the error. The input string is never modified. @param[out] OfwNode The members of this structure point into the input string, designating components of the node. Separators are never included. If "device-arguments" is missing, then DeviceArguments.Ptr is set to NULL. All components that are present have nonzero length. If the call doesn't succeed, the contents of this structure is indeterminate. @param[out] IsFinal In case of successul parsing, this parameter signals whether the node just parsed is the final node in the device path. The call after a final node will attempt to start parsing the next path. If the call doesn't succeed, then this parameter is not changed. @retval RETURN_SUCCESS Parsing successful. @retval RETURN_NOT_FOUND Parsing terminated. *Ptr was (and is) pointing to an empty string. @retval RETURN_INVALID_PARAMETER Parse error. **/ STATIC RETURN_STATUS ParseOfwNode ( IN OUT CONST CHAR8 **Ptr, OUT OFW_NODE *OfwNode, OUT BOOLEAN *IsFinal ) { // // A leading slash is expected. End of string is tolerated. // switch (**Ptr) { case '\0': return RETURN_NOT_FOUND; case '/': ++*Ptr; break; default: return RETURN_INVALID_PARAMETER; } // // driver-name // OfwNode->DriverName.Ptr = *Ptr; OfwNode->DriverName.Len = 0; while (OfwNode->DriverName.Len < 32 && (IsAlnum (**Ptr) || IsDriverNamePunct (**Ptr)) ) { ++*Ptr; ++OfwNode->DriverName.Len; } if (OfwNode->DriverName.Len == 0 || OfwNode->DriverName.Len == 32) { return RETURN_INVALID_PARAMETER; } // // unit-address // if (**Ptr != '@') { return RETURN_INVALID_PARAMETER; } ++*Ptr; OfwNode->UnitAddress.Ptr = *Ptr; OfwNode->UnitAddress.Len = 0; while (IsPrintNotDelim (**Ptr)) { ++*Ptr; ++OfwNode->UnitAddress.Len; } if (OfwNode->UnitAddress.Len == 0) { return RETURN_INVALID_PARAMETER; } // // device-arguments, may be omitted // OfwNode->DeviceArguments.Len = 0; if (**Ptr == ':') { ++*Ptr; OfwNode->DeviceArguments.Ptr = *Ptr; while (IsPrintNotDelim (**Ptr)) { ++*Ptr; ++OfwNode->DeviceArguments.Len; } if (OfwNode->DeviceArguments.Len == 0) { return RETURN_INVALID_PARAMETER; } } else { OfwNode->DeviceArguments.Ptr = NULL; } switch (**Ptr) { case '\n': ++*Ptr; // // fall through // case '\0': *IsFinal = TRUE; break; case '/': *IsFinal = FALSE; break; default: return RETURN_INVALID_PARAMETER; } DEBUG (( DEBUG_VERBOSE, "%a: DriverName=\"%.*a\" UnitAddress=\"%.*a\" DeviceArguments=\"%.*a\"\n", __FUNCTION__, OfwNode->DriverName.Len, OfwNode->DriverName.Ptr, OfwNode->UnitAddress.Len, OfwNode->UnitAddress.Ptr, OfwNode->DeviceArguments.Len, OfwNode->DeviceArguments.Ptr == NULL ? "" : OfwNode->DeviceArguments.Ptr )); return RETURN_SUCCESS; } /** Translate an array of OpenFirmware device nodes to a UEFI device path fragment. @param[in] OfwNode Array of OpenFirmware device nodes to translate, constituting the beginning of an OpenFirmware device path. @param[in] NumNodes Number of elements in OfwNode. @param[out] Translated Destination array receiving the UEFI path fragment, allocated by the caller. If the return value differs from RETURN_SUCCESS, its contents is indeterminate. @param[in out] TranslatedSize On input, the number of CHAR16's in Translated. On RETURN_SUCCESS this parameter is assigned the number of non-NUL CHAR16's written to Translated. In case of other return values, TranslatedSize is indeterminate. @retval RETURN_SUCCESS Translation successful. @retval RETURN_BUFFER_TOO_SMALL The translation does not fit into the number of bytes provided. @retval RETURN_UNSUPPORTED The array of OpenFirmware device nodes can't be translated in the current implementation. **/ STATIC RETURN_STATUS TranslateOfwNodes ( IN CONST OFW_NODE *OfwNode, IN UINTN NumNodes, OUT CHAR16 *Translated, IN OUT UINTN *TranslatedSize ) { UINT32 PciDevFun[2]; UINTN NumEntries; UINTN Written; // // Get PCI device and optional PCI function. Assume a single PCI root. // if (NumNodes < REQUIRED_OFW_NODES || !SubstringEq (OfwNode[0].DriverName, "pci") ) { return RETURN_UNSUPPORTED; } PciDevFun[1] = 0; NumEntries = sizeof (PciDevFun) / sizeof (PciDevFun[0]); if (ParseUnitAddressHexList ( OfwNode[1].UnitAddress, PciDevFun, &NumEntries ) != RETURN_SUCCESS ) { return RETURN_UNSUPPORTED; } if (NumNodes >= 4 && SubstringEq (OfwNode[1].DriverName, "ide") && SubstringEq (OfwNode[2].DriverName, "drive") && SubstringEq (OfwNode[3].DriverName, "disk") ) { // // OpenFirmware device path (IDE disk, IDE CD-ROM): // // /pci@i0cf8/ide@1,1/drive@0/disk@0 // ^ ^ ^ ^ ^ // | | | | master or slave // | | | primary or secondary // | PCI slot & function holding IDE controller // PCI root at system bus port, PIO // // UEFI device path: // // PciRoot(0x0)/Pci(0x1,0x1)/Ata(Primary,Master,0x0) // ^ // fixed LUN // UINT32 Secondary; UINT32 Slave; NumEntries = 1; if (ParseUnitAddressHexList ( OfwNode[2].UnitAddress, &Secondary, &NumEntries ) != RETURN_SUCCESS || Secondary > 1 || ParseUnitAddressHexList ( OfwNode[3].UnitAddress, &Slave, &NumEntries // reuse after previous single-element call ) != RETURN_SUCCESS || Slave > 1 ) { return RETURN_UNSUPPORTED; } Written = UnicodeSPrintAsciiFormat ( Translated, *TranslatedSize * sizeof (*Translated), // BufferSize in bytes "PciRoot(0x0)/Pci(0x%x,0x%x)/Ata(%a,%a,0x0)", PciDevFun[0], PciDevFun[1], Secondary ? "Secondary" : "Primary", Slave ? "Slave" : "Master" ); } else if (NumNodes >= 4 && SubstringEq (OfwNode[1].DriverName, "isa") && SubstringEq (OfwNode[2].DriverName, "fdc") && SubstringEq (OfwNode[3].DriverName, "floppy") ) { // // OpenFirmware device path (floppy disk): // // /pci@i0cf8/isa@1/fdc@03f0/floppy@0 // ^ ^ ^ ^ // | | | A: or B: // | | ISA controller io-port (hex) // | PCI slot holding ISA controller // PCI root at system bus port, PIO // // UEFI device path: // // PciRoot(0x0)/Pci(0x1,0x0)/Floppy(0x0) // ^ // ACPI UID // UINT32 AcpiUid; NumEntries = 1; if (ParseUnitAddressHexList ( OfwNode[3].UnitAddress, &AcpiUid, &NumEntries ) != RETURN_SUCCESS || AcpiUid > 1 ) { return RETURN_UNSUPPORTED; } Written = UnicodeSPrintAsciiFormat ( Translated, *TranslatedSize * sizeof (*Translated), // BufferSize in bytes "PciRoot(0x0)/Pci(0x%x,0x%x)/Floppy(0x%x)", PciDevFun[0], PciDevFun[1], AcpiUid ); } else if (NumNodes >= 3 && SubstringEq (OfwNode[1].DriverName, "scsi") && SubstringEq (OfwNode[2].DriverName, "disk") ) { // // OpenFirmware device path (virtio-blk disk): // // /pci@i0cf8/scsi@6[,3]/disk@0,0 // ^ ^ ^ ^ ^ // | | | fixed // | | PCI function corresponding to disk (optional) // | PCI slot holding disk // PCI root at system bus port, PIO // // UEFI device path prefix: // // PciRoot(0x0)/Pci(0x6,0x0)/HD( -- if PCI function is 0 or absent // PciRoot(0x0)/Pci(0x6,0x3)/HD( -- if PCI function is present and nonzero // Written = UnicodeSPrintAsciiFormat ( Translated, *TranslatedSize * sizeof (*Translated), // BufferSize in bytes "PciRoot(0x0)/Pci(0x%x,0x%x)/HD(", PciDevFun[0], PciDevFun[1] ); } else if (NumNodes >= 4 && SubstringEq (OfwNode[1].DriverName, "scsi") && SubstringEq (OfwNode[2].DriverName, "channel") && SubstringEq (OfwNode[3].DriverName, "disk") ) { // // OpenFirmware device path (virtio-scsi disk): // // /pci@i0cf8/scsi@7[,3]/channel@0/disk@2,3 // ^ ^ ^ ^ ^ // | | | | LUN // | | | target // | | channel (unused, fixed 0) // | PCI slot[, function] holding SCSI controller // PCI root at system bus port, PIO // // UEFI device path prefix: // // PciRoot(0x0)/Pci(0x7,0x0)/Scsi(0x2,0x3) // -- if PCI function is 0 or absent // PciRoot(0x0)/Pci(0x7,0x3)/Scsi(0x2,0x3) // -- if PCI function is present and nonzero // UINT32 TargetLun[2]; TargetLun[1] = 0; NumEntries = sizeof (TargetLun) / sizeof (TargetLun[0]); if (ParseUnitAddressHexList ( OfwNode[3].UnitAddress, TargetLun, &NumEntries ) != RETURN_SUCCESS ) { return RETURN_UNSUPPORTED; } Written = UnicodeSPrintAsciiFormat ( Translated, *TranslatedSize * sizeof (*Translated), // BufferSize in bytes "PciRoot(0x0)/Pci(0x%x,0x%x)/Scsi(0x%x,0x%x)", PciDevFun[0], PciDevFun[1], TargetLun[0], TargetLun[1] ); } else if (NumNodes >= 3 && SubstringEq (OfwNode[1].DriverName, "ethernet") && SubstringEq (OfwNode[2].DriverName, "ethernet-phy") ) { // // OpenFirmware device path (Ethernet NIC): // // /pci@i0cf8/ethernet@3[,2]/ethernet-phy@0 // ^ ^ ^ // | | fixed // | PCI slot[, function] holding Ethernet card // PCI root at system bus port, PIO // // UEFI device path prefix (dependent on presence of nonzero PCI function): // // PciRoot(0x0)/Pci(0x3,0x0)/MAC(525400E15EEF,0x1) // PciRoot(0x0)/Pci(0x3,0x2)/MAC(525400E15EEF,0x1) // ^ ^ // MAC address IfType (1 == Ethernet) // // (Some UEFI NIC drivers don't set 0x1 for IfType.) // Written = UnicodeSPrintAsciiFormat ( Translated, *TranslatedSize * sizeof (*Translated), // BufferSize in bytes "PciRoot(0x0)/Pci(0x%x,0x%x)/MAC", PciDevFun[0], PciDevFun[1] ); } else { return RETURN_UNSUPPORTED; } // // There's no way to differentiate between "completely used up without // truncation" and "truncated", so treat the former as the latter, and return // success only for "some room left unused". // if (Written + 1 < *TranslatedSize) { *TranslatedSize = Written; return RETURN_SUCCESS; } return RETURN_BUFFER_TOO_SMALL; } /** Translate an OpenFirmware device path fragment to a UEFI device path fragment, and advance in the input string. @param[in out] Ptr Address of the pointer pointing to the start of the path string. After successful translation (RETURN_SUCCESS) or at least successful parsing (RETURN_UNSUPPORTED, RETURN_BUFFER_TOO_SMALL), *Ptr is set to the byte immediately following the consumed characters. In other error cases, it points to the byte that caused the error. @param[out] Translated Destination array receiving the UEFI path fragment, allocated by the caller. If the return value differs from RETURN_SUCCESS, its contents is indeterminate. @param[in out] TranslatedSize On input, the number of CHAR16's in Translated. On RETURN_SUCCESS this parameter is assigned the number of non-NUL CHAR16's written to Translated. In case of other return values, TranslatedSize is indeterminate. @retval RETURN_SUCCESS Translation successful. @retval RETURN_BUFFER_TOO_SMALL The OpenFirmware device path was parsed successfully, but its translation did not fit into the number of bytes provided. Further calls to this function are possible. @retval RETURN_UNSUPPORTED The OpenFirmware device path was parsed successfully, but it can't be translated in the current implementation. Further calls to this function are possible. @retval RETURN_NOT_FOUND Translation terminated, *Ptr was (and is) pointing to an empty string. @retval RETURN_INVALID_PARAMETER Parse error. This is a permanent error. **/ STATIC RETURN_STATUS TranslateOfwPath ( IN OUT CONST CHAR8 **Ptr, OUT CHAR16 *Translated, IN OUT UINTN *TranslatedSize ) { UINTN NumNodes; RETURN_STATUS Status; OFW_NODE Node[EXAMINED_OFW_NODES]; BOOLEAN IsFinal; OFW_NODE Skip; NumNodes = 0; Status = ParseOfwNode (Ptr, &Node[NumNodes], &IsFinal); if (Status == RETURN_NOT_FOUND) { DEBUG ((DEBUG_VERBOSE, "%a: no more nodes\n", __FUNCTION__)); return RETURN_NOT_FOUND; } while (Status == RETURN_SUCCESS && !IsFinal) { ++NumNodes; Status = ParseOfwNode ( Ptr, (NumNodes < EXAMINED_OFW_NODES) ? &Node[NumNodes] : &Skip, &IsFinal ); } switch (Status) { case RETURN_SUCCESS: ++NumNodes; break; case RETURN_INVALID_PARAMETER: DEBUG ((DEBUG_VERBOSE, "%a: parse error\n", __FUNCTION__)); return RETURN_INVALID_PARAMETER; default: ASSERT (0); } Status = TranslateOfwNodes ( Node, NumNodes < EXAMINED_OFW_NODES ? NumNodes : EXAMINED_OFW_NODES, Translated, TranslatedSize); switch (Status) { case RETURN_SUCCESS: DEBUG ((DEBUG_VERBOSE, "%a: success: \"%s\"\n", __FUNCTION__, Translated)); break; case RETURN_BUFFER_TOO_SMALL: DEBUG ((DEBUG_VERBOSE, "%a: buffer too small\n", __FUNCTION__)); break; case RETURN_UNSUPPORTED: DEBUG ((DEBUG_VERBOSE, "%a: unsupported\n", __FUNCTION__)); break; default: ASSERT (0); } return Status; } /** Convert the UEFI DevicePath to full text representation with DevPathToText, then match the UEFI device path fragment in Translated against it. @param[in] Translated UEFI device path fragment, translated from OpenFirmware format, to search for. @param[in] TranslatedLength The length of Translated in CHAR16's. @param[in] DevicePath Boot option device path whose textual rendering to search in. @param[in] DevPathToText Binary-to-text conversion protocol for DevicePath. @retval TRUE If Translated was found at the beginning of DevicePath after converting the latter to text. @retval FALSE If DevicePath was NULL, or it could not be converted, or there was no match. **/ STATIC BOOLEAN Match ( IN CONST CHAR16 *Translated, IN UINTN TranslatedLength, IN CONST EFI_DEVICE_PATH_PROTOCOL *DevicePath ) { CHAR16 *Converted; BOOLEAN Result; Converted = ConvertDevicePathToText ( DevicePath, FALSE, // DisplayOnly FALSE // AllowShortcuts ); if (Converted == NULL) { return FALSE; } // // Is Translated a prefix of Converted? // Result = (BOOLEAN)(StrnCmp (Converted, Translated, TranslatedLength) == 0); DEBUG (( DEBUG_VERBOSE, "%a: against \"%s\": %a\n", __FUNCTION__, Converted, Result ? "match" : "no match" )); FreePool (Converted); return Result; } /** Set the boot order based on configuration retrieved from QEMU. Attempt to retrieve the "bootorder" fw_cfg file from QEMU. Translate the OpenFirmware device paths therein to UEFI device path fragments. Match the translated fragments against BootOptionList, and rewrite the BootOrder NvVar so that it corresponds to the order described in fw_cfg. @param[in] BootOptionList A boot option list, created with BdsLibEnumerateAllBootOption (). @retval RETURN_SUCCESS BootOrder NvVar rewritten. @retval RETURN_UNSUPPORTED QEMU's fw_cfg is not supported. @retval RETURN_NOT_FOUND Empty or nonexistent "bootorder" fw_cfg file, or no match found between the "bootorder" fw_cfg file and BootOptionList. @retval RETURN_INVALID_PARAMETER Parse error in the "bootorder" fw_cfg file. @retval RETURN_OUT_OF_RESOURCES Memory allocation failed. @return Values returned by gBS->LocateProtocol () or gRT->SetVariable (). **/ RETURN_STATUS SetBootOrderFromQemu ( IN CONST LIST_ENTRY *BootOptionList ) { RETURN_STATUS Status; FIRMWARE_CONFIG_ITEM FwCfgItem; UINTN FwCfgSize; CHAR8 *FwCfg; CONST CHAR8 *FwCfgPtr; BOOT_ORDER BootOrder; UINTN TranslatedSize; CHAR16 Translated[TRANSLATION_OUTPUT_SIZE]; Status = QemuFwCfgFindFile ("bootorder", &FwCfgItem, &FwCfgSize); if (Status != RETURN_SUCCESS) { return Status; } if (FwCfgSize == 0) { return RETURN_NOT_FOUND; } FwCfg = AllocatePool (FwCfgSize); if (FwCfg == NULL) { return RETURN_OUT_OF_RESOURCES; } QemuFwCfgSelectItem (FwCfgItem); QemuFwCfgReadBytes (FwCfgSize, FwCfg); if (FwCfg[FwCfgSize - 1] != '\0') { Status = RETURN_INVALID_PARAMETER; goto ErrorFreeFwCfg; } DEBUG ((DEBUG_VERBOSE, "%a: FwCfg:\n", __FUNCTION__)); DEBUG ((DEBUG_VERBOSE, "%a\n", FwCfg)); DEBUG ((DEBUG_VERBOSE, "%a: FwCfg: \n", __FUNCTION__)); FwCfgPtr = FwCfg; BootOrder.Produced = 0; BootOrder.Allocated = 1; BootOrder.Data = AllocatePool ( BootOrder.Allocated * sizeof (*BootOrder.Data) ); if (BootOrder.Data == NULL) { Status = RETURN_OUT_OF_RESOURCES; goto ErrorFreeFwCfg; } // // translate each OpenFirmware path // TranslatedSize = sizeof (Translated) / sizeof (Translated[0]); Status = TranslateOfwPath (&FwCfgPtr, Translated, &TranslatedSize); while (Status == RETURN_SUCCESS || Status == RETURN_UNSUPPORTED || Status == RETURN_BUFFER_TOO_SMALL) { if (Status == RETURN_SUCCESS) { CONST LIST_ENTRY *Link; // // match translated OpenFirmware path against all enumerated boot options // for (Link = BootOptionList->ForwardLink; Link != BootOptionList; Link = Link->ForwardLink) { CONST BDS_COMMON_OPTION *BootOption; BootOption = CR ( Link, BDS_COMMON_OPTION, Link, BDS_LOAD_OPTION_SIGNATURE ); if (IS_LOAD_OPTION_TYPE (BootOption->Attribute, LOAD_OPTION_ACTIVE) && Match ( Translated, TranslatedSize, // contains length, not size, in CHAR16's here BootOption->DevicePath ) ) { // // match found, store ID and continue with next OpenFirmware path // Status = BootOrderAppend (&BootOrder, BootOption->BootCurrent); if (Status != RETURN_SUCCESS) { goto ErrorFreeBootOrder; } break; } } // scanned all enumerated boot options } // translation successful TranslatedSize = sizeof (Translated) / sizeof (Translated[0]); Status = TranslateOfwPath (&FwCfgPtr, Translated, &TranslatedSize); } // scanning of OpenFirmware paths done if (Status == RETURN_NOT_FOUND && BootOrder.Produced > 0) { // // No more OpenFirmware paths, some matches found: rewrite BootOrder NvVar. // See Table 10 in the UEFI Spec 2.3.1 with Errata C for the required // attributes. // Status = gRT->SetVariable ( L"BootOrder", &gEfiGlobalVariableGuid, EFI_VARIABLE_NON_VOLATILE | EFI_VARIABLE_BOOTSERVICE_ACCESS | EFI_VARIABLE_RUNTIME_ACCESS, BootOrder.Produced * sizeof (*BootOrder.Data), BootOrder.Data ); DEBUG (( DEBUG_INFO, "%a: setting BootOrder: %a\n", __FUNCTION__, Status == EFI_SUCCESS ? "success" : "error" )); } ErrorFreeBootOrder: FreePool (BootOrder.Data); ErrorFreeFwCfg: FreePool (FwCfg); return Status; }