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On enabling the /analyse option the VS2017 compiler reports: warning C6001: Using uninitialized memory. This warning is reported for the Status variable in AddGenericInitiatorAffinity() as it is not initialised to a default value. This condition is only valid if GenInitAffCount is equal to 0. Since GenInitAffCount is already checked in BuildSratTable() this condition can never happen. The value of the Status variable is returned in failure cases from appropriate locations in AddGenericInitiatorAffinity(). The only case where Status value is being used un-initialised is the return statement at the end of AddGenericInitiatorAffinity(). Therefore, to fix this issue EFI_SUCCESS can be safely returned instead of returning the Status variable at the end of the function. Signed-off-by: Sami Mujawar <sami.mujawar@arm.com> Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com> |
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DynamicTables.dsc.inc | ||
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Readme.md |
Readme.md
Dynamic Tables Framework
Dynamic Tables Framework provides mechanisms to reduce the amount of effort required in porting firmware to new platforms. The aim is to provide an implementation capable of generating the firmware tables from an external source. This is potentially a management node, either local or remote, or, where suitable, a file that might be generated from the system construction. This initial release does not fully implement that - the configuration is held in local UEFI modules.
Feature Summary
The dynamic tables framework is designed to generate standardised firmware tables that describe the hardware information at run-time. A goal of standardised firmware is to have a common firmware for a platform capable of booting both Windows and Linux operating systems.
Traditionally the firmware tables are handcrafted using ACPI Source Language (ASL), Table Definition Language (TDL) and C-code. This approach can be error prone and involves time consuming debugging. In addition, it may be desirable to configure platform hardware at runtime such as: configuring the number of cores available for use by the OS, or turning SoC features ON or OFF.
The dynamic tables framework simplifies this by providing a set of standard table generators, that are implemented as libraries. These generators query a platform specific component, the 'Configuration Manager', to collate the information required for generating the tables at run-time.
The framework also provides the ability to implement custom/OEM generators; thereby facilitating support for custom tables. The custom generators can also utilize the existing standard generators and override any functionality if needed.
The framework currently implements a set of standard ACPI table generators for ARM architecture, that can generate Server Base Boot Requirement (SBBR) compliant tables. Although, the set of standard generators implement the functionality required for ARM architecture; the framework is extensible, and support for other architectures can be added easily.
The framework currently supports the following table generators for ARM:
- DBG2 - Debug Port Table 2
- DSDT - Differentiated system description table. This is essentially a RAW table generator.
- FADT - Fixed ACPI Description Table
- GTDT - Generic Timer Description Table
- IORT - IO Remapping Table
- MADT - Multiple APIC Description Table
- MCFG - PCI Express memory mapped configuration space base address Description Table
- SPCR - Serial Port Console Redirection Table
- SSDT - Secondary System Description Table. This is essentially a RAW table generator.
Roadmap
The current implementation of the Configuration Manager populates the platform information statically as a C structure. Further enhancements to introduce runtime loading of platform information from a platform information file is planned.
Also support for generating SMBIOS tables is planned and will be added subsequently.
Related Modules
ACPICA iASL compiler
The RAW table generator, used to process the DSDT/SSDT files depends on the iASL compiler to convert the DSDT/SSDT ASL files to a C array containing the hex AML code. The "-tc" option of the iASL compiler has been enhanced to support generation of an AML hex file (C header) with a unique symbol name so that it is suitable for inclusion from a C source file.
Related Links
https://github.com/acpica/acpica.git
Supported Platforms
- Juno
- FVP Models
Build Instructions
-
Set path for the iASL compiler with support for generating a C header file as output.
-
Set PACKAGES_PATH to point to the locations of the following repositories:
Example:
set PACKAGES_PATH=%CD%\edk2;%CD%\edk2-platforms;
or
export PACKAGES_PATH=$PWD/edk2:$PWD/edk2-platforms
- To enable Dynamic tables framework the 'DYNAMIC_TABLES_FRAMEWORK' option must be defined. This can be passed as a command line parameter to the edk2 build system.
Example:
build -a AARCH64 -p Platform\ARM\JunoPkg\ArmJuno.dsc -t GCC5 -D DYNAMIC_TABLES_FRAMEWORK
or
build -a AARCH64 -p Platform\ARM\VExpressPkg\ArmVExpress-FVP-AArch64.dsc -t GCC5 -D DYNAMIC_TABLES_FRAMEWORK
Prerequisites
ACPICA iASL compiler with the enhanced "-tc" option to support generation of AML hex (C header) files with unique symbol names.
A patch 'iASL: Enhance the -tc option (create AML hex file in C)', dated 16 March 2018 (2018-03-16), to enable this support has been integrated to the ACPICA source repository.
Ensure that the iASL compiler used for building Dynamic Tables Framework has this feature enabled.
This feature was made available in the ACPICA Compiler update Version 20180508, dated 8 May 2018 (2018-05-08).
Documentation
Refer to the following presentation from UEFI Plugfest Seattle 2018: