diff --git a/sys/contrib/edk2/Include/Library/BaseLib.h b/sys/contrib/edk2/Include/Library/BaseLib.h
index 762cb9ac3abb..ac347f0adc2d 100644
--- a/sys/contrib/edk2/Include/Library/BaseLib.h
+++ b/sys/contrib/edk2/Include/Library/BaseLib.h
@@ -1,7877 +1,7900 @@
/** @file
Provides string functions, linked list functions, math functions, synchronization
functions, file path functions, and CPU architecture-specific functions.
Copyright (c) 2006 - 2019, Intel Corporation. All rights reserved.
Portions copyright (c) 2008 - 2009, Apple Inc. All rights reserved.
Copyright (c) Microsoft Corporation.
Portions Copyright (c) 2020, Hewlett Packard Enterprise Development LP. All rights reserved.
SPDX-License-Identifier: BSD-2-Clause-Patent
**/
#ifndef __BASE_LIB__
#define __BASE_LIB__
//
// Definitions for architecture-specific types
//
#if defined (MDE_CPU_IA32)
///
/// The IA-32 architecture context buffer used by SetJump() and LongJump().
///
typedef struct {
UINT32 Ebx;
UINT32 Esi;
UINT32 Edi;
UINT32 Ebp;
UINT32 Esp;
UINT32 Eip;
UINT32 Ssp;
} BASE_LIBRARY_JUMP_BUFFER;
#define BASE_LIBRARY_JUMP_BUFFER_ALIGNMENT 4
#endif // defined (MDE_CPU_IA32)
#if defined (MDE_CPU_X64)
///
/// The x64 architecture context buffer used by SetJump() and LongJump().
///
typedef struct {
UINT64 Rbx;
UINT64 Rsp;
UINT64 Rbp;
UINT64 Rdi;
UINT64 Rsi;
UINT64 R12;
UINT64 R13;
UINT64 R14;
UINT64 R15;
UINT64 Rip;
UINT64 MxCsr;
UINT8 XmmBuffer[160]; ///< XMM6-XMM15.
UINT64 Ssp;
} BASE_LIBRARY_JUMP_BUFFER;
#define BASE_LIBRARY_JUMP_BUFFER_ALIGNMENT 8
#endif // defined (MDE_CPU_X64)
#if defined (MDE_CPU_EBC)
///
/// The EBC context buffer used by SetJump() and LongJump().
///
typedef struct {
UINT64 R0;
UINT64 R1;
UINT64 R2;
UINT64 R3;
UINT64 IP;
} BASE_LIBRARY_JUMP_BUFFER;
#define BASE_LIBRARY_JUMP_BUFFER_ALIGNMENT 8
#endif // defined (MDE_CPU_EBC)
#if defined (MDE_CPU_ARM)
typedef struct {
UINT32 R3; ///< A copy of R13.
UINT32 R4;
UINT32 R5;
UINT32 R6;
UINT32 R7;
UINT32 R8;
UINT32 R9;
UINT32 R10;
UINT32 R11;
UINT32 R12;
UINT32 R14;
} BASE_LIBRARY_JUMP_BUFFER;
#define BASE_LIBRARY_JUMP_BUFFER_ALIGNMENT 4
#endif // defined (MDE_CPU_ARM)
#if defined (MDE_CPU_AARCH64)
typedef struct {
// GP regs
UINT64 X19;
UINT64 X20;
UINT64 X21;
UINT64 X22;
UINT64 X23;
UINT64 X24;
UINT64 X25;
UINT64 X26;
UINT64 X27;
UINT64 X28;
UINT64 FP;
UINT64 LR;
UINT64 IP0;
// FP regs
UINT64 D8;
UINT64 D9;
UINT64 D10;
UINT64 D11;
UINT64 D12;
UINT64 D13;
UINT64 D14;
UINT64 D15;
} BASE_LIBRARY_JUMP_BUFFER;
#define BASE_LIBRARY_JUMP_BUFFER_ALIGNMENT 8
#endif // defined (MDE_CPU_AARCH64)
#if defined (MDE_CPU_RISCV64)
///
/// The RISC-V architecture context buffer used by SetJump() and LongJump().
///
typedef struct {
UINT64 RA;
UINT64 S0;
UINT64 S1;
UINT64 S2;
UINT64 S3;
UINT64 S4;
UINT64 S5;
UINT64 S6;
UINT64 S7;
UINT64 S8;
UINT64 S9;
UINT64 S10;
UINT64 S11;
UINT64 SP;
} BASE_LIBRARY_JUMP_BUFFER;
#define BASE_LIBRARY_JUMP_BUFFER_ALIGNMENT 8
#endif // defined (MDE_CPU_RISCV64)
+#if defined (MDE_CPU_LOONGARCH64)
+///
+/// The LoongArch architecture context buffer used by SetJump() and LongJump()
+///
+typedef struct {
+ UINT64 S0;
+ UINT64 S1;
+ UINT64 S2;
+ UINT64 S3;
+ UINT64 S4;
+ UINT64 S5;
+ UINT64 S6;
+ UINT64 S7;
+ UINT64 S8;
+ UINT64 SP;
+ UINT64 FP;
+ UINT64 RA;
+} BASE_LIBRARY_JUMP_BUFFER;
+
+#define BASE_LIBRARY_JUMP_BUFFER_ALIGNMENT 8
+
+#endif // defined (MDE_CPU_LOONGARCH64)
+
//
// String Services
//
/**
Returns the length of a Null-terminated Unicode string.
This function is similar as strlen_s defined in C11.
If String is not aligned on a 16-bit boundary, then ASSERT().
@param String A pointer to a Null-terminated Unicode string.
@param MaxSize The maximum number of Destination Unicode
char, including terminating null char.
@retval 0 If String is NULL.
@retval MaxSize If there is no null character in the first MaxSize characters of String.
@return The number of characters that percede the terminating null character.
**/
UINTN
EFIAPI
StrnLenS (
IN CONST CHAR16 *String,
IN UINTN MaxSize
);
/**
Returns the size of a Null-terminated Unicode string in bytes, including the
Null terminator.
This function returns the size of the Null-terminated Unicode string
specified by String in bytes, including the Null terminator.
If String is not aligned on a 16-bit boundary, then ASSERT().
@param String A pointer to a Null-terminated Unicode string.
@param MaxSize The maximum number of Destination Unicode
char, including the Null terminator.
@retval 0 If String is NULL.
@retval (sizeof (CHAR16) * (MaxSize + 1))
If there is no Null terminator in the first MaxSize characters of
String.
@return The size of the Null-terminated Unicode string in bytes, including
the Null terminator.
**/
UINTN
EFIAPI
StrnSizeS (
IN CONST CHAR16 *String,
IN UINTN MaxSize
);
/**
Copies the string pointed to by Source (including the terminating null char)
to the array pointed to by Destination.
This function is similar as strcpy_s defined in C11.
If Destination is not aligned on a 16-bit boundary, then ASSERT().
If Source is not aligned on a 16-bit boundary, then ASSERT().
If an error is returned, then the Destination is unmodified.
@param Destination A pointer to a Null-terminated Unicode string.
@param DestMax The maximum number of Destination Unicode
char, including terminating null char.
@param Source A pointer to a Null-terminated Unicode string.
@retval RETURN_SUCCESS String is copied.
@retval RETURN_BUFFER_TOO_SMALL If DestMax is NOT greater than StrLen(Source).
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If PcdMaximumUnicodeStringLength is not zero,
and DestMax is greater than
PcdMaximumUnicodeStringLength.
If DestMax is 0.
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
StrCpyS (
OUT CHAR16 *Destination,
IN UINTN DestMax,
IN CONST CHAR16 *Source
);
/**
Copies not more than Length successive char from the string pointed to by
Source to the array pointed to by Destination. If no null char is copied from
Source, then Destination[Length] is always set to null.
This function is similar as strncpy_s defined in C11.
If Length > 0 and Destination is not aligned on a 16-bit boundary, then ASSERT().
If Length > 0 and Source is not aligned on a 16-bit boundary, then ASSERT().
If an error is returned, then the Destination is unmodified.
@param Destination A pointer to a Null-terminated Unicode string.
@param DestMax The maximum number of Destination Unicode
char, including terminating null char.
@param Source A pointer to a Null-terminated Unicode string.
@param Length The maximum number of Unicode characters to copy.
@retval RETURN_SUCCESS String is copied.
@retval RETURN_BUFFER_TOO_SMALL If DestMax is NOT greater than
MIN(StrLen(Source), Length).
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If PcdMaximumUnicodeStringLength is not zero,
and DestMax is greater than
PcdMaximumUnicodeStringLength.
If DestMax is 0.
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
StrnCpyS (
OUT CHAR16 *Destination,
IN UINTN DestMax,
IN CONST CHAR16 *Source,
IN UINTN Length
);
/**
Appends a copy of the string pointed to by Source (including the terminating
null char) to the end of the string pointed to by Destination.
This function is similar as strcat_s defined in C11.
If Destination is not aligned on a 16-bit boundary, then ASSERT().
If Source is not aligned on a 16-bit boundary, then ASSERT().
If an error is returned, then the Destination is unmodified.
@param Destination A pointer to a Null-terminated Unicode string.
@param DestMax The maximum number of Destination Unicode
char, including terminating null char.
@param Source A pointer to a Null-terminated Unicode string.
@retval RETURN_SUCCESS String is appended.
@retval RETURN_BAD_BUFFER_SIZE If DestMax is NOT greater than
StrLen(Destination).
@retval RETURN_BUFFER_TOO_SMALL If (DestMax - StrLen(Destination)) is NOT
greater than StrLen(Source).
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If PcdMaximumUnicodeStringLength is not zero,
and DestMax is greater than
PcdMaximumUnicodeStringLength.
If DestMax is 0.
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
StrCatS (
IN OUT CHAR16 *Destination,
IN UINTN DestMax,
IN CONST CHAR16 *Source
);
/**
Appends not more than Length successive char from the string pointed to by
Source to the end of the string pointed to by Destination. If no null char is
copied from Source, then Destination[StrLen(Destination) + Length] is always
set to null.
This function is similar as strncat_s defined in C11.
If Destination is not aligned on a 16-bit boundary, then ASSERT().
If Source is not aligned on a 16-bit boundary, then ASSERT().
If an error is returned, then the Destination is unmodified.
@param Destination A pointer to a Null-terminated Unicode string.
@param DestMax The maximum number of Destination Unicode
char, including terminating null char.
@param Source A pointer to a Null-terminated Unicode string.
@param Length The maximum number of Unicode characters to copy.
@retval RETURN_SUCCESS String is appended.
@retval RETURN_BAD_BUFFER_SIZE If DestMax is NOT greater than
StrLen(Destination).
@retval RETURN_BUFFER_TOO_SMALL If (DestMax - StrLen(Destination)) is NOT
greater than MIN(StrLen(Source), Length).
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If PcdMaximumUnicodeStringLength is not zero,
and DestMax is greater than
PcdMaximumUnicodeStringLength.
If DestMax is 0.
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
StrnCatS (
IN OUT CHAR16 *Destination,
IN UINTN DestMax,
IN CONST CHAR16 *Source,
IN UINTN Length
);
/**
Convert a Null-terminated Unicode decimal string to a value of type UINTN.
This function outputs a value of type UINTN by interpreting the contents of
the Unicode string specified by String as a decimal number. The format of the
input Unicode string String is:
[spaces] [decimal digits].
The valid decimal digit character is in the range [0-9]. The function will
ignore the pad space, which includes spaces or tab characters, before
[decimal digits]. The running zero in the beginning of [decimal digits] will
be ignored. Then, the function stops at the first character that is a not a
valid decimal character or a Null-terminator, whichever one comes first.
If String is not aligned in a 16-bit boundary, then ASSERT().
If String has no valid decimal digits in the above format, then 0 is stored
at the location pointed to by Data.
If the number represented by String exceeds the range defined by UINTN, then
MAX_UINTN is stored at the location pointed to by Data.
If EndPointer is not NULL, a pointer to the character that stopped the scan
is stored at the location pointed to by EndPointer. If String has no valid
decimal digits right after the optional pad spaces, the value of String is
stored at the location pointed to by EndPointer.
@param String Pointer to a Null-terminated Unicode string.
@param EndPointer Pointer to character that stops scan.
@param Data Pointer to the converted value.
@retval RETURN_SUCCESS Value is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
If PcdMaximumUnicodeStringLength is not
zero, and String contains more than
PcdMaximumUnicodeStringLength Unicode
characters, not including the
Null-terminator.
@retval RETURN_UNSUPPORTED If the number represented by String exceeds
the range defined by UINTN.
**/
RETURN_STATUS
EFIAPI
StrDecimalToUintnS (
IN CONST CHAR16 *String,
OUT CHAR16 **EndPointer, OPTIONAL
OUT UINTN *Data
);
/**
Convert a Null-terminated Unicode decimal string to a value of type UINT64.
This function outputs a value of type UINT64 by interpreting the contents of
the Unicode string specified by String as a decimal number. The format of the
input Unicode string String is:
[spaces] [decimal digits].
The valid decimal digit character is in the range [0-9]. The function will
ignore the pad space, which includes spaces or tab characters, before
[decimal digits]. The running zero in the beginning of [decimal digits] will
be ignored. Then, the function stops at the first character that is a not a
valid decimal character or a Null-terminator, whichever one comes first.
If String is not aligned in a 16-bit boundary, then ASSERT().
If String has no valid decimal digits in the above format, then 0 is stored
at the location pointed to by Data.
If the number represented by String exceeds the range defined by UINT64, then
MAX_UINT64 is stored at the location pointed to by Data.
If EndPointer is not NULL, a pointer to the character that stopped the scan
is stored at the location pointed to by EndPointer. If String has no valid
decimal digits right after the optional pad spaces, the value of String is
stored at the location pointed to by EndPointer.
@param String Pointer to a Null-terminated Unicode string.
@param EndPointer Pointer to character that stops scan.
@param Data Pointer to the converted value.
@retval RETURN_SUCCESS Value is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
If PcdMaximumUnicodeStringLength is not
zero, and String contains more than
PcdMaximumUnicodeStringLength Unicode
characters, not including the
Null-terminator.
@retval RETURN_UNSUPPORTED If the number represented by String exceeds
the range defined by UINT64.
**/
RETURN_STATUS
EFIAPI
StrDecimalToUint64S (
IN CONST CHAR16 *String,
OUT CHAR16 **EndPointer, OPTIONAL
OUT UINT64 *Data
);
/**
Convert a Null-terminated Unicode hexadecimal string to a value of type
UINTN.
This function outputs a value of type UINTN by interpreting the contents of
the Unicode string specified by String as a hexadecimal number. The format of
the input Unicode string String is:
[spaces][zeros][x][hexadecimal digits].
The valid hexadecimal digit character is in the range [0-9], [a-f] and [A-F].
The prefix "0x" is optional. Both "x" and "X" is allowed in "0x" prefix.
If "x" appears in the input string, it must be prefixed with at least one 0.
The function will ignore the pad space, which includes spaces or tab
characters, before [zeros], [x] or [hexadecimal digit]. The running zero
before [x] or [hexadecimal digit] will be ignored. Then, the decoding starts
after [x] or the first valid hexadecimal digit. Then, the function stops at
the first character that is a not a valid hexadecimal character or NULL,
whichever one comes first.
If String is not aligned in a 16-bit boundary, then ASSERT().
If String has no valid hexadecimal digits in the above format, then 0 is
stored at the location pointed to by Data.
If the number represented by String exceeds the range defined by UINTN, then
MAX_UINTN is stored at the location pointed to by Data.
If EndPointer is not NULL, a pointer to the character that stopped the scan
is stored at the location pointed to by EndPointer. If String has no valid
hexadecimal digits right after the optional pad spaces, the value of String
is stored at the location pointed to by EndPointer.
@param String Pointer to a Null-terminated Unicode string.
@param EndPointer Pointer to character that stops scan.
@param Data Pointer to the converted value.
@retval RETURN_SUCCESS Value is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
If PcdMaximumUnicodeStringLength is not
zero, and String contains more than
PcdMaximumUnicodeStringLength Unicode
characters, not including the
Null-terminator.
@retval RETURN_UNSUPPORTED If the number represented by String exceeds
the range defined by UINTN.
**/
RETURN_STATUS
EFIAPI
StrHexToUintnS (
IN CONST CHAR16 *String,
OUT CHAR16 **EndPointer, OPTIONAL
OUT UINTN *Data
);
/**
Convert a Null-terminated Unicode hexadecimal string to a value of type
UINT64.
This function outputs a value of type UINT64 by interpreting the contents of
the Unicode string specified by String as a hexadecimal number. The format of
the input Unicode string String is:
[spaces][zeros][x][hexadecimal digits].
The valid hexadecimal digit character is in the range [0-9], [a-f] and [A-F].
The prefix "0x" is optional. Both "x" and "X" is allowed in "0x" prefix.
If "x" appears in the input string, it must be prefixed with at least one 0.
The function will ignore the pad space, which includes spaces or tab
characters, before [zeros], [x] or [hexadecimal digit]. The running zero
before [x] or [hexadecimal digit] will be ignored. Then, the decoding starts
after [x] or the first valid hexadecimal digit. Then, the function stops at
the first character that is a not a valid hexadecimal character or NULL,
whichever one comes first.
If String is not aligned in a 16-bit boundary, then ASSERT().
If String has no valid hexadecimal digits in the above format, then 0 is
stored at the location pointed to by Data.
If the number represented by String exceeds the range defined by UINT64, then
MAX_UINT64 is stored at the location pointed to by Data.
If EndPointer is not NULL, a pointer to the character that stopped the scan
is stored at the location pointed to by EndPointer. If String has no valid
hexadecimal digits right after the optional pad spaces, the value of String
is stored at the location pointed to by EndPointer.
@param String Pointer to a Null-terminated Unicode string.
@param EndPointer Pointer to character that stops scan.
@param Data Pointer to the converted value.
@retval RETURN_SUCCESS Value is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
If PcdMaximumUnicodeStringLength is not
zero, and String contains more than
PcdMaximumUnicodeStringLength Unicode
characters, not including the
Null-terminator.
@retval RETURN_UNSUPPORTED If the number represented by String exceeds
the range defined by UINT64.
**/
RETURN_STATUS
EFIAPI
StrHexToUint64S (
IN CONST CHAR16 *String,
OUT CHAR16 **EndPointer, OPTIONAL
OUT UINT64 *Data
);
/**
Returns the length of a Null-terminated Ascii string.
This function is similar as strlen_s defined in C11.
@param String A pointer to a Null-terminated Ascii string.
@param MaxSize The maximum number of Destination Ascii
char, including terminating null char.
@retval 0 If String is NULL.
@retval MaxSize If there is no null character in the first MaxSize characters of String.
@return The number of characters that percede the terminating null character.
**/
UINTN
EFIAPI
AsciiStrnLenS (
IN CONST CHAR8 *String,
IN UINTN MaxSize
);
/**
Returns the size of a Null-terminated Ascii string in bytes, including the
Null terminator.
This function returns the size of the Null-terminated Ascii string specified
by String in bytes, including the Null terminator.
@param String A pointer to a Null-terminated Ascii string.
@param MaxSize The maximum number of Destination Ascii
char, including the Null terminator.
@retval 0 If String is NULL.
@retval (sizeof (CHAR8) * (MaxSize + 1))
If there is no Null terminator in the first MaxSize characters of
String.
@return The size of the Null-terminated Ascii string in bytes, including the
Null terminator.
**/
UINTN
EFIAPI
AsciiStrnSizeS (
IN CONST CHAR8 *String,
IN UINTN MaxSize
);
/**
Copies the string pointed to by Source (including the terminating null char)
to the array pointed to by Destination.
This function is similar as strcpy_s defined in C11.
If an error is returned, then the Destination is unmodified.
@param Destination A pointer to a Null-terminated Ascii string.
@param DestMax The maximum number of Destination Ascii
char, including terminating null char.
@param Source A pointer to a Null-terminated Ascii string.
@retval RETURN_SUCCESS String is copied.
@retval RETURN_BUFFER_TOO_SMALL If DestMax is NOT greater than StrLen(Source).
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If PcdMaximumAsciiStringLength is not zero,
and DestMax is greater than
PcdMaximumAsciiStringLength.
If DestMax is 0.
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
AsciiStrCpyS (
OUT CHAR8 *Destination,
IN UINTN DestMax,
IN CONST CHAR8 *Source
);
/**
Copies not more than Length successive char from the string pointed to by
Source to the array pointed to by Destination. If no null char is copied from
Source, then Destination[Length] is always set to null.
This function is similar as strncpy_s defined in C11.
If an error is returned, then the Destination is unmodified.
@param Destination A pointer to a Null-terminated Ascii string.
@param DestMax The maximum number of Destination Ascii
char, including terminating null char.
@param Source A pointer to a Null-terminated Ascii string.
@param Length The maximum number of Ascii characters to copy.
@retval RETURN_SUCCESS String is copied.
@retval RETURN_BUFFER_TOO_SMALL If DestMax is NOT greater than
MIN(StrLen(Source), Length).
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If PcdMaximumAsciiStringLength is not zero,
and DestMax is greater than
PcdMaximumAsciiStringLength.
If DestMax is 0.
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
AsciiStrnCpyS (
OUT CHAR8 *Destination,
IN UINTN DestMax,
IN CONST CHAR8 *Source,
IN UINTN Length
);
/**
Appends a copy of the string pointed to by Source (including the terminating
null char) to the end of the string pointed to by Destination.
This function is similar as strcat_s defined in C11.
If an error is returned, then the Destination is unmodified.
@param Destination A pointer to a Null-terminated Ascii string.
@param DestMax The maximum number of Destination Ascii
char, including terminating null char.
@param Source A pointer to a Null-terminated Ascii string.
@retval RETURN_SUCCESS String is appended.
@retval RETURN_BAD_BUFFER_SIZE If DestMax is NOT greater than
StrLen(Destination).
@retval RETURN_BUFFER_TOO_SMALL If (DestMax - StrLen(Destination)) is NOT
greater than StrLen(Source).
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If PcdMaximumAsciiStringLength is not zero,
and DestMax is greater than
PcdMaximumAsciiStringLength.
If DestMax is 0.
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
AsciiStrCatS (
IN OUT CHAR8 *Destination,
IN UINTN DestMax,
IN CONST CHAR8 *Source
);
/**
Appends not more than Length successive char from the string pointed to by
Source to the end of the string pointed to by Destination. If no null char is
copied from Source, then Destination[StrLen(Destination) + Length] is always
set to null.
This function is similar as strncat_s defined in C11.
If an error is returned, then the Destination is unmodified.
@param Destination A pointer to a Null-terminated Ascii string.
@param DestMax The maximum number of Destination Ascii
char, including terminating null char.
@param Source A pointer to a Null-terminated Ascii string.
@param Length The maximum number of Ascii characters to copy.
@retval RETURN_SUCCESS String is appended.
@retval RETURN_BAD_BUFFER_SIZE If DestMax is NOT greater than
StrLen(Destination).
@retval RETURN_BUFFER_TOO_SMALL If (DestMax - StrLen(Destination)) is NOT
greater than MIN(StrLen(Source), Length).
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If PcdMaximumAsciiStringLength is not zero,
and DestMax is greater than
PcdMaximumAsciiStringLength.
If DestMax is 0.
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
AsciiStrnCatS (
IN OUT CHAR8 *Destination,
IN UINTN DestMax,
IN CONST CHAR8 *Source,
IN UINTN Length
);
/**
Convert a Null-terminated Ascii decimal string to a value of type UINTN.
This function outputs a value of type UINTN by interpreting the contents of
the Ascii string specified by String as a decimal number. The format of the
input Ascii string String is:
[spaces] [decimal digits].
The valid decimal digit character is in the range [0-9]. The function will
ignore the pad space, which includes spaces or tab characters, before
[decimal digits]. The running zero in the beginning of [decimal digits] will
be ignored. Then, the function stops at the first character that is a not a
valid decimal character or a Null-terminator, whichever one comes first.
If String has no valid decimal digits in the above format, then 0 is stored
at the location pointed to by Data.
If the number represented by String exceeds the range defined by UINTN, then
MAX_UINTN is stored at the location pointed to by Data.
If EndPointer is not NULL, a pointer to the character that stopped the scan
is stored at the location pointed to by EndPointer. If String has no valid
decimal digits right after the optional pad spaces, the value of String is
stored at the location pointed to by EndPointer.
@param String Pointer to a Null-terminated Ascii string.
@param EndPointer Pointer to character that stops scan.
@param Data Pointer to the converted value.
@retval RETURN_SUCCESS Value is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
If PcdMaximumAsciiStringLength is not zero,
and String contains more than
PcdMaximumAsciiStringLength Ascii
characters, not including the
Null-terminator.
@retval RETURN_UNSUPPORTED If the number represented by String exceeds
the range defined by UINTN.
**/
RETURN_STATUS
EFIAPI
AsciiStrDecimalToUintnS (
IN CONST CHAR8 *String,
OUT CHAR8 **EndPointer, OPTIONAL
OUT UINTN *Data
);
/**
Convert a Null-terminated Ascii decimal string to a value of type UINT64.
This function outputs a value of type UINT64 by interpreting the contents of
the Ascii string specified by String as a decimal number. The format of the
input Ascii string String is:
[spaces] [decimal digits].
The valid decimal digit character is in the range [0-9]. The function will
ignore the pad space, which includes spaces or tab characters, before
[decimal digits]. The running zero in the beginning of [decimal digits] will
be ignored. Then, the function stops at the first character that is a not a
valid decimal character or a Null-terminator, whichever one comes first.
If String has no valid decimal digits in the above format, then 0 is stored
at the location pointed to by Data.
If the number represented by String exceeds the range defined by UINT64, then
MAX_UINT64 is stored at the location pointed to by Data.
If EndPointer is not NULL, a pointer to the character that stopped the scan
is stored at the location pointed to by EndPointer. If String has no valid
decimal digits right after the optional pad spaces, the value of String is
stored at the location pointed to by EndPointer.
@param String Pointer to a Null-terminated Ascii string.
@param EndPointer Pointer to character that stops scan.
@param Data Pointer to the converted value.
@retval RETURN_SUCCESS Value is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
If PcdMaximumAsciiStringLength is not zero,
and String contains more than
PcdMaximumAsciiStringLength Ascii
characters, not including the
Null-terminator.
@retval RETURN_UNSUPPORTED If the number represented by String exceeds
the range defined by UINT64.
**/
RETURN_STATUS
EFIAPI
AsciiStrDecimalToUint64S (
IN CONST CHAR8 *String,
OUT CHAR8 **EndPointer, OPTIONAL
OUT UINT64 *Data
);
/**
Convert a Null-terminated Ascii hexadecimal string to a value of type UINTN.
This function outputs a value of type UINTN by interpreting the contents of
the Ascii string specified by String as a hexadecimal number. The format of
the input Ascii string String is:
[spaces][zeros][x][hexadecimal digits].
The valid hexadecimal digit character is in the range [0-9], [a-f] and [A-F].
The prefix "0x" is optional. Both "x" and "X" is allowed in "0x" prefix. If
"x" appears in the input string, it must be prefixed with at least one 0. The
function will ignore the pad space, which includes spaces or tab characters,
before [zeros], [x] or [hexadecimal digits]. The running zero before [x] or
[hexadecimal digits] will be ignored. Then, the decoding starts after [x] or
the first valid hexadecimal digit. Then, the function stops at the first
character that is a not a valid hexadecimal character or Null-terminator,
whichever on comes first.
If String has no valid hexadecimal digits in the above format, then 0 is
stored at the location pointed to by Data.
If the number represented by String exceeds the range defined by UINTN, then
MAX_UINTN is stored at the location pointed to by Data.
If EndPointer is not NULL, a pointer to the character that stopped the scan
is stored at the location pointed to by EndPointer. If String has no valid
hexadecimal digits right after the optional pad spaces, the value of String
is stored at the location pointed to by EndPointer.
@param String Pointer to a Null-terminated Ascii string.
@param EndPointer Pointer to character that stops scan.
@param Data Pointer to the converted value.
@retval RETURN_SUCCESS Value is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
If PcdMaximumAsciiStringLength is not zero,
and String contains more than
PcdMaximumAsciiStringLength Ascii
characters, not including the
Null-terminator.
@retval RETURN_UNSUPPORTED If the number represented by String exceeds
the range defined by UINTN.
**/
RETURN_STATUS
EFIAPI
AsciiStrHexToUintnS (
IN CONST CHAR8 *String,
OUT CHAR8 **EndPointer, OPTIONAL
OUT UINTN *Data
);
/**
Convert a Null-terminated Ascii hexadecimal string to a value of type UINT64.
This function outputs a value of type UINT64 by interpreting the contents of
the Ascii string specified by String as a hexadecimal number. The format of
the input Ascii string String is:
[spaces][zeros][x][hexadecimal digits].
The valid hexadecimal digit character is in the range [0-9], [a-f] and [A-F].
The prefix "0x" is optional. Both "x" and "X" is allowed in "0x" prefix. If
"x" appears in the input string, it must be prefixed with at least one 0. The
function will ignore the pad space, which includes spaces or tab characters,
before [zeros], [x] or [hexadecimal digits]. The running zero before [x] or
[hexadecimal digits] will be ignored. Then, the decoding starts after [x] or
the first valid hexadecimal digit. Then, the function stops at the first
character that is a not a valid hexadecimal character or Null-terminator,
whichever on comes first.
If String has no valid hexadecimal digits in the above format, then 0 is
stored at the location pointed to by Data.
If the number represented by String exceeds the range defined by UINT64, then
MAX_UINT64 is stored at the location pointed to by Data.
If EndPointer is not NULL, a pointer to the character that stopped the scan
is stored at the location pointed to by EndPointer. If String has no valid
hexadecimal digits right after the optional pad spaces, the value of String
is stored at the location pointed to by EndPointer.
@param String Pointer to a Null-terminated Ascii string.
@param EndPointer Pointer to character that stops scan.
@param Data Pointer to the converted value.
@retval RETURN_SUCCESS Value is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
If PcdMaximumAsciiStringLength is not zero,
and String contains more than
PcdMaximumAsciiStringLength Ascii
characters, not including the
Null-terminator.
@retval RETURN_UNSUPPORTED If the number represented by String exceeds
the range defined by UINT64.
**/
RETURN_STATUS
EFIAPI
AsciiStrHexToUint64S (
IN CONST CHAR8 *String,
OUT CHAR8 **EndPointer, OPTIONAL
OUT UINT64 *Data
);
#ifndef DISABLE_NEW_DEPRECATED_INTERFACES
/**
[ATTENTION] This function is deprecated for security reason.
Copies one Null-terminated Unicode string to another Null-terminated Unicode
string and returns the new Unicode string.
This function copies the contents of the Unicode string Source to the Unicode
string Destination, and returns Destination. If Source and Destination
overlap, then the results are undefined.
If Destination is NULL, then ASSERT().
If Destination is not aligned on a 16-bit boundary, then ASSERT().
If Source is NULL, then ASSERT().
If Source is not aligned on a 16-bit boundary, then ASSERT().
If Source and Destination overlap, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and Source contains more than
PcdMaximumUnicodeStringLength Unicode characters not including the
Null-terminator, then ASSERT().
@param Destination The pointer to a Null-terminated Unicode string.
@param Source The pointer to a Null-terminated Unicode string.
@return Destination.
**/
CHAR16 *
EFIAPI
StrCpy (
OUT CHAR16 *Destination,
IN CONST CHAR16 *Source
);
/**
[ATTENTION] This function is deprecated for security reason.
Copies up to a specified length from one Null-terminated Unicode string to
another Null-terminated Unicode string and returns the new Unicode string.
This function copies the contents of the Unicode string Source to the Unicode
string Destination, and returns Destination. At most, Length Unicode
characters are copied from Source to Destination. If Length is 0, then
Destination is returned unmodified. If Length is greater that the number of
Unicode characters in Source, then Destination is padded with Null Unicode
characters. If Source and Destination overlap, then the results are
undefined.
If Length > 0 and Destination is NULL, then ASSERT().
If Length > 0 and Destination is not aligned on a 16-bit boundary, then ASSERT().
If Length > 0 and Source is NULL, then ASSERT().
If Length > 0 and Source is not aligned on a 16-bit boundary, then ASSERT().
If Source and Destination overlap, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and Length is greater than
PcdMaximumUnicodeStringLength, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and Source contains more than
PcdMaximumUnicodeStringLength Unicode characters, not including the Null-terminator,
then ASSERT().
@param Destination The pointer to a Null-terminated Unicode string.
@param Source The pointer to a Null-terminated Unicode string.
@param Length The maximum number of Unicode characters to copy.
@return Destination.
**/
CHAR16 *
EFIAPI
StrnCpy (
OUT CHAR16 *Destination,
IN CONST CHAR16 *Source,
IN UINTN Length
);
#endif // !defined (DISABLE_NEW_DEPRECATED_INTERFACES)
/**
Returns the length of a Null-terminated Unicode string.
This function returns the number of Unicode characters in the Null-terminated
Unicode string specified by String.
If String is NULL, then ASSERT().
If String is not aligned on a 16-bit boundary, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and String contains more than
PcdMaximumUnicodeStringLength Unicode characters not including the
Null-terminator, then ASSERT().
@param String Pointer to a Null-terminated Unicode string.
@return The length of String.
**/
UINTN
EFIAPI
StrLen (
IN CONST CHAR16 *String
);
/**
Returns the size of a Null-terminated Unicode string in bytes, including the
Null terminator.
This function returns the size, in bytes, of the Null-terminated Unicode string
specified by String.
If String is NULL, then ASSERT().
If String is not aligned on a 16-bit boundary, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and String contains more than
PcdMaximumUnicodeStringLength Unicode characters not including the
Null-terminator, then ASSERT().
@param String The pointer to a Null-terminated Unicode string.
@return The size of String.
**/
UINTN
EFIAPI
StrSize (
IN CONST CHAR16 *String
);
/**
Compares two Null-terminated Unicode strings, and returns the difference
between the first mismatched Unicode characters.
This function compares the Null-terminated Unicode string FirstString to the
Null-terminated Unicode string SecondString. If FirstString is identical to
SecondString, then 0 is returned. Otherwise, the value returned is the first
mismatched Unicode character in SecondString subtracted from the first
mismatched Unicode character in FirstString.
If FirstString is NULL, then ASSERT().
If FirstString is not aligned on a 16-bit boundary, then ASSERT().
If SecondString is NULL, then ASSERT().
If SecondString is not aligned on a 16-bit boundary, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and FirstString contains more
than PcdMaximumUnicodeStringLength Unicode characters not including the
Null-terminator, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and SecondString contains more
than PcdMaximumUnicodeStringLength Unicode characters, not including the
Null-terminator, then ASSERT().
@param FirstString The pointer to a Null-terminated Unicode string.
@param SecondString The pointer to a Null-terminated Unicode string.
@retval 0 FirstString is identical to SecondString.
@return others FirstString is not identical to SecondString.
**/
INTN
EFIAPI
StrCmp (
IN CONST CHAR16 *FirstString,
IN CONST CHAR16 *SecondString
);
/**
Compares up to a specified length the contents of two Null-terminated Unicode strings,
and returns the difference between the first mismatched Unicode characters.
This function compares the Null-terminated Unicode string FirstString to the
Null-terminated Unicode string SecondString. At most, Length Unicode
characters will be compared. If Length is 0, then 0 is returned. If
FirstString is identical to SecondString, then 0 is returned. Otherwise, the
value returned is the first mismatched Unicode character in SecondString
subtracted from the first mismatched Unicode character in FirstString.
If Length > 0 and FirstString is NULL, then ASSERT().
If Length > 0 and FirstString is not aligned on a 16-bit boundary, then ASSERT().
If Length > 0 and SecondString is NULL, then ASSERT().
If Length > 0 and SecondString is not aligned on a 16-bit boundary, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and Length is greater than
PcdMaximumUnicodeStringLength, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and FirstString contains more than
PcdMaximumUnicodeStringLength Unicode characters, not including the Null-terminator,
then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and SecondString contains more than
PcdMaximumUnicodeStringLength Unicode characters, not including the Null-terminator,
then ASSERT().
@param FirstString The pointer to a Null-terminated Unicode string.
@param SecondString The pointer to a Null-terminated Unicode string.
@param Length The maximum number of Unicode characters to compare.
@retval 0 FirstString is identical to SecondString.
@return others FirstString is not identical to SecondString.
**/
INTN
EFIAPI
StrnCmp (
IN CONST CHAR16 *FirstString,
IN CONST CHAR16 *SecondString,
IN UINTN Length
);
#ifndef DISABLE_NEW_DEPRECATED_INTERFACES
/**
[ATTENTION] This function is deprecated for security reason.
Concatenates one Null-terminated Unicode string to another Null-terminated
Unicode string, and returns the concatenated Unicode string.
This function concatenates two Null-terminated Unicode strings. The contents
of Null-terminated Unicode string Source are concatenated to the end of
Null-terminated Unicode string Destination. The Null-terminated concatenated
Unicode String is returned. If Source and Destination overlap, then the
results are undefined.
If Destination is NULL, then ASSERT().
If Destination is not aligned on a 16-bit boundary, then ASSERT().
If Source is NULL, then ASSERT().
If Source is not aligned on a 16-bit boundary, then ASSERT().
If Source and Destination overlap, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and Destination contains more
than PcdMaximumUnicodeStringLength Unicode characters, not including the
Null-terminator, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and Source contains more than
PcdMaximumUnicodeStringLength Unicode characters, not including the
Null-terminator, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and concatenating Destination
and Source results in a Unicode string with more than
PcdMaximumUnicodeStringLength Unicode characters, not including the
Null-terminator, then ASSERT().
@param Destination The pointer to a Null-terminated Unicode string.
@param Source The pointer to a Null-terminated Unicode string.
@return Destination.
**/
CHAR16 *
EFIAPI
StrCat (
IN OUT CHAR16 *Destination,
IN CONST CHAR16 *Source
);
/**
[ATTENTION] This function is deprecated for security reason.
Concatenates up to a specified length one Null-terminated Unicode to the end
of another Null-terminated Unicode string, and returns the concatenated
Unicode string.
This function concatenates two Null-terminated Unicode strings. The contents
of Null-terminated Unicode string Source are concatenated to the end of
Null-terminated Unicode string Destination, and Destination is returned. At
most, Length Unicode characters are concatenated from Source to the end of
Destination, and Destination is always Null-terminated. If Length is 0, then
Destination is returned unmodified. If Source and Destination overlap, then
the results are undefined.
If Destination is NULL, then ASSERT().
If Length > 0 and Destination is not aligned on a 16-bit boundary, then ASSERT().
If Length > 0 and Source is NULL, then ASSERT().
If Length > 0 and Source is not aligned on a 16-bit boundary, then ASSERT().
If Source and Destination overlap, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and Length is greater than
PcdMaximumUnicodeStringLength, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and Destination contains more
than PcdMaximumUnicodeStringLength Unicode characters, not including the
Null-terminator, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and Source contains more than
PcdMaximumUnicodeStringLength Unicode characters, not including the
Null-terminator, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and concatenating Destination
and Source results in a Unicode string with more than PcdMaximumUnicodeStringLength
Unicode characters, not including the Null-terminator, then ASSERT().
@param Destination The pointer to a Null-terminated Unicode string.
@param Source The pointer to a Null-terminated Unicode string.
@param Length The maximum number of Unicode characters to concatenate from
Source.
@return Destination.
**/
CHAR16 *
EFIAPI
StrnCat (
IN OUT CHAR16 *Destination,
IN CONST CHAR16 *Source,
IN UINTN Length
);
#endif // !defined (DISABLE_NEW_DEPRECATED_INTERFACES)
/**
Returns the first occurrence of a Null-terminated Unicode sub-string
in a Null-terminated Unicode string.
This function scans the contents of the Null-terminated Unicode string
specified by String and returns the first occurrence of SearchString.
If SearchString is not found in String, then NULL is returned. If
the length of SearchString is zero, then String is returned.
If String is NULL, then ASSERT().
If String is not aligned on a 16-bit boundary, then ASSERT().
If SearchString is NULL, then ASSERT().
If SearchString is not aligned on a 16-bit boundary, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and SearchString
or String contains more than PcdMaximumUnicodeStringLength Unicode
characters, not including the Null-terminator, then ASSERT().
@param String The pointer to a Null-terminated Unicode string.
@param SearchString The pointer to a Null-terminated Unicode string to search for.
@retval NULL If the SearchString does not appear in String.
@return others If there is a match.
**/
CHAR16 *
EFIAPI
StrStr (
IN CONST CHAR16 *String,
IN CONST CHAR16 *SearchString
);
/**
Convert a Null-terminated Unicode decimal string to a value of
type UINTN.
This function returns a value of type UINTN by interpreting the contents
of the Unicode string specified by String as a decimal number. The format
of the input Unicode string String is:
[spaces] [decimal digits].
The valid decimal digit character is in the range [0-9]. The
function will ignore the pad space, which includes spaces or
tab characters, before [decimal digits]. The running zero in the
beginning of [decimal digits] will be ignored. Then, the function
stops at the first character that is a not a valid decimal character
or a Null-terminator, whichever one comes first.
If String is NULL, then ASSERT().
If String is not aligned in a 16-bit boundary, then ASSERT().
If String has only pad spaces, then 0 is returned.
If String has no pad spaces or valid decimal digits,
then 0 is returned.
If the number represented by String overflows according
to the range defined by UINTN, then MAX_UINTN is returned.
If PcdMaximumUnicodeStringLength is not zero, and String contains
more than PcdMaximumUnicodeStringLength Unicode characters not including
the Null-terminator, then ASSERT().
@param String The pointer to a Null-terminated Unicode string.
@retval Value translated from String.
**/
UINTN
EFIAPI
StrDecimalToUintn (
IN CONST CHAR16 *String
);
/**
Convert a Null-terminated Unicode decimal string to a value of
type UINT64.
This function returns a value of type UINT64 by interpreting the contents
of the Unicode string specified by String as a decimal number. The format
of the input Unicode string String is:
[spaces] [decimal digits].
The valid decimal digit character is in the range [0-9]. The
function will ignore the pad space, which includes spaces or
tab characters, before [decimal digits]. The running zero in the
beginning of [decimal digits] will be ignored. Then, the function
stops at the first character that is a not a valid decimal character
or a Null-terminator, whichever one comes first.
If String is NULL, then ASSERT().
If String is not aligned in a 16-bit boundary, then ASSERT().
If String has only pad spaces, then 0 is returned.
If String has no pad spaces or valid decimal digits,
then 0 is returned.
If the number represented by String overflows according
to the range defined by UINT64, then MAX_UINT64 is returned.
If PcdMaximumUnicodeStringLength is not zero, and String contains
more than PcdMaximumUnicodeStringLength Unicode characters not including
the Null-terminator, then ASSERT().
@param String The pointer to a Null-terminated Unicode string.
@retval Value translated from String.
**/
UINT64
EFIAPI
StrDecimalToUint64 (
IN CONST CHAR16 *String
);
/**
Convert a Null-terminated Unicode hexadecimal string to a value of type UINTN.
This function returns a value of type UINTN by interpreting the contents
of the Unicode string specified by String as a hexadecimal number.
The format of the input Unicode string String is:
[spaces][zeros][x][hexadecimal digits].
The valid hexadecimal digit character is in the range [0-9], [a-f] and [A-F].
The prefix "0x" is optional. Both "x" and "X" is allowed in "0x" prefix.
If "x" appears in the input string, it must be prefixed with at least one 0.
The function will ignore the pad space, which includes spaces or tab characters,
before [zeros], [x] or [hexadecimal digit]. The running zero before [x] or
[hexadecimal digit] will be ignored. Then, the decoding starts after [x] or the
first valid hexadecimal digit. Then, the function stops at the first character
that is a not a valid hexadecimal character or NULL, whichever one comes first.
If String is NULL, then ASSERT().
If String is not aligned in a 16-bit boundary, then ASSERT().
If String has only pad spaces, then zero is returned.
If String has no leading pad spaces, leading zeros or valid hexadecimal digits,
then zero is returned.
If the number represented by String overflows according to the range defined by
UINTN, then MAX_UINTN is returned.
If PcdMaximumUnicodeStringLength is not zero, and String contains more than
PcdMaximumUnicodeStringLength Unicode characters not including the Null-terminator,
then ASSERT().
@param String The pointer to a Null-terminated Unicode string.
@retval Value translated from String.
**/
UINTN
EFIAPI
StrHexToUintn (
IN CONST CHAR16 *String
);
/**
Convert a Null-terminated Unicode hexadecimal string to a value of type UINT64.
This function returns a value of type UINT64 by interpreting the contents
of the Unicode string specified by String as a hexadecimal number.
The format of the input Unicode string String is
[spaces][zeros][x][hexadecimal digits].
The valid hexadecimal digit character is in the range [0-9], [a-f] and [A-F].
The prefix "0x" is optional. Both "x" and "X" is allowed in "0x" prefix.
If "x" appears in the input string, it must be prefixed with at least one 0.
The function will ignore the pad space, which includes spaces or tab characters,
before [zeros], [x] or [hexadecimal digit]. The running zero before [x] or
[hexadecimal digit] will be ignored. Then, the decoding starts after [x] or the
first valid hexadecimal digit. Then, the function stops at the first character that is
a not a valid hexadecimal character or NULL, whichever one comes first.
If String is NULL, then ASSERT().
If String is not aligned in a 16-bit boundary, then ASSERT().
If String has only pad spaces, then zero is returned.
If String has no leading pad spaces, leading zeros or valid hexadecimal digits,
then zero is returned.
If the number represented by String overflows according to the range defined by
UINT64, then MAX_UINT64 is returned.
If PcdMaximumUnicodeStringLength is not zero, and String contains more than
PcdMaximumUnicodeStringLength Unicode characters not including the Null-terminator,
then ASSERT().
@param String The pointer to a Null-terminated Unicode string.
@retval Value translated from String.
**/
UINT64
EFIAPI
StrHexToUint64 (
IN CONST CHAR16 *String
);
/**
Convert a Null-terminated Unicode string to IPv6 address and prefix length.
This function outputs a value of type IPv6_ADDRESS and may output a value
of type UINT8 by interpreting the contents of the Unicode string specified
by String. The format of the input Unicode string String is as follows:
X:X:X:X:X:X:X:X[/P]
X contains one to four hexadecimal digit characters in the range [0-9], [a-f] and
[A-F]. X is converted to a value of type UINT16, whose low byte is stored in low
memory address and high byte is stored in high memory address. P contains decimal
digit characters in the range [0-9]. The running zero in the beginning of P will
be ignored. /P is optional.
When /P is not in the String, the function stops at the first character that is
not a valid hexadecimal digit character after eight X's are converted.
When /P is in the String, the function stops at the first character that is not
a valid decimal digit character after P is converted.
"::" can be used to compress one or more groups of X when X contains only 0.
The "::" can only appear once in the String.
If String is not aligned in a 16-bit boundary, then ASSERT().
If EndPointer is not NULL and Address is translated from String, a pointer
to the character that stopped the scan is stored at the location pointed to
by EndPointer.
@param String Pointer to a Null-terminated Unicode string.
@param EndPointer Pointer to character that stops scan.
@param Address Pointer to the converted IPv6 address.
@param PrefixLength Pointer to the converted IPv6 address prefix
length. MAX_UINT8 is returned when /P is
not in the String.
@retval RETURN_SUCCESS Address is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
@retval RETURN_UNSUPPORTED If X contains more than four hexadecimal
digit characters.
If String contains "::" and number of X
is not less than 8.
If P starts with character that is not a
valid decimal digit character.
If the decimal number converted from P
exceeds 128.
**/
RETURN_STATUS
EFIAPI
StrToIpv6Address (
IN CONST CHAR16 *String,
OUT CHAR16 **EndPointer, OPTIONAL
OUT IPv6_ADDRESS *Address,
OUT UINT8 *PrefixLength OPTIONAL
);
/**
Convert a Null-terminated Unicode string to IPv4 address and prefix length.
This function outputs a value of type IPv4_ADDRESS and may output a value
of type UINT8 by interpreting the contents of the Unicode string specified
by String. The format of the input Unicode string String is as follows:
D.D.D.D[/P]
D and P are decimal digit characters in the range [0-9]. The running zero in
the beginning of D and P will be ignored. /P is optional.
When /P is not in the String, the function stops at the first character that is
not a valid decimal digit character after four D's are converted.
When /P is in the String, the function stops at the first character that is not
a valid decimal digit character after P is converted.
If String is not aligned in a 16-bit boundary, then ASSERT().
If EndPointer is not NULL and Address is translated from String, a pointer
to the character that stopped the scan is stored at the location pointed to
by EndPointer.
@param String Pointer to a Null-terminated Unicode string.
@param EndPointer Pointer to character that stops scan.
@param Address Pointer to the converted IPv4 address.
@param PrefixLength Pointer to the converted IPv4 address prefix
length. MAX_UINT8 is returned when /P is
not in the String.
@retval RETURN_SUCCESS Address is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
@retval RETURN_UNSUPPORTED If String is not in the correct format.
If any decimal number converted from D
exceeds 255.
If the decimal number converted from P
exceeds 32.
**/
RETURN_STATUS
EFIAPI
StrToIpv4Address (
IN CONST CHAR16 *String,
OUT CHAR16 **EndPointer, OPTIONAL
OUT IPv4_ADDRESS *Address,
OUT UINT8 *PrefixLength OPTIONAL
);
#define GUID_STRING_LENGTH 36
/**
Convert a Null-terminated Unicode GUID string to a value of type
EFI_GUID.
This function outputs a GUID value by interpreting the contents of
the Unicode string specified by String. The format of the input
Unicode string String consists of 36 characters, as follows:
aabbccdd-eeff-gghh-iijj-kkllmmnnoopp
The pairs aa - pp are two characters in the range [0-9], [a-f] and
[A-F], with each pair representing a single byte hexadecimal value.
The mapping between String and the EFI_GUID structure is as follows:
aa Data1[24:31]
bb Data1[16:23]
cc Data1[8:15]
dd Data1[0:7]
ee Data2[8:15]
ff Data2[0:7]
gg Data3[8:15]
hh Data3[0:7]
ii Data4[0:7]
jj Data4[8:15]
kk Data4[16:23]
ll Data4[24:31]
mm Data4[32:39]
nn Data4[40:47]
oo Data4[48:55]
pp Data4[56:63]
If String is not aligned in a 16-bit boundary, then ASSERT().
@param String Pointer to a Null-terminated Unicode string.
@param Guid Pointer to the converted GUID.
@retval RETURN_SUCCESS Guid is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
@retval RETURN_UNSUPPORTED If String is not as the above format.
**/
RETURN_STATUS
EFIAPI
StrToGuid (
IN CONST CHAR16 *String,
OUT GUID *Guid
);
/**
Convert a Null-terminated Unicode hexadecimal string to a byte array.
This function outputs a byte array by interpreting the contents of
the Unicode string specified by String in hexadecimal format. The format of
the input Unicode string String is:
[XX]*
X is a hexadecimal digit character in the range [0-9], [a-f] and [A-F].
The function decodes every two hexadecimal digit characters as one byte. The
decoding stops after Length of characters and outputs Buffer containing
(Length / 2) bytes.
If String is not aligned in a 16-bit boundary, then ASSERT().
@param String Pointer to a Null-terminated Unicode string.
@param Length The number of Unicode characters to decode.
@param Buffer Pointer to the converted bytes array.
@param MaxBufferSize The maximum size of Buffer.
@retval RETURN_SUCCESS Buffer is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
If Length is not multiple of 2.
If PcdMaximumUnicodeStringLength is not zero,
and Length is greater than
PcdMaximumUnicodeStringLength.
@retval RETURN_UNSUPPORTED If Length of characters from String contain
a character that is not valid hexadecimal
digit characters, or a Null-terminator.
@retval RETURN_BUFFER_TOO_SMALL If MaxBufferSize is less than (Length / 2).
**/
RETURN_STATUS
EFIAPI
StrHexToBytes (
IN CONST CHAR16 *String,
IN UINTN Length,
OUT UINT8 *Buffer,
IN UINTN MaxBufferSize
);
#ifndef DISABLE_NEW_DEPRECATED_INTERFACES
/**
[ATTENTION] This function is deprecated for security reason.
Convert a Null-terminated Unicode string to a Null-terminated
ASCII string and returns the ASCII string.
This function converts the content of the Unicode string Source
to the ASCII string Destination by copying the lower 8 bits of
each Unicode character. It returns Destination.
The caller is responsible to make sure Destination points to a buffer with size
equal or greater than ((StrLen (Source) + 1) * sizeof (CHAR8)) in bytes.
If any Unicode characters in Source contain non-zero value in
the upper 8 bits, then ASSERT().
If Destination is NULL, then ASSERT().
If Source is NULL, then ASSERT().
If Source is not aligned on a 16-bit boundary, then ASSERT().
If Source and Destination overlap, then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and Source contains
more than PcdMaximumUnicodeStringLength Unicode characters not including
the Null-terminator, then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and Source contains more
than PcdMaximumAsciiStringLength Unicode characters not including the
Null-terminator, then ASSERT().
@param Source The pointer to a Null-terminated Unicode string.
@param Destination The pointer to a Null-terminated ASCII string.
@return Destination.
**/
CHAR8 *
EFIAPI
UnicodeStrToAsciiStr (
IN CONST CHAR16 *Source,
OUT CHAR8 *Destination
);
#endif // !defined (DISABLE_NEW_DEPRECATED_INTERFACES)
/**
Convert a Null-terminated Unicode string to a Null-terminated
ASCII string.
This function is similar to AsciiStrCpyS.
This function converts the content of the Unicode string Source
to the ASCII string Destination by copying the lower 8 bits of
each Unicode character. The function terminates the ASCII string
Destination by appending a Null-terminator character at the end.
The caller is responsible to make sure Destination points to a buffer with size
equal or greater than ((StrLen (Source) + 1) * sizeof (CHAR8)) in bytes.
If any Unicode characters in Source contain non-zero value in
the upper 8 bits, then ASSERT().
If Source is not aligned on a 16-bit boundary, then ASSERT().
If an error is returned, then the Destination is unmodified.
@param Source The pointer to a Null-terminated Unicode string.
@param Destination The pointer to a Null-terminated ASCII string.
@param DestMax The maximum number of Destination Ascii
char, including terminating null char.
@retval RETURN_SUCCESS String is converted.
@retval RETURN_BUFFER_TOO_SMALL If DestMax is NOT greater than StrLen(Source).
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If PcdMaximumAsciiStringLength is not zero,
and DestMax is greater than
PcdMaximumAsciiStringLength.
If PcdMaximumUnicodeStringLength is not zero,
and DestMax is greater than
PcdMaximumUnicodeStringLength.
If DestMax is 0.
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
UnicodeStrToAsciiStrS (
IN CONST CHAR16 *Source,
OUT CHAR8 *Destination,
IN UINTN DestMax
);
/**
Convert not more than Length successive characters from a Null-terminated
Unicode string to a Null-terminated Ascii string. If no null char is copied
from Source, then Destination[Length] is always set to null.
This function converts not more than Length successive characters from the
Unicode string Source to the Ascii string Destination by copying the lower 8
bits of each Unicode character. The function terminates the Ascii string
Destination by appending a Null-terminator character at the end.
The caller is responsible to make sure Destination points to a buffer with size
equal or greater than ((StrLen (Source) + 1) * sizeof (CHAR8)) in bytes.
If any Unicode characters in Source contain non-zero value in the upper 8
bits, then ASSERT().
If Source is not aligned on a 16-bit boundary, then ASSERT().
If an error is returned, then the Destination is unmodified.
@param Source The pointer to a Null-terminated Unicode string.
@param Length The maximum number of Unicode characters to
convert.
@param Destination The pointer to a Null-terminated Ascii string.
@param DestMax The maximum number of Destination Ascii
char, including terminating null char.
@param DestinationLength The number of Unicode characters converted.
@retval RETURN_SUCCESS String is converted.
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If DestinationLength is NULL.
If PcdMaximumAsciiStringLength is not zero,
and Length or DestMax is greater than
PcdMaximumAsciiStringLength.
If PcdMaximumUnicodeStringLength is not
zero, and Length or DestMax is greater than
PcdMaximumUnicodeStringLength.
If DestMax is 0.
@retval RETURN_BUFFER_TOO_SMALL If DestMax is NOT greater than
MIN(StrLen(Source), Length).
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
UnicodeStrnToAsciiStrS (
IN CONST CHAR16 *Source,
IN UINTN Length,
OUT CHAR8 *Destination,
IN UINTN DestMax,
OUT UINTN *DestinationLength
);
#ifndef DISABLE_NEW_DEPRECATED_INTERFACES
/**
[ATTENTION] This function is deprecated for security reason.
Copies one Null-terminated ASCII string to another Null-terminated ASCII
string and returns the new ASCII string.
This function copies the contents of the ASCII string Source to the ASCII
string Destination, and returns Destination. If Source and Destination
overlap, then the results are undefined.
If Destination is NULL, then ASSERT().
If Source is NULL, then ASSERT().
If Source and Destination overlap, then ASSERT().
If PcdMaximumAsciiStringLength is not zero and Source contains more than
PcdMaximumAsciiStringLength ASCII characters not including the Null-terminator,
then ASSERT().
@param Destination The pointer to a Null-terminated ASCII string.
@param Source The pointer to a Null-terminated ASCII string.
@return Destination
**/
CHAR8 *
EFIAPI
AsciiStrCpy (
OUT CHAR8 *Destination,
IN CONST CHAR8 *Source
);
/**
[ATTENTION] This function is deprecated for security reason.
Copies up to a specified length one Null-terminated ASCII string to another
Null-terminated ASCII string and returns the new ASCII string.
This function copies the contents of the ASCII string Source to the ASCII
string Destination, and returns Destination. At most, Length ASCII characters
are copied from Source to Destination. If Length is 0, then Destination is
returned unmodified. If Length is greater that the number of ASCII characters
in Source, then Destination is padded with Null ASCII characters. If Source
and Destination overlap, then the results are undefined.
If Destination is NULL, then ASSERT().
If Source is NULL, then ASSERT().
If Source and Destination overlap, then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and Length is greater than
PcdMaximumAsciiStringLength, then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and Source contains more than
PcdMaximumAsciiStringLength ASCII characters, not including the Null-terminator,
then ASSERT().
@param Destination The pointer to a Null-terminated ASCII string.
@param Source The pointer to a Null-terminated ASCII string.
@param Length The maximum number of ASCII characters to copy.
@return Destination
**/
CHAR8 *
EFIAPI
AsciiStrnCpy (
OUT CHAR8 *Destination,
IN CONST CHAR8 *Source,
IN UINTN Length
);
#endif // !defined (DISABLE_NEW_DEPRECATED_INTERFACES)
/**
Returns the length of a Null-terminated ASCII string.
This function returns the number of ASCII characters in the Null-terminated
ASCII string specified by String.
If Length > 0 and Destination is NULL, then ASSERT().
If Length > 0 and Source is NULL, then ASSERT().
If PcdMaximumAsciiStringLength is not zero and String contains more than
PcdMaximumAsciiStringLength ASCII characters not including the Null-terminator,
then ASSERT().
@param String The pointer to a Null-terminated ASCII string.
@return The length of String.
**/
UINTN
EFIAPI
AsciiStrLen (
IN CONST CHAR8 *String
);
/**
Returns the size of a Null-terminated ASCII string in bytes, including the
Null terminator.
This function returns the size, in bytes, of the Null-terminated ASCII string
specified by String.
If String is NULL, then ASSERT().
If PcdMaximumAsciiStringLength is not zero and String contains more than
PcdMaximumAsciiStringLength ASCII characters not including the Null-terminator,
then ASSERT().
@param String The pointer to a Null-terminated ASCII string.
@return The size of String.
**/
UINTN
EFIAPI
AsciiStrSize (
IN CONST CHAR8 *String
);
/**
Compares two Null-terminated ASCII strings, and returns the difference
between the first mismatched ASCII characters.
This function compares the Null-terminated ASCII string FirstString to the
Null-terminated ASCII string SecondString. If FirstString is identical to
SecondString, then 0 is returned. Otherwise, the value returned is the first
mismatched ASCII character in SecondString subtracted from the first
mismatched ASCII character in FirstString.
If FirstString is NULL, then ASSERT().
If SecondString is NULL, then ASSERT().
If PcdMaximumAsciiStringLength is not zero and FirstString contains more than
PcdMaximumAsciiStringLength ASCII characters not including the Null-terminator,
then ASSERT().
If PcdMaximumAsciiStringLength is not zero and SecondString contains more
than PcdMaximumAsciiStringLength ASCII characters not including the
Null-terminator, then ASSERT().
@param FirstString The pointer to a Null-terminated ASCII string.
@param SecondString The pointer to a Null-terminated ASCII string.
@retval ==0 FirstString is identical to SecondString.
@retval !=0 FirstString is not identical to SecondString.
**/
INTN
EFIAPI
AsciiStrCmp (
IN CONST CHAR8 *FirstString,
IN CONST CHAR8 *SecondString
);
/**
Performs a case insensitive comparison of two Null-terminated ASCII strings,
and returns the difference between the first mismatched ASCII characters.
This function performs a case insensitive comparison of the Null-terminated
ASCII string FirstString to the Null-terminated ASCII string SecondString. If
FirstString is identical to SecondString, then 0 is returned. Otherwise, the
value returned is the first mismatched lower case ASCII character in
SecondString subtracted from the first mismatched lower case ASCII character
in FirstString.
If FirstString is NULL, then ASSERT().
If SecondString is NULL, then ASSERT().
If PcdMaximumAsciiStringLength is not zero and FirstString contains more than
PcdMaximumAsciiStringLength ASCII characters not including the Null-terminator,
then ASSERT().
If PcdMaximumAsciiStringLength is not zero and SecondString contains more
than PcdMaximumAsciiStringLength ASCII characters not including the
Null-terminator, then ASSERT().
@param FirstString The pointer to a Null-terminated ASCII string.
@param SecondString The pointer to a Null-terminated ASCII string.
@retval ==0 FirstString is identical to SecondString using case insensitive
comparisons.
@retval !=0 FirstString is not identical to SecondString using case
insensitive comparisons.
**/
INTN
EFIAPI
AsciiStriCmp (
IN CONST CHAR8 *FirstString,
IN CONST CHAR8 *SecondString
);
/**
Compares two Null-terminated ASCII strings with maximum lengths, and returns
the difference between the first mismatched ASCII characters.
This function compares the Null-terminated ASCII string FirstString to the
Null-terminated ASCII string SecondString. At most, Length ASCII characters
will be compared. If Length is 0, then 0 is returned. If FirstString is
identical to SecondString, then 0 is returned. Otherwise, the value returned
is the first mismatched ASCII character in SecondString subtracted from the
first mismatched ASCII character in FirstString.
If Length > 0 and FirstString is NULL, then ASSERT().
If Length > 0 and SecondString is NULL, then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and Length is greater than
PcdMaximumAsciiStringLength, then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and FirstString contains more than
PcdMaximumAsciiStringLength ASCII characters, not including the Null-terminator,
then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and SecondString contains more than
PcdMaximumAsciiStringLength ASCII characters, not including the Null-terminator,
then ASSERT().
@param FirstString The pointer to a Null-terminated ASCII string.
@param SecondString The pointer to a Null-terminated ASCII string.
@param Length The maximum number of ASCII characters for compare.
@retval ==0 FirstString is identical to SecondString.
@retval !=0 FirstString is not identical to SecondString.
**/
INTN
EFIAPI
AsciiStrnCmp (
IN CONST CHAR8 *FirstString,
IN CONST CHAR8 *SecondString,
IN UINTN Length
);
#ifndef DISABLE_NEW_DEPRECATED_INTERFACES
/**
[ATTENTION] This function is deprecated for security reason.
Concatenates one Null-terminated ASCII string to another Null-terminated
ASCII string, and returns the concatenated ASCII string.
This function concatenates two Null-terminated ASCII strings. The contents of
Null-terminated ASCII string Source are concatenated to the end of Null-
terminated ASCII string Destination. The Null-terminated concatenated ASCII
String is returned.
If Destination is NULL, then ASSERT().
If Source is NULL, then ASSERT().
If PcdMaximumAsciiStringLength is not zero and Destination contains more than
PcdMaximumAsciiStringLength ASCII characters not including the Null-terminator,
then ASSERT().
If PcdMaximumAsciiStringLength is not zero and Source contains more than
PcdMaximumAsciiStringLength ASCII characters not including the Null-terminator,
then ASSERT().
If PcdMaximumAsciiStringLength is not zero and concatenating Destination and
Source results in a ASCII string with more than PcdMaximumAsciiStringLength
ASCII characters, then ASSERT().
@param Destination The pointer to a Null-terminated ASCII string.
@param Source The pointer to a Null-terminated ASCII string.
@return Destination
**/
CHAR8 *
EFIAPI
AsciiStrCat (
IN OUT CHAR8 *Destination,
IN CONST CHAR8 *Source
);
/**
[ATTENTION] This function is deprecated for security reason.
Concatenates up to a specified length one Null-terminated ASCII string to
the end of another Null-terminated ASCII string, and returns the
concatenated ASCII string.
This function concatenates two Null-terminated ASCII strings. The contents
of Null-terminated ASCII string Source are concatenated to the end of Null-
terminated ASCII string Destination, and Destination is returned. At most,
Length ASCII characters are concatenated from Source to the end of
Destination, and Destination is always Null-terminated. If Length is 0, then
Destination is returned unmodified. If Source and Destination overlap, then
the results are undefined.
If Length > 0 and Destination is NULL, then ASSERT().
If Length > 0 and Source is NULL, then ASSERT().
If Source and Destination overlap, then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and Length is greater than
PcdMaximumAsciiStringLength, then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and Destination contains more than
PcdMaximumAsciiStringLength ASCII characters, not including the Null-terminator,
then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and Source contains more than
PcdMaximumAsciiStringLength ASCII characters, not including the Null-terminator,
then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and concatenating Destination and
Source results in a ASCII string with more than PcdMaximumAsciiStringLength
ASCII characters, not including the Null-terminator, then ASSERT().
@param Destination The pointer to a Null-terminated ASCII string.
@param Source The pointer to a Null-terminated ASCII string.
@param Length The maximum number of ASCII characters to concatenate from
Source.
@return Destination
**/
CHAR8 *
EFIAPI
AsciiStrnCat (
IN OUT CHAR8 *Destination,
IN CONST CHAR8 *Source,
IN UINTN Length
);
#endif // !defined (DISABLE_NEW_DEPRECATED_INTERFACES)
/**
Returns the first occurrence of a Null-terminated ASCII sub-string
in a Null-terminated ASCII string.
This function scans the contents of the ASCII string specified by String
and returns the first occurrence of SearchString. If SearchString is not
found in String, then NULL is returned. If the length of SearchString is zero,
then String is returned.
If String is NULL, then ASSERT().
If SearchString is NULL, then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and SearchString or
String contains more than PcdMaximumAsciiStringLength Unicode characters
not including the Null-terminator, then ASSERT().
@param String The pointer to a Null-terminated ASCII string.
@param SearchString The pointer to a Null-terminated ASCII string to search for.
@retval NULL If the SearchString does not appear in String.
@retval others If there is a match return the first occurrence of SearchingString.
If the length of SearchString is zero,return String.
**/
CHAR8 *
EFIAPI
AsciiStrStr (
IN CONST CHAR8 *String,
IN CONST CHAR8 *SearchString
);
/**
Convert a Null-terminated ASCII decimal string to a value of type
UINTN.
This function returns a value of type UINTN by interpreting the contents
of the ASCII string String as a decimal number. The format of the input
ASCII string String is:
[spaces] [decimal digits].
The valid decimal digit character is in the range [0-9]. The function will
ignore the pad space, which includes spaces or tab characters, before the digits.
The running zero in the beginning of [decimal digits] will be ignored. Then, the
function stops at the first character that is a not a valid decimal character or
Null-terminator, whichever on comes first.
If String has only pad spaces, then 0 is returned.
If String has no pad spaces or valid decimal digits, then 0 is returned.
If the number represented by String overflows according to the range defined by
UINTN, then MAX_UINTN is returned.
If String is NULL, then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and String contains more than
PcdMaximumAsciiStringLength ASCII characters not including the Null-terminator,
then ASSERT().
@param String The pointer to a Null-terminated ASCII string.
@retval The value translated from String.
**/
UINTN
EFIAPI
AsciiStrDecimalToUintn (
IN CONST CHAR8 *String
);
/**
Convert a Null-terminated ASCII decimal string to a value of type
UINT64.
This function returns a value of type UINT64 by interpreting the contents
of the ASCII string String as a decimal number. The format of the input
ASCII string String is:
[spaces] [decimal digits].
The valid decimal digit character is in the range [0-9]. The function will
ignore the pad space, which includes spaces or tab characters, before the digits.
The running zero in the beginning of [decimal digits] will be ignored. Then, the
function stops at the first character that is a not a valid decimal character or
Null-terminator, whichever on comes first.
If String has only pad spaces, then 0 is returned.
If String has no pad spaces or valid decimal digits, then 0 is returned.
If the number represented by String overflows according to the range defined by
UINT64, then MAX_UINT64 is returned.
If String is NULL, then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and String contains more than
PcdMaximumAsciiStringLength ASCII characters not including the Null-terminator,
then ASSERT().
@param String The pointer to a Null-terminated ASCII string.
@retval Value translated from String.
**/
UINT64
EFIAPI
AsciiStrDecimalToUint64 (
IN CONST CHAR8 *String
);
/**
Convert a Null-terminated ASCII hexadecimal string to a value of type UINTN.
This function returns a value of type UINTN by interpreting the contents of
the ASCII string String as a hexadecimal number. The format of the input ASCII
string String is:
[spaces][zeros][x][hexadecimal digits].
The valid hexadecimal digit character is in the range [0-9], [a-f] and [A-F].
The prefix "0x" is optional. Both "x" and "X" is allowed in "0x" prefix. If "x"
appears in the input string, it must be prefixed with at least one 0. The function
will ignore the pad space, which includes spaces or tab characters, before [zeros],
[x] or [hexadecimal digits]. The running zero before [x] or [hexadecimal digits]
will be ignored. Then, the decoding starts after [x] or the first valid hexadecimal
digit. Then, the function stops at the first character that is a not a valid
hexadecimal character or Null-terminator, whichever on comes first.
If String has only pad spaces, then 0 is returned.
If String has no leading pad spaces, leading zeros or valid hexadecimal digits, then
0 is returned.
If the number represented by String overflows according to the range defined by UINTN,
then MAX_UINTN is returned.
If String is NULL, then ASSERT().
If PcdMaximumAsciiStringLength is not zero,
and String contains more than PcdMaximumAsciiStringLength ASCII characters not including
the Null-terminator, then ASSERT().
@param String The pointer to a Null-terminated ASCII string.
@retval Value translated from String.
**/
UINTN
EFIAPI
AsciiStrHexToUintn (
IN CONST CHAR8 *String
);
/**
Convert a Null-terminated ASCII hexadecimal string to a value of type UINT64.
This function returns a value of type UINT64 by interpreting the contents of
the ASCII string String as a hexadecimal number. The format of the input ASCII
string String is:
[spaces][zeros][x][hexadecimal digits].
The valid hexadecimal digit character is in the range [0-9], [a-f] and [A-F].
The prefix "0x" is optional. Both "x" and "X" is allowed in "0x" prefix. If "x"
appears in the input string, it must be prefixed with at least one 0. The function
will ignore the pad space, which includes spaces or tab characters, before [zeros],
[x] or [hexadecimal digits]. The running zero before [x] or [hexadecimal digits]
will be ignored. Then, the decoding starts after [x] or the first valid hexadecimal
digit. Then, the function stops at the first character that is a not a valid
hexadecimal character or Null-terminator, whichever on comes first.
If String has only pad spaces, then 0 is returned.
If String has no leading pad spaces, leading zeros or valid hexadecimal digits, then
0 is returned.
If the number represented by String overflows according to the range defined by UINT64,
then MAX_UINT64 is returned.
If String is NULL, then ASSERT().
If PcdMaximumAsciiStringLength is not zero,
and String contains more than PcdMaximumAsciiStringLength ASCII characters not including
the Null-terminator, then ASSERT().
@param String The pointer to a Null-terminated ASCII string.
@retval Value translated from String.
**/
UINT64
EFIAPI
AsciiStrHexToUint64 (
IN CONST CHAR8 *String
);
/**
Convert a Null-terminated ASCII string to IPv6 address and prefix length.
This function outputs a value of type IPv6_ADDRESS and may output a value
of type UINT8 by interpreting the contents of the ASCII string specified
by String. The format of the input ASCII string String is as follows:
X:X:X:X:X:X:X:X[/P]
X contains one to four hexadecimal digit characters in the range [0-9], [a-f] and
[A-F]. X is converted to a value of type UINT16, whose low byte is stored in low
memory address and high byte is stored in high memory address. P contains decimal
digit characters in the range [0-9]. The running zero in the beginning of P will
be ignored. /P is optional.
When /P is not in the String, the function stops at the first character that is
not a valid hexadecimal digit character after eight X's are converted.
When /P is in the String, the function stops at the first character that is not
a valid decimal digit character after P is converted.
"::" can be used to compress one or more groups of X when X contains only 0.
The "::" can only appear once in the String.
If EndPointer is not NULL and Address is translated from String, a pointer
to the character that stopped the scan is stored at the location pointed to
by EndPointer.
@param String Pointer to a Null-terminated ASCII string.
@param EndPointer Pointer to character that stops scan.
@param Address Pointer to the converted IPv6 address.
@param PrefixLength Pointer to the converted IPv6 address prefix
length. MAX_UINT8 is returned when /P is
not in the String.
@retval RETURN_SUCCESS Address is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
@retval RETURN_UNSUPPORTED If X contains more than four hexadecimal
digit characters.
If String contains "::" and number of X
is not less than 8.
If P starts with character that is not a
valid decimal digit character.
If the decimal number converted from P
exceeds 128.
**/
RETURN_STATUS
EFIAPI
AsciiStrToIpv6Address (
IN CONST CHAR8 *String,
OUT CHAR8 **EndPointer, OPTIONAL
OUT IPv6_ADDRESS *Address,
OUT UINT8 *PrefixLength OPTIONAL
);
/**
Convert a Null-terminated ASCII string to IPv4 address and prefix length.
This function outputs a value of type IPv4_ADDRESS and may output a value
of type UINT8 by interpreting the contents of the ASCII string specified
by String. The format of the input ASCII string String is as follows:
D.D.D.D[/P]
D and P are decimal digit characters in the range [0-9]. The running zero in
the beginning of D and P will be ignored. /P is optional.
When /P is not in the String, the function stops at the first character that is
not a valid decimal digit character after four D's are converted.
When /P is in the String, the function stops at the first character that is not
a valid decimal digit character after P is converted.
If EndPointer is not NULL and Address is translated from String, a pointer
to the character that stopped the scan is stored at the location pointed to
by EndPointer.
@param String Pointer to a Null-terminated ASCII string.
@param EndPointer Pointer to character that stops scan.
@param Address Pointer to the converted IPv4 address.
@param PrefixLength Pointer to the converted IPv4 address prefix
length. MAX_UINT8 is returned when /P is
not in the String.
@retval RETURN_SUCCESS Address is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
@retval RETURN_UNSUPPORTED If String is not in the correct format.
If any decimal number converted from D
exceeds 255.
If the decimal number converted from P
exceeds 32.
**/
RETURN_STATUS
EFIAPI
AsciiStrToIpv4Address (
IN CONST CHAR8 *String,
OUT CHAR8 **EndPointer, OPTIONAL
OUT IPv4_ADDRESS *Address,
OUT UINT8 *PrefixLength OPTIONAL
);
/**
Convert a Null-terminated ASCII GUID string to a value of type
EFI_GUID.
This function outputs a GUID value by interpreting the contents of
the ASCII string specified by String. The format of the input
ASCII string String consists of 36 characters, as follows:
aabbccdd-eeff-gghh-iijj-kkllmmnnoopp
The pairs aa - pp are two characters in the range [0-9], [a-f] and
[A-F], with each pair representing a single byte hexadecimal value.
The mapping between String and the EFI_GUID structure is as follows:
aa Data1[24:31]
bb Data1[16:23]
cc Data1[8:15]
dd Data1[0:7]
ee Data2[8:15]
ff Data2[0:7]
gg Data3[8:15]
hh Data3[0:7]
ii Data4[0:7]
jj Data4[8:15]
kk Data4[16:23]
ll Data4[24:31]
mm Data4[32:39]
nn Data4[40:47]
oo Data4[48:55]
pp Data4[56:63]
@param String Pointer to a Null-terminated ASCII string.
@param Guid Pointer to the converted GUID.
@retval RETURN_SUCCESS Guid is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
@retval RETURN_UNSUPPORTED If String is not as the above format.
**/
RETURN_STATUS
EFIAPI
AsciiStrToGuid (
IN CONST CHAR8 *String,
OUT GUID *Guid
);
/**
Convert a Null-terminated ASCII hexadecimal string to a byte array.
This function outputs a byte array by interpreting the contents of
the ASCII string specified by String in hexadecimal format. The format of
the input ASCII string String is:
[XX]*
X is a hexadecimal digit character in the range [0-9], [a-f] and [A-F].
The function decodes every two hexadecimal digit characters as one byte. The
decoding stops after Length of characters and outputs Buffer containing
(Length / 2) bytes.
@param String Pointer to a Null-terminated ASCII string.
@param Length The number of ASCII characters to decode.
@param Buffer Pointer to the converted bytes array.
@param MaxBufferSize The maximum size of Buffer.
@retval RETURN_SUCCESS Buffer is translated from String.
@retval RETURN_INVALID_PARAMETER If String is NULL.
If Data is NULL.
If Length is not multiple of 2.
If PcdMaximumAsciiStringLength is not zero,
and Length is greater than
PcdMaximumAsciiStringLength.
@retval RETURN_UNSUPPORTED If Length of characters from String contain
a character that is not valid hexadecimal
digit characters, or a Null-terminator.
@retval RETURN_BUFFER_TOO_SMALL If MaxBufferSize is less than (Length / 2).
**/
RETURN_STATUS
EFIAPI
AsciiStrHexToBytes (
IN CONST CHAR8 *String,
IN UINTN Length,
OUT UINT8 *Buffer,
IN UINTN MaxBufferSize
);
#ifndef DISABLE_NEW_DEPRECATED_INTERFACES
/**
[ATTENTION] This function is deprecated for security reason.
Convert one Null-terminated ASCII string to a Null-terminated
Unicode string and returns the Unicode string.
This function converts the contents of the ASCII string Source to the Unicode
string Destination, and returns Destination. The function terminates the
Unicode string Destination by appending a Null-terminator character at the end.
The caller is responsible to make sure Destination points to a buffer with size
equal or greater than ((AsciiStrLen (Source) + 1) * sizeof (CHAR16)) in bytes.
If Destination is NULL, then ASSERT().
If Destination is not aligned on a 16-bit boundary, then ASSERT().
If Source is NULL, then ASSERT().
If Source and Destination overlap, then ASSERT().
If PcdMaximumAsciiStringLength is not zero, and Source contains more than
PcdMaximumAsciiStringLength ASCII characters not including the Null-terminator,
then ASSERT().
If PcdMaximumUnicodeStringLength is not zero, and Source contains more than
PcdMaximumUnicodeStringLength ASCII characters not including the
Null-terminator, then ASSERT().
@param Source The pointer to a Null-terminated ASCII string.
@param Destination The pointer to a Null-terminated Unicode string.
@return Destination.
**/
CHAR16 *
EFIAPI
AsciiStrToUnicodeStr (
IN CONST CHAR8 *Source,
OUT CHAR16 *Destination
);
#endif // !defined (DISABLE_NEW_DEPRECATED_INTERFACES)
/**
Convert one Null-terminated ASCII string to a Null-terminated
Unicode string.
This function is similar to StrCpyS.
This function converts the contents of the ASCII string Source to the Unicode
string Destination. The function terminates the Unicode string Destination by
appending a Null-terminator character at the end.
The caller is responsible to make sure Destination points to a buffer with size
equal or greater than ((AsciiStrLen (Source) + 1) * sizeof (CHAR16)) in bytes.
If Destination is not aligned on a 16-bit boundary, then ASSERT().
If an error is returned, then the Destination is unmodified.
@param Source The pointer to a Null-terminated ASCII string.
@param Destination The pointer to a Null-terminated Unicode string.
@param DestMax The maximum number of Destination Unicode
char, including terminating null char.
@retval RETURN_SUCCESS String is converted.
@retval RETURN_BUFFER_TOO_SMALL If DestMax is NOT greater than StrLen(Source).
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If PcdMaximumUnicodeStringLength is not zero,
and DestMax is greater than
PcdMaximumUnicodeStringLength.
If PcdMaximumAsciiStringLength is not zero,
and DestMax is greater than
PcdMaximumAsciiStringLength.
If DestMax is 0.
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
AsciiStrToUnicodeStrS (
IN CONST CHAR8 *Source,
OUT CHAR16 *Destination,
IN UINTN DestMax
);
/**
Convert not more than Length successive characters from a Null-terminated
Ascii string to a Null-terminated Unicode string. If no null char is copied
from Source, then Destination[Length] is always set to null.
This function converts not more than Length successive characters from the
Ascii string Source to the Unicode string Destination. The function
terminates the Unicode string Destination by appending a Null-terminator
character at the end.
The caller is responsible to make sure Destination points to a buffer with
size not smaller than
((MIN(AsciiStrLen(Source), Length) + 1) * sizeof (CHAR8)) in bytes.
If Destination is not aligned on a 16-bit boundary, then ASSERT().
If an error is returned, then Destination and DestinationLength are
unmodified.
@param Source The pointer to a Null-terminated Ascii string.
@param Length The maximum number of Ascii characters to convert.
@param Destination The pointer to a Null-terminated Unicode string.
@param DestMax The maximum number of Destination Unicode char,
including terminating null char.
@param DestinationLength The number of Ascii characters converted.
@retval RETURN_SUCCESS String is converted.
@retval RETURN_INVALID_PARAMETER If Destination is NULL.
If Source is NULL.
If DestinationLength is NULL.
If PcdMaximumUnicodeStringLength is not
zero, and Length or DestMax is greater than
PcdMaximumUnicodeStringLength.
If PcdMaximumAsciiStringLength is not zero,
and Length or DestMax is greater than
PcdMaximumAsciiStringLength.
If DestMax is 0.
@retval RETURN_BUFFER_TOO_SMALL If DestMax is NOT greater than
MIN(AsciiStrLen(Source), Length).
@retval RETURN_ACCESS_DENIED If Source and Destination overlap.
**/
RETURN_STATUS
EFIAPI
AsciiStrnToUnicodeStrS (
IN CONST CHAR8 *Source,
IN UINTN Length,
OUT CHAR16 *Destination,
IN UINTN DestMax,
OUT UINTN *DestinationLength
);
/**
Convert a Unicode character to upper case only if
it maps to a valid small-case ASCII character.
This internal function only deal with Unicode character
which maps to a valid small-case ASCII character, i.e.
L'a' to L'z'. For other Unicode character, the input character
is returned directly.
@param Char The character to convert.
@retval LowerCharacter If the Char is with range L'a' to L'z'.
@retval Unchanged Otherwise.
**/
CHAR16
EFIAPI
CharToUpper (
IN CHAR16 Char
);
/**
Converts a lowercase Ascii character to upper one.
If Chr is lowercase Ascii character, then converts it to upper one.
If Value >= 0xA0, then ASSERT().
If (Value & 0x0F) >= 0x0A, then ASSERT().
@param Chr one Ascii character
@return The uppercase value of Ascii character
**/
CHAR8
EFIAPI
AsciiCharToUpper (
IN CHAR8 Chr
);
/**
Convert binary data to a Base64 encoded ascii string based on RFC4648.
Produce a Null-terminated Ascii string in the output buffer specified by Destination and DestinationSize.
The Ascii string is produced by converting the data string specified by Source and SourceLength.
@param Source Input UINT8 data
@param SourceLength Number of UINT8 bytes of data
@param Destination Pointer to output string buffer
@param DestinationSize Size of ascii buffer. Set to 0 to get the size needed.
Caller is responsible for passing in buffer of DestinationSize
@retval RETURN_SUCCESS When ascii buffer is filled in.
@retval RETURN_INVALID_PARAMETER If Source is NULL or DestinationSize is NULL.
@retval RETURN_INVALID_PARAMETER If SourceLength or DestinationSize is bigger than (MAX_ADDRESS - (UINTN)Destination).
@retval RETURN_BUFFER_TOO_SMALL If SourceLength is 0 and DestinationSize is <1.
@retval RETURN_BUFFER_TOO_SMALL If Destination is NULL or DestinationSize is smaller than required buffersize.
**/
RETURN_STATUS
EFIAPI
Base64Encode (
IN CONST UINT8 *Source,
IN UINTN SourceLength,
OUT CHAR8 *Destination OPTIONAL,
IN OUT UINTN *DestinationSize
);
/**
Decode Base64 ASCII encoded data to 8-bit binary representation, based on
RFC4648.
Decoding occurs according to "Table 1: The Base 64 Alphabet" in RFC4648.
Whitespace is ignored at all positions:
- 0x09 ('\t') horizontal tab
- 0x0A ('\n') new line
- 0x0B ('\v') vertical tab
- 0x0C ('\f') form feed
- 0x0D ('\r') carriage return
- 0x20 (' ') space
The minimum amount of required padding (with ASCII 0x3D, '=') is tolerated
and enforced at the end of the Base64 ASCII encoded data, and only there.
Other characters outside of the encoding alphabet cause the function to
reject the Base64 ASCII encoded data.
@param[in] Source Array of CHAR8 elements containing the Base64
ASCII encoding. May be NULL if SourceSize is
zero.
@param[in] SourceSize Number of CHAR8 elements in Source.
@param[out] Destination Array of UINT8 elements receiving the decoded
8-bit binary representation. Allocated by the
caller. May be NULL if DestinationSize is
zero on input. If NULL, decoding is
performed, but the 8-bit binary
representation is not stored. If non-NULL and
the function returns an error, the contents
of Destination are indeterminate.
@param[in,out] DestinationSize On input, the number of UINT8 elements that
the caller allocated for Destination. On
output, if the function returns
RETURN_SUCCESS or RETURN_BUFFER_TOO_SMALL,
the number of UINT8 elements that are
required for decoding the Base64 ASCII
representation. If the function returns a
value different from both RETURN_SUCCESS and
RETURN_BUFFER_TOO_SMALL, then DestinationSize
is indeterminate on output.
@retval RETURN_SUCCESS SourceSize CHAR8 elements at Source have
been decoded to on-output DestinationSize
UINT8 elements at Destination. Note that
RETURN_SUCCESS covers the case when
DestinationSize is zero on input, and
Source decodes to zero bytes (due to
containing at most ignored whitespace).
@retval RETURN_BUFFER_TOO_SMALL The input value of DestinationSize is not
large enough for decoding SourceSize CHAR8
elements at Source. The required number of
UINT8 elements has been stored to
DestinationSize.
@retval RETURN_INVALID_PARAMETER DestinationSize is NULL.
@retval RETURN_INVALID_PARAMETER Source is NULL, but SourceSize is not zero.
@retval RETURN_INVALID_PARAMETER Destination is NULL, but DestinationSize is
not zero on input.
@retval RETURN_INVALID_PARAMETER Source is non-NULL, and (Source +
SourceSize) would wrap around MAX_ADDRESS.
@retval RETURN_INVALID_PARAMETER Destination is non-NULL, and (Destination +
DestinationSize) would wrap around
MAX_ADDRESS, as specified on input.
@retval RETURN_INVALID_PARAMETER None of Source and Destination are NULL,
and CHAR8[SourceSize] at Source overlaps
UINT8[DestinationSize] at Destination, as
specified on input.
@retval RETURN_INVALID_PARAMETER Invalid CHAR8 element encountered in
Source.
**/
RETURN_STATUS
EFIAPI
Base64Decode (
IN CONST CHAR8 *Source OPTIONAL,
IN UINTN SourceSize,
OUT UINT8 *Destination OPTIONAL,
IN OUT UINTN *DestinationSize
);
/**
Converts an 8-bit value to an 8-bit BCD value.
Converts the 8-bit value specified by Value to BCD. The BCD value is
returned.
If Value >= 100, then ASSERT().
@param Value The 8-bit value to convert to BCD. Range 0..99.
@return The BCD value.
**/
UINT8
EFIAPI
DecimalToBcd8 (
IN UINT8 Value
);
/**
Converts an 8-bit BCD value to an 8-bit value.
Converts the 8-bit BCD value specified by Value to an 8-bit value. The 8-bit
value is returned.
If Value >= 0xA0, then ASSERT().
If (Value & 0x0F) >= 0x0A, then ASSERT().
@param Value The 8-bit BCD value to convert to an 8-bit value.
@return The 8-bit value is returned.
**/
UINT8
EFIAPI
BcdToDecimal8 (
IN UINT8 Value
);
//
// File Path Manipulation Functions
//
/**
Removes the last directory or file entry in a path.
@param[in, out] Path The pointer to the path to modify.
@retval FALSE Nothing was found to remove.
@retval TRUE A directory or file was removed.
**/
BOOLEAN
EFIAPI
PathRemoveLastItem(
IN OUT CHAR16 *Path
);
/**
Function to clean up paths.
- Single periods in the path are removed.
- Double periods in the path are removed along with a single parent directory.
- Forward slashes L'/' are converted to backward slashes L'\'.
This will be done inline and the existing buffer may be larger than required
upon completion.
@param[in] Path The pointer to the string containing the path.
@return Returns Path, otherwise returns NULL to indicate that an error has occurred.
**/
CHAR16*
EFIAPI
PathCleanUpDirectories(
IN CHAR16 *Path
);
//
// Linked List Functions and Macros
//
/**
Initializes the head node of a doubly linked list that is declared as a
global variable in a module.
Initializes the forward and backward links of a new linked list. After
initializing a linked list with this macro, the other linked list functions
may be used to add and remove nodes from the linked list. This macro results
in smaller executables by initializing the linked list in the data section,
instead if calling the InitializeListHead() function to perform the
equivalent operation.
@param ListHead The head note of a list to initialize.
**/
#define INITIALIZE_LIST_HEAD_VARIABLE(ListHead) {&(ListHead), &(ListHead)}
/**
Iterates over each node in a doubly linked list using each node's forward link.
@param Entry A pointer to a list node used as a loop cursor during iteration
@param ListHead The head node of the doubly linked list
**/
#define BASE_LIST_FOR_EACH(Entry, ListHead) \
for(Entry = (ListHead)->ForwardLink; Entry != (ListHead); Entry = Entry->ForwardLink)
/**
Iterates over each node in a doubly linked list using each node's forward link
with safety against node removal.
This macro uses NextEntry to temporarily store the next list node so the node
pointed to by Entry may be deleted in the current loop iteration step and
iteration can continue from the node pointed to by NextEntry.
@param Entry A pointer to a list node used as a loop cursor during iteration
@param NextEntry A pointer to a list node used to temporarily store the next node
@param ListHead The head node of the doubly linked list
**/
#define BASE_LIST_FOR_EACH_SAFE(Entry, NextEntry, ListHead) \
for(Entry = (ListHead)->ForwardLink, NextEntry = Entry->ForwardLink;\
Entry != (ListHead); Entry = NextEntry, NextEntry = Entry->ForwardLink)
/**
Checks whether FirstEntry and SecondEntry are part of the same doubly-linked
list.
If FirstEntry is NULL, then ASSERT().
If FirstEntry->ForwardLink is NULL, then ASSERT().
If FirstEntry->BackLink is NULL, then ASSERT().
If SecondEntry is NULL, then ASSERT();
If PcdMaximumLinkedListLength is not zero, and List contains more than
PcdMaximumLinkedListLength nodes, then ASSERT().
@param FirstEntry A pointer to a node in a linked list.
@param SecondEntry A pointer to the node to locate.
@retval TRUE SecondEntry is in the same doubly-linked list as FirstEntry.
@retval FALSE SecondEntry isn't in the same doubly-linked list as FirstEntry,
or FirstEntry is invalid.
**/
BOOLEAN
EFIAPI
IsNodeInList (
IN CONST LIST_ENTRY *FirstEntry,
IN CONST LIST_ENTRY *SecondEntry
);
/**
Initializes the head node of a doubly linked list, and returns the pointer to
the head node of the doubly linked list.
Initializes the forward and backward links of a new linked list. After
initializing a linked list with this function, the other linked list
functions may be used to add and remove nodes from the linked list. It is up
to the caller of this function to allocate the memory for ListHead.
If ListHead is NULL, then ASSERT().
@param ListHead A pointer to the head node of a new doubly linked list.
@return ListHead
**/
LIST_ENTRY *
EFIAPI
InitializeListHead (
IN OUT LIST_ENTRY *ListHead
);
/**
Adds a node to the beginning of a doubly linked list, and returns the pointer
to the head node of the doubly linked list.
Adds the node Entry at the beginning of the doubly linked list denoted by
ListHead, and returns ListHead.
If ListHead is NULL, then ASSERT().
If Entry is NULL, then ASSERT().
If ListHead was not initialized with INTIALIZE_LIST_HEAD_VARIABLE() or
InitializeListHead(), then ASSERT().
If PcdMaximumLinkedListLength is not zero, and prior to insertion the number
of nodes in ListHead, including the ListHead node, is greater than or
equal to PcdMaximumLinkedListLength, then ASSERT().
@param ListHead A pointer to the head node of a doubly linked list.
@param Entry A pointer to a node that is to be inserted at the beginning
of a doubly linked list.
@return ListHead
**/
LIST_ENTRY *
EFIAPI
InsertHeadList (
IN OUT LIST_ENTRY *ListHead,
IN OUT LIST_ENTRY *Entry
);
/**
Adds a node to the end of a doubly linked list, and returns the pointer to
the head node of the doubly linked list.
Adds the node Entry to the end of the doubly linked list denoted by ListHead,
and returns ListHead.
If ListHead is NULL, then ASSERT().
If Entry is NULL, then ASSERT().
If ListHead was not initialized with INTIALIZE_LIST_HEAD_VARIABLE() or
InitializeListHead(), then ASSERT().
If PcdMaximumLinkedListLength is not zero, and prior to insertion the number
of nodes in ListHead, including the ListHead node, is greater than or
equal to PcdMaximumLinkedListLength, then ASSERT().
@param ListHead A pointer to the head node of a doubly linked list.
@param Entry A pointer to a node that is to be added at the end of the
doubly linked list.
@return ListHead
**/
LIST_ENTRY *
EFIAPI
InsertTailList (
IN OUT LIST_ENTRY *ListHead,
IN OUT LIST_ENTRY *Entry
);
/**
Retrieves the first node of a doubly linked list.
Returns the first node of a doubly linked list. List must have been
initialized with INTIALIZE_LIST_HEAD_VARIABLE() or InitializeListHead().
If List is empty, then List is returned.
If List is NULL, then ASSERT().
If List was not initialized with INTIALIZE_LIST_HEAD_VARIABLE() or
InitializeListHead(), then ASSERT().
If PcdMaximumLinkedListLength is not zero, and the number of nodes
in List, including the List node, is greater than or equal to
PcdMaximumLinkedListLength, then ASSERT().
@param List A pointer to the head node of a doubly linked list.
@return The first node of a doubly linked list.
@retval List The list is empty.
**/
LIST_ENTRY *
EFIAPI
GetFirstNode (
IN CONST LIST_ENTRY *List
);
/**
Retrieves the next node of a doubly linked list.
Returns the node of a doubly linked list that follows Node.
List must have been initialized with INTIALIZE_LIST_HEAD_VARIABLE()
or InitializeListHead(). If List is empty, then List is returned.
If List is NULL, then ASSERT().
If Node is NULL, then ASSERT().
If List was not initialized with INTIALIZE_LIST_HEAD_VARIABLE() or
InitializeListHead(), then ASSERT().
If PcdMaximumLinkedListLength is not zero, and List contains more than
PcdMaximumLinkedListLength nodes, then ASSERT().
If PcdVerifyNodeInList is TRUE and Node is not a node in List, then ASSERT().
@param List A pointer to the head node of a doubly linked list.
@param Node A pointer to a node in the doubly linked list.
@return The pointer to the next node if one exists. Otherwise List is returned.
**/
LIST_ENTRY *
EFIAPI
GetNextNode (
IN CONST LIST_ENTRY *List,
IN CONST LIST_ENTRY *Node
);
/**
Retrieves the previous node of a doubly linked list.
Returns the node of a doubly linked list that precedes Node.
List must have been initialized with INTIALIZE_LIST_HEAD_VARIABLE()
or InitializeListHead(). If List is empty, then List is returned.
If List is NULL, then ASSERT().
If Node is NULL, then ASSERT().
If List was not initialized with INTIALIZE_LIST_HEAD_VARIABLE() or
InitializeListHead(), then ASSERT().
If PcdMaximumLinkedListLength is not zero, and List contains more than
PcdMaximumLinkedListLength nodes, then ASSERT().
If PcdVerifyNodeInList is TRUE and Node is not a node in List, then ASSERT().
@param List A pointer to the head node of a doubly linked list.
@param Node A pointer to a node in the doubly linked list.
@return The pointer to the previous node if one exists. Otherwise List is returned.
**/
LIST_ENTRY *
EFIAPI
GetPreviousNode (
IN CONST LIST_ENTRY *List,
IN CONST LIST_ENTRY *Node
);
/**
Checks to see if a doubly linked list is empty or not.
Checks to see if the doubly linked list is empty. If the linked list contains
zero nodes, this function returns TRUE. Otherwise, it returns FALSE.
If ListHead is NULL, then ASSERT().
If ListHead was not initialized with INTIALIZE_LIST_HEAD_VARIABLE() or
InitializeListHead(), then ASSERT().
If PcdMaximumLinkedListLength is not zero, and the number of nodes
in List, including the List node, is greater than or equal to
PcdMaximumLinkedListLength, then ASSERT().
@param ListHead A pointer to the head node of a doubly linked list.
@retval TRUE The linked list is empty.
@retval FALSE The linked list is not empty.
**/
BOOLEAN
EFIAPI
IsListEmpty (
IN CONST LIST_ENTRY *ListHead
);
/**
Determines if a node in a doubly linked list is the head node of a the same
doubly linked list. This function is typically used to terminate a loop that
traverses all the nodes in a doubly linked list starting with the head node.
Returns TRUE if Node is equal to List. Returns FALSE if Node is one of the
nodes in the doubly linked list specified by List. List must have been
initialized with INTIALIZE_LIST_HEAD_VARIABLE() or InitializeListHead().
If List is NULL, then ASSERT().
If Node is NULL, then ASSERT().
If List was not initialized with INTIALIZE_LIST_HEAD_VARIABLE() or InitializeListHead(),
then ASSERT().
If PcdMaximumLinkedListLength is not zero, and the number of nodes
in List, including the List node, is greater than or equal to
PcdMaximumLinkedListLength, then ASSERT().
If PcdVerifyNodeInList is TRUE and Node is not a node in List the and Node is not equal
to List, then ASSERT().
@param List A pointer to the head node of a doubly linked list.
@param Node A pointer to a node in the doubly linked list.
@retval TRUE Node is the head of the doubly-linked list pointed by List.
@retval FALSE Node is not the head of the doubly-linked list pointed by List.
**/
BOOLEAN
EFIAPI
IsNull (
IN CONST LIST_ENTRY *List,
IN CONST LIST_ENTRY *Node
);
/**
Determines if a node the last node in a doubly linked list.
Returns TRUE if Node is the last node in the doubly linked list specified by
List. Otherwise, FALSE is returned. List must have been initialized with
INTIALIZE_LIST_HEAD_VARIABLE() or InitializeListHead().
If List is NULL, then ASSERT().
If Node is NULL, then ASSERT().
If List was not initialized with INTIALIZE_LIST_HEAD_VARIABLE() or
InitializeListHead(), then ASSERT().
If PcdMaximumLinkedListLength is not zero, and the number of nodes
in List, including the List node, is greater than or equal to
PcdMaximumLinkedListLength, then ASSERT().
If PcdVerifyNodeInList is TRUE and Node is not a node in List, then ASSERT().
@param List A pointer to the head node of a doubly linked list.
@param Node A pointer to a node in the doubly linked list.
@retval TRUE Node is the last node in the linked list.
@retval FALSE Node is not the last node in the linked list.
**/
BOOLEAN
EFIAPI
IsNodeAtEnd (
IN CONST LIST_ENTRY *List,
IN CONST LIST_ENTRY *Node
);
/**
Swaps the location of two nodes in a doubly linked list, and returns the
first node after the swap.
If FirstEntry is identical to SecondEntry, then SecondEntry is returned.
Otherwise, the location of the FirstEntry node is swapped with the location
of the SecondEntry node in a doubly linked list. SecondEntry must be in the
same double linked list as FirstEntry and that double linked list must have
been initialized with INTIALIZE_LIST_HEAD_VARIABLE() or InitializeListHead().
SecondEntry is returned after the nodes are swapped.
If FirstEntry is NULL, then ASSERT().
If SecondEntry is NULL, then ASSERT().
If PcdVerifyNodeInList is TRUE and SecondEntry and FirstEntry are not in the
same linked list, then ASSERT().
If PcdMaximumLinkedListLength is not zero, and the number of nodes in the
linked list containing the FirstEntry and SecondEntry nodes, including
the FirstEntry and SecondEntry nodes, is greater than or equal to
PcdMaximumLinkedListLength, then ASSERT().
@param FirstEntry A pointer to a node in a linked list.
@param SecondEntry A pointer to another node in the same linked list.
@return SecondEntry.
**/
LIST_ENTRY *
EFIAPI
SwapListEntries (
IN OUT LIST_ENTRY *FirstEntry,
IN OUT LIST_ENTRY *SecondEntry
);
/**
Removes a node from a doubly linked list, and returns the node that follows
the removed node.
Removes the node Entry from a doubly linked list. It is up to the caller of
this function to release the memory used by this node if that is required. On
exit, the node following Entry in the doubly linked list is returned. If
Entry is the only node in the linked list, then the head node of the linked
list is returned.
If Entry is NULL, then ASSERT().
If Entry is the head node of an empty list, then ASSERT().
If PcdMaximumLinkedListLength is not zero, and the number of nodes in the
linked list containing Entry, including the Entry node, is greater than
or equal to PcdMaximumLinkedListLength, then ASSERT().
@param Entry A pointer to a node in a linked list.
@return Entry.
**/
LIST_ENTRY *
EFIAPI
RemoveEntryList (
IN CONST LIST_ENTRY *Entry
);
//
// Math Services
//
/**
Shifts a 64-bit integer left between 0 and 63 bits. The low bits are filled
with zeros. The shifted value is returned.
This function shifts the 64-bit value Operand to the left by Count bits. The
low Count bits are set to zero. The shifted value is returned.
If Count is greater than 63, then ASSERT().
@param Operand The 64-bit operand to shift left.
@param Count The number of bits to shift left.
@return Operand << Count.
**/
UINT64
EFIAPI
LShiftU64 (
IN UINT64 Operand,
IN UINTN Count
);
/**
Shifts a 64-bit integer right between 0 and 63 bits. This high bits are
filled with zeros. The shifted value is returned.
This function shifts the 64-bit value Operand to the right by Count bits. The
high Count bits are set to zero. The shifted value is returned.
If Count is greater than 63, then ASSERT().
@param Operand The 64-bit operand to shift right.
@param Count The number of bits to shift right.
@return Operand >> Count
**/
UINT64
EFIAPI
RShiftU64 (
IN UINT64 Operand,
IN UINTN Count
);
/**
Shifts a 64-bit integer right between 0 and 63 bits. The high bits are filled
with original integer's bit 63. The shifted value is returned.
This function shifts the 64-bit value Operand to the right by Count bits. The
high Count bits are set to bit 63 of Operand. The shifted value is returned.
If Count is greater than 63, then ASSERT().
@param Operand The 64-bit operand to shift right.
@param Count The number of bits to shift right.
@return Operand >> Count
**/
UINT64
EFIAPI
ARShiftU64 (
IN UINT64 Operand,
IN UINTN Count
);
/**
Rotates a 32-bit integer left between 0 and 31 bits, filling the low bits
with the high bits that were rotated.
This function rotates the 32-bit value Operand to the left by Count bits. The
low Count bits are fill with the high Count bits of Operand. The rotated
value is returned.
If Count is greater than 31, then ASSERT().
@param Operand The 32-bit operand to rotate left.
@param Count The number of bits to rotate left.
@return Operand << Count
**/
UINT32
EFIAPI
LRotU32 (
IN UINT32 Operand,
IN UINTN Count
);
/**
Rotates a 32-bit integer right between 0 and 31 bits, filling the high bits
with the low bits that were rotated.
This function rotates the 32-bit value Operand to the right by Count bits.
The high Count bits are fill with the low Count bits of Operand. The rotated
value is returned.
If Count is greater than 31, then ASSERT().
@param Operand The 32-bit operand to rotate right.
@param Count The number of bits to rotate right.
@return Operand >> Count
**/
UINT32
EFIAPI
RRotU32 (
IN UINT32 Operand,
IN UINTN Count
);
/**
Rotates a 64-bit integer left between 0 and 63 bits, filling the low bits
with the high bits that were rotated.
This function rotates the 64-bit value Operand to the left by Count bits. The
low Count bits are fill with the high Count bits of Operand. The rotated
value is returned.
If Count is greater than 63, then ASSERT().
@param Operand The 64-bit operand to rotate left.
@param Count The number of bits to rotate left.
@return Operand << Count
**/
UINT64
EFIAPI
LRotU64 (
IN UINT64 Operand,
IN UINTN Count
);
/**
Rotates a 64-bit integer right between 0 and 63 bits, filling the high bits
with the high low bits that were rotated.
This function rotates the 64-bit value Operand to the right by Count bits.
The high Count bits are fill with the low Count bits of Operand. The rotated
value is returned.
If Count is greater than 63, then ASSERT().
@param Operand The 64-bit operand to rotate right.
@param Count The number of bits to rotate right.
@return Operand >> Count
**/
UINT64
EFIAPI
RRotU64 (
IN UINT64 Operand,
IN UINTN Count
);
/**
Returns the bit position of the lowest bit set in a 32-bit value.
This function computes the bit position of the lowest bit set in the 32-bit
value specified by Operand. If Operand is zero, then -1 is returned.
Otherwise, a value between 0 and 31 is returned.
@param Operand The 32-bit operand to evaluate.
@retval 0..31 The lowest bit set in Operand was found.
@retval -1 Operand is zero.
**/
INTN
EFIAPI
LowBitSet32 (
IN UINT32 Operand
);
/**
Returns the bit position of the lowest bit set in a 64-bit value.
This function computes the bit position of the lowest bit set in the 64-bit
value specified by Operand. If Operand is zero, then -1 is returned.
Otherwise, a value between 0 and 63 is returned.
@param Operand The 64-bit operand to evaluate.
@retval 0..63 The lowest bit set in Operand was found.
@retval -1 Operand is zero.
**/
INTN
EFIAPI
LowBitSet64 (
IN UINT64 Operand
);
/**
Returns the bit position of the highest bit set in a 32-bit value. Equivalent
to log2(x).
This function computes the bit position of the highest bit set in the 32-bit
value specified by Operand. If Operand is zero, then -1 is returned.
Otherwise, a value between 0 and 31 is returned.
@param Operand The 32-bit operand to evaluate.
@retval 0..31 Position of the highest bit set in Operand if found.
@retval -1 Operand is zero.
**/
INTN
EFIAPI
HighBitSet32 (
IN UINT32 Operand
);
/**
Returns the bit position of the highest bit set in a 64-bit value. Equivalent
to log2(x).
This function computes the bit position of the highest bit set in the 64-bit
value specified by Operand. If Operand is zero, then -1 is returned.
Otherwise, a value between 0 and 63 is returned.
@param Operand The 64-bit operand to evaluate.
@retval 0..63 Position of the highest bit set in Operand if found.
@retval -1 Operand is zero.
**/
INTN
EFIAPI
HighBitSet64 (
IN UINT64 Operand
);
/**
Returns the value of the highest bit set in a 32-bit value. Equivalent to
1 << log2(x).
This function computes the value of the highest bit set in the 32-bit value
specified by Operand. If Operand is zero, then zero is returned.
@param Operand The 32-bit operand to evaluate.
@return 1 << HighBitSet32(Operand)
@retval 0 Operand is zero.
**/
UINT32
EFIAPI
GetPowerOfTwo32 (
IN UINT32 Operand
);
/**
Returns the value of the highest bit set in a 64-bit value. Equivalent to
1 << log2(x).
This function computes the value of the highest bit set in the 64-bit value
specified by Operand. If Operand is zero, then zero is returned.
@param Operand The 64-bit operand to evaluate.
@return 1 << HighBitSet64(Operand)
@retval 0 Operand is zero.
**/
UINT64
EFIAPI
GetPowerOfTwo64 (
IN UINT64 Operand
);
/**
Switches the endianness of a 16-bit integer.
This function swaps the bytes in a 16-bit unsigned value to switch the value
from little endian to big endian or vice versa. The byte swapped value is
returned.
@param Value A 16-bit unsigned value.
@return The byte swapped Value.
**/
UINT16
EFIAPI
SwapBytes16 (
IN UINT16 Value
);
/**
Switches the endianness of a 32-bit integer.
This function swaps the bytes in a 32-bit unsigned value to switch the value
from little endian to big endian or vice versa. The byte swapped value is
returned.
@param Value A 32-bit unsigned value.
@return The byte swapped Value.
**/
UINT32
EFIAPI
SwapBytes32 (
IN UINT32 Value
);
/**
Switches the endianness of a 64-bit integer.
This function swaps the bytes in a 64-bit unsigned value to switch the value
from little endian to big endian or vice versa. The byte swapped value is
returned.
@param Value A 64-bit unsigned value.
@return The byte swapped Value.
**/
UINT64
EFIAPI
SwapBytes64 (
IN UINT64 Value
);
/**
Multiples a 64-bit unsigned integer by a 32-bit unsigned integer and
generates a 64-bit unsigned result.
This function multiples the 64-bit unsigned value Multiplicand by the 32-bit
unsigned value Multiplier and generates a 64-bit unsigned result. This 64-
bit unsigned result is returned.
@param Multiplicand A 64-bit unsigned value.
@param Multiplier A 32-bit unsigned value.
@return Multiplicand * Multiplier
**/
UINT64
EFIAPI
MultU64x32 (
IN UINT64 Multiplicand,
IN UINT32 Multiplier
);
/**
Multiples a 64-bit unsigned integer by a 64-bit unsigned integer and
generates a 64-bit unsigned result.
This function multiples the 64-bit unsigned value Multiplicand by the 64-bit
unsigned value Multiplier and generates a 64-bit unsigned result. This 64-
bit unsigned result is returned.
@param Multiplicand A 64-bit unsigned value.
@param Multiplier A 64-bit unsigned value.
@return Multiplicand * Multiplier.
**/
UINT64
EFIAPI
MultU64x64 (
IN UINT64 Multiplicand,
IN UINT64 Multiplier
);
/**
Multiples a 64-bit signed integer by a 64-bit signed integer and generates a
64-bit signed result.
This function multiples the 64-bit signed value Multiplicand by the 64-bit
signed value Multiplier and generates a 64-bit signed result. This 64-bit
signed result is returned.
@param Multiplicand A 64-bit signed value.
@param Multiplier A 64-bit signed value.
@return Multiplicand * Multiplier
**/
INT64
EFIAPI
MultS64x64 (
IN INT64 Multiplicand,
IN INT64 Multiplier
);
/**
Divides a 64-bit unsigned integer by a 32-bit unsigned integer and generates
a 64-bit unsigned result.
This function divides the 64-bit unsigned value Dividend by the 32-bit
unsigned value Divisor and generates a 64-bit unsigned quotient. This
function returns the 64-bit unsigned quotient.
If Divisor is 0, then ASSERT().
@param Dividend A 64-bit unsigned value.
@param Divisor A 32-bit unsigned value.
@return Dividend / Divisor.
**/
UINT64
EFIAPI
DivU64x32 (
IN UINT64 Dividend,
IN UINT32 Divisor
);
/**
Divides a 64-bit unsigned integer by a 32-bit unsigned integer and generates
a 32-bit unsigned remainder.
This function divides the 64-bit unsigned value Dividend by the 32-bit
unsigned value Divisor and generates a 32-bit remainder. This function
returns the 32-bit unsigned remainder.
If Divisor is 0, then ASSERT().
@param Dividend A 64-bit unsigned value.
@param Divisor A 32-bit unsigned value.
@return Dividend % Divisor.
**/
UINT32
EFIAPI
ModU64x32 (
IN UINT64 Dividend,
IN UINT32 Divisor
);
/**
Divides a 64-bit unsigned integer by a 32-bit unsigned integer and generates
a 64-bit unsigned result and an optional 32-bit unsigned remainder.
This function divides the 64-bit unsigned value Dividend by the 32-bit
unsigned value Divisor and generates a 64-bit unsigned quotient. If Remainder
is not NULL, then the 32-bit unsigned remainder is returned in Remainder.
This function returns the 64-bit unsigned quotient.
If Divisor is 0, then ASSERT().
@param Dividend A 64-bit unsigned value.
@param Divisor A 32-bit unsigned value.
@param Remainder A pointer to a 32-bit unsigned value. This parameter is
optional and may be NULL.
@return Dividend / Divisor.
**/
UINT64
EFIAPI
DivU64x32Remainder (
IN UINT64 Dividend,
IN UINT32 Divisor,
OUT UINT32 *Remainder OPTIONAL
);
/**
Divides a 64-bit unsigned integer by a 64-bit unsigned integer and generates
a 64-bit unsigned result and an optional 64-bit unsigned remainder.
This function divides the 64-bit unsigned value Dividend by the 64-bit
unsigned value Divisor and generates a 64-bit unsigned quotient. If Remainder
is not NULL, then the 64-bit unsigned remainder is returned in Remainder.
This function returns the 64-bit unsigned quotient.
If Divisor is 0, then ASSERT().
@param Dividend A 64-bit unsigned value.
@param Divisor A 64-bit unsigned value.
@param Remainder A pointer to a 64-bit unsigned value. This parameter is
optional and may be NULL.
@return Dividend / Divisor.
**/
UINT64
EFIAPI
DivU64x64Remainder (
IN UINT64 Dividend,
IN UINT64 Divisor,
OUT UINT64 *Remainder OPTIONAL
);
/**
Divides a 64-bit signed integer by a 64-bit signed integer and generates a
64-bit signed result and a optional 64-bit signed remainder.
This function divides the 64-bit signed value Dividend by the 64-bit signed
value Divisor and generates a 64-bit signed quotient. If Remainder is not
NULL, then the 64-bit signed remainder is returned in Remainder. This
function returns the 64-bit signed quotient.
It is the caller's responsibility to not call this function with a Divisor of 0.
If Divisor is 0, then the quotient and remainder should be assumed to be
the largest negative integer.
If Divisor is 0, then ASSERT().
@param Dividend A 64-bit signed value.
@param Divisor A 64-bit signed value.
@param Remainder A pointer to a 64-bit signed value. This parameter is
optional and may be NULL.
@return Dividend / Divisor.
**/
INT64
EFIAPI
DivS64x64Remainder (
IN INT64 Dividend,
IN INT64 Divisor,
OUT INT64 *Remainder OPTIONAL
);
/**
Reads a 16-bit value from memory that may be unaligned.
This function returns the 16-bit value pointed to by Buffer. The function
guarantees that the read operation does not produce an alignment fault.
If the Buffer is NULL, then ASSERT().
@param Buffer The pointer to a 16-bit value that may be unaligned.
@return The 16-bit value read from Buffer.
**/
UINT16
EFIAPI
ReadUnaligned16 (
IN CONST UINT16 *Buffer
);
/**
Writes a 16-bit value to memory that may be unaligned.
This function writes the 16-bit value specified by Value to Buffer. Value is
returned. The function guarantees that the write operation does not produce
an alignment fault.
If the Buffer is NULL, then ASSERT().
@param Buffer The pointer to a 16-bit value that may be unaligned.
@param Value 16-bit value to write to Buffer.
@return The 16-bit value to write to Buffer.
**/
UINT16
EFIAPI
WriteUnaligned16 (
OUT UINT16 *Buffer,
IN UINT16 Value
);
/**
Reads a 24-bit value from memory that may be unaligned.
This function returns the 24-bit value pointed to by Buffer. The function
guarantees that the read operation does not produce an alignment fault.
If the Buffer is NULL, then ASSERT().
@param Buffer The pointer to a 24-bit value that may be unaligned.
@return The 24-bit value read from Buffer.
**/
UINT32
EFIAPI
ReadUnaligned24 (
IN CONST UINT32 *Buffer
);
/**
Writes a 24-bit value to memory that may be unaligned.
This function writes the 24-bit value specified by Value to Buffer. Value is
returned. The function guarantees that the write operation does not produce
an alignment fault.
If the Buffer is NULL, then ASSERT().
@param Buffer The pointer to a 24-bit value that may be unaligned.
@param Value 24-bit value to write to Buffer.
@return The 24-bit value to write to Buffer.
**/
UINT32
EFIAPI
WriteUnaligned24 (
OUT UINT32 *Buffer,
IN UINT32 Value
);
/**
Reads a 32-bit value from memory that may be unaligned.
This function returns the 32-bit value pointed to by Buffer. The function
guarantees that the read operation does not produce an alignment fault.
If the Buffer is NULL, then ASSERT().
@param Buffer The pointer to a 32-bit value that may be unaligned.
@return The 32-bit value read from Buffer.
**/
UINT32
EFIAPI
ReadUnaligned32 (
IN CONST UINT32 *Buffer
);
/**
Writes a 32-bit value to memory that may be unaligned.
This function writes the 32-bit value specified by Value to Buffer. Value is
returned. The function guarantees that the write operation does not produce
an alignment fault.
If the Buffer is NULL, then ASSERT().
@param Buffer The pointer to a 32-bit value that may be unaligned.
@param Value 32-bit value to write to Buffer.
@return The 32-bit value to write to Buffer.
**/
UINT32
EFIAPI
WriteUnaligned32 (
OUT UINT32 *Buffer,
IN UINT32 Value
);
/**
Reads a 64-bit value from memory that may be unaligned.
This function returns the 64-bit value pointed to by Buffer. The function
guarantees that the read operation does not produce an alignment fault.
If the Buffer is NULL, then ASSERT().
@param Buffer The pointer to a 64-bit value that may be unaligned.
@return The 64-bit value read from Buffer.
**/
UINT64
EFIAPI
ReadUnaligned64 (
IN CONST UINT64 *Buffer
);
/**
Writes a 64-bit value to memory that may be unaligned.
This function writes the 64-bit value specified by Value to Buffer. Value is
returned. The function guarantees that the write operation does not produce
an alignment fault.
If the Buffer is NULL, then ASSERT().
@param Buffer The pointer to a 64-bit value that may be unaligned.
@param Value 64-bit value to write to Buffer.
@return The 64-bit value to write to Buffer.
**/
UINT64
EFIAPI
WriteUnaligned64 (
OUT UINT64 *Buffer,
IN UINT64 Value
);
//
// Bit Field Functions
//
/**
Returns a bit field from an 8-bit value.
Returns the bitfield specified by the StartBit and the EndBit from Operand.
If 8-bit operations are not supported, then ASSERT().
If StartBit is greater than 7, then ASSERT().
If EndBit is greater than 7, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..7.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..7.
@return The bit field read.
**/
UINT8
EFIAPI
BitFieldRead8 (
IN UINT8 Operand,
IN UINTN StartBit,
IN UINTN EndBit
);
/**
Writes a bit field to an 8-bit value, and returns the result.
Writes Value to the bit field specified by the StartBit and the EndBit in
Operand. All other bits in Operand are preserved. The new 8-bit value is
returned.
If 8-bit operations are not supported, then ASSERT().
If StartBit is greater than 7, then ASSERT().
If EndBit is greater than 7, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If Value is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..7.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..7.
@param Value New value of the bit field.
@return The new 8-bit value.
**/
UINT8
EFIAPI
BitFieldWrite8 (
IN UINT8 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT8 Value
);
/**
Reads a bit field from an 8-bit value, performs a bitwise OR, and returns the
result.
Performs a bitwise OR between the bit field specified by StartBit
and EndBit in Operand and the value specified by OrData. All other bits in
Operand are preserved. The new 8-bit value is returned.
If 8-bit operations are not supported, then ASSERT().
If StartBit is greater than 7, then ASSERT().
If EndBit is greater than 7, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..7.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..7.
@param OrData The value to OR with the read value from the value
@return The new 8-bit value.
**/
UINT8
EFIAPI
BitFieldOr8 (
IN UINT8 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT8 OrData
);
/**
Reads a bit field from an 8-bit value, performs a bitwise AND, and returns
the result.
Performs a bitwise AND between the bit field specified by StartBit and EndBit
in Operand and the value specified by AndData. All other bits in Operand are
preserved. The new 8-bit value is returned.
If 8-bit operations are not supported, then ASSERT().
If StartBit is greater than 7, then ASSERT().
If EndBit is greater than 7, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..7.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..7.
@param AndData The value to AND with the read value from the value.
@return The new 8-bit value.
**/
UINT8
EFIAPI
BitFieldAnd8 (
IN UINT8 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT8 AndData
);
/**
Reads a bit field from an 8-bit value, performs a bitwise AND followed by a
bitwise OR, and returns the result.
Performs a bitwise AND between the bit field specified by StartBit and EndBit
in Operand and the value specified by AndData, followed by a bitwise
OR with value specified by OrData. All other bits in Operand are
preserved. The new 8-bit value is returned.
If 8-bit operations are not supported, then ASSERT().
If StartBit is greater than 7, then ASSERT().
If EndBit is greater than 7, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..7.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..7.
@param AndData The value to AND with the read value from the value.
@param OrData The value to OR with the result of the AND operation.
@return The new 8-bit value.
**/
UINT8
EFIAPI
BitFieldAndThenOr8 (
IN UINT8 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT8 AndData,
IN UINT8 OrData
);
/**
Returns a bit field from a 16-bit value.
Returns the bitfield specified by the StartBit and the EndBit from Operand.
If 16-bit operations are not supported, then ASSERT().
If StartBit is greater than 15, then ASSERT().
If EndBit is greater than 15, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..15.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..15.
@return The bit field read.
**/
UINT16
EFIAPI
BitFieldRead16 (
IN UINT16 Operand,
IN UINTN StartBit,
IN UINTN EndBit
);
/**
Writes a bit field to a 16-bit value, and returns the result.
Writes Value to the bit field specified by the StartBit and the EndBit in
Operand. All other bits in Operand are preserved. The new 16-bit value is
returned.
If 16-bit operations are not supported, then ASSERT().
If StartBit is greater than 15, then ASSERT().
If EndBit is greater than 15, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If Value is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..15.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..15.
@param Value New value of the bit field.
@return The new 16-bit value.
**/
UINT16
EFIAPI
BitFieldWrite16 (
IN UINT16 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT16 Value
);
/**
Reads a bit field from a 16-bit value, performs a bitwise OR, and returns the
result.
Performs a bitwise OR between the bit field specified by StartBit
and EndBit in Operand and the value specified by OrData. All other bits in
Operand are preserved. The new 16-bit value is returned.
If 16-bit operations are not supported, then ASSERT().
If StartBit is greater than 15, then ASSERT().
If EndBit is greater than 15, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..15.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..15.
@param OrData The value to OR with the read value from the value
@return The new 16-bit value.
**/
UINT16
EFIAPI
BitFieldOr16 (
IN UINT16 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT16 OrData
);
/**
Reads a bit field from a 16-bit value, performs a bitwise AND, and returns
the result.
Performs a bitwise AND between the bit field specified by StartBit and EndBit
in Operand and the value specified by AndData. All other bits in Operand are
preserved. The new 16-bit value is returned.
If 16-bit operations are not supported, then ASSERT().
If StartBit is greater than 15, then ASSERT().
If EndBit is greater than 15, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..15.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..15.
@param AndData The value to AND with the read value from the value
@return The new 16-bit value.
**/
UINT16
EFIAPI
BitFieldAnd16 (
IN UINT16 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT16 AndData
);
/**
Reads a bit field from a 16-bit value, performs a bitwise AND followed by a
bitwise OR, and returns the result.
Performs a bitwise AND between the bit field specified by StartBit and EndBit
in Operand and the value specified by AndData, followed by a bitwise
OR with value specified by OrData. All other bits in Operand are
preserved. The new 16-bit value is returned.
If 16-bit operations are not supported, then ASSERT().
If StartBit is greater than 15, then ASSERT().
If EndBit is greater than 15, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..15.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..15.
@param AndData The value to AND with the read value from the value.
@param OrData The value to OR with the result of the AND operation.
@return The new 16-bit value.
**/
UINT16
EFIAPI
BitFieldAndThenOr16 (
IN UINT16 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT16 AndData,
IN UINT16 OrData
);
/**
Returns a bit field from a 32-bit value.
Returns the bitfield specified by the StartBit and the EndBit from Operand.
If 32-bit operations are not supported, then ASSERT().
If StartBit is greater than 31, then ASSERT().
If EndBit is greater than 31, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..31.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..31.
@return The bit field read.
**/
UINT32
EFIAPI
BitFieldRead32 (
IN UINT32 Operand,
IN UINTN StartBit,
IN UINTN EndBit
);
/**
Writes a bit field to a 32-bit value, and returns the result.
Writes Value to the bit field specified by the StartBit and the EndBit in
Operand. All other bits in Operand are preserved. The new 32-bit value is
returned.
If 32-bit operations are not supported, then ASSERT().
If StartBit is greater than 31, then ASSERT().
If EndBit is greater than 31, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If Value is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..31.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..31.
@param Value New value of the bit field.
@return The new 32-bit value.
**/
UINT32
EFIAPI
BitFieldWrite32 (
IN UINT32 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT32 Value
);
/**
Reads a bit field from a 32-bit value, performs a bitwise OR, and returns the
result.
Performs a bitwise OR between the bit field specified by StartBit
and EndBit in Operand and the value specified by OrData. All other bits in
Operand are preserved. The new 32-bit value is returned.
If 32-bit operations are not supported, then ASSERT().
If StartBit is greater than 31, then ASSERT().
If EndBit is greater than 31, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..31.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..31.
@param OrData The value to OR with the read value from the value.
@return The new 32-bit value.
**/
UINT32
EFIAPI
BitFieldOr32 (
IN UINT32 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT32 OrData
);
/**
Reads a bit field from a 32-bit value, performs a bitwise AND, and returns
the result.
Performs a bitwise AND between the bit field specified by StartBit and EndBit
in Operand and the value specified by AndData. All other bits in Operand are
preserved. The new 32-bit value is returned.
If 32-bit operations are not supported, then ASSERT().
If StartBit is greater than 31, then ASSERT().
If EndBit is greater than 31, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..31.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..31.
@param AndData The value to AND with the read value from the value
@return The new 32-bit value.
**/
UINT32
EFIAPI
BitFieldAnd32 (
IN UINT32 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT32 AndData
);
/**
Reads a bit field from a 32-bit value, performs a bitwise AND followed by a
bitwise OR, and returns the result.
Performs a bitwise AND between the bit field specified by StartBit and EndBit
in Operand and the value specified by AndData, followed by a bitwise
OR with value specified by OrData. All other bits in Operand are
preserved. The new 32-bit value is returned.
If 32-bit operations are not supported, then ASSERT().
If StartBit is greater than 31, then ASSERT().
If EndBit is greater than 31, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..31.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..31.
@param AndData The value to AND with the read value from the value.
@param OrData The value to OR with the result of the AND operation.
@return The new 32-bit value.
**/
UINT32
EFIAPI
BitFieldAndThenOr32 (
IN UINT32 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT32 AndData,
IN UINT32 OrData
);
/**
Returns a bit field from a 64-bit value.
Returns the bitfield specified by the StartBit and the EndBit from Operand.
If 64-bit operations are not supported, then ASSERT().
If StartBit is greater than 63, then ASSERT().
If EndBit is greater than 63, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..63.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..63.
@return The bit field read.
**/
UINT64
EFIAPI
BitFieldRead64 (
IN UINT64 Operand,
IN UINTN StartBit,
IN UINTN EndBit
);
/**
Writes a bit field to a 64-bit value, and returns the result.
Writes Value to the bit field specified by the StartBit and the EndBit in
Operand. All other bits in Operand are preserved. The new 64-bit value is
returned.
If 64-bit operations are not supported, then ASSERT().
If StartBit is greater than 63, then ASSERT().
If EndBit is greater than 63, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If Value is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..63.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..63.
@param Value New value of the bit field.
@return The new 64-bit value.
**/
UINT64
EFIAPI
BitFieldWrite64 (
IN UINT64 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT64 Value
);
/**
Reads a bit field from a 64-bit value, performs a bitwise OR, and returns the
result.
Performs a bitwise OR between the bit field specified by StartBit
and EndBit in Operand and the value specified by OrData. All other bits in
Operand are preserved. The new 64-bit value is returned.
If 64-bit operations are not supported, then ASSERT().
If StartBit is greater than 63, then ASSERT().
If EndBit is greater than 63, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..63.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..63.
@param OrData The value to OR with the read value from the value
@return The new 64-bit value.
**/
UINT64
EFIAPI
BitFieldOr64 (
IN UINT64 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT64 OrData
);
/**
Reads a bit field from a 64-bit value, performs a bitwise AND, and returns
the result.
Performs a bitwise AND between the bit field specified by StartBit and EndBit
in Operand and the value specified by AndData. All other bits in Operand are
preserved. The new 64-bit value is returned.
If 64-bit operations are not supported, then ASSERT().
If StartBit is greater than 63, then ASSERT().
If EndBit is greater than 63, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..63.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..63.
@param AndData The value to AND with the read value from the value
@return The new 64-bit value.
**/
UINT64
EFIAPI
BitFieldAnd64 (
IN UINT64 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT64 AndData
);
/**
Reads a bit field from a 64-bit value, performs a bitwise AND followed by a
bitwise OR, and returns the result.
Performs a bitwise AND between the bit field specified by StartBit and EndBit
in Operand and the value specified by AndData, followed by a bitwise
OR with value specified by OrData. All other bits in Operand are
preserved. The new 64-bit value is returned.
If 64-bit operations are not supported, then ASSERT().
If StartBit is greater than 63, then ASSERT().
If EndBit is greater than 63, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..63.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..63.
@param AndData The value to AND with the read value from the value.
@param OrData The value to OR with the result of the AND operation.
@return The new 64-bit value.
**/
UINT64
EFIAPI
BitFieldAndThenOr64 (
IN UINT64 Operand,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT64 AndData,
IN UINT64 OrData
);
/**
Reads a bit field from a 32-bit value, counts and returns
the number of set bits.
Counts the number of set bits in the bit field specified by
StartBit and EndBit in Operand. The count is returned.
If StartBit is greater than 31, then ASSERT().
If EndBit is greater than 31, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..31.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..31.
@return The number of bits set between StartBit and EndBit.
**/
UINT8
EFIAPI
BitFieldCountOnes32 (
IN UINT32 Operand,
IN UINTN StartBit,
IN UINTN EndBit
);
/**
Reads a bit field from a 64-bit value, counts and returns
the number of set bits.
Counts the number of set bits in the bit field specified by
StartBit and EndBit in Operand. The count is returned.
If StartBit is greater than 63, then ASSERT().
If EndBit is greater than 63, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
@param Operand Operand on which to perform the bitfield operation.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..63.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..63.
@return The number of bits set between StartBit and EndBit.
**/
UINT8
EFIAPI
BitFieldCountOnes64 (
IN UINT64 Operand,
IN UINTN StartBit,
IN UINTN EndBit
);
//
// Base Library Checksum Functions
//
/**
Returns the sum of all elements in a buffer in unit of UINT8.
During calculation, the carry bits are dropped.
This function calculates the sum of all elements in a buffer
in unit of UINT8. The carry bits in result of addition are dropped.
The result is returned as UINT8. If Length is Zero, then Zero is
returned.
If Buffer is NULL, then ASSERT().
If Length is greater than (MAX_ADDRESS - Buffer + 1), then ASSERT().
@param Buffer The pointer to the buffer to carry out the sum operation.
@param Length The size, in bytes, of Buffer.
@return Sum The sum of Buffer with carry bits dropped during additions.
**/
UINT8
EFIAPI
CalculateSum8 (
IN CONST UINT8 *Buffer,
IN UINTN Length
);
/**
Returns the two's complement checksum of all elements in a buffer
of 8-bit values.
This function first calculates the sum of the 8-bit values in the
buffer specified by Buffer and Length. The carry bits in the result
of addition are dropped. Then, the two's complement of the sum is
returned. If Length is 0, then 0 is returned.
If Buffer is NULL, then ASSERT().
If Length is greater than (MAX_ADDRESS - Buffer + 1), then ASSERT().
@param Buffer The pointer to the buffer to carry out the checksum operation.
@param Length The size, in bytes, of Buffer.
@return Checksum The two's complement checksum of Buffer.
**/
UINT8
EFIAPI
CalculateCheckSum8 (
IN CONST UINT8 *Buffer,
IN UINTN Length
);
/**
Returns the sum of all elements in a buffer of 16-bit values. During
calculation, the carry bits are dropped.
This function calculates the sum of the 16-bit values in the buffer
specified by Buffer and Length. The carry bits in result of addition are dropped.
The 16-bit result is returned. If Length is 0, then 0 is returned.
If Buffer is NULL, then ASSERT().
If Buffer is not aligned on a 16-bit boundary, then ASSERT().
If Length is not aligned on a 16-bit boundary, then ASSERT().
If Length is greater than (MAX_ADDRESS - Buffer + 1), then ASSERT().
@param Buffer The pointer to the buffer to carry out the sum operation.
@param Length The size, in bytes, of Buffer.
@return Sum The sum of Buffer with carry bits dropped during additions.
**/
UINT16
EFIAPI
CalculateSum16 (
IN CONST UINT16 *Buffer,
IN UINTN Length
);
/**
Returns the two's complement checksum of all elements in a buffer of
16-bit values.
This function first calculates the sum of the 16-bit values in the buffer
specified by Buffer and Length. The carry bits in the result of addition
are dropped. Then, the two's complement of the sum is returned. If Length
is 0, then 0 is returned.
If Buffer is NULL, then ASSERT().
If Buffer is not aligned on a 16-bit boundary, then ASSERT().
If Length is not aligned on a 16-bit boundary, then ASSERT().
If Length is greater than (MAX_ADDRESS - Buffer + 1), then ASSERT().
@param Buffer The pointer to the buffer to carry out the checksum operation.
@param Length The size, in bytes, of Buffer.
@return Checksum The two's complement checksum of Buffer.
**/
UINT16
EFIAPI
CalculateCheckSum16 (
IN CONST UINT16 *Buffer,
IN UINTN Length
);
/**
Returns the sum of all elements in a buffer of 32-bit values. During
calculation, the carry bits are dropped.
This function calculates the sum of the 32-bit values in the buffer
specified by Buffer and Length. The carry bits in result of addition are dropped.
The 32-bit result is returned. If Length is 0, then 0 is returned.
If Buffer is NULL, then ASSERT().
If Buffer is not aligned on a 32-bit boundary, then ASSERT().
If Length is not aligned on a 32-bit boundary, then ASSERT().
If Length is greater than (MAX_ADDRESS - Buffer + 1), then ASSERT().
@param Buffer The pointer to the buffer to carry out the sum operation.
@param Length The size, in bytes, of Buffer.
@return Sum The sum of Buffer with carry bits dropped during additions.
**/
UINT32
EFIAPI
CalculateSum32 (
IN CONST UINT32 *Buffer,
IN UINTN Length
);
/**
Returns the two's complement checksum of all elements in a buffer of
32-bit values.
This function first calculates the sum of the 32-bit values in the buffer
specified by Buffer and Length. The carry bits in the result of addition
are dropped. Then, the two's complement of the sum is returned. If Length
is 0, then 0 is returned.
If Buffer is NULL, then ASSERT().
If Buffer is not aligned on a 32-bit boundary, then ASSERT().
If Length is not aligned on a 32-bit boundary, then ASSERT().
If Length is greater than (MAX_ADDRESS - Buffer + 1), then ASSERT().
@param Buffer The pointer to the buffer to carry out the checksum operation.
@param Length The size, in bytes, of Buffer.
@return Checksum The two's complement checksum of Buffer.
**/
UINT32
EFIAPI
CalculateCheckSum32 (
IN CONST UINT32 *Buffer,
IN UINTN Length
);
/**
Returns the sum of all elements in a buffer of 64-bit values. During
calculation, the carry bits are dropped.
This function calculates the sum of the 64-bit values in the buffer
specified by Buffer and Length. The carry bits in result of addition are dropped.
The 64-bit result is returned. If Length is 0, then 0 is returned.
If Buffer is NULL, then ASSERT().
If Buffer is not aligned on a 64-bit boundary, then ASSERT().
If Length is not aligned on a 64-bit boundary, then ASSERT().
If Length is greater than (MAX_ADDRESS - Buffer + 1), then ASSERT().
@param Buffer The pointer to the buffer to carry out the sum operation.
@param Length The size, in bytes, of Buffer.
@return Sum The sum of Buffer with carry bits dropped during additions.
**/
UINT64
EFIAPI
CalculateSum64 (
IN CONST UINT64 *Buffer,
IN UINTN Length
);
/**
Returns the two's complement checksum of all elements in a buffer of
64-bit values.
This function first calculates the sum of the 64-bit values in the buffer
specified by Buffer and Length. The carry bits in the result of addition
are dropped. Then, the two's complement of the sum is returned. If Length
is 0, then 0 is returned.
If Buffer is NULL, then ASSERT().
If Buffer is not aligned on a 64-bit boundary, then ASSERT().
If Length is not aligned on a 64-bit boundary, then ASSERT().
If Length is greater than (MAX_ADDRESS - Buffer + 1), then ASSERT().
@param Buffer The pointer to the buffer to carry out the checksum operation.
@param Length The size, in bytes, of Buffer.
@return Checksum The two's complement checksum of Buffer.
**/
UINT64
EFIAPI
CalculateCheckSum64 (
IN CONST UINT64 *Buffer,
IN UINTN Length
);
/**
Computes and returns a 32-bit CRC for a data buffer.
CRC32 value bases on ITU-T V.42.
If Buffer is NULL, then ASSERT().
If Length is greater than (MAX_ADDRESS - Buffer + 1), then ASSERT().
@param[in] Buffer A pointer to the buffer on which the 32-bit CRC is to be computed.
@param[in] Length The number of bytes in the buffer Data.
@retval Crc32 The 32-bit CRC was computed for the data buffer.
**/
UINT32
EFIAPI
CalculateCrc32(
IN VOID *Buffer,
IN UINTN Length
);
//
// Base Library CPU Functions
//
/**
Function entry point used when a stack switch is requested with SwitchStack()
@param Context1 Context1 parameter passed into SwitchStack().
@param Context2 Context2 parameter passed into SwitchStack().
**/
typedef
VOID
(EFIAPI *SWITCH_STACK_ENTRY_POINT)(
IN VOID *Context1, OPTIONAL
IN VOID *Context2 OPTIONAL
);
/**
Used to serialize load and store operations.
All loads and stores that proceed calls to this function are guaranteed to be
globally visible when this function returns.
**/
VOID
EFIAPI
MemoryFence (
VOID
);
/**
Saves the current CPU context that can be restored with a call to LongJump()
and returns 0.
Saves the current CPU context in the buffer specified by JumpBuffer and
returns 0. The initial call to SetJump() must always return 0. Subsequent
calls to LongJump() cause a non-zero value to be returned by SetJump().
If JumpBuffer is NULL, then ASSERT().
For Itanium processors, if JumpBuffer is not aligned on a 16-byte boundary, then ASSERT().
NOTE: The structure BASE_LIBRARY_JUMP_BUFFER is CPU architecture specific.
The same structure must never be used for more than one CPU architecture context.
For example, a BASE_LIBRARY_JUMP_BUFFER allocated by an IA-32 module must never be used from an x64 module.
SetJump()/LongJump() is not currently supported for the EBC processor type.
@param JumpBuffer A pointer to CPU context buffer.
@retval 0 Indicates a return from SetJump().
**/
RETURNS_TWICE
UINTN
EFIAPI
SetJump (
OUT BASE_LIBRARY_JUMP_BUFFER *JumpBuffer
);
/**
Restores the CPU context that was saved with SetJump().
Restores the CPU context from the buffer specified by JumpBuffer. This
function never returns to the caller. Instead is resumes execution based on
the state of JumpBuffer.
If JumpBuffer is NULL, then ASSERT().
For Itanium processors, if JumpBuffer is not aligned on a 16-byte boundary, then ASSERT().
If Value is 0, then ASSERT().
@param JumpBuffer A pointer to CPU context buffer.
@param Value The value to return when the SetJump() context is
restored and must be non-zero.
**/
VOID
EFIAPI
LongJump (
IN BASE_LIBRARY_JUMP_BUFFER *JumpBuffer,
IN UINTN Value
);
/**
Enables CPU interrupts.
**/
VOID
EFIAPI
EnableInterrupts (
VOID
);
/**
Disables CPU interrupts.
**/
VOID
EFIAPI
DisableInterrupts (
VOID
);
/**
Disables CPU interrupts and returns the interrupt state prior to the disable
operation.
@retval TRUE CPU interrupts were enabled on entry to this call.
@retval FALSE CPU interrupts were disabled on entry to this call.
**/
BOOLEAN
EFIAPI
SaveAndDisableInterrupts (
VOID
);
/**
Enables CPU interrupts for the smallest window required to capture any
pending interrupts.
**/
VOID
EFIAPI
EnableDisableInterrupts (
VOID
);
/**
Retrieves the current CPU interrupt state.
Returns TRUE if interrupts are currently enabled. Otherwise
returns FALSE.
@retval TRUE CPU interrupts are enabled.
@retval FALSE CPU interrupts are disabled.
**/
BOOLEAN
EFIAPI
GetInterruptState (
VOID
);
/**
Set the current CPU interrupt state.
Sets the current CPU interrupt state to the state specified by
InterruptState. If InterruptState is TRUE, then interrupts are enabled. If
InterruptState is FALSE, then interrupts are disabled. InterruptState is
returned.
@param InterruptState TRUE if interrupts should enabled. FALSE if
interrupts should be disabled.
@return InterruptState
**/
BOOLEAN
EFIAPI
SetInterruptState (
IN BOOLEAN InterruptState
);
/**
Requests CPU to pause for a short period of time.
Requests CPU to pause for a short period of time. Typically used in MP
systems to prevent memory starvation while waiting for a spin lock.
**/
VOID
EFIAPI
CpuPause (
VOID
);
/**
Transfers control to a function starting with a new stack.
Transfers control to the function specified by EntryPoint using the
new stack specified by NewStack and passing in the parameters specified
by Context1 and Context2. Context1 and Context2 are optional and may
be NULL. The function EntryPoint must never return. This function
supports a variable number of arguments following the NewStack parameter.
These additional arguments are ignored on IA-32, x64, and EBC architectures.
Itanium processors expect one additional parameter of type VOID * that specifies
the new backing store pointer.
If EntryPoint is NULL, then ASSERT().
If NewStack is NULL, then ASSERT().
@param EntryPoint A pointer to function to call with the new stack.
@param Context1 A pointer to the context to pass into the EntryPoint
function.
@param Context2 A pointer to the context to pass into the EntryPoint
function.
@param NewStack A pointer to the new stack to use for the EntryPoint
function.
@param ... This variable argument list is ignored for IA-32, x64, and
EBC architectures. For Itanium processors, this variable
argument list is expected to contain a single parameter of
type VOID * that specifies the new backing store pointer.
**/
VOID
EFIAPI
SwitchStack (
IN SWITCH_STACK_ENTRY_POINT EntryPoint,
IN VOID *Context1, OPTIONAL
IN VOID *Context2, OPTIONAL
IN VOID *NewStack,
...
);
/**
Generates a breakpoint on the CPU.
Generates a breakpoint on the CPU. The breakpoint must be implemented such
that code can resume normal execution after the breakpoint.
**/
VOID
EFIAPI
CpuBreakpoint (
VOID
);
/**
Executes an infinite loop.
Forces the CPU to execute an infinite loop. A debugger may be used to skip
past the loop and the code that follows the loop must execute properly. This
implies that the infinite loop must not cause the code that follow it to be
optimized away.
**/
VOID
EFIAPI
CpuDeadLoop (
VOID
);
/**
Uses as a barrier to stop speculative execution.
Ensures that no later instruction will execute speculatively, until all prior
instructions have completed.
**/
VOID
EFIAPI
SpeculationBarrier (
VOID
);
#if defined (MDE_CPU_IA32) || defined (MDE_CPU_X64)
///
/// IA32 and x64 Specific Functions.
/// Byte packed structure for 16-bit Real Mode EFLAGS.
///
typedef union {
struct {
UINT32 CF:1; ///< Carry Flag.
UINT32 Reserved_0:1; ///< Reserved.
UINT32 PF:1; ///< Parity Flag.
UINT32 Reserved_1:1; ///< Reserved.
UINT32 AF:1; ///< Auxiliary Carry Flag.
UINT32 Reserved_2:1; ///< Reserved.
UINT32 ZF:1; ///< Zero Flag.
UINT32 SF:1; ///< Sign Flag.
UINT32 TF:1; ///< Trap Flag.
UINT32 IF:1; ///< Interrupt Enable Flag.
UINT32 DF:1; ///< Direction Flag.
UINT32 OF:1; ///< Overflow Flag.
UINT32 IOPL:2; ///< I/O Privilege Level.
UINT32 NT:1; ///< Nested Task.
UINT32 Reserved_3:1; ///< Reserved.
} Bits;
UINT16 Uint16;
} IA32_FLAGS16;
///
/// Byte packed structure for EFLAGS/RFLAGS.
/// 32-bits on IA-32.
/// 64-bits on x64. The upper 32-bits on x64 are reserved.
///
typedef union {
struct {
UINT32 CF:1; ///< Carry Flag.
UINT32 Reserved_0:1; ///< Reserved.
UINT32 PF:1; ///< Parity Flag.
UINT32 Reserved_1:1; ///< Reserved.
UINT32 AF:1; ///< Auxiliary Carry Flag.
UINT32 Reserved_2:1; ///< Reserved.
UINT32 ZF:1; ///< Zero Flag.
UINT32 SF:1; ///< Sign Flag.
UINT32 TF:1; ///< Trap Flag.
UINT32 IF:1; ///< Interrupt Enable Flag.
UINT32 DF:1; ///< Direction Flag.
UINT32 OF:1; ///< Overflow Flag.
UINT32 IOPL:2; ///< I/O Privilege Level.
UINT32 NT:1; ///< Nested Task.
UINT32 Reserved_3:1; ///< Reserved.
UINT32 RF:1; ///< Resume Flag.
UINT32 VM:1; ///< Virtual 8086 Mode.
UINT32 AC:1; ///< Alignment Check.
UINT32 VIF:1; ///< Virtual Interrupt Flag.
UINT32 VIP:1; ///< Virtual Interrupt Pending.
UINT32 ID:1; ///< ID Flag.
UINT32 Reserved_4:10; ///< Reserved.
} Bits;
UINTN UintN;
} IA32_EFLAGS32;
///
/// Byte packed structure for Control Register 0 (CR0).
/// 32-bits on IA-32.
/// 64-bits on x64. The upper 32-bits on x64 are reserved.
///
typedef union {
struct {
UINT32 PE:1; ///< Protection Enable.
UINT32 MP:1; ///< Monitor Coprocessor.
UINT32 EM:1; ///< Emulation.
UINT32 TS:1; ///< Task Switched.
UINT32 ET:1; ///< Extension Type.
UINT32 NE:1; ///< Numeric Error.
UINT32 Reserved_0:10; ///< Reserved.
UINT32 WP:1; ///< Write Protect.
UINT32 Reserved_1:1; ///< Reserved.
UINT32 AM:1; ///< Alignment Mask.
UINT32 Reserved_2:10; ///< Reserved.
UINT32 NW:1; ///< Mot Write-through.
UINT32 CD:1; ///< Cache Disable.
UINT32 PG:1; ///< Paging.
} Bits;
UINTN UintN;
} IA32_CR0;
///
/// Byte packed structure for Control Register 4 (CR4).
/// 32-bits on IA-32.
/// 64-bits on x64. The upper 32-bits on x64 are reserved.
///
typedef union {
struct {
UINT32 VME:1; ///< Virtual-8086 Mode Extensions.
UINT32 PVI:1; ///< Protected-Mode Virtual Interrupts.
UINT32 TSD:1; ///< Time Stamp Disable.
UINT32 DE:1; ///< Debugging Extensions.
UINT32 PSE:1; ///< Page Size Extensions.
UINT32 PAE:1; ///< Physical Address Extension.
UINT32 MCE:1; ///< Machine Check Enable.
UINT32 PGE:1; ///< Page Global Enable.
UINT32 PCE:1; ///< Performance Monitoring Counter
///< Enable.
UINT32 OSFXSR:1; ///< Operating System Support for
///< FXSAVE and FXRSTOR instructions
UINT32 OSXMMEXCPT:1; ///< Operating System Support for
///< Unmasked SIMD Floating Point
///< Exceptions.
UINT32 UMIP:1; ///< User-Mode Instruction Prevention.
UINT32 LA57:1; ///< Linear Address 57bit.
UINT32 VMXE:1; ///< VMX Enable.
UINT32 SMXE:1; ///< SMX Enable.
UINT32 Reserved_3:1; ///< Reserved.
UINT32 FSGSBASE:1; ///< FSGSBASE Enable.
UINT32 PCIDE:1; ///< PCID Enable.
UINT32 OSXSAVE:1; ///< XSAVE and Processor Extended States Enable.
UINT32 Reserved_4:1; ///< Reserved.
UINT32 SMEP:1; ///< SMEP Enable.
UINT32 SMAP:1; ///< SMAP Enable.
UINT32 PKE:1; ///< Protection-Key Enable.
UINT32 Reserved_5:9; ///< Reserved.
} Bits;
UINTN UintN;
} IA32_CR4;
///
/// Byte packed structure for a segment descriptor in a GDT/LDT.
///
typedef union {
struct {
UINT32 LimitLow:16;
UINT32 BaseLow:16;
UINT32 BaseMid:8;
UINT32 Type:4;
UINT32 S:1;
UINT32 DPL:2;
UINT32 P:1;
UINT32 LimitHigh:4;
UINT32 AVL:1;
UINT32 L:1;
UINT32 DB:1;
UINT32 G:1;
UINT32 BaseHigh:8;
} Bits;
UINT64 Uint64;
} IA32_SEGMENT_DESCRIPTOR;
///
/// Byte packed structure for an IDTR, GDTR, LDTR descriptor.
///
#pragma pack (1)
typedef struct {
UINT16 Limit;
UINTN Base;
} IA32_DESCRIPTOR;
#pragma pack ()
#define IA32_IDT_GATE_TYPE_TASK 0x85
#define IA32_IDT_GATE_TYPE_INTERRUPT_16 0x86
#define IA32_IDT_GATE_TYPE_TRAP_16 0x87
#define IA32_IDT_GATE_TYPE_INTERRUPT_32 0x8E
#define IA32_IDT_GATE_TYPE_TRAP_32 0x8F
#define IA32_GDT_TYPE_TSS 0x9
#define IA32_GDT_ALIGNMENT 8
#if defined (MDE_CPU_IA32)
///
/// Byte packed structure for an IA-32 Interrupt Gate Descriptor.
///
typedef union {
struct {
UINT32 OffsetLow:16; ///< Offset bits 15..0.
UINT32 Selector:16; ///< Selector.
UINT32 Reserved_0:8; ///< Reserved.
UINT32 GateType:8; ///< Gate Type. See #defines above.
UINT32 OffsetHigh:16; ///< Offset bits 31..16.
} Bits;
UINT64 Uint64;
} IA32_IDT_GATE_DESCRIPTOR;
#pragma pack (1)
//
// IA32 Task-State Segment Definition
//
typedef struct {
UINT16 PreviousTaskLink;
UINT16 Reserved_2;
UINT32 ESP0;
UINT16 SS0;
UINT16 Reserved_10;
UINT32 ESP1;
UINT16 SS1;
UINT16 Reserved_18;
UINT32 ESP2;
UINT16 SS2;
UINT16 Reserved_26;
UINT32 CR3;
UINT32 EIP;
UINT32 EFLAGS;
UINT32 EAX;
UINT32 ECX;
UINT32 EDX;
UINT32 EBX;
UINT32 ESP;
UINT32 EBP;
UINT32 ESI;
UINT32 EDI;
UINT16 ES;
UINT16 Reserved_74;
UINT16 CS;
UINT16 Reserved_78;
UINT16 SS;
UINT16 Reserved_82;
UINT16 DS;
UINT16 Reserved_86;
UINT16 FS;
UINT16 Reserved_90;
UINT16 GS;
UINT16 Reserved_94;
UINT16 LDTSegmentSelector;
UINT16 Reserved_98;
UINT16 T;
UINT16 IOMapBaseAddress;
} IA32_TASK_STATE_SEGMENT;
typedef union {
struct {
UINT32 LimitLow:16; ///< Segment Limit 15..00
UINT32 BaseLow:16; ///< Base Address 15..00
UINT32 BaseMid:8; ///< Base Address 23..16
UINT32 Type:4; ///< Type (1 0 B 1)
UINT32 Reserved_43:1; ///< 0
UINT32 DPL:2; ///< Descriptor Privilege Level
UINT32 P:1; ///< Segment Present
UINT32 LimitHigh:4; ///< Segment Limit 19..16
UINT32 AVL:1; ///< Available for use by system software
UINT32 Reserved_52:2; ///< 0 0
UINT32 G:1; ///< Granularity
UINT32 BaseHigh:8; ///< Base Address 31..24
} Bits;
UINT64 Uint64;
} IA32_TSS_DESCRIPTOR;
#pragma pack ()
#endif // defined (MDE_CPU_IA32)
#if defined (MDE_CPU_X64)
///
/// Byte packed structure for an x64 Interrupt Gate Descriptor.
///
typedef union {
struct {
UINT32 OffsetLow:16; ///< Offset bits 15..0.
UINT32 Selector:16; ///< Selector.
UINT32 Reserved_0:8; ///< Reserved.
UINT32 GateType:8; ///< Gate Type. See #defines above.
UINT32 OffsetHigh:16; ///< Offset bits 31..16.
UINT32 OffsetUpper:32; ///< Offset bits 63..32.
UINT32 Reserved_1:32; ///< Reserved.
} Bits;
struct {
UINT64 Uint64;
UINT64 Uint64_1;
} Uint128;
} IA32_IDT_GATE_DESCRIPTOR;
#pragma pack (1)
//
// IA32 Task-State Segment Definition
//
typedef struct {
UINT32 Reserved_0;
UINT64 RSP0;
UINT64 RSP1;
UINT64 RSP2;
UINT64 Reserved_28;
UINT64 IST[7];
UINT64 Reserved_92;
UINT16 Reserved_100;
UINT16 IOMapBaseAddress;
} IA32_TASK_STATE_SEGMENT;
typedef union {
struct {
UINT32 LimitLow:16; ///< Segment Limit 15..00
UINT32 BaseLow:16; ///< Base Address 15..00
UINT32 BaseMidl:8; ///< Base Address 23..16
UINT32 Type:4; ///< Type (1 0 B 1)
UINT32 Reserved_43:1; ///< 0
UINT32 DPL:2; ///< Descriptor Privilege Level
UINT32 P:1; ///< Segment Present
UINT32 LimitHigh:4; ///< Segment Limit 19..16
UINT32 AVL:1; ///< Available for use by system software
UINT32 Reserved_52:2; ///< 0 0
UINT32 G:1; ///< Granularity
UINT32 BaseMidh:8; ///< Base Address 31..24
UINT32 BaseHigh:32; ///< Base Address 63..32
UINT32 Reserved_96:32; ///< Reserved
} Bits;
struct {
UINT64 Uint64;
UINT64 Uint64_1;
} Uint128;
} IA32_TSS_DESCRIPTOR;
#pragma pack ()
#endif // defined (MDE_CPU_X64)
///
/// Byte packed structure for an FP/SSE/SSE2 context.
///
typedef struct {
UINT8 Buffer[512];
} IA32_FX_BUFFER;
///
/// Structures for the 16-bit real mode thunks.
///
typedef struct {
UINT32 Reserved1;
UINT32 Reserved2;
UINT32 Reserved3;
UINT32 Reserved4;
UINT8 BL;
UINT8 BH;
UINT16 Reserved5;
UINT8 DL;
UINT8 DH;
UINT16 Reserved6;
UINT8 CL;
UINT8 CH;
UINT16 Reserved7;
UINT8 AL;
UINT8 AH;
UINT16 Reserved8;
} IA32_BYTE_REGS;
typedef struct {
UINT16 DI;
UINT16 Reserved1;
UINT16 SI;
UINT16 Reserved2;
UINT16 BP;
UINT16 Reserved3;
UINT16 SP;
UINT16 Reserved4;
UINT16 BX;
UINT16 Reserved5;
UINT16 DX;
UINT16 Reserved6;
UINT16 CX;
UINT16 Reserved7;
UINT16 AX;
UINT16 Reserved8;
} IA32_WORD_REGS;
typedef struct {
UINT32 EDI;
UINT32 ESI;
UINT32 EBP;
UINT32 ESP;
UINT32 EBX;
UINT32 EDX;
UINT32 ECX;
UINT32 EAX;
UINT16 DS;
UINT16 ES;
UINT16 FS;
UINT16 GS;
IA32_EFLAGS32 EFLAGS;
UINT32 Eip;
UINT16 CS;
UINT16 SS;
} IA32_DWORD_REGS;
typedef union {
IA32_DWORD_REGS E;
IA32_WORD_REGS X;
IA32_BYTE_REGS H;
} IA32_REGISTER_SET;
///
/// Byte packed structure for an 16-bit real mode thunks.
///
typedef struct {
IA32_REGISTER_SET *RealModeState;
VOID *RealModeBuffer;
UINT32 RealModeBufferSize;
UINT32 ThunkAttributes;
} THUNK_CONTEXT;
#define THUNK_ATTRIBUTE_BIG_REAL_MODE 0x00000001
#define THUNK_ATTRIBUTE_DISABLE_A20_MASK_INT_15 0x00000002
#define THUNK_ATTRIBUTE_DISABLE_A20_MASK_KBD_CTRL 0x00000004
///
/// Type definition for representing labels in NASM source code that allow for
/// the patching of immediate operands of IA32 and X64 instructions.
///
/// While the type is technically defined as a function type (note: not a
/// pointer-to-function type), such labels in NASM source code never stand for
/// actual functions, and identifiers declared with this function type should
/// never be called. This is also why the EFIAPI calling convention specifier
/// is missing from the typedef, and why the typedef does not follow the usual
/// edk2 coding style for function (or pointer-to-function) typedefs. The VOID
/// return type and the VOID argument list are merely artifacts.
///
typedef VOID (X86_ASSEMBLY_PATCH_LABEL) (VOID);
/**
Retrieves CPUID information.
Executes the CPUID instruction with EAX set to the value specified by Index.
This function always returns Index.
If Eax is not NULL, then the value of EAX after CPUID is returned in Eax.
If Ebx is not NULL, then the value of EBX after CPUID is returned in Ebx.
If Ecx is not NULL, then the value of ECX after CPUID is returned in Ecx.
If Edx is not NULL, then the value of EDX after CPUID is returned in Edx.
This function is only available on IA-32 and x64.
@param Index The 32-bit value to load into EAX prior to invoking the CPUID
instruction.
@param Eax The pointer to the 32-bit EAX value returned by the CPUID
instruction. This is an optional parameter that may be NULL.
@param Ebx The pointer to the 32-bit EBX value returned by the CPUID
instruction. This is an optional parameter that may be NULL.
@param Ecx The pointer to the 32-bit ECX value returned by the CPUID
instruction. This is an optional parameter that may be NULL.
@param Edx The pointer to the 32-bit EDX value returned by the CPUID
instruction. This is an optional parameter that may be NULL.
@return Index.
**/
UINT32
EFIAPI
AsmCpuid (
IN UINT32 Index,
OUT UINT32 *Eax, OPTIONAL
OUT UINT32 *Ebx, OPTIONAL
OUT UINT32 *Ecx, OPTIONAL
OUT UINT32 *Edx OPTIONAL
);
/**
Retrieves CPUID information using an extended leaf identifier.
Executes the CPUID instruction with EAX set to the value specified by Index
and ECX set to the value specified by SubIndex. This function always returns
Index. This function is only available on IA-32 and x64.
If Eax is not NULL, then the value of EAX after CPUID is returned in Eax.
If Ebx is not NULL, then the value of EBX after CPUID is returned in Ebx.
If Ecx is not NULL, then the value of ECX after CPUID is returned in Ecx.
If Edx is not NULL, then the value of EDX after CPUID is returned in Edx.
@param Index The 32-bit value to load into EAX prior to invoking the
CPUID instruction.
@param SubIndex The 32-bit value to load into ECX prior to invoking the
CPUID instruction.
@param Eax The pointer to the 32-bit EAX value returned by the CPUID
instruction. This is an optional parameter that may be
NULL.
@param Ebx The pointer to the 32-bit EBX value returned by the CPUID
instruction. This is an optional parameter that may be
NULL.
@param Ecx The pointer to the 32-bit ECX value returned by the CPUID
instruction. This is an optional parameter that may be
NULL.
@param Edx The pointer to the 32-bit EDX value returned by the CPUID
instruction. This is an optional parameter that may be
NULL.
@return Index.
**/
UINT32
EFIAPI
AsmCpuidEx (
IN UINT32 Index,
IN UINT32 SubIndex,
OUT UINT32 *Eax, OPTIONAL
OUT UINT32 *Ebx, OPTIONAL
OUT UINT32 *Ecx, OPTIONAL
OUT UINT32 *Edx OPTIONAL
);
/**
Set CD bit and clear NW bit of CR0 followed by a WBINVD.
Disables the caches by setting the CD bit of CR0 to 1, clearing the NW bit of CR0 to 0,
and executing a WBINVD instruction. This function is only available on IA-32 and x64.
**/
VOID
EFIAPI
AsmDisableCache (
VOID
);
/**
Perform a WBINVD and clear both the CD and NW bits of CR0.
Enables the caches by executing a WBINVD instruction and then clear both the CD and NW
bits of CR0 to 0. This function is only available on IA-32 and x64.
**/
VOID
EFIAPI
AsmEnableCache (
VOID
);
/**
Returns the lower 32-bits of a Machine Specific Register(MSR).
Reads and returns the lower 32-bits of the MSR specified by Index.
No parameter checking is performed on Index, and some Index values may cause
CPU exceptions. The caller must either guarantee that Index is valid, or the
caller must set up exception handlers to catch the exceptions. This function
is only available on IA-32 and x64.
@param Index The 32-bit MSR index to read.
@return The lower 32 bits of the MSR identified by Index.
**/
UINT32
EFIAPI
AsmReadMsr32 (
IN UINT32 Index
);
/**
Writes a 32-bit value to a Machine Specific Register(MSR), and returns the value.
The upper 32-bits of the MSR are set to zero.
Writes the 32-bit value specified by Value to the MSR specified by Index. The
upper 32-bits of the MSR write are set to zero. The 32-bit value written to
the MSR is returned. No parameter checking is performed on Index or Value,
and some of these may cause CPU exceptions. The caller must either guarantee
that Index and Value are valid, or the caller must establish proper exception
handlers. This function is only available on IA-32 and x64.
@param Index The 32-bit MSR index to write.
@param Value The 32-bit value to write to the MSR.
@return Value
**/
UINT32
EFIAPI
AsmWriteMsr32 (
IN UINT32 Index,
IN UINT32 Value
);
/**
Reads a 64-bit MSR, performs a bitwise OR on the lower 32-bits, and
writes the result back to the 64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise OR
between the lower 32-bits of the read result and the value specified by
OrData, and writes the result to the 64-bit MSR specified by Index. The lower
32-bits of the value written to the MSR is returned. No parameter checking is
performed on Index or OrData, and some of these may cause CPU exceptions. The
caller must either guarantee that Index and OrData are valid, or the caller
must establish proper exception handlers. This function is only available on
IA-32 and x64.
@param Index The 32-bit MSR index to write.
@param OrData The value to OR with the read value from the MSR.
@return The lower 32-bit value written to the MSR.
**/
UINT32
EFIAPI
AsmMsrOr32 (
IN UINT32 Index,
IN UINT32 OrData
);
/**
Reads a 64-bit MSR, performs a bitwise AND on the lower 32-bits, and writes
the result back to the 64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise AND between the
lower 32-bits of the read result and the value specified by AndData, and
writes the result to the 64-bit MSR specified by Index. The lower 32-bits of
the value written to the MSR is returned. No parameter checking is performed
on Index or AndData, and some of these may cause CPU exceptions. The caller
must either guarantee that Index and AndData are valid, or the caller must
establish proper exception handlers. This function is only available on IA-32
and x64.
@param Index The 32-bit MSR index to write.
@param AndData The value to AND with the read value from the MSR.
@return The lower 32-bit value written to the MSR.
**/
UINT32
EFIAPI
AsmMsrAnd32 (
IN UINT32 Index,
IN UINT32 AndData
);
/**
Reads a 64-bit MSR, performs a bitwise AND followed by a bitwise OR
on the lower 32-bits, and writes the result back to the 64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise AND between the
lower 32-bits of the read result and the value specified by AndData
preserving the upper 32-bits, performs a bitwise OR between the
result of the AND operation and the value specified by OrData, and writes the
result to the 64-bit MSR specified by Address. The lower 32-bits of the value
written to the MSR is returned. No parameter checking is performed on Index,
AndData, or OrData, and some of these may cause CPU exceptions. The caller
must either guarantee that Index, AndData, and OrData are valid, or the
caller must establish proper exception handlers. This function is only
available on IA-32 and x64.
@param Index The 32-bit MSR index to write.
@param AndData The value to AND with the read value from the MSR.
@param OrData The value to OR with the result of the AND operation.
@return The lower 32-bit value written to the MSR.
**/
UINT32
EFIAPI
AsmMsrAndThenOr32 (
IN UINT32 Index,
IN UINT32 AndData,
IN UINT32 OrData
);
/**
Reads a bit field of an MSR.
Reads the bit field in the lower 32-bits of a 64-bit MSR. The bit field is
specified by the StartBit and the EndBit. The value of the bit field is
returned. The caller must either guarantee that Index is valid, or the caller
must set up exception handlers to catch the exceptions. This function is only
available on IA-32 and x64.
If StartBit is greater than 31, then ASSERT().
If EndBit is greater than 31, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
@param Index The 32-bit MSR index to read.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..31.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..31.
@return The bit field read from the MSR.
**/
UINT32
EFIAPI
AsmMsrBitFieldRead32 (
IN UINT32 Index,
IN UINTN StartBit,
IN UINTN EndBit
);
/**
Writes a bit field to an MSR.
Writes Value to a bit field in the lower 32-bits of a 64-bit MSR. The bit
field is specified by the StartBit and the EndBit. All other bits in the
destination MSR are preserved. The lower 32-bits of the MSR written is
returned. The caller must either guarantee that Index and the data written
is valid, or the caller must set up exception handlers to catch the exceptions.
This function is only available on IA-32 and x64.
If StartBit is greater than 31, then ASSERT().
If EndBit is greater than 31, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If Value is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Index The 32-bit MSR index to write.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..31.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..31.
@param Value New value of the bit field.
@return The lower 32-bit of the value written to the MSR.
**/
UINT32
EFIAPI
AsmMsrBitFieldWrite32 (
IN UINT32 Index,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT32 Value
);
/**
Reads a bit field in a 64-bit MSR, performs a bitwise OR, and writes the
result back to the bit field in the 64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise OR
between the read result and the value specified by OrData, and writes the
result to the 64-bit MSR specified by Index. The lower 32-bits of the value
written to the MSR are returned. Extra left bits in OrData are stripped. The
caller must either guarantee that Index and the data written is valid, or
the caller must set up exception handlers to catch the exceptions. This
function is only available on IA-32 and x64.
If StartBit is greater than 31, then ASSERT().
If EndBit is greater than 31, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Index The 32-bit MSR index to write.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..31.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..31.
@param OrData The value to OR with the read value from the MSR.
@return The lower 32-bit of the value written to the MSR.
**/
UINT32
EFIAPI
AsmMsrBitFieldOr32 (
IN UINT32 Index,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT32 OrData
);
/**
Reads a bit field in a 64-bit MSR, performs a bitwise AND, and writes the
result back to the bit field in the 64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise AND between the
read result and the value specified by AndData, and writes the result to the
64-bit MSR specified by Index. The lower 32-bits of the value written to the
MSR are returned. Extra left bits in AndData are stripped. The caller must
either guarantee that Index and the data written is valid, or the caller must
set up exception handlers to catch the exceptions. This function is only
available on IA-32 and x64.
If StartBit is greater than 31, then ASSERT().
If EndBit is greater than 31, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Index The 32-bit MSR index to write.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..31.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..31.
@param AndData The value to AND with the read value from the MSR.
@return The lower 32-bit of the value written to the MSR.
**/
UINT32
EFIAPI
AsmMsrBitFieldAnd32 (
IN UINT32 Index,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT32 AndData
);
/**
Reads a bit field in a 64-bit MSR, performs a bitwise AND followed by a
bitwise OR, and writes the result back to the bit field in the
64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise AND followed by a
bitwise OR between the read result and the value specified by
AndData, and writes the result to the 64-bit MSR specified by Index. The
lower 32-bits of the value written to the MSR are returned. Extra left bits
in both AndData and OrData are stripped. The caller must either guarantee
that Index and the data written is valid, or the caller must set up exception
handlers to catch the exceptions. This function is only available on IA-32
and x64.
If StartBit is greater than 31, then ASSERT().
If EndBit is greater than 31, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Index The 32-bit MSR index to write.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..31.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..31.
@param AndData The value to AND with the read value from the MSR.
@param OrData The value to OR with the result of the AND operation.
@return The lower 32-bit of the value written to the MSR.
**/
UINT32
EFIAPI
AsmMsrBitFieldAndThenOr32 (
IN UINT32 Index,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT32 AndData,
IN UINT32 OrData
);
/**
Returns a 64-bit Machine Specific Register(MSR).
Reads and returns the 64-bit MSR specified by Index. No parameter checking is
performed on Index, and some Index values may cause CPU exceptions. The
caller must either guarantee that Index is valid, or the caller must set up
exception handlers to catch the exceptions. This function is only available
on IA-32 and x64.
@param Index The 32-bit MSR index to read.
@return The value of the MSR identified by Index.
**/
UINT64
EFIAPI
AsmReadMsr64 (
IN UINT32 Index
);
/**
Writes a 64-bit value to a Machine Specific Register(MSR), and returns the
value.
Writes the 64-bit value specified by Value to the MSR specified by Index. The
64-bit value written to the MSR is returned. No parameter checking is
performed on Index or Value, and some of these may cause CPU exceptions. The
caller must either guarantee that Index and Value are valid, or the caller
must establish proper exception handlers. This function is only available on
IA-32 and x64.
@param Index The 32-bit MSR index to write.
@param Value The 64-bit value to write to the MSR.
@return Value
**/
UINT64
EFIAPI
AsmWriteMsr64 (
IN UINT32 Index,
IN UINT64 Value
);
/**
Reads a 64-bit MSR, performs a bitwise OR, and writes the result
back to the 64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise OR
between the read result and the value specified by OrData, and writes the
result to the 64-bit MSR specified by Index. The value written to the MSR is
returned. No parameter checking is performed on Index or OrData, and some of
these may cause CPU exceptions. The caller must either guarantee that Index
and OrData are valid, or the caller must establish proper exception handlers.
This function is only available on IA-32 and x64.
@param Index The 32-bit MSR index to write.
@param OrData The value to OR with the read value from the MSR.
@return The value written back to the MSR.
**/
UINT64
EFIAPI
AsmMsrOr64 (
IN UINT32 Index,
IN UINT64 OrData
);
/**
Reads a 64-bit MSR, performs a bitwise AND, and writes the result back to the
64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise AND between the
read result and the value specified by OrData, and writes the result to the
64-bit MSR specified by Index. The value written to the MSR is returned. No
parameter checking is performed on Index or OrData, and some of these may
cause CPU exceptions. The caller must either guarantee that Index and OrData
are valid, or the caller must establish proper exception handlers. This
function is only available on IA-32 and x64.
@param Index The 32-bit MSR index to write.
@param AndData The value to AND with the read value from the MSR.
@return The value written back to the MSR.
**/
UINT64
EFIAPI
AsmMsrAnd64 (
IN UINT32 Index,
IN UINT64 AndData
);
/**
Reads a 64-bit MSR, performs a bitwise AND followed by a bitwise
OR, and writes the result back to the 64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise AND between read
result and the value specified by AndData, performs a bitwise OR
between the result of the AND operation and the value specified by OrData,
and writes the result to the 64-bit MSR specified by Index. The value written
to the MSR is returned. No parameter checking is performed on Index, AndData,
or OrData, and some of these may cause CPU exceptions. The caller must either
guarantee that Index, AndData, and OrData are valid, or the caller must
establish proper exception handlers. This function is only available on IA-32
and x64.
@param Index The 32-bit MSR index to write.
@param AndData The value to AND with the read value from the MSR.
@param OrData The value to OR with the result of the AND operation.
@return The value written back to the MSR.
**/
UINT64
EFIAPI
AsmMsrAndThenOr64 (
IN UINT32 Index,
IN UINT64 AndData,
IN UINT64 OrData
);
/**
Reads a bit field of an MSR.
Reads the bit field in the 64-bit MSR. The bit field is specified by the
StartBit and the EndBit. The value of the bit field is returned. The caller
must either guarantee that Index is valid, or the caller must set up
exception handlers to catch the exceptions. This function is only available
on IA-32 and x64.
If StartBit is greater than 63, then ASSERT().
If EndBit is greater than 63, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
@param Index The 32-bit MSR index to read.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..63.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..63.
@return The value read from the MSR.
**/
UINT64
EFIAPI
AsmMsrBitFieldRead64 (
IN UINT32 Index,
IN UINTN StartBit,
IN UINTN EndBit
);
/**
Writes a bit field to an MSR.
Writes Value to a bit field in a 64-bit MSR. The bit field is specified by
the StartBit and the EndBit. All other bits in the destination MSR are
preserved. The MSR written is returned. The caller must either guarantee
that Index and the data written is valid, or the caller must set up exception
handlers to catch the exceptions. This function is only available on IA-32 and x64.
If StartBit is greater than 63, then ASSERT().
If EndBit is greater than 63, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If Value is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Index The 32-bit MSR index to write.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..63.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..63.
@param Value New value of the bit field.
@return The value written back to the MSR.
**/
UINT64
EFIAPI
AsmMsrBitFieldWrite64 (
IN UINT32 Index,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT64 Value
);
/**
Reads a bit field in a 64-bit MSR, performs a bitwise OR, and
writes the result back to the bit field in the 64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise OR
between the read result and the value specified by OrData, and writes the
result to the 64-bit MSR specified by Index. The value written to the MSR is
returned. Extra left bits in OrData are stripped. The caller must either
guarantee that Index and the data written is valid, or the caller must set up
exception handlers to catch the exceptions. This function is only available
on IA-32 and x64.
If StartBit is greater than 63, then ASSERT().
If EndBit is greater than 63, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Index The 32-bit MSR index to write.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..63.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..63.
@param OrData The value to OR with the read value from the bit field.
@return The value written back to the MSR.
**/
UINT64
EFIAPI
AsmMsrBitFieldOr64 (
IN UINT32 Index,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT64 OrData
);
/**
Reads a bit field in a 64-bit MSR, performs a bitwise AND, and writes the
result back to the bit field in the 64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise AND between the
read result and the value specified by AndData, and writes the result to the
64-bit MSR specified by Index. The value written to the MSR is returned.
Extra left bits in AndData are stripped. The caller must either guarantee
that Index and the data written is valid, or the caller must set up exception
handlers to catch the exceptions. This function is only available on IA-32
and x64.
If StartBit is greater than 63, then ASSERT().
If EndBit is greater than 63, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Index The 32-bit MSR index to write.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..63.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..63.
@param AndData The value to AND with the read value from the bit field.
@return The value written back to the MSR.
**/
UINT64
EFIAPI
AsmMsrBitFieldAnd64 (
IN UINT32 Index,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT64 AndData
);
/**
Reads a bit field in a 64-bit MSR, performs a bitwise AND followed by a
bitwise OR, and writes the result back to the bit field in the
64-bit MSR.
Reads the 64-bit MSR specified by Index, performs a bitwise AND followed by
a bitwise OR between the read result and the value specified by
AndData, and writes the result to the 64-bit MSR specified by Index. The
value written to the MSR is returned. Extra left bits in both AndData and
OrData are stripped. The caller must either guarantee that Index and the data
written is valid, or the caller must set up exception handlers to catch the
exceptions. This function is only available on IA-32 and x64.
If StartBit is greater than 63, then ASSERT().
If EndBit is greater than 63, then ASSERT().
If EndBit is less than StartBit, then ASSERT().
If AndData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
If OrData is larger than the bitmask value range specified by StartBit and EndBit, then ASSERT().
@param Index The 32-bit MSR index to write.
@param StartBit The ordinal of the least significant bit in the bit field.
Range 0..63.
@param EndBit The ordinal of the most significant bit in the bit field.
Range 0..63.
@param AndData The value to AND with the read value from the bit field.
@param OrData The value to OR with the result of the AND operation.
@return The value written back to the MSR.
**/
UINT64
EFIAPI
AsmMsrBitFieldAndThenOr64 (
IN UINT32 Index,
IN UINTN StartBit,
IN UINTN EndBit,
IN UINT64 AndData,
IN UINT64 OrData
);
/**
Reads the current value of the EFLAGS register.
Reads and returns the current value of the EFLAGS register. This function is
only available on IA-32 and x64. This returns a 32-bit value on IA-32 and a
64-bit value on x64.
@return EFLAGS on IA-32 or RFLAGS on x64.
**/
UINTN
EFIAPI
AsmReadEflags (
VOID
);
/**
Reads the current value of the Control Register 0 (CR0).
Reads and returns the current value of CR0. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of the Control Register 0 (CR0).
**/
UINTN
EFIAPI
AsmReadCr0 (
VOID
);
/**
Reads the current value of the Control Register 2 (CR2).
Reads and returns the current value of CR2. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of the Control Register 2 (CR2).
**/
UINTN
EFIAPI
AsmReadCr2 (
VOID
);
/**
Reads the current value of the Control Register 3 (CR3).
Reads and returns the current value of CR3. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of the Control Register 3 (CR3).
**/
UINTN
EFIAPI
AsmReadCr3 (
VOID
);
/**
Reads the current value of the Control Register 4 (CR4).
Reads and returns the current value of CR4. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of the Control Register 4 (CR4).
**/
UINTN
EFIAPI
AsmReadCr4 (
VOID
);
/**
Writes a value to Control Register 0 (CR0).
Writes and returns a new value to CR0. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Cr0 The value to write to CR0.
@return The value written to CR0.
**/
UINTN
EFIAPI
AsmWriteCr0 (
UINTN Cr0
);
/**
Writes a value to Control Register 2 (CR2).
Writes and returns a new value to CR2. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Cr2 The value to write to CR2.
@return The value written to CR2.
**/
UINTN
EFIAPI
AsmWriteCr2 (
UINTN Cr2
);
/**
Writes a value to Control Register 3 (CR3).
Writes and returns a new value to CR3. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Cr3 The value to write to CR3.
@return The value written to CR3.
**/
UINTN
EFIAPI
AsmWriteCr3 (
UINTN Cr3
);
/**
Writes a value to Control Register 4 (CR4).
Writes and returns a new value to CR4. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Cr4 The value to write to CR4.
@return The value written to CR4.
**/
UINTN
EFIAPI
AsmWriteCr4 (
UINTN Cr4
);
/**
Reads the current value of Debug Register 0 (DR0).
Reads and returns the current value of DR0. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of Debug Register 0 (DR0).
**/
UINTN
EFIAPI
AsmReadDr0 (
VOID
);
/**
Reads the current value of Debug Register 1 (DR1).
Reads and returns the current value of DR1. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of Debug Register 1 (DR1).
**/
UINTN
EFIAPI
AsmReadDr1 (
VOID
);
/**
Reads the current value of Debug Register 2 (DR2).
Reads and returns the current value of DR2. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of Debug Register 2 (DR2).
**/
UINTN
EFIAPI
AsmReadDr2 (
VOID
);
/**
Reads the current value of Debug Register 3 (DR3).
Reads and returns the current value of DR3. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of Debug Register 3 (DR3).
**/
UINTN
EFIAPI
AsmReadDr3 (
VOID
);
/**
Reads the current value of Debug Register 4 (DR4).
Reads and returns the current value of DR4. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of Debug Register 4 (DR4).
**/
UINTN
EFIAPI
AsmReadDr4 (
VOID
);
/**
Reads the current value of Debug Register 5 (DR5).
Reads and returns the current value of DR5. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of Debug Register 5 (DR5).
**/
UINTN
EFIAPI
AsmReadDr5 (
VOID
);
/**
Reads the current value of Debug Register 6 (DR6).
Reads and returns the current value of DR6. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of Debug Register 6 (DR6).
**/
UINTN
EFIAPI
AsmReadDr6 (
VOID
);
/**
Reads the current value of Debug Register 7 (DR7).
Reads and returns the current value of DR7. This function is only available
on IA-32 and x64. This returns a 32-bit value on IA-32 and a 64-bit value on
x64.
@return The value of Debug Register 7 (DR7).
**/
UINTN
EFIAPI
AsmReadDr7 (
VOID
);
/**
Writes a value to Debug Register 0 (DR0).
Writes and returns a new value to DR0. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Dr0 The value to write to Dr0.
@return The value written to Debug Register 0 (DR0).
**/
UINTN
EFIAPI
AsmWriteDr0 (
UINTN Dr0
);
/**
Writes a value to Debug Register 1 (DR1).
Writes and returns a new value to DR1. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Dr1 The value to write to Dr1.
@return The value written to Debug Register 1 (DR1).
**/
UINTN
EFIAPI
AsmWriteDr1 (
UINTN Dr1
);
/**
Writes a value to Debug Register 2 (DR2).
Writes and returns a new value to DR2. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Dr2 The value to write to Dr2.
@return The value written to Debug Register 2 (DR2).
**/
UINTN
EFIAPI
AsmWriteDr2 (
UINTN Dr2
);
/**
Writes a value to Debug Register 3 (DR3).
Writes and returns a new value to DR3. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Dr3 The value to write to Dr3.
@return The value written to Debug Register 3 (DR3).
**/
UINTN
EFIAPI
AsmWriteDr3 (
UINTN Dr3
);
/**
Writes a value to Debug Register 4 (DR4).
Writes and returns a new value to DR4. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Dr4 The value to write to Dr4.
@return The value written to Debug Register 4 (DR4).
**/
UINTN
EFIAPI
AsmWriteDr4 (
UINTN Dr4
);
/**
Writes a value to Debug Register 5 (DR5).
Writes and returns a new value to DR5. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Dr5 The value to write to Dr5.
@return The value written to Debug Register 5 (DR5).
**/
UINTN
EFIAPI
AsmWriteDr5 (
UINTN Dr5
);
/**
Writes a value to Debug Register 6 (DR6).
Writes and returns a new value to DR6. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Dr6 The value to write to Dr6.
@return The value written to Debug Register 6 (DR6).
**/
UINTN
EFIAPI
AsmWriteDr6 (
UINTN Dr6
);
/**
Writes a value to Debug Register 7 (DR7).
Writes and returns a new value to DR7. This function is only available on
IA-32 and x64. This writes a 32-bit value on IA-32 and a 64-bit value on x64.
@param Dr7 The value to write to Dr7.
@return The value written to Debug Register 7 (DR7).
**/
UINTN
EFIAPI
AsmWriteDr7 (
UINTN Dr7
);
/**
Reads the current value of Code Segment Register (CS).
Reads and returns the current value of CS. This function is only available on
IA-32 and x64.
@return The current value of CS.
**/
UINT16
EFIAPI
AsmReadCs (
VOID
);
/**
Reads the current value of Data Segment Register (DS).
Reads and returns the current value of DS. This function is only available on
IA-32 and x64.
@return The current value of DS.
**/
UINT16
EFIAPI
AsmReadDs (
VOID
);
/**
Reads the current value of Extra Segment Register (ES).
Reads and returns the current value of ES. This function is only available on
IA-32 and x64.
@return The current value of ES.
**/
UINT16
EFIAPI
AsmReadEs (
VOID
);
/**
Reads the current value of FS Data Segment Register (FS).
Reads and returns the current value of FS. This function is only available on
IA-32 and x64.
@return The current value of FS.
**/
UINT16
EFIAPI
AsmReadFs (
VOID
);
/**
Reads the current value of GS Data Segment Register (GS).
Reads and returns the current value of GS. This function is only available on
IA-32 and x64.
@return The current value of GS.
**/
UINT16
EFIAPI
AsmReadGs (
VOID
);
/**
Reads the current value of Stack Segment Register (SS).
Reads and returns the current value of SS. This function is only available on
IA-32 and x64.
@return The current value of SS.
**/
UINT16
EFIAPI
AsmReadSs (
VOID
);
/**
Reads the current value of Task Register (TR).
Reads and returns the current value of TR. This function is only available on
IA-32 and x64.
@return The current value of TR.
**/
UINT16
EFIAPI
AsmReadTr (
VOID
);
/**
Reads the current Global Descriptor Table Register(GDTR) descriptor.
Reads and returns the current GDTR descriptor and returns it in Gdtr. This
function is only available on IA-32 and x64.
If Gdtr is NULL, then ASSERT().
@param Gdtr The pointer to a GDTR descriptor.
**/
VOID
EFIAPI
AsmReadGdtr (
OUT IA32_DESCRIPTOR *Gdtr
);
/**
Writes the current Global Descriptor Table Register (GDTR) descriptor.
Writes and the current GDTR descriptor specified by Gdtr. This function is
only available on IA-32 and x64.
If Gdtr is NULL, then ASSERT().
@param Gdtr The pointer to a GDTR descriptor.
**/
VOID
EFIAPI
AsmWriteGdtr (
IN CONST IA32_DESCRIPTOR *Gdtr
);
/**
Reads the current Interrupt Descriptor Table Register(IDTR) descriptor.
Reads and returns the current IDTR descriptor and returns it in Idtr. This
function is only available on IA-32 and x64.
If Idtr is NULL, then ASSERT().
@param Idtr The pointer to a IDTR descriptor.
**/
VOID
EFIAPI
AsmReadIdtr (
OUT IA32_DESCRIPTOR *Idtr
);
/**
Writes the current Interrupt Descriptor Table Register(IDTR) descriptor.
Writes the current IDTR descriptor and returns it in Idtr. This function is
only available on IA-32 and x64.
If Idtr is NULL, then ASSERT().
@param Idtr The pointer to a IDTR descriptor.
**/
VOID
EFIAPI
AsmWriteIdtr (
IN CONST IA32_DESCRIPTOR *Idtr
);
/**
Reads the current Local Descriptor Table Register(LDTR) selector.
Reads and returns the current 16-bit LDTR descriptor value. This function is
only available on IA-32 and x64.
@return The current selector of LDT.
**/
UINT16
EFIAPI
AsmReadLdtr (
VOID
);
/**
Writes the current Local Descriptor Table Register (LDTR) selector.
Writes and the current LDTR descriptor specified by Ldtr. This function is
only available on IA-32 and x64.
@param Ldtr 16-bit LDTR selector value.
**/
VOID
EFIAPI
AsmWriteLdtr (
IN UINT16 Ldtr
);
/**
Save the current floating point/SSE/SSE2 context to a buffer.
Saves the current floating point/SSE/SSE2 state to the buffer specified by
Buffer. Buffer must be aligned on a 16-byte boundary. This function is only
available on IA-32 and x64.
If Buffer is NULL, then ASSERT().
If Buffer is not aligned on a 16-byte boundary, then ASSERT().
@param Buffer The pointer to a buffer to save the floating point/SSE/SSE2 context.
**/
VOID
EFIAPI
AsmFxSave (
OUT IA32_FX_BUFFER *Buffer
);
/**
Restores the current floating point/SSE/SSE2 context from a buffer.
Restores the current floating point/SSE/SSE2 state from the buffer specified
by Buffer. Buffer must be aligned on a 16-byte boundary. This function is
only available on IA-32 and x64.
If Buffer is NULL, then ASSERT().
If Buffer is not aligned on a 16-byte boundary, then ASSERT().
If Buffer was not saved with AsmFxSave(), then ASSERT().
@param Buffer The pointer to a buffer to save the floating point/SSE/SSE2 context.
**/
VOID
EFIAPI
AsmFxRestore (
IN CONST IA32_FX_BUFFER *Buffer
);
/**
Reads the current value of 64-bit MMX Register #0 (MM0).
Reads and returns the current value of MM0. This function is only available
on IA-32 and x64.
@return The current value of MM0.
**/
UINT64
EFIAPI
AsmReadMm0 (
VOID
);
/**
Reads the current value of 64-bit MMX Register #1 (MM1).
Reads and returns the current value of MM1. This function is only available
on IA-32 and x64.
@return The current value of MM1.
**/
UINT64
EFIAPI
AsmReadMm1 (
VOID
);
/**
Reads the current value of 64-bit MMX Register #2 (MM2).
Reads and returns the current value of MM2. This function is only available
on IA-32 and x64.
@return The current value of MM2.
**/
UINT64
EFIAPI
AsmReadMm2 (
VOID
);
/**
Reads the current value of 64-bit MMX Register #3 (MM3).
Reads and returns the current value of MM3. This function is only available
on IA-32 and x64.
@return The current value of MM3.
**/
UINT64
EFIAPI
AsmReadMm3 (
VOID
);
/**
Reads the current value of 64-bit MMX Register #4 (MM4).
Reads and returns the current value of MM4. This function is only available
on IA-32 and x64.
@return The current value of MM4.
**/
UINT64
EFIAPI
AsmReadMm4 (
VOID
);
/**
Reads the current value of 64-bit MMX Register #5 (MM5).
Reads and returns the current value of MM5. This function is only available
on IA-32 and x64.
@return The current value of MM5.
**/
UINT64
EFIAPI
AsmReadMm5 (
VOID
);
/**
Reads the current value of 64-bit MMX Register #6 (MM6).
Reads and returns the current value of MM6. This function is only available
on IA-32 and x64.
@return The current value of MM6.
**/
UINT64
EFIAPI
AsmReadMm6 (
VOID
);
/**
Reads the current value of 64-bit MMX Register #7 (MM7).
Reads and returns the current value of MM7. This function is only available
on IA-32 and x64.
@return The current value of MM7.
**/
UINT64
EFIAPI
AsmReadMm7 (
VOID
);
/**
Writes the current value of 64-bit MMX Register #0 (MM0).
Writes the current value of MM0. This function is only available on IA32 and
x64.
@param Value The 64-bit value to write to MM0.
**/
VOID
EFIAPI
AsmWriteMm0 (
IN UINT64 Value
);
/**
Writes the current value of 64-bit MMX Register #1 (MM1).
Writes the current value of MM1. This function is only available on IA32 and
x64.
@param Value The 64-bit value to write to MM1.
**/
VOID
EFIAPI
AsmWriteMm1 (
IN UINT64 Value
);
/**
Writes the current value of 64-bit MMX Register #2 (MM2).
Writes the current value of MM2. This function is only available on IA32 and
x64.
@param Value The 64-bit value to write to MM2.
**/
VOID
EFIAPI
AsmWriteMm2 (
IN UINT64 Value
);
/**
Writes the current value of 64-bit MMX Register #3 (MM3).
Writes the current value of MM3. This function is only available on IA32 and
x64.
@param Value The 64-bit value to write to MM3.
**/
VOID
EFIAPI
AsmWriteMm3 (
IN UINT64 Value
);
/**
Writes the current value of 64-bit MMX Register #4 (MM4).
Writes the current value of MM4. This function is only available on IA32 and
x64.
@param Value The 64-bit value to write to MM4.
**/
VOID
EFIAPI
AsmWriteMm4 (
IN UINT64 Value
);
/**
Writes the current value of 64-bit MMX Register #5 (MM5).
Writes the current value of MM5. This function is only available on IA32 and
x64.
@param Value The 64-bit value to write to MM5.
**/
VOID
EFIAPI
AsmWriteMm5 (
IN UINT64 Value
);
/**
Writes the current value of 64-bit MMX Register #6 (MM6).
Writes the current value of MM6. This function is only available on IA32 and
x64.
@param Value The 64-bit value to write to MM6.
**/
VOID
EFIAPI
AsmWriteMm6 (
IN UINT64 Value
);
/**
Writes the current value of 64-bit MMX Register #7 (MM7).
Writes the current value of MM7. This function is only available on IA32 and
x64.
@param Value The 64-bit value to write to MM7.
**/
VOID
EFIAPI
AsmWriteMm7 (
IN UINT64 Value
);
/**
Reads the current value of Time Stamp Counter (TSC).
Reads and returns the current value of TSC. This function is only available
on IA-32 and x64.
@return The current value of TSC
**/
UINT64
EFIAPI
AsmReadTsc (
VOID
);
/**
Reads the current value of a Performance Counter (PMC).
Reads and returns the current value of performance counter specified by
Index. This function is only available on IA-32 and x64.
@param Index The 32-bit Performance Counter index to read.
@return The value of the PMC specified by Index.
**/
UINT64
EFIAPI
AsmReadPmc (
IN UINT32 Index
);
/**
Sets up a monitor buffer that is used by AsmMwait().
Executes a MONITOR instruction with the register state specified by Eax, Ecx
and Edx. Returns Eax. This function is only available on IA-32 and x64.
@param Eax The value to load into EAX or RAX before executing the MONITOR
instruction.
@param Ecx The value to load into ECX or RCX before executing the MONITOR
instruction.
@param Edx The value to load into EDX or RDX before executing the MONITOR
instruction.
@return Eax
**/
UINTN
EFIAPI
AsmMonitor (
IN UINTN Eax,
IN UINTN Ecx,
IN UINTN Edx
);
/**
Executes an MWAIT instruction.
Executes an MWAIT instruction with the register state specified by Eax and
Ecx. Returns Eax. This function is only available on IA-32 and x64.
@param Eax The value to load into EAX or RAX before executing the MONITOR
instruction.
@param Ecx The value to load into ECX or RCX before executing the MONITOR
instruction.
@return Eax
**/
UINTN
EFIAPI
AsmMwait (
IN UINTN Eax,
IN UINTN Ecx
);
/**
Executes a WBINVD instruction.
Executes a WBINVD instruction. This function is only available on IA-32 and
x64.
**/
VOID
EFIAPI
AsmWbinvd (
VOID
);
/**
Executes a INVD instruction.
Executes a INVD instruction. This function is only available on IA-32 and
x64.
**/
VOID
EFIAPI
AsmInvd (
VOID
);
/**
Flushes a cache line from all the instruction and data caches within the
coherency domain of the CPU.
Flushed the cache line specified by LinearAddress, and returns LinearAddress.
This function is only available on IA-32 and x64.
@param LinearAddress The address of the cache line to flush. If the CPU is
in a physical addressing mode, then LinearAddress is a
physical address. If the CPU is in a virtual
addressing mode, then LinearAddress is a virtual
address.
@return LinearAddress.
**/
VOID *
EFIAPI
AsmFlushCacheLine (
IN VOID *LinearAddress
);
/**
Enables the 32-bit paging mode on the CPU.
Enables the 32-bit paging mode on the CPU. CR0, CR3, CR4, and the page tables
must be properly initialized prior to calling this service. This function
assumes the current execution mode is 32-bit protected mode. This function is
only available on IA-32. After the 32-bit paging mode is enabled, control is
transferred to the function specified by EntryPoint using the new stack
specified by NewStack and passing in the parameters specified by Context1 and
Context2. Context1 and Context2 are optional and may be NULL. The function
EntryPoint must never return.
If the current execution mode is not 32-bit protected mode, then ASSERT().
If EntryPoint is NULL, then ASSERT().
If NewStack is NULL, then ASSERT().
There are a number of constraints that must be followed before calling this
function:
1) Interrupts must be disabled.
2) The caller must be in 32-bit protected mode with flat descriptors. This
means all descriptors must have a base of 0 and a limit of 4GB.
3) CR0 and CR4 must be compatible with 32-bit protected mode with flat
descriptors.
4) CR3 must point to valid page tables that will be used once the transition
is complete, and those page tables must guarantee that the pages for this
function and the stack are identity mapped.
@param EntryPoint A pointer to function to call with the new stack after
paging is enabled.
@param Context1 A pointer to the context to pass into the EntryPoint
function as the first parameter after paging is enabled.
@param Context2 A pointer to the context to pass into the EntryPoint
function as the second parameter after paging is enabled.
@param NewStack A pointer to the new stack to use for the EntryPoint
function after paging is enabled.
**/
VOID
EFIAPI
AsmEnablePaging32 (
IN SWITCH_STACK_ENTRY_POINT EntryPoint,
IN VOID *Context1, OPTIONAL
IN VOID *Context2, OPTIONAL
IN VOID *NewStack
);
/**
Disables the 32-bit paging mode on the CPU.
Disables the 32-bit paging mode on the CPU and returns to 32-bit protected
mode. This function assumes the current execution mode is 32-paged protected
mode. This function is only available on IA-32. After the 32-bit paging mode
is disabled, control is transferred to the function specified by EntryPoint
using the new stack specified by NewStack and passing in the parameters
specified by Context1 and Context2. Context1 and Context2 are optional and
may be NULL. The function EntryPoint must never return.
If the current execution mode is not 32-bit paged mode, then ASSERT().
If EntryPoint is NULL, then ASSERT().
If NewStack is NULL, then ASSERT().
There are a number of constraints that must be followed before calling this
function:
1) Interrupts must be disabled.
2) The caller must be in 32-bit paged mode.
3) CR0, CR3, and CR4 must be compatible with 32-bit paged mode.
4) CR3 must point to valid page tables that guarantee that the pages for
this function and the stack are identity mapped.
@param EntryPoint A pointer to function to call with the new stack after
paging is disabled.
@param Context1 A pointer to the context to pass into the EntryPoint
function as the first parameter after paging is disabled.
@param Context2 A pointer to the context to pass into the EntryPoint
function as the second parameter after paging is
disabled.
@param NewStack A pointer to the new stack to use for the EntryPoint
function after paging is disabled.
**/
VOID
EFIAPI
AsmDisablePaging32 (
IN SWITCH_STACK_ENTRY_POINT EntryPoint,
IN VOID *Context1, OPTIONAL
IN VOID *Context2, OPTIONAL
IN VOID *NewStack
);
/**
Enables the 64-bit paging mode on the CPU.
Enables the 64-bit paging mode on the CPU. CR0, CR3, CR4, and the page tables
must be properly initialized prior to calling this service. This function
assumes the current execution mode is 32-bit protected mode with flat
descriptors. This function is only available on IA-32. After the 64-bit
paging mode is enabled, control is transferred to the function specified by
EntryPoint using the new stack specified by NewStack and passing in the
parameters specified by Context1 and Context2. Context1 and Context2 are
optional and may be 0. The function EntryPoint must never return.
If the current execution mode is not 32-bit protected mode with flat
descriptors, then ASSERT().
If EntryPoint is 0, then ASSERT().
If NewStack is 0, then ASSERT().
@param Cs The 16-bit selector to load in the CS before EntryPoint
is called. The descriptor in the GDT that this selector
references must be setup for long mode.
@param EntryPoint The 64-bit virtual address of the function to call with
the new stack after paging is enabled.
@param Context1 The 64-bit virtual address of the context to pass into
the EntryPoint function as the first parameter after
paging is enabled.
@param Context2 The 64-bit virtual address of the context to pass into
the EntryPoint function as the second parameter after
paging is enabled.
@param NewStack The 64-bit virtual address of the new stack to use for
the EntryPoint function after paging is enabled.
**/
VOID
EFIAPI
AsmEnablePaging64 (
IN UINT16 Cs,
IN UINT64 EntryPoint,
IN UINT64 Context1, OPTIONAL
IN UINT64 Context2, OPTIONAL
IN UINT64 NewStack
);
/**
Disables the 64-bit paging mode on the CPU.
Disables the 64-bit paging mode on the CPU and returns to 32-bit protected
mode. This function assumes the current execution mode is 64-paging mode.
This function is only available on x64. After the 64-bit paging mode is
disabled, control is transferred to the function specified by EntryPoint
using the new stack specified by NewStack and passing in the parameters
specified by Context1 and Context2. Context1 and Context2 are optional and
may be 0. The function EntryPoint must never return.
If the current execution mode is not 64-bit paged mode, then ASSERT().
If EntryPoint is 0, then ASSERT().
If NewStack is 0, then ASSERT().
@param Cs The 16-bit selector to load in the CS before EntryPoint
is called. The descriptor in the GDT that this selector
references must be setup for 32-bit protected mode.
@param EntryPoint The 64-bit virtual address of the function to call with
the new stack after paging is disabled.
@param Context1 The 64-bit virtual address of the context to pass into
the EntryPoint function as the first parameter after
paging is disabled.
@param Context2 The 64-bit virtual address of the context to pass into
the EntryPoint function as the second parameter after
paging is disabled.
@param NewStack The 64-bit virtual address of the new stack to use for
the EntryPoint function after paging is disabled.
**/
VOID
EFIAPI
AsmDisablePaging64 (
IN UINT16 Cs,
IN UINT32 EntryPoint,
IN UINT32 Context1, OPTIONAL
IN UINT32 Context2, OPTIONAL
IN UINT32 NewStack
);
//
// 16-bit thunking services
//
/**
Retrieves the properties for 16-bit thunk functions.
Computes the size of the buffer and stack below 1MB required to use the
AsmPrepareThunk16(), AsmThunk16() and AsmPrepareAndThunk16() functions. This
buffer size is returned in RealModeBufferSize, and the stack size is returned
in ExtraStackSize. If parameters are passed to the 16-bit real mode code,
then the actual minimum stack size is ExtraStackSize plus the maximum number
of bytes that need to be passed to the 16-bit real mode code.
If RealModeBufferSize is NULL, then ASSERT().
If ExtraStackSize is NULL, then ASSERT().
@param RealModeBufferSize A pointer to the size of the buffer below 1MB
required to use the 16-bit thunk functions.
@param ExtraStackSize A pointer to the extra size of stack below 1MB
that the 16-bit thunk functions require for
temporary storage in the transition to and from
16-bit real mode.
**/
VOID
EFIAPI
AsmGetThunk16Properties (
OUT UINT32 *RealModeBufferSize,
OUT UINT32 *ExtraStackSize
);
/**
Prepares all structures a code required to use AsmThunk16().
Prepares all structures and code required to use AsmThunk16().
This interface is limited to be used in either physical mode or virtual modes with paging enabled where the
virtual to physical mappings for ThunkContext.RealModeBuffer is mapped 1:1.
If ThunkContext is NULL, then ASSERT().
@param ThunkContext A pointer to the context structure that describes the
16-bit real mode code to call.
**/
VOID
EFIAPI
AsmPrepareThunk16 (
IN OUT THUNK_CONTEXT *ThunkContext
);
/**
Transfers control to a 16-bit real mode entry point and returns the results.
Transfers control to a 16-bit real mode entry point and returns the results.
AsmPrepareThunk16() must be called with ThunkContext before this function is used.
This function must be called with interrupts disabled.
The register state from the RealModeState field of ThunkContext is restored just prior
to calling the 16-bit real mode entry point. This includes the EFLAGS field of RealModeState,
which is used to set the interrupt state when a 16-bit real mode entry point is called.
Control is transferred to the 16-bit real mode entry point specified by the CS and Eip fields of RealModeState.
The stack is initialized to the SS and ESP fields of RealModeState. Any parameters passed to
the 16-bit real mode code must be populated by the caller at SS:ESP prior to calling this function.
The 16-bit real mode entry point is invoked with a 16-bit CALL FAR instruction,
so when accessing stack contents, the 16-bit real mode code must account for the 16-bit segment
and 16-bit offset of the return address that were pushed onto the stack. The 16-bit real mode entry
point must exit with a RETF instruction. The register state is captured into RealModeState immediately
after the RETF instruction is executed.
If EFLAGS specifies interrupts enabled, or any of the 16-bit real mode code enables interrupts,
or any of the 16-bit real mode code makes a SW interrupt, then the caller is responsible for making sure
the IDT at address 0 is initialized to handle any HW or SW interrupts that may occur while in 16-bit real mode.
If EFLAGS specifies interrupts enabled, or any of the 16-bit real mode code enables interrupts,
then the caller is responsible for making sure the 8259 PIC is in a state compatible with 16-bit real mode.
This includes the base vectors, the interrupt masks, and the edge/level trigger mode.
If THUNK_ATTRIBUTE_BIG_REAL_MODE is set in the ThunkAttributes field of ThunkContext, then the user code
is invoked in big real mode. Otherwise, the user code is invoked in 16-bit real mode with 64KB segment limits.
If neither THUNK_ATTRIBUTE_DISABLE_A20_MASK_INT_15 nor THUNK_ATTRIBUTE_DISABLE_A20_MASK_KBD_CTRL are set in
ThunkAttributes, then it is assumed that the user code did not enable the A20 mask, and no attempt is made to
disable the A20 mask.
If THUNK_ATTRIBUTE_DISABLE_A20_MASK_INT_15 is set and THUNK_ATTRIBUTE_DISABLE_A20_MASK_KBD_CTRL is clear in
ThunkAttributes, then attempt to use the INT 15 service to disable the A20 mask. If this INT 15 call fails,
then attempt to disable the A20 mask by directly accessing the 8042 keyboard controller I/O ports.
If THUNK_ATTRIBUTE_DISABLE_A20_MASK_INT_15 is clear and THUNK_ATTRIBUTE_DISABLE_A20_MASK_KBD_CTRL is set in
ThunkAttributes, then attempt to disable the A20 mask by directly accessing the 8042 keyboard controller I/O ports.
If ThunkContext is NULL, then ASSERT().
If AsmPrepareThunk16() was not previously called with ThunkContext, then ASSERT().
If both THUNK_ATTRIBUTE_DISABLE_A20_MASK_INT_15 and THUNK_ATTRIBUTE_DISABLE_A20_MASK_KBD_CTRL are set in
ThunkAttributes, then ASSERT().
This interface is limited to be used in either physical mode or virtual modes with paging enabled where the
virtual to physical mappings for ThunkContext.RealModeBuffer are mapped 1:1.
@param ThunkContext A pointer to the context structure that describes the
16-bit real mode code to call.
**/
VOID
EFIAPI
AsmThunk16 (
IN OUT THUNK_CONTEXT *ThunkContext
);
/**
Prepares all structures and code for a 16-bit real mode thunk, transfers
control to a 16-bit real mode entry point, and returns the results.
Prepares all structures and code for a 16-bit real mode thunk, transfers
control to a 16-bit real mode entry point, and returns the results. If the
caller only need to perform a single 16-bit real mode thunk, then this
service should be used. If the caller intends to make more than one 16-bit
real mode thunk, then it is more efficient if AsmPrepareThunk16() is called
once and AsmThunk16() can be called for each 16-bit real mode thunk.
This interface is limited to be used in either physical mode or virtual modes with paging enabled where the
virtual to physical mappings for ThunkContext.RealModeBuffer is mapped 1:1.
See AsmPrepareThunk16() and AsmThunk16() for the detailed description and ASSERT() conditions.
@param ThunkContext A pointer to the context structure that describes the
16-bit real mode code to call.
**/
VOID
EFIAPI
AsmPrepareAndThunk16 (
IN OUT THUNK_CONTEXT *ThunkContext
);
/**
Generates a 16-bit random number through RDRAND instruction.
if Rand is NULL, then ASSERT().
@param[out] Rand Buffer pointer to store the random result.
@retval TRUE RDRAND call was successful.
@retval FALSE Failed attempts to call RDRAND.
**/
BOOLEAN
EFIAPI
AsmRdRand16 (
OUT UINT16 *Rand
);
/**
Generates a 32-bit random number through RDRAND instruction.
if Rand is NULL, then ASSERT().
@param[out] Rand Buffer pointer to store the random result.
@retval TRUE RDRAND call was successful.
@retval FALSE Failed attempts to call RDRAND.
**/
BOOLEAN
EFIAPI
AsmRdRand32 (
OUT UINT32 *Rand
);
/**
Generates a 64-bit random number through RDRAND instruction.
if Rand is NULL, then ASSERT().
@param[out] Rand Buffer pointer to store the random result.
@retval TRUE RDRAND call was successful.
@retval FALSE Failed attempts to call RDRAND.
**/
BOOLEAN
EFIAPI
AsmRdRand64 (
OUT UINT64 *Rand
);
/**
Load given selector into TR register.
@param[in] Selector Task segment selector
**/
VOID
EFIAPI
AsmWriteTr (
IN UINT16 Selector
);
/**
Performs a serializing operation on all load-from-memory instructions that
were issued prior the AsmLfence function.
Executes a LFENCE instruction. This function is only available on IA-32 and x64.
**/
VOID
EFIAPI
AsmLfence (
VOID
);
/**
Patch the immediate operand of an IA32 or X64 instruction such that the byte,
word, dword or qword operand is encoded at the end of the instruction's
binary representation.
This function should be used to update object code that was compiled with
NASM from assembly source code. Example:
NASM source code:
mov eax, strict dword 0 ; the imm32 zero operand will be patched
ASM_PFX(gPatchCr3):
mov cr3, eax
C source code:
X86_ASSEMBLY_PATCH_LABEL gPatchCr3;
PatchInstructionX86 (gPatchCr3, AsmReadCr3 (), 4);
@param[out] InstructionEnd Pointer right past the instruction to patch. The
immediate operand to patch is expected to
comprise the trailing bytes of the instruction.
If InstructionEnd is closer to address 0 than
ValueSize permits, then ASSERT().
@param[in] PatchValue The constant to write to the immediate operand.
The caller is responsible for ensuring that
PatchValue can be represented in the byte, word,
dword or qword operand (as indicated through
ValueSize); otherwise ASSERT().
@param[in] ValueSize The size of the operand in bytes; must be 1, 2,
4, or 8. ASSERT() otherwise.
**/
VOID
EFIAPI
PatchInstructionX86 (
OUT X86_ASSEMBLY_PATCH_LABEL *InstructionEnd,
IN UINT64 PatchValue,
IN UINTN ValueSize
);
#endif // defined (MDE_CPU_IA32) || defined (MDE_CPU_X64)
#endif // !defined (__BASE_LIB__)
diff --git a/sys/contrib/edk2/Include/Uefi/UefiBaseType.h b/sys/contrib/edk2/Include/Uefi/UefiBaseType.h
index 6a2f33039377..6637a28ea6d9 100644
--- a/sys/contrib/edk2/Include/Uefi/UefiBaseType.h
+++ b/sys/contrib/edk2/Include/Uefi/UefiBaseType.h
@@ -1,298 +1,312 @@
/** @file
Defines data types and constants introduced in UEFI.
Copyright (c) 2006 - 2018, Intel Corporation. All rights reserved.
Portions copyright (c) 2011 - 2016, ARM Ltd. All rights reserved.
Copyright (c) 2020, Hewlett Packard Enterprise Development LP. All rights reserved.
SPDX-License-Identifier: BSD-2-Clause-Patent
**/
#ifndef __UEFI_BASETYPE_H__
#define __UEFI_BASETYPE_H__
#include
//
// Basic data type definitions introduced in UEFI.
//
///
/// 128-bit buffer containing a unique identifier value.
///
typedef GUID EFI_GUID;
///
/// Function return status for EFI API.
///
typedef RETURN_STATUS EFI_STATUS;
///
/// A collection of related interfaces.
///
typedef VOID *EFI_HANDLE;
///
/// Handle to an event structure.
///
typedef VOID *EFI_EVENT;
///
/// Task priority level.
///
typedef UINTN EFI_TPL;
///
/// Logical block address.
///
typedef UINT64 EFI_LBA;
///
/// 64-bit physical memory address.
///
typedef UINT64 EFI_PHYSICAL_ADDRESS;
///
/// 64-bit virtual memory address.
///
typedef UINT64 EFI_VIRTUAL_ADDRESS;
///
/// EFI Time Abstraction:
/// Year: 1900 - 9999
/// Month: 1 - 12
/// Day: 1 - 31
/// Hour: 0 - 23
/// Minute: 0 - 59
/// Second: 0 - 59
/// Nanosecond: 0 - 999,999,999
/// TimeZone: -1440 to 1440 or 2047
///
typedef struct {
UINT16 Year;
UINT8 Month;
UINT8 Day;
UINT8 Hour;
UINT8 Minute;
UINT8 Second;
UINT8 Pad1;
UINT32 Nanosecond;
INT16 TimeZone;
UINT8 Daylight;
UINT8 Pad2;
} EFI_TIME;
///
/// 4-byte buffer. An IPv4 internet protocol address.
///
typedef IPv4_ADDRESS EFI_IPv4_ADDRESS;
///
/// 16-byte buffer. An IPv6 internet protocol address.
///
typedef IPv6_ADDRESS EFI_IPv6_ADDRESS;
///
/// 32-byte buffer containing a network Media Access Control address.
///
typedef struct {
UINT8 Addr[32];
} EFI_MAC_ADDRESS;
///
/// 16-byte buffer aligned on a 4-byte boundary.
/// An IPv4 or IPv6 internet protocol address.
///
typedef union {
UINT32 Addr[4];
EFI_IPv4_ADDRESS v4;
EFI_IPv6_ADDRESS v6;
} EFI_IP_ADDRESS;
///
/// Enumeration of EFI_STATUS.
///@{
#define EFI_SUCCESS RETURN_SUCCESS
#define EFI_LOAD_ERROR RETURN_LOAD_ERROR
#define EFI_INVALID_PARAMETER RETURN_INVALID_PARAMETER
#define EFI_UNSUPPORTED RETURN_UNSUPPORTED
#define EFI_BAD_BUFFER_SIZE RETURN_BAD_BUFFER_SIZE
#define EFI_BUFFER_TOO_SMALL RETURN_BUFFER_TOO_SMALL
#define EFI_NOT_READY RETURN_NOT_READY
#define EFI_DEVICE_ERROR RETURN_DEVICE_ERROR
#define EFI_WRITE_PROTECTED RETURN_WRITE_PROTECTED
#define EFI_OUT_OF_RESOURCES RETURN_OUT_OF_RESOURCES
#define EFI_VOLUME_CORRUPTED RETURN_VOLUME_CORRUPTED
#define EFI_VOLUME_FULL RETURN_VOLUME_FULL
#define EFI_NO_MEDIA RETURN_NO_MEDIA
#define EFI_MEDIA_CHANGED RETURN_MEDIA_CHANGED
#define EFI_NOT_FOUND RETURN_NOT_FOUND
#define EFI_ACCESS_DENIED RETURN_ACCESS_DENIED
#define EFI_NO_RESPONSE RETURN_NO_RESPONSE
#define EFI_NO_MAPPING RETURN_NO_MAPPING
#define EFI_TIMEOUT RETURN_TIMEOUT
#define EFI_NOT_STARTED RETURN_NOT_STARTED
#define EFI_ALREADY_STARTED RETURN_ALREADY_STARTED
#define EFI_ABORTED RETURN_ABORTED
#define EFI_ICMP_ERROR RETURN_ICMP_ERROR
#define EFI_TFTP_ERROR RETURN_TFTP_ERROR
#define EFI_PROTOCOL_ERROR RETURN_PROTOCOL_ERROR
#define EFI_INCOMPATIBLE_VERSION RETURN_INCOMPATIBLE_VERSION
#define EFI_SECURITY_VIOLATION RETURN_SECURITY_VIOLATION
#define EFI_CRC_ERROR RETURN_CRC_ERROR
#define EFI_END_OF_MEDIA RETURN_END_OF_MEDIA
#define EFI_END_OF_FILE RETURN_END_OF_FILE
#define EFI_INVALID_LANGUAGE RETURN_INVALID_LANGUAGE
#define EFI_COMPROMISED_DATA RETURN_COMPROMISED_DATA
#define EFI_HTTP_ERROR RETURN_HTTP_ERROR
#define EFI_WARN_UNKNOWN_GLYPH RETURN_WARN_UNKNOWN_GLYPH
#define EFI_WARN_DELETE_FAILURE RETURN_WARN_DELETE_FAILURE
#define EFI_WARN_WRITE_FAILURE RETURN_WARN_WRITE_FAILURE
#define EFI_WARN_BUFFER_TOO_SMALL RETURN_WARN_BUFFER_TOO_SMALL
#define EFI_WARN_STALE_DATA RETURN_WARN_STALE_DATA
#define EFI_WARN_FILE_SYSTEM RETURN_WARN_FILE_SYSTEM
///@}
///
/// Define macro to encode the status code.
///
#define EFIERR(_a) ENCODE_ERROR(_a)
#define EFI_ERROR(A) RETURN_ERROR(A)
///
/// ICMP error definitions
///@{
#define EFI_NETWORK_UNREACHABLE EFIERR(100)
#define EFI_HOST_UNREACHABLE EFIERR(101)
#define EFI_PROTOCOL_UNREACHABLE EFIERR(102)
#define EFI_PORT_UNREACHABLE EFIERR(103)
///@}
///
/// Tcp connection status definitions
///@{
#define EFI_CONNECTION_FIN EFIERR(104)
#define EFI_CONNECTION_RESET EFIERR(105)
#define EFI_CONNECTION_REFUSED EFIERR(106)
///@}
//
// The EFI memory allocation functions work in units of EFI_PAGEs that are
// 4KB. This should in no way be confused with the page size of the processor.
// An EFI_PAGE is just the quanta of memory in EFI.
//
#define EFI_PAGE_SIZE SIZE_4KB
#define EFI_PAGE_MASK 0xFFF
#define EFI_PAGE_SHIFT 12
/**
Macro that converts a size, in bytes, to a number of EFI_PAGESs.
@param Size A size in bytes. This parameter is assumed to be type UINTN.
Passing in a parameter that is larger than UINTN may produce
unexpected results.
@return The number of EFI_PAGESs associated with the number of bytes specified
by Size.
**/
#define EFI_SIZE_TO_PAGES(Size) (((Size) >> EFI_PAGE_SHIFT) + (((Size) & EFI_PAGE_MASK) ? 1 : 0))
/**
Macro that converts a number of EFI_PAGEs to a size in bytes.
@param Pages The number of EFI_PAGES. This parameter is assumed to be
type UINTN. Passing in a parameter that is larger than
UINTN may produce unexpected results.
@return The number of bytes associated with the number of EFI_PAGEs specified
by Pages.
**/
#define EFI_PAGES_TO_SIZE(Pages) ((Pages) << EFI_PAGE_SHIFT)
///
/// PE32+ Machine type for IA32 UEFI images.
///
#define EFI_IMAGE_MACHINE_IA32 0x014C
///
/// PE32+ Machine type for IA64 UEFI images.
///
#define EFI_IMAGE_MACHINE_IA64 0x0200
///
/// PE32+ Machine type for EBC UEFI images.
///
#define EFI_IMAGE_MACHINE_EBC 0x0EBC
///
/// PE32+ Machine type for X64 UEFI images.
///
#define EFI_IMAGE_MACHINE_X64 0x8664
///
/// PE32+ Machine type for ARM mixed ARM and Thumb/Thumb2 images.
///
#define EFI_IMAGE_MACHINE_ARMTHUMB_MIXED 0x01C2
///
/// PE32+ Machine type for AARCH64 A64 images.
///
#define EFI_IMAGE_MACHINE_AARCH64 0xAA64
///
/// PE32+ Machine type for RISC-V 32/64/128
///
#define EFI_IMAGE_MACHINE_RISCV32 0x5032
#define EFI_IMAGE_MACHINE_RISCV64 0x5064
#define EFI_IMAGE_MACHINE_RISCV128 0x5128
+///
+/// PE32+ Machine type for LoongArch 32/64 images.
+///
+#define EFI_IMAGE_MACHINE_LOONGARCH32 0x6232
+#define EFI_IMAGE_MACHINE_LOONGARCH64 0x6264
+
+
#if defined (MDE_CPU_IA32)
#define EFI_IMAGE_MACHINE_TYPE_SUPPORTED(Machine) \
((Machine) == EFI_IMAGE_MACHINE_IA32)
#define EFI_IMAGE_MACHINE_CROSS_TYPE_SUPPORTED(Machine) ((Machine) == EFI_IMAGE_MACHINE_X64)
#elif defined (MDE_CPU_X64)
#define EFI_IMAGE_MACHINE_TYPE_SUPPORTED(Machine) \
((Machine) == EFI_IMAGE_MACHINE_X64)
#define EFI_IMAGE_MACHINE_CROSS_TYPE_SUPPORTED(Machine) ((Machine) == EFI_IMAGE_MACHINE_IA32)
#elif defined (MDE_CPU_ARM)
#define EFI_IMAGE_MACHINE_TYPE_SUPPORTED(Machine) ((Machine) == EFI_IMAGE_MACHINE_ARMTHUMB_MIXED)
#define EFI_IMAGE_MACHINE_CROSS_TYPE_SUPPORTED(Machine) (FALSE)
#elif defined (MDE_CPU_AARCH64)
#define EFI_IMAGE_MACHINE_TYPE_SUPPORTED(Machine) \
((Machine) == EFI_IMAGE_MACHINE_AARCH64)
#define EFI_IMAGE_MACHINE_CROSS_TYPE_SUPPORTED(Machine) (FALSE)
#elif defined (MDE_CPU_RISCV64)
#define EFI_IMAGE_MACHINE_TYPE_SUPPORTED(Machine) \
((Machine) == EFI_IMAGE_MACHINE_RISCV64)
#define EFI_IMAGE_MACHINE_CROSS_TYPE_SUPPORTED(Machine) (FALSE)
+ #elif defined (MDE_CPU_LOONGARCH64)
+
+#define EFI_IMAGE_MACHINE_TYPE_SUPPORTED(Machine) \
+ ((Machine) == EFI_IMAGE_MACHINE_LOONGARCH64)
+
+#define EFI_IMAGE_MACHINE_CROSS_TYPE_SUPPORTED(Machine) (FALSE)
+
#elif defined (MDE_CPU_EBC)
///
/// This is just to make sure you can cross compile with the EBC compiler.
/// It does not make sense to have a PE loader coded in EBC.
///
#define EFI_IMAGE_MACHINE_TYPE_SUPPORTED(Machine) ((Machine) == EFI_IMAGE_MACHINE_EBC)
#define EFI_IMAGE_MACHINE_CROSS_TYPE_SUPPORTED(Machine) (FALSE)
#else
#error Unknown Processor Type
#endif
#endif
diff --git a/sys/contrib/edk2/Include/Uefi/UefiSpec.h b/sys/contrib/edk2/Include/Uefi/UefiSpec.h
index 0e165478d6c3..051834460512 100644
--- a/sys/contrib/edk2/Include/Uefi/UefiSpec.h
+++ b/sys/contrib/edk2/Include/Uefi/UefiSpec.h
@@ -1,2231 +1,2234 @@
/** @file
Include file that supports UEFI.
This include file must contain things defined in the UEFI 2.7 specification.
If a code construct is defined in the UEFI 2.7 specification it must be included
by this include file.
Copyright (c) 2006 - 2019, Intel Corporation. All rights reserved.
Portions Copyright (c) 2020, Hewlett Packard Enterprise Development LP. All rights reserved.
SPDX-License-Identifier: BSD-2-Clause-Patent
**/
#ifndef __UEFI_SPEC_H__
#define __UEFI_SPEC_H__
#include
#include
#include
#include
#include
///
/// Enumeration of EFI memory allocation types.
///
typedef enum {
///
/// Allocate any available range of pages that satisfies the request.
///
AllocateAnyPages,
///
/// Allocate any available range of pages whose uppermost address is less than
/// or equal to a specified maximum address.
///
AllocateMaxAddress,
///
/// Allocate pages at a specified address.
///
AllocateAddress,
///
/// Maximum enumeration value that may be used for bounds checking.
///
MaxAllocateType
} EFI_ALLOCATE_TYPE;
//
// Bit definitions for EFI_TIME.Daylight
//
#define EFI_TIME_ADJUST_DAYLIGHT 0x01
#define EFI_TIME_IN_DAYLIGHT 0x02
///
/// Value definition for EFI_TIME.TimeZone.
///
#define EFI_UNSPECIFIED_TIMEZONE 0x07FF
//
// Memory cacheability attributes
//
#define EFI_MEMORY_UC 0x0000000000000001ULL
#define EFI_MEMORY_WC 0x0000000000000002ULL
#define EFI_MEMORY_WT 0x0000000000000004ULL
#define EFI_MEMORY_WB 0x0000000000000008ULL
#define EFI_MEMORY_UCE 0x0000000000000010ULL
//
// Physical memory protection attributes
//
// Note: UEFI spec 2.5 and following: use EFI_MEMORY_RO as write-protected physical memory
// protection attribute. Also, EFI_MEMORY_WP means cacheability attribute.
//
#define EFI_MEMORY_WP 0x0000000000001000ULL
#define EFI_MEMORY_RP 0x0000000000002000ULL
#define EFI_MEMORY_XP 0x0000000000004000ULL
#define EFI_MEMORY_RO 0x0000000000020000ULL
//
// Physical memory persistence attribute.
// The memory region supports byte-addressable non-volatility.
//
#define EFI_MEMORY_NV 0x0000000000008000ULL
//
// The memory region provides higher reliability relative to other memory in the system.
// If all memory has the same reliability, then this bit is not used.
//
#define EFI_MEMORY_MORE_RELIABLE 0x0000000000010000ULL
//
// Note: UEFI spec 2.8 and following:
//
// Specific-purpose memory (SPM). The memory is earmarked for
// specific purposes such as for specific device drivers or applications.
// The SPM attribute serves as a hint to the OS to avoid allocating this
// memory for core OS data or code that can not be relocated.
//
#define EFI_MEMORY_SP 0x0000000000040000ULL
//
// If this flag is set, the memory region is capable of being
// protected with the CPU?s memory cryptographic
// capabilities. If this flag is clear, the memory region is not
// capable of being protected with the CPU?s memory
// cryptographic capabilities or the CPU does not support CPU
// memory cryptographic capabilities.
//
#define EFI_MEMORY_CPU_CRYPTO 0x0000000000080000ULL
//
// Runtime memory attribute
//
#define EFI_MEMORY_RUNTIME 0x8000000000000000ULL
///
/// Memory descriptor version number.
///
#define EFI_MEMORY_DESCRIPTOR_VERSION 1
///
/// Definition of an EFI memory descriptor.
///
typedef struct {
///
/// Type of the memory region.
/// Type EFI_MEMORY_TYPE is defined in the
/// AllocatePages() function description.
///
UINT32 Type;
///
/// Physical address of the first byte in the memory region. PhysicalStart must be
/// aligned on a 4 KiB boundary, and must not be above 0xfffffffffffff000. Type
/// EFI_PHYSICAL_ADDRESS is defined in the AllocatePages() function description
///
EFI_PHYSICAL_ADDRESS PhysicalStart;
///
/// Virtual address of the first byte in the memory region.
/// VirtualStart must be aligned on a 4 KiB boundary,
/// and must not be above 0xfffffffffffff000.
///
EFI_VIRTUAL_ADDRESS VirtualStart;
///
/// NumberOfPagesNumber of 4 KiB pages in the memory region.
/// NumberOfPages must not be 0, and must not be any value
/// that would represent a memory page with a start address,
/// either physical or virtual, above 0xfffffffffffff000.
///
UINT64 NumberOfPages;
///
/// Attributes of the memory region that describe the bit mask of capabilities
/// for that memory region, and not necessarily the current settings for that
/// memory region.
///
UINT64 Attribute;
} EFI_MEMORY_DESCRIPTOR;
/**
Allocates memory pages from the system.
@param[in] Type The type of allocation to perform.
@param[in] MemoryType The type of memory to allocate.
MemoryType values in the range 0x70000000..0x7FFFFFFF
are reserved for OEM use. MemoryType values in the range
0x80000000..0xFFFFFFFF are reserved for use by UEFI OS loaders
that are provided by operating system vendors.
@param[in] Pages The number of contiguous 4 KB pages to allocate.
@param[in, out] Memory The pointer to a physical address. On input, the way in which the address is
used depends on the value of Type.
@retval EFI_SUCCESS The requested pages were allocated.
@retval EFI_INVALID_PARAMETER 1) Type is not AllocateAnyPages or
AllocateMaxAddress or AllocateAddress.
2) MemoryType is in the range
EfiMaxMemoryType..0x6FFFFFFF.
3) Memory is NULL.
4) MemoryType is EfiPersistentMemory.
@retval EFI_OUT_OF_RESOURCES The pages could not be allocated.
@retval EFI_NOT_FOUND The requested pages could not be found.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_ALLOCATE_PAGES)(
IN EFI_ALLOCATE_TYPE Type,
IN EFI_MEMORY_TYPE MemoryType,
IN UINTN Pages,
IN OUT EFI_PHYSICAL_ADDRESS *Memory
);
/**
Frees memory pages.
@param[in] Memory The base physical address of the pages to be freed.
@param[in] Pages The number of contiguous 4 KB pages to free.
@retval EFI_SUCCESS The requested pages were freed.
@retval EFI_INVALID_PARAMETER Memory is not a page-aligned address or Pages is invalid.
@retval EFI_NOT_FOUND The requested memory pages were not allocated with
AllocatePages().
**/
typedef
EFI_STATUS
(EFIAPI *EFI_FREE_PAGES)(
IN EFI_PHYSICAL_ADDRESS Memory,
IN UINTN Pages
);
/**
Returns the current memory map.
@param[in, out] MemoryMapSize A pointer to the size, in bytes, of the MemoryMap buffer.
On input, this is the size of the buffer allocated by the caller.
On output, it is the size of the buffer returned by the firmware if
the buffer was large enough, or the size of the buffer needed to contain
the map if the buffer was too small.
@param[out] MemoryMap A pointer to the buffer in which firmware places the current memory
map.
@param[out] MapKey A pointer to the location in which firmware returns the key for the
current memory map.
@param[out] DescriptorSize A pointer to the location in which firmware returns the size, in bytes, of
an individual EFI_MEMORY_DESCRIPTOR.
@param[out] DescriptorVersion A pointer to the location in which firmware returns the version number
associated with the EFI_MEMORY_DESCRIPTOR.
@retval EFI_SUCCESS The memory map was returned in the MemoryMap buffer.
@retval EFI_BUFFER_TOO_SMALL The MemoryMap buffer was too small. The current buffer size
needed to hold the memory map is returned in MemoryMapSize.
@retval EFI_INVALID_PARAMETER 1) MemoryMapSize is NULL.
2) The MemoryMap buffer is not too small and MemoryMap is
NULL.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_GET_MEMORY_MAP)(
IN OUT UINTN *MemoryMapSize,
OUT EFI_MEMORY_DESCRIPTOR *MemoryMap,
OUT UINTN *MapKey,
OUT UINTN *DescriptorSize,
OUT UINT32 *DescriptorVersion
);
/**
Allocates pool memory.
@param[in] PoolType The type of pool to allocate.
MemoryType values in the range 0x70000000..0x7FFFFFFF
are reserved for OEM use. MemoryType values in the range
0x80000000..0xFFFFFFFF are reserved for use by UEFI OS loaders
that are provided by operating system vendors.
@param[in] Size The number of bytes to allocate from the pool.
@param[out] Buffer A pointer to a pointer to the allocated buffer if the call succeeds;
undefined otherwise.
@retval EFI_SUCCESS The requested number of bytes was allocated.
@retval EFI_OUT_OF_RESOURCES The pool requested could not be allocated.
@retval EFI_INVALID_PARAMETER Buffer is NULL.
PoolType is in the range EfiMaxMemoryType..0x6FFFFFFF.
PoolType is EfiPersistentMemory.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_ALLOCATE_POOL)(
IN EFI_MEMORY_TYPE PoolType,
IN UINTN Size,
OUT VOID **Buffer
);
/**
Returns pool memory to the system.
@param[in] Buffer The pointer to the buffer to free.
@retval EFI_SUCCESS The memory was returned to the system.
@retval EFI_INVALID_PARAMETER Buffer was invalid.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_FREE_POOL)(
IN VOID *Buffer
);
/**
Changes the runtime addressing mode of EFI firmware from physical to virtual.
@param[in] MemoryMapSize The size in bytes of VirtualMap.
@param[in] DescriptorSize The size in bytes of an entry in the VirtualMap.
@param[in] DescriptorVersion The version of the structure entries in VirtualMap.
@param[in] VirtualMap An array of memory descriptors which contain new virtual
address mapping information for all runtime ranges.
@retval EFI_SUCCESS The virtual address map has been applied.
@retval EFI_UNSUPPORTED EFI firmware is not at runtime, or the EFI firmware is already in
virtual address mapped mode.
@retval EFI_INVALID_PARAMETER DescriptorSize or DescriptorVersion is invalid.
@retval EFI_NO_MAPPING A virtual address was not supplied for a range in the memory
map that requires a mapping.
@retval EFI_NOT_FOUND A virtual address was supplied for an address that is not found
in the memory map.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_SET_VIRTUAL_ADDRESS_MAP)(
IN UINTN MemoryMapSize,
IN UINTN DescriptorSize,
IN UINT32 DescriptorVersion,
IN EFI_MEMORY_DESCRIPTOR *VirtualMap
);
/**
Connects one or more drivers to a controller.
@param[in] ControllerHandle The handle of the controller to which driver(s) are to be connected.
@param[in] DriverImageHandle A pointer to an ordered list handles that support the
EFI_DRIVER_BINDING_PROTOCOL.
@param[in] RemainingDevicePath A pointer to the device path that specifies a child of the
controller specified by ControllerHandle.
@param[in] Recursive If TRUE, then ConnectController() is called recursively
until the entire tree of controllers below the controller specified
by ControllerHandle have been created. If FALSE, then
the tree of controllers is only expanded one level.
@retval EFI_SUCCESS 1) One or more drivers were connected to ControllerHandle.
2) No drivers were connected to ControllerHandle, but
RemainingDevicePath is not NULL, and it is an End Device
Path Node.
@retval EFI_INVALID_PARAMETER ControllerHandle is NULL.
@retval EFI_NOT_FOUND 1) There are no EFI_DRIVER_BINDING_PROTOCOL instances
present in the system.
2) No drivers were connected to ControllerHandle.
@retval EFI_SECURITY_VIOLATION
The user has no permission to start UEFI device drivers on the device path
associated with the ControllerHandle or specified by the RemainingDevicePath.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_CONNECT_CONTROLLER)(
IN EFI_HANDLE ControllerHandle,
IN EFI_HANDLE *DriverImageHandle, OPTIONAL
IN EFI_DEVICE_PATH_PROTOCOL *RemainingDevicePath, OPTIONAL
IN BOOLEAN Recursive
);
/**
Disconnects one or more drivers from a controller.
@param[in] ControllerHandle The handle of the controller from which driver(s) are to be disconnected.
@param[in] DriverImageHandle The driver to disconnect from ControllerHandle.
If DriverImageHandle is NULL, then all the drivers currently managing
ControllerHandle are disconnected from ControllerHandle.
@param[in] ChildHandle The handle of the child to destroy.
If ChildHandle is NULL, then all the children of ControllerHandle are
destroyed before the drivers are disconnected from ControllerHandle.
@retval EFI_SUCCESS 1) One or more drivers were disconnected from the controller.
2) On entry, no drivers are managing ControllerHandle.
3) DriverImageHandle is not NULL, and on entry
DriverImageHandle is not managing ControllerHandle.
@retval EFI_INVALID_PARAMETER 1) ControllerHandle is NULL.
2) DriverImageHandle is not NULL, and it is not a valid EFI_HANDLE.
3) ChildHandle is not NULL, and it is not a valid EFI_HANDLE.
4) DriverImageHandle does not support the EFI_DRIVER_BINDING_PROTOCOL.
@retval EFI_OUT_OF_RESOURCES There are not enough resources available to disconnect any drivers from
ControllerHandle.
@retval EFI_DEVICE_ERROR The controller could not be disconnected because of a device error.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_DISCONNECT_CONTROLLER)(
IN EFI_HANDLE ControllerHandle,
IN EFI_HANDLE DriverImageHandle, OPTIONAL
IN EFI_HANDLE ChildHandle OPTIONAL
);
//
// ConvertPointer DebugDisposition type.
//
#define EFI_OPTIONAL_PTR 0x00000001
/**
Determines the new virtual address that is to be used on subsequent memory accesses.
@param[in] DebugDisposition Supplies type information for the pointer being converted.
@param[in, out] Address A pointer to a pointer that is to be fixed to be the value needed
for the new virtual address mappings being applied.
@retval EFI_SUCCESS The pointer pointed to by Address was modified.
@retval EFI_INVALID_PARAMETER 1) Address is NULL.
2) *Address is NULL and DebugDisposition does
not have the EFI_OPTIONAL_PTR bit set.
@retval EFI_NOT_FOUND The pointer pointed to by Address was not found to be part
of the current memory map. This is normally fatal.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_CONVERT_POINTER)(
IN UINTN DebugDisposition,
IN OUT VOID **Address
);
//
// These types can be ORed together as needed - for example,
// EVT_TIMER might be Ored with EVT_NOTIFY_WAIT or
// EVT_NOTIFY_SIGNAL.
//
#define EVT_TIMER 0x80000000
#define EVT_RUNTIME 0x40000000
#define EVT_NOTIFY_WAIT 0x00000100
#define EVT_NOTIFY_SIGNAL 0x00000200
#define EVT_SIGNAL_EXIT_BOOT_SERVICES 0x00000201
#define EVT_SIGNAL_VIRTUAL_ADDRESS_CHANGE 0x60000202
//
// The event's NotifyContext pointer points to a runtime memory
// address.
// The event is deprecated in UEFI2.0 and later specifications.
//
#define EVT_RUNTIME_CONTEXT 0x20000000
/**
Invoke a notification event
@param[in] Event Event whose notification function is being invoked.
@param[in] Context The pointer to the notification function's context,
which is implementation-dependent.
**/
typedef
VOID
(EFIAPI *EFI_EVENT_NOTIFY)(
IN EFI_EVENT Event,
IN VOID *Context
);
/**
Creates an event.
@param[in] Type The type of event to create and its mode and attributes.
@param[in] NotifyTpl The task priority level of event notifications, if needed.
@param[in] NotifyFunction The pointer to the event's notification function, if any.
@param[in] NotifyContext The pointer to the notification function's context; corresponds to parameter
Context in the notification function.
@param[out] Event The pointer to the newly created event if the call succeeds; undefined
otherwise.
@retval EFI_SUCCESS The event structure was created.
@retval EFI_INVALID_PARAMETER One or more parameters are invalid.
@retval EFI_OUT_OF_RESOURCES The event could not be allocated.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_CREATE_EVENT)(
IN UINT32 Type,
IN EFI_TPL NotifyTpl,
IN EFI_EVENT_NOTIFY NotifyFunction,
IN VOID *NotifyContext,
OUT EFI_EVENT *Event
);
/**
Creates an event in a group.
@param[in] Type The type of event to create and its mode and attributes.
@param[in] NotifyTpl The task priority level of event notifications,if needed.
@param[in] NotifyFunction The pointer to the event's notification function, if any.
@param[in] NotifyContext The pointer to the notification function's context; corresponds to parameter
Context in the notification function.
@param[in] EventGroup The pointer to the unique identifier of the group to which this event belongs.
If this is NULL, then the function behaves as if the parameters were passed
to CreateEvent.
@param[out] Event The pointer to the newly created event if the call succeeds; undefined
otherwise.
@retval EFI_SUCCESS The event structure was created.
@retval EFI_INVALID_PARAMETER One or more parameters are invalid.
@retval EFI_OUT_OF_RESOURCES The event could not be allocated.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_CREATE_EVENT_EX)(
IN UINT32 Type,
IN EFI_TPL NotifyTpl,
IN EFI_EVENT_NOTIFY NotifyFunction OPTIONAL,
IN CONST VOID *NotifyContext OPTIONAL,
IN CONST EFI_GUID *EventGroup OPTIONAL,
OUT EFI_EVENT *Event
);
///
/// Timer delay types
///
typedef enum {
///
/// An event's timer settings is to be cancelled and not trigger time is to be set/
///
TimerCancel,
///
/// An event is to be signaled periodically at a specified interval from the current time.
///
TimerPeriodic,
///
/// An event is to be signaled once at a specified interval from the current time.
///
TimerRelative
} EFI_TIMER_DELAY;
/**
Sets the type of timer and the trigger time for a timer event.
@param[in] Event The timer event that is to be signaled at the specified time.
@param[in] Type The type of time that is specified in TriggerTime.
@param[in] TriggerTime The number of 100ns units until the timer expires.
A TriggerTime of 0 is legal.
If Type is TimerRelative and TriggerTime is 0, then the timer
event will be signaled on the next timer tick.
If Type is TimerPeriodic and TriggerTime is 0, then the timer
event will be signaled on every timer tick.
@retval EFI_SUCCESS The event has been set to be signaled at the requested time.
@retval EFI_INVALID_PARAMETER Event or Type is not valid.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_SET_TIMER)(
IN EFI_EVENT Event,
IN EFI_TIMER_DELAY Type,
IN UINT64 TriggerTime
);
/**
Signals an event.
@param[in] Event The event to signal.
@retval EFI_SUCCESS The event has been signaled.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_SIGNAL_EVENT)(
IN EFI_EVENT Event
);
/**
Stops execution until an event is signaled.
@param[in] NumberOfEvents The number of events in the Event array.
@param[in] Event An array of EFI_EVENT.
@param[out] Index The pointer to the index of the event which satisfied the wait condition.
@retval EFI_SUCCESS The event indicated by Index was signaled.
@retval EFI_INVALID_PARAMETER 1) NumberOfEvents is 0.
2) The event indicated by Index is of type
EVT_NOTIFY_SIGNAL.
@retval EFI_UNSUPPORTED The current TPL is not TPL_APPLICATION.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_WAIT_FOR_EVENT)(
IN UINTN NumberOfEvents,
IN EFI_EVENT *Event,
OUT UINTN *Index
);
/**
Closes an event.
@param[in] Event The event to close.
@retval EFI_SUCCESS The event has been closed.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_CLOSE_EVENT)(
IN EFI_EVENT Event
);
/**
Checks whether an event is in the signaled state.
@param[in] Event The event to check.
@retval EFI_SUCCESS The event is in the signaled state.
@retval EFI_NOT_READY The event is not in the signaled state.
@retval EFI_INVALID_PARAMETER Event is of type EVT_NOTIFY_SIGNAL.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_CHECK_EVENT)(
IN EFI_EVENT Event
);
//
// Task priority level
//
#define TPL_APPLICATION 4
#define TPL_CALLBACK 8
#define TPL_NOTIFY 16
#define TPL_HIGH_LEVEL 31
/**
Raises a task's priority level and returns its previous level.
@param[in] NewTpl The new task priority level.
@return Previous task priority level
**/
typedef
EFI_TPL
(EFIAPI *EFI_RAISE_TPL)(
IN EFI_TPL NewTpl
);
/**
Restores a task's priority level to its previous value.
@param[in] OldTpl The previous task priority level to restore.
**/
typedef
VOID
(EFIAPI *EFI_RESTORE_TPL)(
IN EFI_TPL OldTpl
);
/**
Returns the value of a variable.
@param[in] VariableName A Null-terminated string that is the name of the vendor's
variable.
@param[in] VendorGuid A unique identifier for the vendor.
@param[out] Attributes If not NULL, a pointer to the memory location to return the
attributes bitmask for the variable.
@param[in, out] DataSize On input, the size in bytes of the return Data buffer.
On output the size of data returned in Data.
@param[out] Data The buffer to return the contents of the variable. May be NULL
with a zero DataSize in order to determine the size buffer needed.
@retval EFI_SUCCESS The function completed successfully.
@retval EFI_NOT_FOUND The variable was not found.
@retval EFI_BUFFER_TOO_SMALL The DataSize is too small for the result.
@retval EFI_INVALID_PARAMETER VariableName is NULL.
@retval EFI_INVALID_PARAMETER VendorGuid is NULL.
@retval EFI_INVALID_PARAMETER DataSize is NULL.
@retval EFI_INVALID_PARAMETER The DataSize is not too small and Data is NULL.
@retval EFI_DEVICE_ERROR The variable could not be retrieved due to a hardware error.
@retval EFI_SECURITY_VIOLATION The variable could not be retrieved due to an authentication failure.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_GET_VARIABLE)(
IN CHAR16 *VariableName,
IN EFI_GUID *VendorGuid,
OUT UINT32 *Attributes, OPTIONAL
IN OUT UINTN *DataSize,
OUT VOID *Data OPTIONAL
);
/**
Enumerates the current variable names.
@param[in, out] VariableNameSize The size of the VariableName buffer. The size must be large
enough to fit input string supplied in VariableName buffer.
@param[in, out] VariableName On input, supplies the last VariableName that was returned
by GetNextVariableName(). On output, returns the Nullterminated
string of the current variable.
@param[in, out] VendorGuid On input, supplies the last VendorGuid that was returned by
GetNextVariableName(). On output, returns the
VendorGuid of the current variable.
@retval EFI_SUCCESS The function completed successfully.
@retval EFI_NOT_FOUND The next variable was not found.
@retval EFI_BUFFER_TOO_SMALL The VariableNameSize is too small for the result.
VariableNameSize has been updated with the size needed to complete the request.
@retval EFI_INVALID_PARAMETER VariableNameSize is NULL.
@retval EFI_INVALID_PARAMETER VariableName is NULL.
@retval EFI_INVALID_PARAMETER VendorGuid is NULL.
@retval EFI_INVALID_PARAMETER The input values of VariableName and VendorGuid are not a name and
GUID of an existing variable.
@retval EFI_INVALID_PARAMETER Null-terminator is not found in the first VariableNameSize bytes of
the input VariableName buffer.
@retval EFI_DEVICE_ERROR The variable could not be retrieved due to a hardware error.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_GET_NEXT_VARIABLE_NAME)(
IN OUT UINTN *VariableNameSize,
IN OUT CHAR16 *VariableName,
IN OUT EFI_GUID *VendorGuid
);
/**
Sets the value of a variable.
@param[in] VariableName A Null-terminated string that is the name of the vendor's variable.
Each VariableName is unique for each VendorGuid. VariableName must
contain 1 or more characters. If VariableName is an empty string,
then EFI_INVALID_PARAMETER is returned.
@param[in] VendorGuid A unique identifier for the vendor.
@param[in] Attributes Attributes bitmask to set for the variable.
@param[in] DataSize The size in bytes of the Data buffer. Unless the EFI_VARIABLE_APPEND_WRITE or
EFI_VARIABLE_TIME_BASED_AUTHENTICATED_WRITE_ACCESS attribute is set, a size of zero
causes the variable to be deleted. When the EFI_VARIABLE_APPEND_WRITE attribute is
set, then a SetVariable() call with a DataSize of zero will not cause any change to
the variable value (the timestamp associated with the variable may be updated however
even if no new data value is provided,see the description of the
EFI_VARIABLE_AUTHENTICATION_2 descriptor below. In this case the DataSize will not
be zero since the EFI_VARIABLE_AUTHENTICATION_2 descriptor will be populated).
@param[in] Data The contents for the variable.
@retval EFI_SUCCESS The firmware has successfully stored the variable and its data as
defined by the Attributes.
@retval EFI_INVALID_PARAMETER An invalid combination of attribute bits, name, and GUID was supplied, or the
DataSize exceeds the maximum allowed.
@retval EFI_INVALID_PARAMETER VariableName is an empty string.
@retval EFI_OUT_OF_RESOURCES Not enough storage is available to hold the variable and its data.
@retval EFI_DEVICE_ERROR The variable could not be retrieved due to a hardware error.
@retval EFI_WRITE_PROTECTED The variable in question is read-only.
@retval EFI_WRITE_PROTECTED The variable in question cannot be deleted.
@retval EFI_SECURITY_VIOLATION The variable could not be written due to EFI_VARIABLE_TIME_BASED_AUTHENTICATED_WRITE_ACESS being set,
but the AuthInfo does NOT pass the validation check carried out by the firmware.
@retval EFI_NOT_FOUND The variable trying to be updated or deleted was not found.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_SET_VARIABLE)(
IN CHAR16 *VariableName,
IN EFI_GUID *VendorGuid,
IN UINT32 Attributes,
IN UINTN DataSize,
IN VOID *Data
);
///
/// This provides the capabilities of the
/// real time clock device as exposed through the EFI interfaces.
///
typedef struct {
///
/// Provides the reporting resolution of the real-time clock device in
/// counts per second. For a normal PC-AT CMOS RTC device, this
/// value would be 1 Hz, or 1, to indicate that the device only reports
/// the time to the resolution of 1 second.
///
UINT32 Resolution;
///
/// Provides the timekeeping accuracy of the real-time clock in an
/// error rate of 1E-6 parts per million. For a clock with an accuracy
/// of 50 parts per million, the value in this field would be
/// 50,000,000.
///
UINT32 Accuracy;
///
/// A TRUE indicates that a time set operation clears the device's
/// time below the Resolution reporting level. A FALSE
/// indicates that the state below the Resolution level of the
/// device is not cleared when the time is set. Normal PC-AT CMOS
/// RTC devices set this value to FALSE.
///
BOOLEAN SetsToZero;
} EFI_TIME_CAPABILITIES;
/**
Returns the current time and date information, and the time-keeping capabilities
of the hardware platform.
@param[out] Time A pointer to storage to receive a snapshot of the current time.
@param[out] Capabilities An optional pointer to a buffer to receive the real time clock
device's capabilities.
@retval EFI_SUCCESS The operation completed successfully.
@retval EFI_INVALID_PARAMETER Time is NULL.
@retval EFI_DEVICE_ERROR The time could not be retrieved due to hardware error.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_GET_TIME)(
OUT EFI_TIME *Time,
OUT EFI_TIME_CAPABILITIES *Capabilities OPTIONAL
);
/**
Sets the current local time and date information.
@param[in] Time A pointer to the current time.
@retval EFI_SUCCESS The operation completed successfully.
@retval EFI_INVALID_PARAMETER A time field is out of range.
@retval EFI_DEVICE_ERROR The time could not be set due due to hardware error.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_SET_TIME)(
IN EFI_TIME *Time
);
/**
Returns the current wakeup alarm clock setting.
@param[out] Enabled Indicates if the alarm is currently enabled or disabled.
@param[out] Pending Indicates if the alarm signal is pending and requires acknowledgement.
@param[out] Time The current alarm setting.
@retval EFI_SUCCESS The alarm settings were returned.
@retval EFI_INVALID_PARAMETER Enabled is NULL.
@retval EFI_INVALID_PARAMETER Pending is NULL.
@retval EFI_INVALID_PARAMETER Time is NULL.
@retval EFI_DEVICE_ERROR The wakeup time could not be retrieved due to a hardware error.
@retval EFI_UNSUPPORTED A wakeup timer is not supported on this platform.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_GET_WAKEUP_TIME)(
OUT BOOLEAN *Enabled,
OUT BOOLEAN *Pending,
OUT EFI_TIME *Time
);
/**
Sets the system wakeup alarm clock time.
@param[in] Enable Enable or disable the wakeup alarm.
@param[in] Time If Enable is TRUE, the time to set the wakeup alarm for.
If Enable is FALSE, then this parameter is optional, and may be NULL.
@retval EFI_SUCCESS If Enable is TRUE, then the wakeup alarm was enabled. If
Enable is FALSE, then the wakeup alarm was disabled.
@retval EFI_INVALID_PARAMETER A time field is out of range.
@retval EFI_DEVICE_ERROR The wakeup time could not be set due to a hardware error.
@retval EFI_UNSUPPORTED A wakeup timer is not supported on this platform.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_SET_WAKEUP_TIME)(
IN BOOLEAN Enable,
IN EFI_TIME *Time OPTIONAL
);
/**
Loads an EFI image into memory.
@param[in] BootPolicy If TRUE, indicates that the request originates from the boot
manager, and that the boot manager is attempting to load
FilePath as a boot selection. Ignored if SourceBuffer is
not NULL.
@param[in] ParentImageHandle The caller's image handle.
@param[in] DevicePath The DeviceHandle specific file path from which the image is
loaded.
@param[in] SourceBuffer If not NULL, a pointer to the memory location containing a copy
of the image to be loaded.
@param[in] SourceSize The size in bytes of SourceBuffer. Ignored if SourceBuffer is NULL.
@param[out] ImageHandle The pointer to the returned image handle that is created when the
image is successfully loaded.
@retval EFI_SUCCESS Image was loaded into memory correctly.
@retval EFI_NOT_FOUND Both SourceBuffer and DevicePath are NULL.
@retval EFI_INVALID_PARAMETER One or more parametes are invalid.
@retval EFI_UNSUPPORTED The image type is not supported.
@retval EFI_OUT_OF_RESOURCES Image was not loaded due to insufficient resources.
@retval EFI_LOAD_ERROR Image was not loaded because the image format was corrupt or not
understood.
@retval EFI_DEVICE_ERROR Image was not loaded because the device returned a read error.
@retval EFI_ACCESS_DENIED Image was not loaded because the platform policy prohibits the
image from being loaded. NULL is returned in *ImageHandle.
@retval EFI_SECURITY_VIOLATION Image was loaded and an ImageHandle was created with a
valid EFI_LOADED_IMAGE_PROTOCOL. However, the current
platform policy specifies that the image should not be started.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_IMAGE_LOAD)(
IN BOOLEAN BootPolicy,
IN EFI_HANDLE ParentImageHandle,
IN EFI_DEVICE_PATH_PROTOCOL *DevicePath,
IN VOID *SourceBuffer OPTIONAL,
IN UINTN SourceSize,
OUT EFI_HANDLE *ImageHandle
);
/**
Transfers control to a loaded image's entry point.
@param[in] ImageHandle Handle of image to be started.
@param[out] ExitDataSize The pointer to the size, in bytes, of ExitData.
@param[out] ExitData The pointer to a pointer to a data buffer that includes a Null-terminated
string, optionally followed by additional binary data.
@retval EFI_INVALID_PARAMETER ImageHandle is either an invalid image handle or the image
has already been initialized with StartImage.
@retval EFI_SECURITY_VIOLATION The current platform policy specifies that the image should not be started.
@return Exit code from image
**/
typedef
EFI_STATUS
(EFIAPI *EFI_IMAGE_START)(
IN EFI_HANDLE ImageHandle,
OUT UINTN *ExitDataSize,
OUT CHAR16 **ExitData OPTIONAL
);
/**
Terminates a loaded EFI image and returns control to boot services.
@param[in] ImageHandle Handle that identifies the image. This parameter is passed to the
image on entry.
@param[in] ExitStatus The image's exit code.
@param[in] ExitDataSize The size, in bytes, of ExitData. Ignored if ExitStatus is EFI_SUCCESS.
@param[in] ExitData The pointer to a data buffer that includes a Null-terminated string,
optionally followed by additional binary data. The string is a
description that the caller may use to further indicate the reason
for the image's exit. ExitData is only valid if ExitStatus
is something other than EFI_SUCCESS. The ExitData buffer
must be allocated by calling AllocatePool().
@retval EFI_SUCCESS The image specified by ImageHandle was unloaded.
@retval EFI_INVALID_PARAMETER The image specified by ImageHandle has been loaded and
started with LoadImage() and StartImage(), but the
image is not the currently executing image.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_EXIT)(
IN EFI_HANDLE ImageHandle,
IN EFI_STATUS ExitStatus,
IN UINTN ExitDataSize,
IN CHAR16 *ExitData OPTIONAL
);
/**
Unloads an image.
@param[in] ImageHandle Handle that identifies the image to be unloaded.
@retval EFI_SUCCESS The image has been unloaded.
@retval EFI_INVALID_PARAMETER ImageHandle is not a valid image handle.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_IMAGE_UNLOAD)(
IN EFI_HANDLE ImageHandle
);
/**
Terminates all boot services.
@param[in] ImageHandle Handle that identifies the exiting image.
@param[in] MapKey Key to the latest memory map.
@retval EFI_SUCCESS Boot services have been terminated.
@retval EFI_INVALID_PARAMETER MapKey is incorrect.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_EXIT_BOOT_SERVICES)(
IN EFI_HANDLE ImageHandle,
IN UINTN MapKey
);
/**
Induces a fine-grained stall.
@param[in] Microseconds The number of microseconds to stall execution.
@retval EFI_SUCCESS Execution was stalled at least the requested number of
Microseconds.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_STALL)(
IN UINTN Microseconds
);
/**
Sets the system's watchdog timer.
@param[in] Timeout The number of seconds to set the watchdog timer to.
@param[in] WatchdogCode The numeric code to log on a watchdog timer timeout event.
@param[in] DataSize The size, in bytes, of WatchdogData.
@param[in] WatchdogData A data buffer that includes a Null-terminated string, optionally
followed by additional binary data.
@retval EFI_SUCCESS The timeout has been set.
@retval EFI_INVALID_PARAMETER The supplied WatchdogCode is invalid.
@retval EFI_UNSUPPORTED The system does not have a watchdog timer.
@retval EFI_DEVICE_ERROR The watchdog timer could not be programmed due to a hardware
error.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_SET_WATCHDOG_TIMER)(
IN UINTN Timeout,
IN UINT64 WatchdogCode,
IN UINTN DataSize,
IN CHAR16 *WatchdogData OPTIONAL
);
/**
Resets the entire platform.
@param[in] ResetType The type of reset to perform.
@param[in] ResetStatus The status code for the reset.
@param[in] DataSize The size, in bytes, of ResetData.
@param[in] ResetData For a ResetType of EfiResetCold, EfiResetWarm, or
EfiResetShutdown the data buffer starts with a Null-terminated
string, optionally followed by additional binary data.
The string is a description that the caller may use to further
indicate the reason for the system reset.
For a ResetType of EfiResetPlatformSpecific the data buffer
also starts with a Null-terminated string that is followed
by an EFI_GUID that describes the specific type of reset to perform.
**/
typedef
VOID
(EFIAPI *EFI_RESET_SYSTEM)(
IN EFI_RESET_TYPE ResetType,
IN EFI_STATUS ResetStatus,
IN UINTN DataSize,
IN VOID *ResetData OPTIONAL
);
/**
Returns a monotonically increasing count for the platform.
@param[out] Count The pointer to returned value.
@retval EFI_SUCCESS The next monotonic count was returned.
@retval EFI_INVALID_PARAMETER Count is NULL.
@retval EFI_DEVICE_ERROR The device is not functioning properly.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_GET_NEXT_MONOTONIC_COUNT)(
OUT UINT64 *Count
);
/**
Returns the next high 32 bits of the platform's monotonic counter.
@param[out] HighCount The pointer to returned value.
@retval EFI_SUCCESS The next high monotonic count was returned.
@retval EFI_INVALID_PARAMETER HighCount is NULL.
@retval EFI_DEVICE_ERROR The device is not functioning properly.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_GET_NEXT_HIGH_MONO_COUNT)(
OUT UINT32 *HighCount
);
/**
Computes and returns a 32-bit CRC for a data buffer.
@param[in] Data A pointer to the buffer on which the 32-bit CRC is to be computed.
@param[in] DataSize The number of bytes in the buffer Data.
@param[out] Crc32 The 32-bit CRC that was computed for the data buffer specified by Data
and DataSize.
@retval EFI_SUCCESS The 32-bit CRC was computed for the data buffer and returned in
Crc32.
@retval EFI_INVALID_PARAMETER Data is NULL.
@retval EFI_INVALID_PARAMETER Crc32 is NULL.
@retval EFI_INVALID_PARAMETER DataSize is 0.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_CALCULATE_CRC32)(
IN VOID *Data,
IN UINTN DataSize,
OUT UINT32 *Crc32
);
/**
Copies the contents of one buffer to another buffer.
@param[in] Destination The pointer to the destination buffer of the memory copy.
@param[in] Source The pointer to the source buffer of the memory copy.
@param[in] Length Number of bytes to copy from Source to Destination.
**/
typedef
VOID
(EFIAPI *EFI_COPY_MEM)(
IN VOID *Destination,
IN VOID *Source,
IN UINTN Length
);
/**
The SetMem() function fills a buffer with a specified value.
@param[in] Buffer The pointer to the buffer to fill.
@param[in] Size Number of bytes in Buffer to fill.
@param[in] Value Value to fill Buffer with.
**/
typedef
VOID
(EFIAPI *EFI_SET_MEM)(
IN VOID *Buffer,
IN UINTN Size,
IN UINT8 Value
);
///
/// Enumeration of EFI Interface Types
///
typedef enum {
///
/// Indicates that the supplied protocol interface is supplied in native form.
///
EFI_NATIVE_INTERFACE
} EFI_INTERFACE_TYPE;
/**
Installs a protocol interface on a device handle. If the handle does not exist, it is created and added
to the list of handles in the system. InstallMultipleProtocolInterfaces() performs
more error checking than InstallProtocolInterface(), so it is recommended that
InstallMultipleProtocolInterfaces() be used in place of
InstallProtocolInterface()
@param[in, out] Handle A pointer to the EFI_HANDLE on which the interface is to be installed.
@param[in] Protocol The numeric ID of the protocol interface.
@param[in] InterfaceType Indicates whether Interface is supplied in native form.
@param[in] Interface A pointer to the protocol interface.
@retval EFI_SUCCESS The protocol interface was installed.
@retval EFI_OUT_OF_RESOURCES Space for a new handle could not be allocated.
@retval EFI_INVALID_PARAMETER Handle is NULL.
@retval EFI_INVALID_PARAMETER Protocol is NULL.
@retval EFI_INVALID_PARAMETER InterfaceType is not EFI_NATIVE_INTERFACE.
@retval EFI_INVALID_PARAMETER Protocol is already installed on the handle specified by Handle.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_INSTALL_PROTOCOL_INTERFACE)(
IN OUT EFI_HANDLE *Handle,
IN EFI_GUID *Protocol,
IN EFI_INTERFACE_TYPE InterfaceType,
IN VOID *Interface
);
/**
Installs one or more protocol interfaces into the boot services environment.
@param[in, out] Handle The pointer to a handle to install the new protocol interfaces on,
or a pointer to NULL if a new handle is to be allocated.
@param ... A variable argument list containing pairs of protocol GUIDs and protocol
interfaces.
@retval EFI_SUCCESS All the protocol interface was installed.
@retval EFI_OUT_OF_RESOURCES There was not enough memory in pool to install all the protocols.
@retval EFI_ALREADY_STARTED A Device Path Protocol instance was passed in that is already present in
the handle database.
@retval EFI_INVALID_PARAMETER Handle is NULL.
@retval EFI_INVALID_PARAMETER Protocol is already installed on the handle specified by Handle.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_INSTALL_MULTIPLE_PROTOCOL_INTERFACES)(
IN OUT EFI_HANDLE *Handle,
...
);
/**
Reinstalls a protocol interface on a device handle.
@param[in] Handle Handle on which the interface is to be reinstalled.
@param[in] Protocol The numeric ID of the interface.
@param[in] OldInterface A pointer to the old interface. NULL can be used if a structure is not
associated with Protocol.
@param[in] NewInterface A pointer to the new interface.
@retval EFI_SUCCESS The protocol interface was reinstalled.
@retval EFI_NOT_FOUND The OldInterface on the handle was not found.
@retval EFI_ACCESS_DENIED The protocol interface could not be reinstalled,
because OldInterface is still being used by a
driver that will not release it.
@retval EFI_INVALID_PARAMETER Handle is NULL.
@retval EFI_INVALID_PARAMETER Protocol is NULL.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_REINSTALL_PROTOCOL_INTERFACE)(
IN EFI_HANDLE Handle,
IN EFI_GUID *Protocol,
IN VOID *OldInterface,
IN VOID *NewInterface
);
/**
Removes a protocol interface from a device handle. It is recommended that
UninstallMultipleProtocolInterfaces() be used in place of
UninstallProtocolInterface().
@param[in] Handle The handle on which the interface was installed.
@param[in] Protocol The numeric ID of the interface.
@param[in] Interface A pointer to the interface.
@retval EFI_SUCCESS The interface was removed.
@retval EFI_NOT_FOUND The interface was not found.
@retval EFI_ACCESS_DENIED The interface was not removed because the interface
is still being used by a driver.
@retval EFI_INVALID_PARAMETER Handle is NULL.
@retval EFI_INVALID_PARAMETER Protocol is NULL.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_UNINSTALL_PROTOCOL_INTERFACE)(
IN EFI_HANDLE Handle,
IN EFI_GUID *Protocol,
IN VOID *Interface
);
/**
Removes one or more protocol interfaces into the boot services environment.
@param[in] Handle The handle to remove the protocol interfaces from.
@param ... A variable argument list containing pairs of protocol GUIDs and
protocol interfaces.
@retval EFI_SUCCESS All the protocol interfaces were removed.
@retval EFI_INVALID_PARAMETER One of the protocol interfaces was not previously installed on Handle.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_UNINSTALL_MULTIPLE_PROTOCOL_INTERFACES)(
IN EFI_HANDLE Handle,
...
);
/**
Queries a handle to determine if it supports a specified protocol.
@param[in] Handle The handle being queried.
@param[in] Protocol The published unique identifier of the protocol.
@param[out] Interface Supplies the address where a pointer to the corresponding Protocol
Interface is returned.
@retval EFI_SUCCESS The interface information for the specified protocol was returned.
@retval EFI_UNSUPPORTED The device does not support the specified protocol.
@retval EFI_INVALID_PARAMETER Handle is NULL.
@retval EFI_INVALID_PARAMETER Protocol is NULL.
@retval EFI_INVALID_PARAMETER Interface is NULL.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_HANDLE_PROTOCOL)(
IN EFI_HANDLE Handle,
IN EFI_GUID *Protocol,
OUT VOID **Interface
);
#define EFI_OPEN_PROTOCOL_BY_HANDLE_PROTOCOL 0x00000001
#define EFI_OPEN_PROTOCOL_GET_PROTOCOL 0x00000002
#define EFI_OPEN_PROTOCOL_TEST_PROTOCOL 0x00000004
#define EFI_OPEN_PROTOCOL_BY_CHILD_CONTROLLER 0x00000008
#define EFI_OPEN_PROTOCOL_BY_DRIVER 0x00000010
#define EFI_OPEN_PROTOCOL_EXCLUSIVE 0x00000020
/**
Queries a handle to determine if it supports a specified protocol. If the protocol is supported by the
handle, it opens the protocol on behalf of the calling agent.
@param[in] Handle The handle for the protocol interface that is being opened.
@param[in] Protocol The published unique identifier of the protocol.
@param[out] Interface Supplies the address where a pointer to the corresponding Protocol
Interface is returned.
@param[in] AgentHandle The handle of the agent that is opening the protocol interface
specified by Protocol and Interface.
@param[in] ControllerHandle If the agent that is opening a protocol is a driver that follows the
UEFI Driver Model, then this parameter is the controller handle
that requires the protocol interface. If the agent does not follow
the UEFI Driver Model, then this parameter is optional and may
be NULL.
@param[in] Attributes The open mode of the protocol interface specified by Handle
and Protocol.
@retval EFI_SUCCESS An item was added to the open list for the protocol interface, and the
protocol interface was returned in Interface.
@retval EFI_UNSUPPORTED Handle does not support Protocol.
@retval EFI_INVALID_PARAMETER One or more parameters are invalid.
@retval EFI_ACCESS_DENIED Required attributes can't be supported in current environment.
@retval EFI_ALREADY_STARTED Item on the open list already has requierd attributes whose agent
handle is the same as AgentHandle.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_OPEN_PROTOCOL)(
IN EFI_HANDLE Handle,
IN EFI_GUID *Protocol,
OUT VOID **Interface, OPTIONAL
IN EFI_HANDLE AgentHandle,
IN EFI_HANDLE ControllerHandle,
IN UINT32 Attributes
);
/**
Closes a protocol on a handle that was opened using OpenProtocol().
@param[in] Handle The handle for the protocol interface that was previously opened
with OpenProtocol(), and is now being closed.
@param[in] Protocol The published unique identifier of the protocol.
@param[in] AgentHandle The handle of the agent that is closing the protocol interface.
@param[in] ControllerHandle If the agent that opened a protocol is a driver that follows the
UEFI Driver Model, then this parameter is the controller handle
that required the protocol interface.
@retval EFI_SUCCESS The protocol instance was closed.
@retval EFI_INVALID_PARAMETER 1) Handle is NULL.
2) AgentHandle is NULL.
3) ControllerHandle is not NULL and ControllerHandle is not a valid EFI_HANDLE.
4) Protocol is NULL.
@retval EFI_NOT_FOUND 1) Handle does not support the protocol specified by Protocol.
2) The protocol interface specified by Handle and Protocol is not
currently open by AgentHandle and ControllerHandle.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_CLOSE_PROTOCOL)(
IN EFI_HANDLE Handle,
IN EFI_GUID *Protocol,
IN EFI_HANDLE AgentHandle,
IN EFI_HANDLE ControllerHandle
);
///
/// EFI Oprn Protocol Information Entry
///
typedef struct {
EFI_HANDLE AgentHandle;
EFI_HANDLE ControllerHandle;
UINT32 Attributes;
UINT32 OpenCount;
} EFI_OPEN_PROTOCOL_INFORMATION_ENTRY;
/**
Retrieves the list of agents that currently have a protocol interface opened.
@param[in] Handle The handle for the protocol interface that is being queried.
@param[in] Protocol The published unique identifier of the protocol.
@param[out] EntryBuffer A pointer to a buffer of open protocol information in the form of
EFI_OPEN_PROTOCOL_INFORMATION_ENTRY structures.
@param[out] EntryCount A pointer to the number of entries in EntryBuffer.
@retval EFI_SUCCESS The open protocol information was returned in EntryBuffer, and the
number of entries was returned EntryCount.
@retval EFI_OUT_OF_RESOURCES There are not enough resources available to allocate EntryBuffer.
@retval EFI_NOT_FOUND Handle does not support the protocol specified by Protocol.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_OPEN_PROTOCOL_INFORMATION)(
IN EFI_HANDLE Handle,
IN EFI_GUID *Protocol,
OUT EFI_OPEN_PROTOCOL_INFORMATION_ENTRY **EntryBuffer,
OUT UINTN *EntryCount
);
/**
Retrieves the list of protocol interface GUIDs that are installed on a handle in a buffer allocated
from pool.
@param[in] Handle The handle from which to retrieve the list of protocol interface
GUIDs.
@param[out] ProtocolBuffer A pointer to the list of protocol interface GUID pointers that are
installed on Handle.
@param[out] ProtocolBufferCount A pointer to the number of GUID pointers present in
ProtocolBuffer.
@retval EFI_SUCCESS The list of protocol interface GUIDs installed on Handle was returned in
ProtocolBuffer. The number of protocol interface GUIDs was
returned in ProtocolBufferCount.
@retval EFI_OUT_OF_RESOURCES There is not enough pool memory to store the results.
@retval EFI_INVALID_PARAMETER Handle is NULL.
@retval EFI_INVALID_PARAMETER Handle is not a valid EFI_HANDLE.
@retval EFI_INVALID_PARAMETER ProtocolBuffer is NULL.
@retval EFI_INVALID_PARAMETER ProtocolBufferCount is NULL.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_PROTOCOLS_PER_HANDLE)(
IN EFI_HANDLE Handle,
OUT EFI_GUID ***ProtocolBuffer,
OUT UINTN *ProtocolBufferCount
);
/**
Creates an event that is to be signaled whenever an interface is installed for a specified protocol.
@param[in] Protocol The numeric ID of the protocol for which the event is to be registered.
@param[in] Event Event that is to be signaled whenever a protocol interface is registered
for Protocol.
@param[out] Registration A pointer to a memory location to receive the registration value.
@retval EFI_SUCCESS The notification event has been registered.
@retval EFI_OUT_OF_RESOURCES Space for the notification event could not be allocated.
@retval EFI_INVALID_PARAMETER Protocol is NULL.
@retval EFI_INVALID_PARAMETER Event is NULL.
@retval EFI_INVALID_PARAMETER Registration is NULL.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_REGISTER_PROTOCOL_NOTIFY)(
IN EFI_GUID *Protocol,
IN EFI_EVENT Event,
OUT VOID **Registration
);
///
/// Enumeration of EFI Locate Search Types
///
typedef enum {
///
/// Retrieve all the handles in the handle database.
///
AllHandles,
///
/// Retrieve the next handle fron a RegisterProtocolNotify() event.
///
ByRegisterNotify,
///
/// Retrieve the set of handles from the handle database that support a
/// specified protocol.
///
ByProtocol
} EFI_LOCATE_SEARCH_TYPE;
/**
Returns an array of handles that support a specified protocol.
@param[in] SearchType Specifies which handle(s) are to be returned.
@param[in] Protocol Specifies the protocol to search by.
@param[in] SearchKey Specifies the search key.
@param[in, out] BufferSize On input, the size in bytes of Buffer. On output, the size in bytes of
the array returned in Buffer (if the buffer was large enough) or the
size, in bytes, of the buffer needed to obtain the array (if the buffer was
not large enough).
@param[out] Buffer The buffer in which the array is returned.
@retval EFI_SUCCESS The array of handles was returned.
@retval EFI_NOT_FOUND No handles match the search.
@retval EFI_BUFFER_TOO_SMALL The BufferSize is too small for the result.
@retval EFI_INVALID_PARAMETER SearchType is not a member of EFI_LOCATE_SEARCH_TYPE.
@retval EFI_INVALID_PARAMETER SearchType is ByRegisterNotify and SearchKey is NULL.
@retval EFI_INVALID_PARAMETER SearchType is ByProtocol and Protocol is NULL.
@retval EFI_INVALID_PARAMETER One or more matches are found and BufferSize is NULL.
@retval EFI_INVALID_PARAMETER BufferSize is large enough for the result and Buffer is NULL.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_LOCATE_HANDLE)(
IN EFI_LOCATE_SEARCH_TYPE SearchType,
IN EFI_GUID *Protocol, OPTIONAL
IN VOID *SearchKey, OPTIONAL
IN OUT UINTN *BufferSize,
OUT EFI_HANDLE *Buffer
);
/**
Locates the handle to a device on the device path that supports the specified protocol.
@param[in] Protocol Specifies the protocol to search for.
@param[in, out] DevicePath On input, a pointer to a pointer to the device path. On output, the device
path pointer is modified to point to the remaining part of the device
path.
@param[out] Device A pointer to the returned device handle.
@retval EFI_SUCCESS The resulting handle was returned.
@retval EFI_NOT_FOUND No handles match the search.
@retval EFI_INVALID_PARAMETER Protocol is NULL.
@retval EFI_INVALID_PARAMETER DevicePath is NULL.
@retval EFI_INVALID_PARAMETER A handle matched the search and Device is NULL.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_LOCATE_DEVICE_PATH)(
IN EFI_GUID *Protocol,
IN OUT EFI_DEVICE_PATH_PROTOCOL **DevicePath,
OUT EFI_HANDLE *Device
);
/**
Adds, updates, or removes a configuration table entry from the EFI System Table.
@param[in] Guid A pointer to the GUID for the entry to add, update, or remove.
@param[in] Table A pointer to the configuration table for the entry to add, update, or
remove. May be NULL.
@retval EFI_SUCCESS The (Guid, Table) pair was added, updated, or removed.
@retval EFI_NOT_FOUND An attempt was made to delete a nonexistent entry.
@retval EFI_INVALID_PARAMETER Guid is NULL.
@retval EFI_OUT_OF_RESOURCES There is not enough memory available to complete the operation.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_INSTALL_CONFIGURATION_TABLE)(
IN EFI_GUID *Guid,
IN VOID *Table
);
/**
Returns an array of handles that support the requested protocol in a buffer allocated from pool.
@param[in] SearchType Specifies which handle(s) are to be returned.
@param[in] Protocol Provides the protocol to search by.
This parameter is only valid for a SearchType of ByProtocol.
@param[in] SearchKey Supplies the search key depending on the SearchType.
@param[out] NoHandles The number of handles returned in Buffer.
@param[out] Buffer A pointer to the buffer to return the requested array of handles that
support Protocol.
@retval EFI_SUCCESS The array of handles was returned in Buffer, and the number of
handles in Buffer was returned in NoHandles.
@retval EFI_NOT_FOUND No handles match the search.
@retval EFI_OUT_OF_RESOURCES There is not enough pool memory to store the matching results.
@retval EFI_INVALID_PARAMETER NoHandles is NULL.
@retval EFI_INVALID_PARAMETER Buffer is NULL.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_LOCATE_HANDLE_BUFFER)(
IN EFI_LOCATE_SEARCH_TYPE SearchType,
IN EFI_GUID *Protocol, OPTIONAL
IN VOID *SearchKey, OPTIONAL
OUT UINTN *NoHandles,
OUT EFI_HANDLE **Buffer
);
/**
Returns the first protocol instance that matches the given protocol.
@param[in] Protocol Provides the protocol to search for.
@param[in] Registration Optional registration key returned from
RegisterProtocolNotify().
@param[out] Interface On return, a pointer to the first interface that matches Protocol and
Registration.
@retval EFI_SUCCESS A protocol instance matching Protocol was found and returned in
Interface.
@retval EFI_NOT_FOUND No protocol instances were found that match Protocol and
Registration.
@retval EFI_INVALID_PARAMETER Interface is NULL.
Protocol is NULL.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_LOCATE_PROTOCOL)(
IN EFI_GUID *Protocol,
IN VOID *Registration, OPTIONAL
OUT VOID **Interface
);
///
/// EFI Capsule Block Descriptor
///
typedef struct {
///
/// Length in bytes of the data pointed to by DataBlock/ContinuationPointer.
///
UINT64 Length;
union {
///
/// Physical address of the data block. This member of the union is
/// used if Length is not equal to zero.
///
EFI_PHYSICAL_ADDRESS DataBlock;
///
/// Physical address of another block of
/// EFI_CAPSULE_BLOCK_DESCRIPTOR structures. This
/// member of the union is used if Length is equal to zero. If
/// ContinuationPointer is zero this entry represents the end of the list.
///
EFI_PHYSICAL_ADDRESS ContinuationPointer;
} Union;
} EFI_CAPSULE_BLOCK_DESCRIPTOR;
///
/// EFI Capsule Header.
///
typedef struct {
///
/// A GUID that defines the contents of a capsule.
///
EFI_GUID CapsuleGuid;
///
/// The size of the capsule header. This may be larger than the size of
/// the EFI_CAPSULE_HEADER since CapsuleGuid may imply
/// extended header entries
///
UINT32 HeaderSize;
///
/// Bit-mapped list describing the capsule attributes. The Flag values
/// of 0x0000 - 0xFFFF are defined by CapsuleGuid. Flag values
/// of 0x10000 - 0xFFFFFFFF are defined by this specification
///
UINT32 Flags;
///
/// Size in bytes of the capsule.
///
UINT32 CapsuleImageSize;
} EFI_CAPSULE_HEADER;
///
/// The EFI System Table entry must point to an array of capsules
/// that contain the same CapsuleGuid value. The array must be
/// prefixed by a UINT32 that represents the size of the array of capsules.
///
typedef struct {
///
/// the size of the array of capsules.
///
UINT32 CapsuleArrayNumber;
///
/// Point to an array of capsules that contain the same CapsuleGuid value.
///
VOID* CapsulePtr[1];
} EFI_CAPSULE_TABLE;
#define CAPSULE_FLAGS_PERSIST_ACROSS_RESET 0x00010000
#define CAPSULE_FLAGS_POPULATE_SYSTEM_TABLE 0x00020000
#define CAPSULE_FLAGS_INITIATE_RESET 0x00040000
/**
Passes capsules to the firmware with both virtual and physical mapping. Depending on the intended
consumption, the firmware may process the capsule immediately. If the payload should persist
across a system reset, the reset value returned from EFI_QueryCapsuleCapabilities must
be passed into ResetSystem() and will cause the capsule to be processed by the firmware as
part of the reset process.
@param[in] CapsuleHeaderArray Virtual pointer to an array of virtual pointers to the capsules
being passed into update capsule.
@param[in] CapsuleCount Number of pointers to EFI_CAPSULE_HEADER in
CaspuleHeaderArray.
@param[in] ScatterGatherList Physical pointer to a set of
EFI_CAPSULE_BLOCK_DESCRIPTOR that describes the
location in physical memory of a set of capsules.
@retval EFI_SUCCESS Valid capsule was passed. If
CAPSULE_FLAGS_PERSIT_ACROSS_RESET is not set, the
capsule has been successfully processed by the firmware.
@retval EFI_INVALID_PARAMETER CapsuleSize is NULL, or an incompatible set of flags were
set in the capsule header.
@retval EFI_INVALID_PARAMETER CapsuleCount is 0.
@retval EFI_DEVICE_ERROR The capsule update was started, but failed due to a device error.
@retval EFI_UNSUPPORTED The capsule type is not supported on this platform.
@retval EFI_OUT_OF_RESOURCES When ExitBootServices() has been previously called this error indicates the capsule
is compatible with this platform but is not capable of being submitted or processed
in runtime. The caller may resubmit the capsule prior to ExitBootServices().
@retval EFI_OUT_OF_RESOURCES When ExitBootServices() has not been previously called then this error indicates
the capsule is compatible with this platform but there are insufficient resources to process.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_UPDATE_CAPSULE)(
IN EFI_CAPSULE_HEADER **CapsuleHeaderArray,
IN UINTN CapsuleCount,
IN EFI_PHYSICAL_ADDRESS ScatterGatherList OPTIONAL
);
/**
Returns if the capsule can be supported via UpdateCapsule().
@param[in] CapsuleHeaderArray Virtual pointer to an array of virtual pointers to the capsules
being passed into update capsule.
@param[in] CapsuleCount Number of pointers to EFI_CAPSULE_HEADER in
CaspuleHeaderArray.
@param[out] MaxiumCapsuleSize On output the maximum size that UpdateCapsule() can
support as an argument to UpdateCapsule() via
CapsuleHeaderArray and ScatterGatherList.
@param[out] ResetType Returns the type of reset required for the capsule update.
@retval EFI_SUCCESS Valid answer returned.
@retval EFI_UNSUPPORTED The capsule type is not supported on this platform, and
MaximumCapsuleSize and ResetType are undefined.
@retval EFI_INVALID_PARAMETER MaximumCapsuleSize is NULL.
@retval EFI_OUT_OF_RESOURCES When ExitBootServices() has been previously called this error indicates the capsule
is compatible with this platform but is not capable of being submitted or processed
in runtime. The caller may resubmit the capsule prior to ExitBootServices().
@retval EFI_OUT_OF_RESOURCES When ExitBootServices() has not been previously called then this error indicates
the capsule is compatible with this platform but there are insufficient resources to process.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_QUERY_CAPSULE_CAPABILITIES)(
IN EFI_CAPSULE_HEADER **CapsuleHeaderArray,
IN UINTN CapsuleCount,
OUT UINT64 *MaximumCapsuleSize,
OUT EFI_RESET_TYPE *ResetType
);
/**
Returns information about the EFI variables.
@param[in] Attributes Attributes bitmask to specify the type of variables on
which to return information.
@param[out] MaximumVariableStorageSize On output the maximum size of the storage space
available for the EFI variables associated with the
attributes specified.
@param[out] RemainingVariableStorageSize Returns the remaining size of the storage space
available for the EFI variables associated with the
attributes specified.
@param[out] MaximumVariableSize Returns the maximum size of the individual EFI
variables associated with the attributes specified.
@retval EFI_SUCCESS Valid answer returned.
@retval EFI_INVALID_PARAMETER An invalid combination of attribute bits was supplied
@retval EFI_UNSUPPORTED The attribute is not supported on this platform, and the
MaximumVariableStorageSize,
RemainingVariableStorageSize, MaximumVariableSize
are undefined.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_QUERY_VARIABLE_INFO)(
IN UINT32 Attributes,
OUT UINT64 *MaximumVariableStorageSize,
OUT UINT64 *RemainingVariableStorageSize,
OUT UINT64 *MaximumVariableSize
);
//
// Firmware should stop at a firmware user interface on next boot
//
#define EFI_OS_INDICATIONS_BOOT_TO_FW_UI 0x0000000000000001
#define EFI_OS_INDICATIONS_TIMESTAMP_REVOCATION 0x0000000000000002
#define EFI_OS_INDICATIONS_FILE_CAPSULE_DELIVERY_SUPPORTED 0x0000000000000004
#define EFI_OS_INDICATIONS_FMP_CAPSULE_SUPPORTED 0x0000000000000008
#define EFI_OS_INDICATIONS_CAPSULE_RESULT_VAR_SUPPORTED 0x0000000000000010
#define EFI_OS_INDICATIONS_START_PLATFORM_RECOVERY 0x0000000000000040
#define EFI_OS_INDICATIONS_JSON_CONFIG_DATA_REFRESH 0x0000000000000080
//
// EFI Runtime Services Table
//
#define EFI_SYSTEM_TABLE_SIGNATURE SIGNATURE_64 ('I','B','I',' ','S','Y','S','T')
#define EFI_2_80_SYSTEM_TABLE_REVISION ((2 << 16) | (80))
#define EFI_2_70_SYSTEM_TABLE_REVISION ((2 << 16) | (70))
#define EFI_2_60_SYSTEM_TABLE_REVISION ((2 << 16) | (60))
#define EFI_2_50_SYSTEM_TABLE_REVISION ((2 << 16) | (50))
#define EFI_2_40_SYSTEM_TABLE_REVISION ((2 << 16) | (40))
#define EFI_2_31_SYSTEM_TABLE_REVISION ((2 << 16) | (31))
#define EFI_2_30_SYSTEM_TABLE_REVISION ((2 << 16) | (30))
#define EFI_2_20_SYSTEM_TABLE_REVISION ((2 << 16) | (20))
#define EFI_2_10_SYSTEM_TABLE_REVISION ((2 << 16) | (10))
#define EFI_2_00_SYSTEM_TABLE_REVISION ((2 << 16) | (00))
#define EFI_1_10_SYSTEM_TABLE_REVISION ((1 << 16) | (10))
#define EFI_1_02_SYSTEM_TABLE_REVISION ((1 << 16) | (02))
#define EFI_SYSTEM_TABLE_REVISION EFI_2_70_SYSTEM_TABLE_REVISION
#define EFI_SPECIFICATION_VERSION EFI_SYSTEM_TABLE_REVISION
#define EFI_RUNTIME_SERVICES_SIGNATURE SIGNATURE_64 ('R','U','N','T','S','E','R','V')
#define EFI_RUNTIME_SERVICES_REVISION EFI_SPECIFICATION_VERSION
///
/// EFI Runtime Services Table.
///
typedef struct {
///
/// The table header for the EFI Runtime Services Table.
///
EFI_TABLE_HEADER Hdr;
//
// Time Services
//
EFI_GET_TIME GetTime;
EFI_SET_TIME SetTime;
EFI_GET_WAKEUP_TIME GetWakeupTime;
EFI_SET_WAKEUP_TIME SetWakeupTime;
//
// Virtual Memory Services
//
EFI_SET_VIRTUAL_ADDRESS_MAP SetVirtualAddressMap;
EFI_CONVERT_POINTER ConvertPointer;
//
// Variable Services
//
EFI_GET_VARIABLE GetVariable;
EFI_GET_NEXT_VARIABLE_NAME GetNextVariableName;
EFI_SET_VARIABLE SetVariable;
//
// Miscellaneous Services
//
EFI_GET_NEXT_HIGH_MONO_COUNT GetNextHighMonotonicCount;
EFI_RESET_SYSTEM ResetSystem;
//
// UEFI 2.0 Capsule Services
//
EFI_UPDATE_CAPSULE UpdateCapsule;
EFI_QUERY_CAPSULE_CAPABILITIES QueryCapsuleCapabilities;
//
// Miscellaneous UEFI 2.0 Service
//
EFI_QUERY_VARIABLE_INFO QueryVariableInfo;
} EFI_RUNTIME_SERVICES;
#define EFI_BOOT_SERVICES_SIGNATURE SIGNATURE_64 ('B','O','O','T','S','E','R','V')
#define EFI_BOOT_SERVICES_REVISION EFI_SPECIFICATION_VERSION
///
/// EFI Boot Services Table.
///
typedef struct {
///
/// The table header for the EFI Boot Services Table.
///
EFI_TABLE_HEADER Hdr;
//
// Task Priority Services
//
EFI_RAISE_TPL RaiseTPL;
EFI_RESTORE_TPL RestoreTPL;
//
// Memory Services
//
EFI_ALLOCATE_PAGES AllocatePages;
EFI_FREE_PAGES FreePages;
EFI_GET_MEMORY_MAP GetMemoryMap;
EFI_ALLOCATE_POOL AllocatePool;
EFI_FREE_POOL FreePool;
//
// Event & Timer Services
//
EFI_CREATE_EVENT CreateEvent;
EFI_SET_TIMER SetTimer;
EFI_WAIT_FOR_EVENT WaitForEvent;
EFI_SIGNAL_EVENT SignalEvent;
EFI_CLOSE_EVENT CloseEvent;
EFI_CHECK_EVENT CheckEvent;
//
// Protocol Handler Services
//
EFI_INSTALL_PROTOCOL_INTERFACE InstallProtocolInterface;
EFI_REINSTALL_PROTOCOL_INTERFACE ReinstallProtocolInterface;
EFI_UNINSTALL_PROTOCOL_INTERFACE UninstallProtocolInterface;
EFI_HANDLE_PROTOCOL HandleProtocol;
VOID *Reserved;
EFI_REGISTER_PROTOCOL_NOTIFY RegisterProtocolNotify;
EFI_LOCATE_HANDLE LocateHandle;
EFI_LOCATE_DEVICE_PATH LocateDevicePath;
EFI_INSTALL_CONFIGURATION_TABLE InstallConfigurationTable;
//
// Image Services
//
EFI_IMAGE_LOAD LoadImage;
EFI_IMAGE_START StartImage;
EFI_EXIT Exit;
EFI_IMAGE_UNLOAD UnloadImage;
EFI_EXIT_BOOT_SERVICES ExitBootServices;
//
// Miscellaneous Services
//
EFI_GET_NEXT_MONOTONIC_COUNT GetNextMonotonicCount;
EFI_STALL Stall;
EFI_SET_WATCHDOG_TIMER SetWatchdogTimer;
//
// DriverSupport Services
//
EFI_CONNECT_CONTROLLER ConnectController;
EFI_DISCONNECT_CONTROLLER DisconnectController;
//
// Open and Close Protocol Services
//
EFI_OPEN_PROTOCOL OpenProtocol;
EFI_CLOSE_PROTOCOL CloseProtocol;
EFI_OPEN_PROTOCOL_INFORMATION OpenProtocolInformation;
//
// Library Services
//
EFI_PROTOCOLS_PER_HANDLE ProtocolsPerHandle;
EFI_LOCATE_HANDLE_BUFFER LocateHandleBuffer;
EFI_LOCATE_PROTOCOL LocateProtocol;
EFI_INSTALL_MULTIPLE_PROTOCOL_INTERFACES InstallMultipleProtocolInterfaces;
EFI_UNINSTALL_MULTIPLE_PROTOCOL_INTERFACES UninstallMultipleProtocolInterfaces;
//
// 32-bit CRC Services
//
EFI_CALCULATE_CRC32 CalculateCrc32;
//
// Miscellaneous Services
//
EFI_COPY_MEM CopyMem;
EFI_SET_MEM SetMem;
EFI_CREATE_EVENT_EX CreateEventEx;
} EFI_BOOT_SERVICES;
///
/// Contains a set of GUID/pointer pairs comprised of the ConfigurationTable field in the
/// EFI System Table.
///
typedef struct {
///
/// The 128-bit GUID value that uniquely identifies the system configuration table.
///
EFI_GUID VendorGuid;
///
/// A pointer to the table associated with VendorGuid.
///
VOID *VendorTable;
} EFI_CONFIGURATION_TABLE;
///
/// EFI System Table
///
typedef struct {
///
/// The table header for the EFI System Table.
///
EFI_TABLE_HEADER Hdr;
///
/// A pointer to a null terminated string that identifies the vendor
/// that produces the system firmware for the platform.
///
CHAR16 *FirmwareVendor;
///
/// A firmware vendor specific value that identifies the revision
/// of the system firmware for the platform.
///
UINT32 FirmwareRevision;
///
/// The handle for the active console input device. This handle must support
/// EFI_SIMPLE_TEXT_INPUT_PROTOCOL and EFI_SIMPLE_TEXT_INPUT_EX_PROTOCOL.
///
EFI_HANDLE ConsoleInHandle;
///
/// A pointer to the EFI_SIMPLE_TEXT_INPUT_PROTOCOL interface that is
/// associated with ConsoleInHandle.
///
EFI_SIMPLE_TEXT_INPUT_PROTOCOL *ConIn;
///
/// The handle for the active console output device.
///
EFI_HANDLE ConsoleOutHandle;
///
/// A pointer to the EFI_SIMPLE_TEXT_OUTPUT_PROTOCOL interface
/// that is associated with ConsoleOutHandle.
///
EFI_SIMPLE_TEXT_OUTPUT_PROTOCOL *ConOut;
///
/// The handle for the active standard error console device.
/// This handle must support the EFI_SIMPLE_TEXT_OUTPUT_PROTOCOL.
///
EFI_HANDLE StandardErrorHandle;
///
/// A pointer to the EFI_SIMPLE_TEXT_OUTPUT_PROTOCOL interface
/// that is associated with StandardErrorHandle.
///
EFI_SIMPLE_TEXT_OUTPUT_PROTOCOL *StdErr;
///
/// A pointer to the EFI Runtime Services Table.
///
EFI_RUNTIME_SERVICES *RuntimeServices;
///
/// A pointer to the EFI Boot Services Table.
///
EFI_BOOT_SERVICES *BootServices;
///
/// The number of system configuration tables in the buffer ConfigurationTable.
///
UINTN NumberOfTableEntries;
///
/// A pointer to the system configuration tables.
/// The number of entries in the table is NumberOfTableEntries.
///
EFI_CONFIGURATION_TABLE *ConfigurationTable;
} EFI_SYSTEM_TABLE;
/**
This is the declaration of an EFI image entry point. This entry point is
the same for UEFI Applications, UEFI OS Loaders, and UEFI Drivers including
both device drivers and bus drivers.
@param[in] ImageHandle The firmware allocated handle for the UEFI image.
@param[in] SystemTable A pointer to the EFI System Table.
@retval EFI_SUCCESS The operation completed successfully.
@retval Others An unexpected error occurred.
**/
typedef
EFI_STATUS
(EFIAPI *EFI_IMAGE_ENTRY_POINT)(
IN EFI_HANDLE ImageHandle,
IN EFI_SYSTEM_TABLE *SystemTable
);
//
// EFI Load Option. This data structure describes format of UEFI boot option variables.
//
// NOTE: EFI Load Option is a byte packed buffer of variable length fields.
// The first two fields have fixed length. They are declared as members of the
// EFI_LOAD_OPTION structure. All the other fields are variable length fields.
// They are listed in the comment block below for reference purposes.
//
#pragma pack(1)
typedef struct _EFI_LOAD_OPTION {
///
/// The attributes for this load option entry. All unused bits must be zero
/// and are reserved by the UEFI specification for future growth.
///
UINT32 Attributes;
///
/// Length in bytes of the FilePathList. OptionalData starts at offset
/// sizeof(UINT32) + sizeof(UINT16) + StrSize(Description) + FilePathListLength
/// of the EFI_LOAD_OPTION descriptor.
///
UINT16 FilePathListLength;
///
/// The user readable description for the load option.
/// This field ends with a Null character.
///
// CHAR16 Description[];
///
/// A packed array of UEFI device paths. The first element of the array is a
/// device path that describes the device and location of the Image for this
/// load option. The FilePathList[0] is specific to the device type. Other
/// device paths may optionally exist in the FilePathList, but their usage is
/// OSV specific. Each element in the array is variable length, and ends at
/// the device path end structure. Because the size of Description is
/// arbitrary, this data structure is not guaranteed to be aligned on a
/// natural boundary. This data structure may have to be copied to an aligned
/// natural boundary before it is used.
///
// EFI_DEVICE_PATH_PROTOCOL FilePathList[];
///
/// The remaining bytes in the load option descriptor are a binary data buffer
/// that is passed to the loaded image. If the field is zero bytes long, a
/// NULL pointer is passed to the loaded image. The number of bytes in
/// OptionalData can be computed by subtracting the starting offset of
/// OptionalData from total size in bytes of the EFI_LOAD_OPTION.
///
// UINT8 OptionalData[];
} EFI_LOAD_OPTION;
#pragma pack()
//
// EFI Load Options Attributes
//
#define LOAD_OPTION_ACTIVE 0x00000001
#define LOAD_OPTION_FORCE_RECONNECT 0x00000002
#define LOAD_OPTION_HIDDEN 0x00000008
#define LOAD_OPTION_CATEGORY 0x00001F00
#define LOAD_OPTION_CATEGORY_BOOT 0x00000000
#define LOAD_OPTION_CATEGORY_APP 0x00000100
#define EFI_BOOT_OPTION_SUPPORT_KEY 0x00000001
#define EFI_BOOT_OPTION_SUPPORT_APP 0x00000002
#define EFI_BOOT_OPTION_SUPPORT_SYSPREP 0x00000010
#define EFI_BOOT_OPTION_SUPPORT_COUNT 0x00000300
///
/// EFI Boot Key Data
///
typedef union {
struct {
///
/// Indicates the revision of the EFI_KEY_OPTION structure. This revision level should be 0.
///
UINT32 Revision : 8;
///
/// Either the left or right Shift keys must be pressed (1) or must not be pressed (0).
///
UINT32 ShiftPressed : 1;
///
/// Either the left or right Control keys must be pressed (1) or must not be pressed (0).
///
UINT32 ControlPressed : 1;
///
/// Either the left or right Alt keys must be pressed (1) or must not be pressed (0).
///
UINT32 AltPressed : 1;
///
/// Either the left or right Logo keys must be pressed (1) or must not be pressed (0).
///
UINT32 LogoPressed : 1;
///
/// The Menu key must be pressed (1) or must not be pressed (0).
///
UINT32 MenuPressed : 1;
///
/// The SysReq key must be pressed (1) or must not be pressed (0).
///
UINT32 SysReqPressed : 1;
UINT32 Reserved : 16;
///
/// Specifies the actual number of entries in EFI_KEY_OPTION.Keys, from 0-3. If
/// zero, then only the shift state is considered. If more than one, then the boot option will
/// only be launched if all of the specified keys are pressed with the same shift state.
///
UINT32 InputKeyCount : 2;
} Options;
UINT32 PackedValue;
} EFI_BOOT_KEY_DATA;
///
/// EFI Key Option.
///
#pragma pack(1)
typedef struct {
///
/// Specifies options about how the key will be processed.
///
EFI_BOOT_KEY_DATA KeyData;
///
/// The CRC-32 which should match the CRC-32 of the entire EFI_LOAD_OPTION to
/// which BootOption refers. If the CRC-32s do not match this value, then this key
/// option is ignored.
///
UINT32 BootOptionCrc;
///
/// The Boot#### option which will be invoked if this key is pressed and the boot option
/// is active (LOAD_OPTION_ACTIVE is set).
///
UINT16 BootOption;
///
/// The key codes to compare against those returned by the
/// EFI_SIMPLE_TEXT_INPUT and EFI_SIMPLE_TEXT_INPUT_EX protocols.
/// The number of key codes (0-3) is specified by the EFI_KEY_CODE_COUNT field in KeyOptions.
///
//EFI_INPUT_KEY Keys[];
} EFI_KEY_OPTION;
#pragma pack()
//
// EFI File location to boot from on removable media devices
//
#define EFI_REMOVABLE_MEDIA_FILE_NAME_IA32 L"\\EFI\\BOOT\\BOOTIA32.EFI"
#define EFI_REMOVABLE_MEDIA_FILE_NAME_IA64 L"\\EFI\\BOOT\\BOOTIA64.EFI"
#define EFI_REMOVABLE_MEDIA_FILE_NAME_X64 L"\\EFI\\BOOT\\BOOTX64.EFI"
#define EFI_REMOVABLE_MEDIA_FILE_NAME_ARM L"\\EFI\\BOOT\\BOOTARM.EFI"
#define EFI_REMOVABLE_MEDIA_FILE_NAME_AARCH64 L"\\EFI\\BOOT\\BOOTAA64.EFI"
#define EFI_REMOVABLE_MEDIA_FILE_NAME_RISCV64 L"\\EFI\\BOOT\\BOOTRISCV64.EFI"
+#define EFI_REMOVABLE_MEDIA_FILE_NAME_LOONGARCH64 L"\\EFI\\BOOT\\BOOTLOONGARCH64.EFI"
#if defined (MDE_CPU_IA32)
#define EFI_REMOVABLE_MEDIA_FILE_NAME EFI_REMOVABLE_MEDIA_FILE_NAME_IA32
#elif defined (MDE_CPU_X64)
#define EFI_REMOVABLE_MEDIA_FILE_NAME EFI_REMOVABLE_MEDIA_FILE_NAME_X64
#elif defined (MDE_CPU_EBC)
#elif defined (MDE_CPU_ARM)
#define EFI_REMOVABLE_MEDIA_FILE_NAME EFI_REMOVABLE_MEDIA_FILE_NAME_ARM
#elif defined (MDE_CPU_AARCH64)
#define EFI_REMOVABLE_MEDIA_FILE_NAME EFI_REMOVABLE_MEDIA_FILE_NAME_AARCH64
#elif defined (MDE_CPU_RISCV64)
#define EFI_REMOVABLE_MEDIA_FILE_NAME EFI_REMOVABLE_MEDIA_FILE_NAME_RISCV64
-#else
+ #elif defined (MDE_CPU_LOONGARCH64)
+#define EFI_REMOVABLE_MEDIA_FILE_NAME EFI_REMOVABLE_MEDIA_FILE_NAME_LOONGARCH64
+ #else
#error Unknown Processor Type
#endif
//
// The directory within the active EFI System Partition defined for delivery of capsule to firmware
//
#define EFI_CAPSULE_FILE_DIRECTORY L"\\EFI\\UpdateCapsule\\"
#include
#include
#include
#endif