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diff --git a/Lessons/Lesson_15/README.md b/Lessons/Lesson_15/README.md new file mode 100644 index 0000000..55447ca --- /dev/null +++ b/Lessons/Lesson_15/README.md @@ -0,0 +1,359 @@ +Let's print content of variables that define boot options in UEFI. + +To do it, we need to use `GetVariable()` API function from the EFI Runtime Services: +``` +GetVariable() + +Summary: +Returns the value of a variable. + +Prototype: +typedef +EFI_STATUS +GetVariable ( + IN CHAR16 *VariableName, + IN EFI_GUID *VendorGuid, + OUT UINT32 *Attributes OPTIONAL, + IN OUT UINTN *DataSize, + OUT VOID *Data OPTIONAL + ); + +Parameters: +VariableName A Null-terminated string that is the name of the vendor’s variable. +VendorGuid A unique identifier for the vendor +Attributes If not NULL, a pointer to the memory location to return the + attributes bitmask for the variable. + If not NULL, then Attributes is set on output both when + EFI_SUCCESS and when EFI_BUFFER_TOO_SMALL is returned. +DataSize On input, the size in bytes of the return Data buffer. + On output the size of data returned in Data. +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. + +Description: +Each vendor may create and manage its own variables without the risk of name conflicts by using a +unique VendorGuid. When a variable is set its Attributes are supplied to indicate how the data variable +should be stored and maintained by the system. The attributes affect when the variable may be accessed +and volatility of the data + +If the Data buffer is too small to hold the contents of the variable, the error EFI_BUFFER_TOO_SMALL is +returned and DataSize is set to the required buffer size to obtain the data. + +Status Codes Returned: +EFI_SUCCESS The function completed successfully. +EFI_NOT_FOUND The variable was not found. +EFI_BUFFER_TOO_SMALL The DataSize is too small for the result. DataSize has been + updated with the size needed to complete the request. If + Attributes is not NULL, then the attributes bitmask for the + variable has been stored to the memory location pointed-to by + Attributes. +... + +``` + +In previous lesson we've discovered that these options are present in our environment under GUID `EFI_GLOBAL_VARIABLE` (gEfiGlobalVariableGuid): +``` +Boot0000 +Boot0001 +Boot0002 +Boot0003 +Boot0004 +BootCurrent +BootOrder +``` + +If we look at the UEFI spec for these options description we would find: +``` +Each Boot#### variable contains an EFI_LOAD_OPTION. Each Boot#### variable is the name “Boot” +appended with a unique four digit hexadecimal number. For example, Boot0001, Boot0002, Boot0A02, +etc. + +... + +The BootOrder variable contains an array of UINT16’s that make up an ordered list of the Boot#### +options. The first element in the array is the value for the first logical boot option, the second element is +the value for the second logical boot option, etc. The BootOrder order list is used by the firmware’s +boot manager as the default boot order. + +... + +The BootCurrent variable is a single UINT16 that defines the Boot#### option that was selected on +the current boot. +``` + +Create `ShowBootVariables` for this lesson. + +First let's try to get simple `UINT16 BootCurrent` option. + +We would be getting variables a lot in this program, so it is best to create a function that abstracts all the necessities of the `GetVariable` API calls: +``` +EFI_STATUS +GetNvramVariable( CHAR16 *VariableName, + EFI_GUID *VariableOwnerGuid, + VOID **Buffer, + UINTN *BufferSize) +{ + UINTN Size = 0; + *BufferSize = 0; + + EFI_STATUS Status = gRT->GetVariable(VariableName, VariableOwnerGuid, NULL, &Size, NULL); + if (Status != EFI_BUFFER_TOO_SMALL) { + Print(L"Error! 'gRT->GetVariable' call returned %r\n", Status); + return Status; + } + + *Buffer = AllocateZeroPool(Size); + if (!Buffer) { + Print(L"Error! 'AllocateZeroPool' call returned %r\n", Status); + return EFI_OUT_OF_RESOURCES; + } + + Status = gRT->GetVariable(VariableName, VariableOwnerGuid, NULL, &Size, *Buffer); + if (Status == EFI_SUCCESS) { + *BufferSize = Size; + } else { + FreePool( *Buffer ); + *Buffer = NULL; + } + + return Status; +} +``` + +As with many other different UEFI APIs first `GetVariable` call gives us `EFI_BUFFER_TOO_SMALL` error, but fills `Size` variable with the size of the array that we need to allocate and pass to this function for the correct execution. +We allocate necessary size with the `AllocateZeroPool` edk2 library call, like we did it in previous lesson. After that we call `GetVariable` function for the second time, expecting `EFI_SUCCESS` status. + + +The main function would look like this: +``` +#include <Library/UefiRuntimeServicesTableLib.h> +#include <Library/UefiBootServicesTableLib.h> +#include <Library/UefiLib.h> +#include <Library/MemoryAllocationLib.h> + +EFI_STATUS +GetNvramVariable( CHAR16 *VariableName, + EFI_GUID *VariableOwnerGuid, + VOID **Buffer, + UINTN *BufferSize) +{ + ... +} + +INTN EFIAPI ShellAppMain(IN UINTN Argc, IN CHAR16 **Argv) +{ + UINTN OptionSize; + EFI_STATUS Status; + + UINT16* BootCurrent; + Status = GetNvramVariable(L"BootCurrent", &gEfiGlobalVariableGuid, (VOID**)&BootCurrent, &OptionSize); + if (Status == EFI_SUCCESS) { + Print(L"BootCurrent=%d\n", *BootCurrent); + } else { + Print(L"Can't get BootCurrent variable\n"); + } + + return EFI_SUCCESS; +} +``` + +If we execute this code under OVMF we would get: +``` +FS0:\> ShowBootVariables.efi +3 +``` +This means that `Boot0003` is active. + + +Now let's get `UINT16 BootOrder[]` variable. It is an array of XXXX numbers that describe Boot option priority. +So `{0,2,4,1,3}` for example would mean this order: +``` +Boot0000 +Boot0002 +Boot0004 +Boot0001 +Boot0003 +``` + +This is the code to get and print this array: +``` +UINT16* BootOrderArray; +Status = GetNvramVariable(L"BootOrder", &gEfiGlobalVariableGuid, (VOID**)&BootOrderArray, &OptionSize); +if (Status == EFI_SUCCESS) { + for (UINTN i=0; i<(OptionSize/sizeof(UINT16)); i++) { + Print(L"Boot%04d%s\n", BootOrderArray[i], (BootOrderArray[i] == *BootCurrent)? L"*" : L"" ); + } +} else { + Print(L"Can't get BootOrder variable\n"); +} +``` + +If we execute this code under OVMF we would get: +``` +Boot0000 +Boot0001 +Boot0002 +Boot0003* +Boot0004 +``` + + +Now let's print information about every `Boot####` option. + +According to the UEFI the spec these options are stored in a `EFI_LOAD_OPTION` structure: +``` +typedef struct _EFI_LOAD_OPTION { + UINT32 Attributes; + UINT16 FilePathListLength; + // CHAR16 Description[]; + // EFI_DEVICE_PATH_PROTOCOL FilePathList[]; + // UINT8 OptionalData[]; +} EFI_LOAD_OPTION; + +Parameters +Attributes The attributes for this load option entry. All unused bits must be zero + and are reserved by the UEFI specification for future growth. +FilePathListLength Length in bytes of the FilePathList. OptionalData starts at + offset sizeof(UINT32) + sizeof(UINT16) + + StrSize(Description) + FilePathListLength of the + EFI_LOAD_OPTION descriptor. +Description The user readable description for the load option. This field ends + with a Null character. +FilePathList 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. +OptionalData 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. +``` +In edk2 it is defined in a file https://github.com/tianocore/edk2/blob/master/MdePkg/Include/Uefi/UefiSpec.h + +Pay attention to the fact that some fields in this structure are commented: +``` +// CHAR16 Description[]; +// EFI_DEVICE_PATH_PROTOCOL FilePathList[]; +// UINT8 OptionalData[]; +``` +It is because these fields are variable size arrays, so we need to calculate offsets to them dynamically. + +Create a function that accepts names of a Boot variable (such as "Boot0003") and outputs all the needed information about it: +``` +VOID PrintBootOption(CHAR16* BootOptionName) +{ + UINTN OptionSize; + UINT8* Buffer; + + EFI_STATUS Status = GetNvramVariable(BootOptionName, &gEfiGlobalVariableGuid, (VOID**)&Buffer, &OptionSize); + if (Status == EFI_SUCCESS) { + EFI_LOAD_OPTION* LoadOption = (EFI_LOAD_OPTION*) Buffer; + CHAR16* Description = (CHAR16*)(Buffer + sizeof (EFI_LOAD_OPTION)); + UINTN DescriptionSize = StrSize(Description); + + Print(L"%s\n", Description); + if (LoadOption->FilePathListLength != 0) { + VOID* FilePathList = (UINT8 *)Description + DescriptionSize; + CHAR16* DevPathString = ConvertDevicePathToText(FilePathList, TRUE, FALSE); + Print(L"%s\n", DevPathString); + } + } else { + Print(L"Can't get %s variable\n", BootOptionName); + } +} +``` + +This code uses pointer arithmetics that we've discussed above. To get `Description` field size we simply use `StrSize(Description)` call as `Description` field always ends with Null. + +To print DevicePath as a string we use `ConvertDevicePathToText` call (we've used it earlier in our `ImageInfo` application). To use it we need to add `#include <Library/DevicePathLib.h>` to our program. + +Now we need to construct "BootXXXX" variables from a `BootOrder` numbers. + +To do so we would use `UnicodeSPrint` function from the https://github.com/tianocore/edk2/blob/master/MdePkg/Include/Library/PrintLib.h +``` +/** + Produces a Null-terminated Unicode string in an output buffer based on a Null-terminated + Unicode format string and variable argument list. + This function is similar as snprintf_s defined in C11. + + ... + + @param StartOfBuffer A pointer to the output buffer for the produced Null-terminated + Unicode string. + @param BufferSize The size, in bytes, of the output buffer specified by StartOfBuffer. + @param FormatString A Null-terminated Unicode format string. + @param ... Variable argument list whose contents are accessed based on the + format string specified by FormatString. + @return The number of Unicode characters in the produced output buffer not including the + Null-terminator. +**/ + +UINTN +EFIAPI +UnicodeSPrint ( + OUT CHAR16 *StartOfBuffer, + IN UINTN BufferSize, + IN CONST CHAR16 *FormatString, + ... + ); +``` + +Just in case in the same file there is a similar function for ASCII: +``` +UINTN +EFIAPI +AsciiSPrint ( + OUT CHAR8 *StartOfBuffer, + IN UINTN BufferSize, + IN CONST CHAR8 *FormatString, + ... + ); +``` + + +So the code inside BootOrder loop now would look like this: +``` +CHAR16 BootOptionStr[sizeof("Boot####")+1]; +UnicodeSPrint(BootOptionStr, (sizeof("Boot####")+1)*sizeof(CHAR16), L"Boot%04x", BootOrderArray[i]); +Print(L"%s%s\n", BootOptionStr, (BootOrderArray[i] == *BootCurrent)? L"*" : L"" ); +PrintBootOption(BootOptionStr); +Print(L"\n"); +``` + +Don't forget to add `#include <Library/PrintLib.h>` to the start of the file. + + +If we compile our app and execute it under OVMF we would get: +``` +FS0:\> ShowBootVariables.efi +Boot0000 +UiApp +Fv(7CB8BDC9-F8EB-4F34-AAEA-3EE4AF6516A1)/FvFile(462CAA21-7614-4503-836E-8AB6F4662331) + +Boot0001 +UEFI QEMU DVD-ROM QM00003 +PciRoot(0x0)/Pci(0x1,0x1)/Ata(0x0) + +Boot0002 +UEFI QEMU HARDDISK QM00001 +PciRoot(0x0)/Pci(0x1,0x1)/Ata(0x0) + +Boot0003* +EFI Internal Shell +Fv(7CB8BDC9-F8EB-4F34-AAEA-3EE4AF6516A1)/FvFile(7C04A583-9E3E-4F1C-AD65-E05268D0B4D1) + +Boot0004 +UEFI PXEv4 (MAC:525400123456) +PciRoot(0x0)/Pci(0x3,0x0)/MAC(525400123456,0x1)/IPv4(0.0.0.0) +``` + +We are definitely in the UEFI shell, so the `BootCurrent`(="*") is placed correctly. + + |