2 Rewrite the BootOrder NvVar based on QEMU's "bootorder" fw_cfg file.
4 Copyright (C) 2012 - 2013, Red Hat, Inc.
5 Copyright (c) 2013, Intel Corporation. All rights reserved.<BR>
7 This program and the accompanying materials are licensed and made available
8 under the terms and conditions of the BSD License which accompanies this
9 distribution. The full text of the license may be found at
10 http://opensource.org/licenses/bsd-license.php
12 THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, WITHOUT
13 WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.
16 #include <Library/QemuFwCfgLib.h>
17 #include <Library/DebugLib.h>
18 #include <Library/MemoryAllocationLib.h>
19 #include <Library/GenericBdsLib.h>
20 #include <Library/UefiBootServicesTableLib.h>
21 #include <Library/UefiRuntimeServicesTableLib.h>
22 #include <Library/BaseLib.h>
23 #include <Library/PrintLib.h>
24 #include <Library/DevicePathLib.h>
25 #include <Guid/GlobalVariable.h>
29 OpenFirmware to UEFI device path translation output buffer size in CHAR16's.
31 #define TRANSLATION_OUTPUT_SIZE 0x100
35 Numbers of nodes in OpenFirmware device paths that are required and examined.
37 #define REQUIRED_OFW_NODES 2
38 #define EXAMINED_OFW_NODES 4
42 Simple character classification routines, corresponding to POSIX class names
51 return (('0' <= Chr
&& Chr
<= '9') ||
52 ('A' <= Chr
&& Chr
<= 'Z') ||
53 ('a' <= Chr
&& Chr
<= 'z')
64 return (Chr
== ',' || Chr
== '.' || Chr
== '_' ||
65 Chr
== '+' || Chr
== '-'
76 return (32 <= Chr
&& Chr
<= 126 &&
77 Chr
!= '/' && Chr
!= '@' && Chr
!= ':');
82 Utility types and functions.
85 CONST CHAR8
*Ptr
; // not necessarily NUL-terminated
86 UINTN Len
; // number of non-NUL characters
92 Check if Substring and String have identical contents.
94 The function relies on the restriction that a SUBSTRING cannot have embedded
97 @param[in] Substring The SUBSTRING input to the comparison.
99 @param[in] String The ASCII string input to the comparison.
102 @return Whether the inputs have identical contents.
108 IN SUBSTRING Substring
,
109 IN CONST CHAR8
*String
118 while (Pos
< Substring
.Len
&& Substring
.Ptr
[Pos
] == *Chr
) {
123 return (BOOLEAN
)(Pos
== Substring
.Len
&& *Chr
== '\0');
129 Parse a comma-separated list of hexadecimal integers into the elements of an
132 Whitespace, "0x" prefixes, leading or trailing commas, sequences of commas,
133 or an empty string are not allowed; they are rejected.
135 The function relies on ASCII encoding.
137 @param[in] UnitAddress The substring to parse.
139 @param[out] Result The array, allocated by the caller, to receive
140 the parsed values. This parameter may be NULL if
141 NumResults is zero on input.
143 @param[in out] NumResults On input, the number of elements allocated for
144 Result. On output, the number of elements it has
145 taken (or would have taken) to parse the string
149 @retval RETURN_SUCCESS UnitAddress has been fully parsed.
150 NumResults is set to the number of parsed
151 values; the corresponding elements have
152 been set in Result. The rest of Result's
153 elements are unchanged.
155 @retval RETURN_BUFFER_TOO_SMALL UnitAddress has been fully parsed.
156 NumResults is set to the number of parsed
157 values, but elements have been stored only
158 up to the input value of NumResults, which
159 is less than what has been parsed.
161 @retval RETURN_INVALID_PARAMETER Parse error. The contents of Results is
162 indeterminate. NumResults has not been
168 ParseUnitAddressHexList (
169 IN SUBSTRING UnitAddress
,
171 IN OUT UINTN
*NumResults
174 UINTN Entry
; // number of entry currently being parsed
175 UINT32 EntryVal
; // value being constructed for current entry
176 CHAR8 PrevChr
; // UnitAddress character previously checked
177 UINTN Pos
; // current position within UnitAddress
178 RETURN_STATUS Status
;
184 for (Pos
= 0; Pos
< UnitAddress
.Len
; ++Pos
) {
188 Chr
= UnitAddress
.Ptr
[Pos
];
189 Val
= ('a' <= Chr
&& Chr
<= 'f') ? (Chr
- 'a' + 10) :
190 ('A' <= Chr
&& Chr
<= 'F') ? (Chr
- 'A' + 10) :
191 ('0' <= Chr
&& Chr
<= '9') ? (Chr
- '0' ) :
195 if (EntryVal
> 0xFFFFFFF) {
196 return RETURN_INVALID_PARAMETER
;
198 EntryVal
= (EntryVal
<< 4) | Val
;
199 } else if (Chr
== ',') {
200 if (PrevChr
== ',') {
201 return RETURN_INVALID_PARAMETER
;
203 if (Entry
< *NumResults
) {
204 Result
[Entry
] = EntryVal
;
209 return RETURN_INVALID_PARAMETER
;
215 if (PrevChr
== ',') {
216 return RETURN_INVALID_PARAMETER
;
218 if (Entry
< *NumResults
) {
219 Result
[Entry
] = EntryVal
;
220 Status
= RETURN_SUCCESS
;
222 Status
= RETURN_BUFFER_TOO_SMALL
;
232 A simple array of Boot Option ID's.
242 Array element tracking an enumerated boot option that has the
243 LOAD_OPTION_ACTIVE attribute.
246 CONST BDS_COMMON_OPTION
*BootOption
; // reference only, no ownership
247 BOOLEAN Appended
; // has been added to a BOOT_ORDER?
253 Append an active boot option to BootOrder, reallocating the latter if needed.
255 @param[in out] BootOrder The structure pointing to the array and holding
256 allocation and usage counters.
258 @param[in] ActiveOption The active boot option whose ID should be
259 appended to the array.
262 @retval RETURN_SUCCESS ID of ActiveOption appended.
264 @retval RETURN_OUT_OF_RESOURCES Memory reallocation failed.
270 IN OUT BOOT_ORDER
*BootOrder
,
271 IN OUT ACTIVE_OPTION
*ActiveOption
274 if (BootOrder
->Produced
== BootOrder
->Allocated
) {
278 ASSERT (BootOrder
->Allocated
> 0);
279 AllocatedNew
= BootOrder
->Allocated
* 2;
280 DataNew
= ReallocatePool (
281 BootOrder
->Allocated
* sizeof (*BootOrder
->Data
),
282 AllocatedNew
* sizeof (*DataNew
),
285 if (DataNew
== NULL
) {
286 return RETURN_OUT_OF_RESOURCES
;
288 BootOrder
->Allocated
= AllocatedNew
;
289 BootOrder
->Data
= DataNew
;
292 BootOrder
->Data
[BootOrder
->Produced
++] =
293 ActiveOption
->BootOption
->BootCurrent
;
294 ActiveOption
->Appended
= TRUE
;
295 return RETURN_SUCCESS
;
301 Create an array of ACTIVE_OPTION elements for a boot option list.
303 @param[in] BootOptionList A boot option list, created with
304 BdsLibEnumerateAllBootOption().
306 @param[out] ActiveOption Pointer to the first element in the new array.
307 The caller is responsible for freeing the array
308 with FreePool() after use.
310 @param[out] Count Number of elements in the new array.
313 @retval RETURN_SUCCESS The ActiveOption array has been created.
315 @retval RETURN_NOT_FOUND No active entry has been found in
318 @retval RETURN_OUT_OF_RESOURCES Memory allocation failed.
323 CollectActiveOptions (
324 IN CONST LIST_ENTRY
*BootOptionList
,
325 OUT ACTIVE_OPTION
**ActiveOption
,
331 *ActiveOption
= NULL
;
334 // Scan the list twice:
335 // - count active entries,
336 // - store links to active entries.
338 for (ScanMode
= 0; ScanMode
< 2; ++ScanMode
) {
339 CONST LIST_ENTRY
*Link
;
341 Link
= BootOptionList
->ForwardLink
;
343 while (Link
!= BootOptionList
) {
344 CONST BDS_COMMON_OPTION
*Current
;
346 Current
= CR (Link
, BDS_COMMON_OPTION
, Link
, BDS_LOAD_OPTION_SIGNATURE
);
347 if (IS_LOAD_OPTION_TYPE (Current
->Attribute
, LOAD_OPTION_ACTIVE
)) {
349 (*ActiveOption
)[*Count
].BootOption
= Current
;
350 (*ActiveOption
)[*Count
].Appended
= FALSE
;
354 Link
= Link
->ForwardLink
;
359 return RETURN_NOT_FOUND
;
361 *ActiveOption
= AllocatePool (*Count
* sizeof **ActiveOption
);
362 if (*ActiveOption
== NULL
) {
363 return RETURN_OUT_OF_RESOURCES
;
367 return RETURN_SUCCESS
;
372 OpenFirmware device path node
375 SUBSTRING DriverName
;
376 SUBSTRING UnitAddress
;
377 SUBSTRING DeviceArguments
;
383 Parse an OpenFirmware device path node into the caller-allocated OFW_NODE
384 structure, and advance in the input string.
386 The node format is mostly parsed after IEEE 1275-1994, 3.2.1.1 "Node names"
387 (a leading slash is expected and not returned):
389 /driver-name@unit-address[:device-arguments][<LF>]
391 A single trailing <LF> character is consumed but not returned. A trailing
392 <LF> or NUL character terminates the device path.
394 The function relies on ASCII encoding.
396 @param[in out] Ptr Address of the pointer pointing to the start of the
397 node string. After successful parsing *Ptr is set to
398 the byte immediately following the consumed
399 characters. On error it points to the byte that
400 caused the error. The input string is never modified.
402 @param[out] OfwNode The members of this structure point into the input
403 string, designating components of the node.
404 Separators are never included. If "device-arguments"
405 is missing, then DeviceArguments.Ptr is set to NULL.
406 All components that are present have nonzero length.
408 If the call doesn't succeed, the contents of this
409 structure is indeterminate.
411 @param[out] IsFinal In case of successul parsing, this parameter signals
412 whether the node just parsed is the final node in the
413 device path. The call after a final node will attempt
414 to start parsing the next path. If the call doesn't
415 succeed, then this parameter is not changed.
418 @retval RETURN_SUCCESS Parsing successful.
420 @retval RETURN_NOT_FOUND Parsing terminated. *Ptr was (and is)
421 pointing to an empty string.
423 @retval RETURN_INVALID_PARAMETER Parse error.
429 IN OUT CONST CHAR8
**Ptr
,
430 OUT OFW_NODE
*OfwNode
,
435 // A leading slash is expected. End of string is tolerated.
439 return RETURN_NOT_FOUND
;
446 return RETURN_INVALID_PARAMETER
;
452 OfwNode
->DriverName
.Ptr
= *Ptr
;
453 OfwNode
->DriverName
.Len
= 0;
454 while (OfwNode
->DriverName
.Len
< 32 &&
455 (IsAlnum (**Ptr
) || IsDriverNamePunct (**Ptr
))
458 ++OfwNode
->DriverName
.Len
;
461 if (OfwNode
->DriverName
.Len
== 0 || OfwNode
->DriverName
.Len
== 32) {
462 return RETURN_INVALID_PARAMETER
;
470 return RETURN_INVALID_PARAMETER
;
474 OfwNode
->UnitAddress
.Ptr
= *Ptr
;
475 OfwNode
->UnitAddress
.Len
= 0;
476 while (IsPrintNotDelim (**Ptr
)) {
478 ++OfwNode
->UnitAddress
.Len
;
481 if (OfwNode
->UnitAddress
.Len
== 0) {
482 return RETURN_INVALID_PARAMETER
;
487 // device-arguments, may be omitted
489 OfwNode
->DeviceArguments
.Len
= 0;
492 OfwNode
->DeviceArguments
.Ptr
= *Ptr
;
494 while (IsPrintNotDelim (**Ptr
)) {
496 ++OfwNode
->DeviceArguments
.Len
;
499 if (OfwNode
->DeviceArguments
.Len
== 0) {
500 return RETURN_INVALID_PARAMETER
;
504 OfwNode
->DeviceArguments
.Ptr
= NULL
;
523 return RETURN_INVALID_PARAMETER
;
528 "%a: DriverName=\"%.*a\" UnitAddress=\"%.*a\" DeviceArguments=\"%.*a\"\n",
530 OfwNode
->DriverName
.Len
, OfwNode
->DriverName
.Ptr
,
531 OfwNode
->UnitAddress
.Len
, OfwNode
->UnitAddress
.Ptr
,
532 OfwNode
->DeviceArguments
.Len
,
533 OfwNode
->DeviceArguments
.Ptr
== NULL
? "" : OfwNode
->DeviceArguments
.Ptr
535 return RETURN_SUCCESS
;
541 Translate an array of OpenFirmware device nodes to a UEFI device path
544 @param[in] OfwNode Array of OpenFirmware device nodes to
545 translate, constituting the beginning of an
546 OpenFirmware device path.
548 @param[in] NumNodes Number of elements in OfwNode.
550 @param[out] Translated Destination array receiving the UEFI path
551 fragment, allocated by the caller. If the
552 return value differs from RETURN_SUCCESS, its
553 contents is indeterminate.
555 @param[in out] TranslatedSize On input, the number of CHAR16's in
556 Translated. On RETURN_SUCCESS this parameter
557 is assigned the number of non-NUL CHAR16's
558 written to Translated. In case of other return
559 values, TranslatedSize is indeterminate.
562 @retval RETURN_SUCCESS Translation successful.
564 @retval RETURN_BUFFER_TOO_SMALL The translation does not fit into the number
567 @retval RETURN_UNSUPPORTED The array of OpenFirmware device nodes can't
568 be translated in the current implementation.
574 IN CONST OFW_NODE
*OfwNode
,
576 OUT CHAR16
*Translated
,
577 IN OUT UINTN
*TranslatedSize
585 // Get PCI device and optional PCI function. Assume a single PCI root.
587 if (NumNodes
< REQUIRED_OFW_NODES
||
588 !SubstringEq (OfwNode
[0].DriverName
, "pci")
590 return RETURN_UNSUPPORTED
;
593 NumEntries
= sizeof (PciDevFun
) / sizeof (PciDevFun
[0]);
594 if (ParseUnitAddressHexList (
595 OfwNode
[1].UnitAddress
,
600 return RETURN_UNSUPPORTED
;
604 SubstringEq (OfwNode
[1].DriverName
, "ide") &&
605 SubstringEq (OfwNode
[2].DriverName
, "drive") &&
606 SubstringEq (OfwNode
[3].DriverName
, "disk")
609 // OpenFirmware device path (IDE disk, IDE CD-ROM):
611 // /pci@i0cf8/ide@1,1/drive@0/disk@0
613 // | | | | master or slave
614 // | | | primary or secondary
615 // | PCI slot & function holding IDE controller
616 // PCI root at system bus port, PIO
620 // PciRoot(0x0)/Pci(0x1,0x1)/Ata(Primary,Master,0x0)
628 if (ParseUnitAddressHexList (
629 OfwNode
[2].UnitAddress
,
632 ) != RETURN_SUCCESS
||
634 ParseUnitAddressHexList (
635 OfwNode
[3].UnitAddress
,
637 &NumEntries
// reuse after previous single-element call
638 ) != RETURN_SUCCESS
||
641 return RETURN_UNSUPPORTED
;
644 Written
= UnicodeSPrintAsciiFormat (
646 *TranslatedSize
* sizeof (*Translated
), // BufferSize in bytes
647 "PciRoot(0x0)/Pci(0x%x,0x%x)/Ata(%a,%a,0x0)",
650 Secondary
? "Secondary" : "Primary",
651 Slave
? "Slave" : "Master"
653 } else if (NumNodes
>= 4 &&
654 SubstringEq (OfwNode
[1].DriverName
, "isa") &&
655 SubstringEq (OfwNode
[2].DriverName
, "fdc") &&
656 SubstringEq (OfwNode
[3].DriverName
, "floppy")
659 // OpenFirmware device path (floppy disk):
661 // /pci@i0cf8/isa@1/fdc@03f0/floppy@0
664 // | | ISA controller io-port (hex)
665 // | PCI slot holding ISA controller
666 // PCI root at system bus port, PIO
670 // PciRoot(0x0)/Pci(0x1,0x0)/Floppy(0x0)
677 if (ParseUnitAddressHexList (
678 OfwNode
[3].UnitAddress
,
681 ) != RETURN_SUCCESS
||
684 return RETURN_UNSUPPORTED
;
687 Written
= UnicodeSPrintAsciiFormat (
689 *TranslatedSize
* sizeof (*Translated
), // BufferSize in bytes
690 "PciRoot(0x0)/Pci(0x%x,0x%x)/Floppy(0x%x)",
695 } else if (NumNodes
>= 3 &&
696 SubstringEq (OfwNode
[1].DriverName
, "scsi") &&
697 SubstringEq (OfwNode
[2].DriverName
, "disk")
700 // OpenFirmware device path (virtio-blk disk):
702 // /pci@i0cf8/scsi@6[,3]/disk@0,0
705 // | | PCI function corresponding to disk (optional)
706 // | PCI slot holding disk
707 // PCI root at system bus port, PIO
709 // UEFI device path prefix:
711 // PciRoot(0x0)/Pci(0x6,0x0)/HD( -- if PCI function is 0 or absent
712 // PciRoot(0x0)/Pci(0x6,0x3)/HD( -- if PCI function is present and nonzero
714 Written
= UnicodeSPrintAsciiFormat (
716 *TranslatedSize
* sizeof (*Translated
), // BufferSize in bytes
717 "PciRoot(0x0)/Pci(0x%x,0x%x)/HD(",
721 } else if (NumNodes
>= 4 &&
722 SubstringEq (OfwNode
[1].DriverName
, "scsi") &&
723 SubstringEq (OfwNode
[2].DriverName
, "channel") &&
724 SubstringEq (OfwNode
[3].DriverName
, "disk")
727 // OpenFirmware device path (virtio-scsi disk):
729 // /pci@i0cf8/scsi@7[,3]/channel@0/disk@2,3
733 // | | channel (unused, fixed 0)
734 // | PCI slot[, function] holding SCSI controller
735 // PCI root at system bus port, PIO
737 // UEFI device path prefix:
739 // PciRoot(0x0)/Pci(0x7,0x0)/Scsi(0x2,0x3)
740 // -- if PCI function is 0 or absent
741 // PciRoot(0x0)/Pci(0x7,0x3)/Scsi(0x2,0x3)
742 // -- if PCI function is present and nonzero
747 NumEntries
= sizeof (TargetLun
) / sizeof (TargetLun
[0]);
748 if (ParseUnitAddressHexList (
749 OfwNode
[3].UnitAddress
,
754 return RETURN_UNSUPPORTED
;
757 Written
= UnicodeSPrintAsciiFormat (
759 *TranslatedSize
* sizeof (*Translated
), // BufferSize in bytes
760 "PciRoot(0x0)/Pci(0x%x,0x%x)/Scsi(0x%x,0x%x)",
766 } else if (NumNodes
>= 3 &&
767 SubstringEq (OfwNode
[1].DriverName
, "ethernet") &&
768 SubstringEq (OfwNode
[2].DriverName
, "ethernet-phy")
771 // OpenFirmware device path (Ethernet NIC):
773 // /pci@i0cf8/ethernet@3[,2]/ethernet-phy@0
776 // | PCI slot[, function] holding Ethernet card
777 // PCI root at system bus port, PIO
779 // UEFI device path prefix (dependent on presence of nonzero PCI function):
781 // PciRoot(0x0)/Pci(0x3,0x0)/MAC(525400E15EEF,0x1)
782 // PciRoot(0x0)/Pci(0x3,0x2)/MAC(525400E15EEF,0x1)
784 // MAC address IfType (1 == Ethernet)
786 // (Some UEFI NIC drivers don't set 0x1 for IfType.)
788 Written
= UnicodeSPrintAsciiFormat (
790 *TranslatedSize
* sizeof (*Translated
), // BufferSize in bytes
791 "PciRoot(0x0)/Pci(0x%x,0x%x)/MAC",
796 return RETURN_UNSUPPORTED
;
800 // There's no way to differentiate between "completely used up without
801 // truncation" and "truncated", so treat the former as the latter, and return
802 // success only for "some room left unused".
804 if (Written
+ 1 < *TranslatedSize
) {
805 *TranslatedSize
= Written
;
806 return RETURN_SUCCESS
;
809 return RETURN_BUFFER_TOO_SMALL
;
815 Translate an OpenFirmware device path fragment to a UEFI device path
816 fragment, and advance in the input string.
818 @param[in out] Ptr Address of the pointer pointing to the start
819 of the path string. After successful
820 translation (RETURN_SUCCESS) or at least
821 successful parsing (RETURN_UNSUPPORTED,
822 RETURN_BUFFER_TOO_SMALL), *Ptr is set to the
823 byte immediately following the consumed
824 characters. In other error cases, it points to
825 the byte that caused the error.
827 @param[out] Translated Destination array receiving the UEFI path
828 fragment, allocated by the caller. If the
829 return value differs from RETURN_SUCCESS, its
830 contents is indeterminate.
832 @param[in out] TranslatedSize On input, the number of CHAR16's in
833 Translated. On RETURN_SUCCESS this parameter
834 is assigned the number of non-NUL CHAR16's
835 written to Translated. In case of other return
836 values, TranslatedSize is indeterminate.
839 @retval RETURN_SUCCESS Translation successful.
841 @retval RETURN_BUFFER_TOO_SMALL The OpenFirmware device path was parsed
842 successfully, but its translation did not
843 fit into the number of bytes provided.
844 Further calls to this function are
847 @retval RETURN_UNSUPPORTED The OpenFirmware device path was parsed
848 successfully, but it can't be translated in
849 the current implementation. Further calls
850 to this function are possible.
852 @retval RETURN_NOT_FOUND Translation terminated, *Ptr was (and is)
853 pointing to an empty string.
855 @retval RETURN_INVALID_PARAMETER Parse error. This is a permanent error.
861 IN OUT CONST CHAR8
**Ptr
,
862 OUT CHAR16
*Translated
,
863 IN OUT UINTN
*TranslatedSize
867 RETURN_STATUS Status
;
868 OFW_NODE Node
[EXAMINED_OFW_NODES
];
873 Status
= ParseOfwNode (Ptr
, &Node
[NumNodes
], &IsFinal
);
875 if (Status
== RETURN_NOT_FOUND
) {
876 DEBUG ((DEBUG_VERBOSE
, "%a: no more nodes\n", __FUNCTION__
));
877 return RETURN_NOT_FOUND
;
880 while (Status
== RETURN_SUCCESS
&& !IsFinal
) {
882 Status
= ParseOfwNode (
884 (NumNodes
< EXAMINED_OFW_NODES
) ? &Node
[NumNodes
] : &Skip
,
894 case RETURN_INVALID_PARAMETER
:
895 DEBUG ((DEBUG_VERBOSE
, "%a: parse error\n", __FUNCTION__
));
896 return RETURN_INVALID_PARAMETER
;
902 Status
= TranslateOfwNodes (
904 NumNodes
< EXAMINED_OFW_NODES
? NumNodes
: EXAMINED_OFW_NODES
,
909 DEBUG ((DEBUG_VERBOSE
, "%a: success: \"%s\"\n", __FUNCTION__
, Translated
));
912 case RETURN_BUFFER_TOO_SMALL
:
913 DEBUG ((DEBUG_VERBOSE
, "%a: buffer too small\n", __FUNCTION__
));
916 case RETURN_UNSUPPORTED
:
917 DEBUG ((DEBUG_VERBOSE
, "%a: unsupported\n", __FUNCTION__
));
929 Convert the UEFI DevicePath to full text representation with DevPathToText,
930 then match the UEFI device path fragment in Translated against it.
932 @param[in] Translated UEFI device path fragment, translated from
933 OpenFirmware format, to search for.
935 @param[in] TranslatedLength The length of Translated in CHAR16's.
937 @param[in] DevicePath Boot option device path whose textual rendering
940 @param[in] DevPathToText Binary-to-text conversion protocol for DevicePath.
943 @retval TRUE If Translated was found at the beginning of DevicePath after
944 converting the latter to text.
946 @retval FALSE If DevicePath was NULL, or it could not be converted, or there
953 IN CONST CHAR16
*Translated
,
954 IN UINTN TranslatedLength
,
955 IN CONST EFI_DEVICE_PATH_PROTOCOL
*DevicePath
961 Converted
= ConvertDevicePathToText (
963 FALSE
, // DisplayOnly
964 FALSE
// AllowShortcuts
966 if (Converted
== NULL
) {
971 // Attempt to expand any relative UEFI device path starting with HD() to an
972 // absolute device path first. The logic imitates BdsLibBootViaBootOption().
973 // We don't have to free the absolute device path,
974 // BdsExpandPartitionPartialDevicePathToFull() has internal caching.
977 if (DevicePathType (DevicePath
) == MEDIA_DEVICE_PATH
&&
978 DevicePathSubType (DevicePath
) == MEDIA_HARDDRIVE_DP
) {
979 EFI_DEVICE_PATH_PROTOCOL
*AbsDevicePath
;
980 CHAR16
*AbsConverted
;
982 AbsDevicePath
= BdsExpandPartitionPartialDevicePathToFull (
983 (HARDDRIVE_DEVICE_PATH
*) DevicePath
);
984 if (AbsDevicePath
== NULL
) {
987 AbsConverted
= ConvertDevicePathToText (AbsDevicePath
, FALSE
, FALSE
);
988 if (AbsConverted
== NULL
) {
991 DEBUG ((DEBUG_VERBOSE
,
992 "%a: expanded relative device path \"%s\" for prefix matching\n",
993 __FUNCTION__
, Converted
));
994 FreePool (Converted
);
995 Converted
= AbsConverted
;
999 // Is Translated a prefix of Converted?
1001 Result
= (BOOLEAN
)(StrnCmp (Converted
, Translated
, TranslatedLength
) == 0);
1004 "%a: against \"%s\": %a\n",
1007 Result
? "match" : "no match"
1010 FreePool (Converted
);
1016 Append some of the unselected active boot options to the boot order.
1018 This function should accommodate any further policy changes in "boot option
1019 survival". Currently we're adding back everything that starts with neither
1022 @param[in,out] BootOrder The structure holding the boot order to
1023 complete. The caller is responsible for
1024 initializing (and potentially populating) it
1025 before calling this function.
1027 @param[in,out] ActiveOption The array of active boot options to scan.
1028 Entries marked as Appended will be skipped.
1029 Those of the rest that satisfy the survival
1030 policy will be added to BootOrder with
1033 @param[in] ActiveCount Number of elements in ActiveOption.
1036 @retval RETURN_SUCCESS BootOrder has been extended with any eligible boot
1039 @return Error codes returned by BootOrderAppend().
1044 IN OUT BOOT_ORDER
*BootOrder
,
1045 IN OUT ACTIVE_OPTION
*ActiveOption
,
1046 IN UINTN ActiveCount
1049 RETURN_STATUS Status
;
1052 Status
= RETURN_SUCCESS
;
1054 while (!RETURN_ERROR (Status
) && Idx
< ActiveCount
) {
1055 if (!ActiveOption
[Idx
].Appended
) {
1056 CONST BDS_COMMON_OPTION
*Current
;
1057 CONST EFI_DEVICE_PATH_PROTOCOL
*FirstNode
;
1059 Current
= ActiveOption
[Idx
].BootOption
;
1060 FirstNode
= Current
->DevicePath
;
1061 if (FirstNode
!= NULL
) {
1063 STATIC CHAR16 ConvFallBack
[] = L
"<unable to convert>";
1066 Converted
= ConvertDevicePathToText (FirstNode
, FALSE
, FALSE
);
1067 if (Converted
== NULL
) {
1068 Converted
= ConvFallBack
;
1072 if (DevicePathType(FirstNode
) == MEDIA_DEVICE_PATH
&&
1073 DevicePathSubType(FirstNode
) == MEDIA_HARDDRIVE_DP
) {
1078 } else if (DevicePathType(FirstNode
) == ACPI_DEVICE_PATH
&&
1079 DevicePathSubType(FirstNode
) == ACPI_DP
) {
1080 ACPI_HID_DEVICE_PATH
*Acpi
;
1082 Acpi
= (ACPI_HID_DEVICE_PATH
*) FirstNode
;
1083 if ((Acpi
->HID
& PNP_EISA_ID_MASK
) == PNP_EISA_ID_CONST
&&
1084 EISA_ID_TO_NUM (Acpi
->HID
) == 0x0a03) {
1093 Status
= BootOrderAppend (BootOrder
, &ActiveOption
[Idx
]);
1094 if (!RETURN_ERROR (Status
)) {
1095 DEBUG ((DEBUG_VERBOSE
, "%a: keeping \"%s\"\n", __FUNCTION__
,
1099 DEBUG ((DEBUG_VERBOSE
, "%a: dropping \"%s\"\n", __FUNCTION__
,
1103 if (Converted
!= ConvFallBack
) {
1104 FreePool (Converted
);
1116 Set the boot order based on configuration retrieved from QEMU.
1118 Attempt to retrieve the "bootorder" fw_cfg file from QEMU. Translate the
1119 OpenFirmware device paths therein to UEFI device path fragments. Match the
1120 translated fragments against BootOptionList, and rewrite the BootOrder NvVar
1121 so that it corresponds to the order described in fw_cfg.
1123 @param[in] BootOptionList A boot option list, created with
1124 BdsLibEnumerateAllBootOption ().
1127 @retval RETURN_SUCCESS BootOrder NvVar rewritten.
1129 @retval RETURN_UNSUPPORTED QEMU's fw_cfg is not supported.
1131 @retval RETURN_NOT_FOUND Empty or nonexistent "bootorder" fw_cfg
1132 file, or no match found between the
1133 "bootorder" fw_cfg file and BootOptionList.
1135 @retval RETURN_INVALID_PARAMETER Parse error in the "bootorder" fw_cfg file.
1137 @retval RETURN_OUT_OF_RESOURCES Memory allocation failed.
1139 @return Values returned by gBS->LocateProtocol ()
1140 or gRT->SetVariable ().
1144 SetBootOrderFromQemu (
1145 IN CONST LIST_ENTRY
*BootOptionList
1148 RETURN_STATUS Status
;
1149 FIRMWARE_CONFIG_ITEM FwCfgItem
;
1152 CONST CHAR8
*FwCfgPtr
;
1154 BOOT_ORDER BootOrder
;
1155 ACTIVE_OPTION
*ActiveOption
;
1158 UINTN TranslatedSize
;
1159 CHAR16 Translated
[TRANSLATION_OUTPUT_SIZE
];
1161 Status
= QemuFwCfgFindFile ("bootorder", &FwCfgItem
, &FwCfgSize
);
1162 if (Status
!= RETURN_SUCCESS
) {
1166 if (FwCfgSize
== 0) {
1167 return RETURN_NOT_FOUND
;
1170 FwCfg
= AllocatePool (FwCfgSize
);
1171 if (FwCfg
== NULL
) {
1172 return RETURN_OUT_OF_RESOURCES
;
1175 QemuFwCfgSelectItem (FwCfgItem
);
1176 QemuFwCfgReadBytes (FwCfgSize
, FwCfg
);
1177 if (FwCfg
[FwCfgSize
- 1] != '\0') {
1178 Status
= RETURN_INVALID_PARAMETER
;
1179 goto ErrorFreeFwCfg
;
1182 DEBUG ((DEBUG_VERBOSE
, "%a: FwCfg:\n", __FUNCTION__
));
1183 DEBUG ((DEBUG_VERBOSE
, "%a\n", FwCfg
));
1184 DEBUG ((DEBUG_VERBOSE
, "%a: FwCfg: <end>\n", __FUNCTION__
));
1187 BootOrder
.Produced
= 0;
1188 BootOrder
.Allocated
= 1;
1189 BootOrder
.Data
= AllocatePool (
1190 BootOrder
.Allocated
* sizeof (*BootOrder
.Data
)
1192 if (BootOrder
.Data
== NULL
) {
1193 Status
= RETURN_OUT_OF_RESOURCES
;
1194 goto ErrorFreeFwCfg
;
1197 Status
= CollectActiveOptions (BootOptionList
, &ActiveOption
, &ActiveCount
);
1198 if (RETURN_ERROR (Status
)) {
1199 goto ErrorFreeBootOrder
;
1203 // translate each OpenFirmware path
1205 TranslatedSize
= sizeof (Translated
) / sizeof (Translated
[0]);
1206 Status
= TranslateOfwPath (&FwCfgPtr
, Translated
, &TranslatedSize
);
1207 while (Status
== RETURN_SUCCESS
||
1208 Status
== RETURN_UNSUPPORTED
||
1209 Status
== RETURN_BUFFER_TOO_SMALL
) {
1210 if (Status
== RETURN_SUCCESS
) {
1214 // match translated OpenFirmware path against all active boot options
1216 for (Idx
= 0; Idx
< ActiveCount
; ++Idx
) {
1219 TranslatedSize
, // contains length, not size, in CHAR16's here
1220 ActiveOption
[Idx
].BootOption
->DevicePath
1224 // match found, store ID and continue with next OpenFirmware path
1226 Status
= BootOrderAppend (&BootOrder
, &ActiveOption
[Idx
]);
1227 if (Status
!= RETURN_SUCCESS
) {
1228 goto ErrorFreeActiveOption
;
1232 } // scanned all active boot options
1233 } // translation successful
1235 TranslatedSize
= sizeof (Translated
) / sizeof (Translated
[0]);
1236 Status
= TranslateOfwPath (&FwCfgPtr
, Translated
, &TranslatedSize
);
1237 } // scanning of OpenFirmware paths done
1239 if (Status
== RETURN_NOT_FOUND
&& BootOrder
.Produced
> 0) {
1241 // No more OpenFirmware paths, some matches found: rewrite BootOrder NvVar.
1242 // Some of the active boot options that have not been selected over fw_cfg
1243 // should be preserved at the end of the boot order.
1245 Status
= BootOrderComplete (&BootOrder
, ActiveOption
, ActiveCount
);
1246 if (RETURN_ERROR (Status
)) {
1247 goto ErrorFreeActiveOption
;
1251 // See Table 10 in the UEFI Spec 2.3.1 with Errata C for the required
1254 Status
= gRT
->SetVariable (
1256 &gEfiGlobalVariableGuid
,
1257 EFI_VARIABLE_NON_VOLATILE
|
1258 EFI_VARIABLE_BOOTSERVICE_ACCESS
|
1259 EFI_VARIABLE_RUNTIME_ACCESS
,
1260 BootOrder
.Produced
* sizeof (*BootOrder
.Data
),
1265 "%a: setting BootOrder: %a\n",
1267 Status
== EFI_SUCCESS
? "success" : "error"
1271 ErrorFreeActiveOption
:
1272 FreePool (ActiveOption
);
1275 FreePool (BootOrder
.Data
);