AmlLib library implements an AML parser, AML tree interface,
serialiser, code generator and other interfaces to generate
Definition Block tables.
The AmlLib APIs are a collection of interfaces that enable
parsing, iterating, modifying, adding, and serialising AML
data to generate a Definition Block table.
The AmlLib APIs are declared in Include\AmlLib\AmlLib.h
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
AML Core interface APIs are internal APIs of the
AmlLib library. These APIs can be used to:
- Create/Delete/Clone an AML tree/node
- Get/update Fixed and Variable arguments
- Serialize an AML tree.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
AML Codegen is a Dynamic AML technique that facilitates
generation of small segments of AML code. The AML code
generated using AML Codegen is represented as nodes in
the AML Tree.
AML Resource Data Codegen implements interfaces required
for generating Resource Data elements that can be attached
to an AML tree.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
AML Codegen is a Dynamic AML technique that facilitates
generation of small segments of AML code. The AML code
generated using AML Codegen is represented as nodes in
the AML Tree.
Some examples where AML Codegen can be used are:
- AML Codegen APIs can be used to generate a simple
AML tree.
- An AML template can be parsed to create an AML
tree. This AML Tree can be searched to locate a
node that needs updating. The AML Codegen APIs
can be used to attach new AML nodes.
- A combination of AML Fixup and AML Codegen can
be used to generate an AML tree.
The AML tree can then be serialised as a Definition
Block table.
Following AML Codegen APIs are implemented:
- AmlCodeGenDefinitionBlock()
- AmlCodeGenScope()
- AmlCodeGenNameString()
- AmlCodeGenNameInteger()
- AmlCodeGenDevice()
These AML Codegen APIs in combination with AML Resource
Data Codegen APIs can be used to generate a simple AML
tree.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The AML language allows defining field lists in a Definition
Block. Although Dynamic AML does not provide interfaces to
modify Field Lists; an AML template code may contain Field
lists and the AML parser must be capable of parsing and
representing the Field lists in the AML tree.
The AML parser creates an Object node that represents the
'Field Node'. The AML Field list parser creates an object
node for each field element parsed in the AML byte stream,
and adds them to the variable list of arguments of the
'Field Node'.
Nodes that can have a field list are referred as 'Field
nodes'. They have the AML_HAS_FIELD_LIST attribute set in
the AML encoding.
According to the ACPI 6.3 specification, s20.2.5.2 "Named
Objects Encoding", field elements can be:
- NamedField := NameSeg PkgLength;
- ReservedField := 0x00 PkgLength;
- AccessField := 0x01 AccessType AccessAttrib;
- ConnectField := <0x02 NameString> | <0x02 BufferData>;
- ExtendedAccessField := 0x03 AccessType ExtendedAccessAttrib
AccessLength.
A small set of opcodes describes the field elements. They are
referred as field opcodes. An AML_BYTE_ENCODING table has been
created for field OpCodes.
Field elements:
- don't have a SubOpCode;
- have at most 3 fixed arguments (as opposed to 6 for standard
AML objects);
- don't have a variable list of arguments;
- only the NamedField field element is part of the AML namespace.
ConnectField's BufferData is a buffer node containing a single
resource data element.
NamedField field elements do not have an AML OpCode. NameSeg
starts with a Char type and can thus be differentiated from the
Opcodes for other fields.
A pseudo OpCode has been created to simplify the parser.
Following is a representation of a field node in an AML tree:
(FieldNode)
\
|- [0][1][3] # Fixed Arguments
|- {(FldEl0)->(FldEl1)->...)} # Variable Arguments
Where FldEl[n] is one of NamedField, ReservedField, AccessField,
ConnectField, ExtendedAccessField.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The AML language allows a Definition Block to implement
methods that an Operating System can invoke at runtime.
Although Dynamic AML does not provide interfaces to
modify AML methods; an AML template code may contain
methods and/or method invocations.
Method definitions have an opcode defined in the AML
encoding and can be easily parsed. However, the language
does not define an opcode for method invocation. Method
invocations are represented as a NameString followed by
the arguments to the method. This poses a significant
challenge for the AML parser as it has to determine if
a NameString appearing in the AML byte stream is a method
invocation and if it is a method invocation, then how
many arguments follow.
This also means the Method definition must occur prior to
the method invocation in the AML byte stream. This is a
hard requirement for the AML parser.
The AML method parser maintains a NameSpaceRefList that
keeps a track of every namespace node and its raw AML
absolute path. The AmlIsMethodInvocation() searches the
NameSpaceRefList to determine if a NameString matches
a Method definition.
A pseudo opcode has been defined in the AML encoding to
represent the Method invocation in the AML tree.
The AML encoding for method invocations in the ACPI
specification 6.3 is:
MethodInvocation := NameString TermArgList
The AmlLib library redefines this as:
MethodInvocation := MethodInvocationOp NameString
ArgumentCount TermArgList
ArgumentCount := ByteData
Where MethodInvocationOp is the pseudo opcode and
ArgumentCount is the number of arguments passed to
the method.
NOTE:
The AmlLib library's definition for a method
invocation only applies to the representation
of method invocation node in the AML tree.
When computing the size of a tree or serialising
it, the additional data is not taken into account
i.e. the MethodInvocationOp and the ArgumentCount
are stripped before serialising.
Method invocation nodes have the AML_METHOD_INVOVATION
attribute set in the AmlLib library's representation of
the AML encoding.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Resource data are defined in the ACPI 6.3 specification,
s6.4 "Resource Data Types for ACPI". They can be created
using the ASL ResourceTemplate () statement, cf s19.3.3
"ASL Resource Templates".
Resource data can be of the small or large type and are
defined by their encoding. The resource data is stored
in the Bytelist of a BufferOp node. The Bytelist of a
BufferOp node is represented by an AML Data node in
the AML tree.
The resource data parser, examines the Bytelist (Data
node buffer) to detect the presence of resource data.
If the Bytelist data matches the encoding for resource
data types, the resource data parser fragments the
Bytelist containing the resource data buffer into
resource data elements represented as individual Data
nodes and stores them in the variable arguments list
of the BufferOp object nodes.
Example: ASL code and the corresponding AML tree
representation for the resource data.
ASL Code
--------
Name (_CRS, ResourceTemplate() {
QWordMemory (...)
Interrupt (...)
}
AML Tree
--------
(NameOp)
\
|-[_CRS]-[BufferOp] # Fixed Arguments
|-{NULL} \ # Variable Argument
\ list
|-[BuffSize] # Fixed Arguments
|-{(Rd1)->(Rd2)->(EndTag)} # Variable Argument
list
Where:
Rd1 - QWordMemory resource data element.
Rd2 - Interrupt resource data element.
EndTag - Resource data end tag.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Resource data are defined in the ACPI 6.3 specification,
s6.4 "Resource Data Types for ACPI". They can be created
using the ASL ResourceTemplate () statement, cf s19.3.3
"ASL Resource Templates".
Resource data can be of the small or large type and are
defined by their encoding. The resource data is stored
in the Bytelist of a BufferOp node. To simplify
operations on resource data, the resource data parser
examines the Bytelist to detect the presence of resource
data. If the data matches the encoding of resource
data type(s), the parser fragments the resource data
buffer into resource data elements (data nodes) and
stores them in the variable arguments list of the
BufferOp node.
The resource data helper provides functions and macros
to assist operations on resource data elements.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Both ASL and AML are declarative language. The ASL code
is compiled to AML bytecode. The AML bytecode is processed
by the ACPI AML interpreter that runs as part of an OS.
AML has a complex encoding making dynamic generation of
Definition Block tables difficult.
Dynamic AML generation involves techniques like AML Fixup
and AML Codegen, both requiring parsing of AML bytecode.
The AML parser is a module that parses an AML byte stream
and represents it as an AML tree. Representing the AML
bytecode as an AML tree is key to reducing the complexity
and enabling Dynamic AML generation.
In an AML Tree each AML statement (that also corresponds
to an ASL statement) is represented as an 'Object Node'.
Each Object Node has an OpCode and up to 6 Fixed Arguments
followed by a list of Variable Arguments.
(ObjectNode)
\
|- [0][1][2][3][4][5] # Fixed Arguments
|- {(VarArg1)->(VarArg2)->...N} # Variable Arguments
A Fixed Argument or Variable Argument can be either an
Object Node or a Data Node.
A 'Data Node' consists of a data buffer.
A 'Root Node' is a special type of Object Node that does
not have an Opcode or Fixed Arguments. It only has a list
of Variable Arguments. The Root Node is at the top of the
AML tree and contains the Definition Block Header.
The AML parser uses the 'AML Encoding' to parse an AML byte
stream and represents it as an AML Tree. Representing in the
form of an AML tree simplifies modification, addition and
removal of the tree nodes. The modified tree can then be
serialised to a buffer representing a Definition Block table.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
AML is a declarative language that is processed by the
ACPI AML interpreter. The ACPI AML interpreter will
compile the set of declarations into the ACPI Namespace
at definition block load time.
The hardware information described in AML is effectively
mapped in the ACPI Namespace. The AML ACPI namespace
interface implement the functionality to search the ACPI
Namespace. Example: The AmlFindNode() can be used to locate
a device node in the ACPI namespace using an ASL path as
the search input.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The AML debug print functions enable logging
of the operations on the AML tree and the data
output. The debug logging functionality is
enabled for debug builds when the DEBUG_INFO
or DEBUG_VERBOSE mask is enabled in the PCD
gEfiMdePkgTokenSpaceGuid.PcdDebugPrintErrorLevel
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
AML Fixup and AML Codegen facilitate dynamic generation
of Definition Block tables. The AML byte stream that is
generated is represented in an AML tree. Once the AML
table generation is completed, the AML tree needs to be
serialised for installing as an ACPI table.
The AML serialise interface implements the functionality
to iterate the nodes in the AML tree, collating the AML
bytecode, computing the checksum and writing the AML byte
stream to a buffer that represents the Definition Block
table.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Co-authored-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Dynamic AML involves parsing/packing of AML opcode and
data into AML byte streams. The AML stream interface
provides safe buffer management as well as supports
forward and reverse streams. It provides functions to
create, read, write, clone and compare AML streams.
Co-authored-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Dynamic AML requires encoding/decoding and conversion of
AML and ASL strings. A collection of helper functions
have been provided for internal use in the AmlLib Library.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The AML utility interfaces are a collection of helper functions
that assist in computing the checksum, size and to propagate the
node information as a result of addition or update of AML nodes.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
It is often desirable to clone an AML branch/tree
or an AML node. An example of could be to clone
an AML template before fixup so that the original
AML template remains unmodified. Another example
would be replicating a device branch in the AML
tree and fixing up the device information.
To facilitate such scenarios the AmlLib library
provides functions that can be used to clone an
AML branch/tree or an AML node.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The AML tree iterator provides interfaces to traverse the nodes
in the AML tree. The iterator can traverse the AML tree nodes in
the following order:
- Linear progression: Iterate following the AML byte stream
order (depth first).
- Branch progression: Iterate following the AML byte stream
order (depth first), but stop iterating
at the end of the branch.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The AML tree traversal provides interfaces to traverse the
nodes in the AML tree.
It provides interfaces to traverse the AML tree in the
following order:
- Traverse sibling nodes.
(Node) /-i # Child of fixed argument b
\ /
|- [a][b][c][d] # Fixed Arguments
|- {(e)->(f)->(g)} # Variable Arguments
\
\-h # Child of variable argument e
Traversal Order:
- AmlGetNextSibling() : a, b, c, d, e, f, g, NULL
- AmlGetPreviousSibling(): g, f, e, d, c, b, a, NULL
- Iterate depth-first path (follow AML byte stream).
(Node) /-i # Child of fixed argument b
\ /
|- [a][b][c][d] # Fixed Arguments
|- {(e)->(f)->(g)} # Variable Arguments
\
\-h # Child of variable argument e
Traversal Order:
- AmlGetNextNode(): a, b, i, c, d, e, h, f, g, NULL
- AmlGetPreviousNode() g, f, h, e, d, c, i, b, a, NULL
Note: The branch i and h will be traversed if it has
any children.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The AML tree enumerator interface allows enumeration of the
nodes in the AML tree. The enumerator interface can be useful
to search, serialise, print etc. the nodes in the AML tree.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The AML tree is composite and has the following node types:
- Root node.
- Object node.
- Data node.
These nodes are part of the Fixed Arguments or the Variable
arguments list in the AML tree.
The AML tree interface provides functions to manage the fixed
and the variable argument nodes in the AML tree.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
AML has a complex grammar, and this makes runtime modifications
on an AML byte stream difficult. A solution is to parse the AML
bytecode and represent it in a tree data structure, henceforth
called the AML tree.
The AML tree is composite in the sense it has the following node
types:
- A 'Root node' that represents the root of the AML tree.
- An 'Object node' that contains the OP Code (AML Encoding).
- A 'Data node' that contains a data buffer.
The Root node contains the Definition block header (ACPI header)
and a Variable Argument list.
The Object node is composed of an array of Fixed Arguments and
a Variable Argument list.
Fixed arguments can be either Object Nodes or Data nodes. Their
placement (index) in the Fixed Argument array is defined by the
AML encoding of the enclosing Object Node.
Variable arguments can be Object nodes or Data nodes.
Following is a depiction of a typical AML tree:
(/) # Root Node
\
|-{(N1)->...} # Variable Argument list, N1 is
\ # an Object Node
\ /-i # Child of fixed argument b
\ /
|- [a][b][c][d] # Fixed Arguments
|- {(e)->(f)->(g)} # Variable Arguments
\
\-h # Child of variable argument e
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
ASL is a source language for defining ACPI objects including
writing ACPI control methods. An ASL file is compiled using
an ASL compiler tool to generate ACPI Machine Language (AML).
This AML bytecode is processed by the ACPI AML interpreter
that runs as part of an Operating System (OS).
Both ASL and AML are declarative languages. Although they
are closely related they are different languages.
ASL statements declare objects. Each object has three parts,
two of which can be NULL:
Object := ObjectType FixedList VariableList
The AML grammar defines corresponding encodings that makes
up the AML byte stream.
This patch introduces the AML grammar definitions used by
AmlLib for encoding/decoding AML byte streams.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Dynamic AML is a solution to generate Definition Block tables
at runtime. Dynamic AML provides the following techniques for
generating AML tables.
- AML Fixup
- AML Codegen
- AML Fixup + Codegen
AML fixup involves patching small sections of a template AML
code at runtime, while AML Codegen provides APIs to generate
small sections of AML code at runtime. A combination of
Fixup and Codegen can also be used.
AML has a complex grammar. To simplify the generation of
AML tables, Dynamic AML introduces AmlLib that provides a
rich set of APIs for parsing, traversing, fixup, codegen
and serialisation of AML byte code.
This patch introduces the definitions used by AmlLib.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
ACPI Definition block (e.g. DSDT or SSDT) tables are implemented
using ACPI source language (ASL) and compiled to ACPI Machine
language (AML). The AML bytecode runs in the OS ACPI Interpreter.
AML has a complex grammar which makes generation of ACPI Definition
block tables difficult.
Dynamic Tables Framework introduces a new feature 'Dynamic AML' that
aims at simplifying the generation of ACPI Definition block tables.
Dynamic AML provides the following techniques for generating ACPI
Definition blocks.
- AML Fixup
- AML Codegen
- AML Fixup + Codegen
AML Fixup involves patching an AML template code at runtime and then
installing the fixed-up AML code as an ACPI table.
AML Codegen provides APIs to generate small segments of AML code that
can be serialised for installation as an ACPI table.
AML Fixup + Codegen is an approach where parts of an AML template are
fixed-up at runtime as well as the AML Codegen APIs are used to insert
small segments of AML code in the AML template. This AML code is then
serialised for installation as an ACPI table.
To assist Dynamic AML generation an AmlLib library is introduced that
provides a rich set of APIs that can be used to parse, traverse, fixup,
codegen and serialise AML definition blocks.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
If MDEPKG_NDEBUG is defined, then debug and assert related
macros wrapped by it are mapped to NULL implementations.
Therefore, add MDEPKG_NDEBUG flags for release builds of
DynamicTablesPkg.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The EdkII BaseTools have been updated to facilitate the
generation of C file containing AML data using the AmlToC
script. The build system follows the following sequence
for an ASL file compilation:
- The ASL file is preprocessed using the C preprocessor
- The Trim utility prunes the preprocessed file to removed
unwanted data.
- This file is compiled using an ASL compiler to generate
an AML file.
- The AmlToC python script reads the AML data and generates
a C file with an array containing the AML data.
- This C file containing a unique symbol name for the AML
data array is then compiled with the firmware module.
This removes the dependency on the ACPICA iASL compiler's
"-tc" option which achieved the same effect but was less
portable. Therefore, remove the "-tc" option from the ASL
flags as this option is only been supported by the ACPICA
iASL compiler.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The TianoCore EDKII project has introduced a Core CI infrastructure
using TianoCore EDKII Tools PIP modules:
* https://pypi.org/project/edk2-pytool-library/
* https://pypi.org/project/edk2-pytool-extensions/
The edk2\.pytool\Readme.md provides information to configure the
environment and to run local builds.
This patch defines the necessary settings for enabling the Core CI
builds for DynamicTablesPkg.
- Add DynamicTablesPkg.ci.yaml for Core CI
- Update ReadMe.md for details and instructions
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The TianoCore EDKII project has introduced a Core CI infrastructure
using TianoCore EDKII Tools PIP modules:
* https://pypi.org/project/edk2-pytool-library/
* https://pypi.org/project/edk2-pytool-extensions/
More information on configuring the environment and running the
builds can be found in edk2\.pytool\Readme.md
This patch fixes the issues reported by the CI system mainly around
fixing typo errors and package dec and dsc files. A subsequent patch
enables the CI builds for the DynamicTablesPkg.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
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>
VS2017 reports 'warning C4028: formal parameter 2 different
from declaration' for the library constructor and destructor
interfaces for the SRAT Generator modules.
Remove the CONST qualifier for the ImageHandle and the
SystemTable pointer in the library constructor and destructor
to make it compatible with the formal declaration.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Ard Biesheuvel <ard.biesheuvel@linaro.org>
The Dynamic Tables Factory protocol has an erroneous
EFIAPI calling convention macro in the function
pointer declaration.
Remove the erroneous EFIAPI calling convention macro
from the interface declarations.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Philippe Mathieu-Daude <philmd@redhat.com>
On enabling the /analyse option the VS2017 compiler
reports: warning C6001: Using uninitialized memory.
This warning is reported as some variables that were
being logged were uninitialised. To fix this, moved
the logging code after the variables being logged are
initialised.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
On enabling the /analyse option the VS2017 compiler
reports: warning C6001: Using uninitialized memory.
This warning is reported as some variables that were
being logged were uninitialised. To fix this, moved
the logging code after the variables being logged are
initialised.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The VS2017 compiler reports 'warning C4267: 'return': conversion
from 'size_t' to 'UINT32', possible loss of data' for a number of
functions that compute the IORT node length. Similarly, it reports
warnings for IORT node length field assignments as the length
field is 16-bit wide.
This patch adds type casts at appropriate places and also implements
validations to ensure that the max width of the respective fields
is not exceeded.
This patch also fixes a typo in one of the local variable names.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Removing GT Block frame count check from AddGTBlockTimerFrames()
as this is already validated in BuildGtdtTable().
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The ARM DCC serial port subtype is an option that is
supported by the DBG2 generator. However, the serial
port initialisation should only be done for PL011/SBSA
compatible UARTs.
Add check to conditionally initialise the serial port.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Philippe Mathieu-Daude <philmd@redhat.com>
The VS2017 compiler reports 'warning C4366: The result of
the unary '&' operator may be unaligned' if an address of
an unaligned structure member is passed as an argument to
a function.
Fix this warning by using local variables in place of
unaligned structure members.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The VS2017 compiler reports 'warning C4244: '=': conversion from
'const UINT32' to 'UINT8', possible loss of data' when the ACPI
table revision field is being updated.
The width of the revision field in the EFI_ACPI_DESCRIPTION_HEADER
struct is 8-bit wide. Therefore, to fix the above warning make the
ACPI Table revision field usage 8-bit wide across Dynamic Tables
Framework.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The ArmBootArch field of the FADT table is 16-bit wide. The
VS2017 compiler reports 'warning C4244: '=': conversion from
'UINT32' to 'UINT16', possible loss of data' when assigning the
CM_ARM_BOOT_ARCH_INFO.BootArchFlags value as the width of this
field in CM_ARM_BOOT_ARCH_INFO is 32-bit wide.
To fix this warning, update the CM_ARM_BOOT_ARCH_INFO struct
to make the BootArchFlags field 16-bit wide. This also makes
it compatible with the ACPI FADT specification.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The VS2017 compiler reports 'warning C4267: '=': conversion from
'size_t' to 'UINT16', possible loss of data'.
The sizeof() operator is used to calculate the size of the
GT Block structure. The length field in the GT Block structure
is 16-bit wide. Since the return type of sizeof() operator
is size_t the VS2017 compiler reports the above warning.
To fix the warning, an explicit type cast is added. An additional
check is also performed to ensure that the calculated GT Block
length does not exceed MAX_UINT16.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Philippe Mathieu-Daude <philmd@redhat.com>
The length field for the Processor Hierarchy node structure is
8-bit wide while the number of private resource field is 32-bit
wide. Therefore, the GetProcHierarchyNodeSize() returns the size
as a 32-bit value.
The VS2017 compiler reports 'warning C4244: '=': conversion from
'UINT32' to 'UINT8', possible loss of data' while assigning the
length field of the Processor Hierarchy node structure.
To fix this, a type cast is added. In addition, there is a check
to ensure that the Processor Hierarchy node size does not exceed
MAX_UINT8.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The VS2017 compiler reports 'warning C4244: '=': conversion
from 'UINT16' to 'UINT8', possible loss of data' for the
SPCR InterfaceType field assignment.
The SPCR InterfaceType field uses the same encoding as that
of the DBG2 table Port Subtype field. However SPCR.InterfaceType
is 8-bit while the Port Subtype field in DBG2 table is 16-bit.
Since the Configuration Manager represents the Serial port
information using the struct CM_ARM_SERIAL_PORT_INFO, the
PortSubtype member in this struct is 16-bit.
To fix the warning an explicit type case is added. A validation
is also added to ensure that the Serial Port Subtype value
provided by the Configuration Manager is within the 8-bit
range (less than 256).
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Philippe Mathieu-Daude <philmd@redhat.com>
The VS2017 compiler reports 'error C2016: C requires that
a struct or union has at least one member' for the struct
CM_ARM_CPU_INFO.
Remove struct CM_ARM_CPU_INFO as this is not in use.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The edk2 BaseTools report a warning if a local header file
is not listed under the [Sources] section in the INF file.
Add header files to the [Sources] section in the respective
INF files to fix the warnings.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Philippe Mathieu-Daude <philmd@redhat.com>
VS2017 reports 'warning C4028: formal parameter 2 different
from declaration' for the library constructor and destructor
interfaces for the Generator modules. VS2017 compiler also
reports similar warnings for the DXE entry points.
Remove the CONST qualifier for the SystemTable pointer (the
second parameter to the constructor/destructor/DXE Entry
point) to make it compatible with the formal declaration.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The SRAT generator uses the configuration manager protocol
to obtain the affinity information for the GICC, GIC ITS,
Memory, Generic Initiator, etc. and generates the SRAT table.
The table generator supports ACPI 6.3, SRAT table revision 3.
The ACPI and PCI device handles of the Generic Initiator
Affinity structures are represented using tokens. The
generator invokes the configuration manager protocol
interfaces and requests for objects referenced by tokens
to get the device handle information.
The Configuration Manager object definition for the GICC has
been updated to include the Proximity Domain, Clock Domain
and associated flag information. Similarly the Configuration
Manager object for the GIC ITS has been updated to include
the Proximity Domain information. These changes should not
impact any existing implementations as the new fields have
been added towards the end of the Configuration Manager
Objects.
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
DynamicTablesPkg can be built for ARM as well as for AARCH64, but on
the former, doing so will result in a build failure due to the lack
of 64-bit division helpers provided by the ArmPkg intrinsics library.
So add the missing reference, for both ARM and AARCH64 (which may
start relying on intrinsics due to future changes)
Link: https://bugzilla.tianocore.org/show_bug.cgi?id=2269
Reported-by: Laszlo Ersek <lersek@redhat.com>
Signed-off-by: Ard Biesheuvel <ard.biesheuvel@linaro.org>
Acked-by: Laszlo Ersek <lersek@redhat.com>
Reviewed-by: Philippe Mathieu-Daude <philmd@redhat.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Sami Mujawar <sami.mujawar@arm.com>
Tested-by: Sami Mujawar <sami.mujawar@arm.com>
Changed the line endings to DOS line endings for
DynamicTablesPkg/DynamicTablesPkg.dsc
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
The ACPI 6.3 specification adds support for describing
ARMv8.1 EL2 virtual timers. Update GTDT Generator
to extend this support.
Signed-off-by: Pierre Gondois <pierre.gondois@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Sami Mujawar <sami.mujawar@arm.com>
The PPTT generator uses the configuration manager protocol to
obtain information about platform's processor topology and caches.
This data is then used to generate the PPTT table.
The table generator supports ACPI 6.3, PPTT table revision 2.
The dynamic PPTT generator also carries out extensive input
validation which includes cycle detection and MADT-PPTT
cross-validation. A number of architectural compliance checks
are also performed.
Signed-off-by: Krzysztof Koch <krzysztof.koch@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Sami Mujawar <sami.mujawar@arm.com>
The Dynamic Tables Framework now supports generating Multiple APIC
Description Table (MADT) revision 5 for ARM platforms while maintaining
backward-compatibility with ACPI 6.2.
The relevant change is the enablement of the Statistical Profiling
Extension (SPE).
Signed-off-by: Krzysztof Koch <krzysztof.koch@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Sami Mujawar <sami.mujawar@arm.com>
Check for duplicate frame numbers when populating the GT Block Timer
Frames inside the GTDT table generator.
Signed-off-by: Krzysztof Koch <krzysztof.koch@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Sami Mujawar <sami.mujawar@arm.com>
Check for duplicate ACPI Processor UIDs when populating the GIC CPU
(GICC) Interface structures inside the MADT table generator.
Signed-off-by: Krzysztof Koch <krzysztof.koch@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Sami Mujawar <sami.mujawar@arm.com>
Added generic function for detecting duplicate values in an array.
Also defined a function prototype to test if two objects are equal.
The prototype is used as an argument to the 'FindDuplicateValues'
function.
Signed-off-by: Krzysztof Koch <krzysztof.koch@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Sami Mujawar <sami.mujawar@arm.com>
Added code to check if the Generic Timer Block Structure's frame number
provided by the platform repository is within the allowed range (0-7).
References:
- ACPI 6.2 Errata A, Table 5-122, September 2017
Signed-off-by: Krzysztof Koch <krzysztof.koch@arm.com>
Reviewed-by: Alexei Fedorov <Alexei.Fedorov@arm.com>
Reviewed-by: Sami Mujawar <sami.mujawar@arm.com>
This patch was originally merged in edk2 master at
07f4e26eb6. However, this was
later reverted at 4c20a79133
as it was merged during the Soft Feature Freeze for
edk2-stable201903.
Resubmitting this patch as the edk2 merge window is now open.
Minor updates to comments and typo fixes. Also removed
unused structure CM_ARM_CPU_INFO_LIST.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This patch was originally merged in edk2 master at
d3a15f435f. However, this was
later reverted at 82c4426a17
as it was merged during the Soft Feature Freeze for
edk2-stable201903.
Resubmitting this patch as the edk2 merge window is now open.
According to ACPI 6.2 Specification - Errata A, 'One,
and only one, GIC distributor structure must be present
in the MADT for an ARM based system'. Therefore,
the GIC Distributor ID field in the ACPI MADT GICD
substructure can be set to zero and there is no need
for the Configuration Manager to provide this information.
Update the CM_ARM_GICD_INFO structure to remove the GicId
field. Similarly update the MADT Generator to set the GicId
field in the GICD substructure to zero.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This patch was originally merged in edk2 master at
6814256083. However, this was
later reverted at db8382ef5e
as it was merged during the Soft Feature Freeze for
edk2-stable201903.
Resubmitting this patch as the edk2 merge window is now open.
The DBG2_DEBUG_PORT_DDI() macro supports adding only one
Generic Base Address Register. Therefore, removed the
superfluous parameter NumReg and updated the macro to
use DBG2_NUMBER_OF_GENERIC_ADDRESS_REGISTERS which has
a value 1.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This patch originally merged in edk2 master at
c788bdaba4. However, this was
later reverted at bdbbedea94
as it was merged during the Soft Feature Freeze for
edk2-stable201903.
Resubmitting this patch as the edk2 merge window is now open.
Added option for OEMs to provide OEM Table ID and
OEM Revision for ACPI tables.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This patch was originally merged in edk2 master at
1d49a75367. However, this was
later reverted at 334111b0da
as it was merged during the Soft Feature Freeze for
edk2-stable201903.
Resubmitting this patch as the edk2 merge window is now open.
Renamed the enum EArmObjIdMapping to EArmObjIdMappingArray
and updated the IORT generator accordingly.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This patch was originally merged in edk2 master at
bde673b2dc. However, this was
later reverted at 7d180efeaa
as it was merged during the Soft Feature Freeze for
edk2-stable201903.
Resubmitting this patch as the edk2 merge window is now open.
Updated the Protocols section to reflect the protocols
that are produced or consumed.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
Having a top-level .dsc makes it easier to perform standalone build
tests of the core code, so add one.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Leif Lindholm <leif.lindholm@linaro.org>
Reviewed-by: Sami Mujawar <sami.mujawar@arm.com>
This patch changes the stated dependency in AcpiDbg2LibArm.inf from
currently listed SerialPortLib to actually required PL011UartLib.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Leif Lindholm <leif.lindholm@linaro.org>
Reviewed-by: Sami Mujawar <sami.mujawar@arm.com>
This reverts commit bde673b2dc.
Reverting this patch as Soft Feature Freeze for
edk2-stable201903 started on 22 Feb 2019.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This reverts commit 1d49a75367.
Reverting this patch as Soft Feature Freeze for
edk2-stable201903 started on 22 Feb 2019.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This reverts commit c788bdaba4.
Reverting this patch as Soft Feature Freeze for
edk2-stable201903 started on 22 Feb 2019.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This reverts commit 6814256083.
Reverting this patch as Soft Feature Freeze for
edk2-stable201903 started on 22 Feb 2019.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This reverts commit d3a15f435f.
Reverting this patch as Soft Feature Freeze for
edk2-stable201903 started on 22 Feb 2019.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This reverts commit 07f4e26eb6.
Reverting this patch as Soft Feature Freeze for
edk2-stable201903 started on 22 Feb 2019.
Cc: Laszlo Ersek <lersek@redhat.com>
Cc: Alexei Fedorov <alexei.fedorov@arm.com>
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
Minor updates to comments and typo fixes. Also removed
unused structure CM_ARM_CPU_INFO_LIST.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
According to ACPI 6.2 Specification - Errata A, 'One,
and only one, GIC distributor structure must be present
in the MADT for an ARM based system'. Therefore,
the GIC Distributor ID field in the ACPI MADT GICD
substructure can be set to zero and there is no need
for the Configuration Manager to provide this information.
Update the CM_ARM_GICD_INFO structure to remove the GicId
field. Similarly update the MADT Generator to set the GicId
field in the GICD substructure to zero.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The DBG2_DEBUG_PORT_DDI() macro supports adding only one
Generic Base Address Register. Therefore, removed the
superfluous parameter NumReg and updated the macro to
use DBG2_NUMBER_OF_GENERIC_ADDRESS_REGISTERS which has
a value 1.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
Added option for OEMs to provide OEM Table ID and
OEM Revision for ACPI tables.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
Renamed the enum EArmObjIdMapping to EArmObjIdMappingArray
and updated the IORT generator accordingly.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
Updated the Protocols section to reflect the protocols
that are produced or consumed.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
Add support for 16550 UART to ACPI SPCR table as it is a
supported UART type by HLOS.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Ashish Singhal <ashishsingha@nvidia.com>
Reviewed-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The IORT generator uses the configuration manager protocol
to obtain information about the PCI Root Complex, SMMU,
GIC ITS, Performance Monitoring counters etc. and generates
the IORT table.
The mappings between the components are represented using
tokens. The generator invokes the configuration manager
protocol interfaces and requests for objects referenced by
tokens to establish the link.
This table data is then used by the Table Manager to install
the IORT table.
The Table Manager then invokes the generator interface to free
any resources allocated by the IORT table generator.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The MCFG generator uses the configuration manager protocol
to obtain the PCI Configuration space information from the
platform configuration manager and builds the MCFG table.
This table data is then used by the Table Manager to install
the MCFG table.
The Table Manager then invokes the generator interface to free
any resources allocated by the MCFG table generator.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The DBG2 generator uses the configuration manager protocol
to obtain the debug serial port information from the platform
configuration manager. It then updates a template DBG2 table
structure. This table data is used by the Table Manager to
install the DBG2 table.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The SPCR generator uses the configuration manager protocol to
obtain the serial port information from the platform configuration
manager. It then updates a template SPCR table structure. This
table data is used by the Table Manager to install the SPCR table.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The GTDT generator uses the configuration manager protocol to
obtain information about the architectural and platform timers
available on the platform and generates the ACPI GTDT table.
This table data is then used by the Table Manager to install
the GTDT table.
The Table Manager then invokes the generator interface to free
any resources allocated by the GTDT table generator.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The MADT generator uses the configuration manager protocol to
obtain information about the Arm interrupt controllers (GICC,
GICD, etc.) and generates the ACPI MADT table. This table data
is then used by the Table Manager to install the MADT table.
The Table Manager then invokes the generator interface to free
any resources allocated by the MADT table generator.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The FADT generator collates the relevant information required
for generating a FADT table from configuration manager using
the configuration manager protocol. It then updates a template
FADT table structure. This table data is used by the Table
Manager to install the FADT table.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
A Raw generator is a simple generator. This generator provides
the ability to install a binary blob (that contains ACPI table
data) as an ACPI table. The binary blob could be pre-generated
ACPI table data or it may be the pre-compiled output from an
iAsl compiler for a DSDT or SSDT table.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The dynamic table manager implements the top level component
that drives the table generation and installation process.
It uses the configuration manager protocol to get the list
of tables to be installed from the configuration manager.
It iterates through the list of tables, requests the table
factories for corresponding generators and invokes the
generator interface to build the tables.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The dynamic table factory dxe implements the dynamic table
factory protocol. It also implements the ACPI, SMBIOS and
DT table factories. The table generators register themselves
with the respective table factories and the factories are
responsible for instantiating instances of the generators
to build the firmware tables.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This patch introduces the dynamic table factory protocol
that provides an interface to register and retrieve
registered generators.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
A helper library that implements common functionality
for use by table generators.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This patch defines a helper macro 'GET_OBJECT_LIST()' that
expands to a function that uses the configuration manager
protocol to retrieve configuration manager object(s).
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
Introduce configuration manager protocol interface
that is used by the dynamic tables framework core
to communicate with configuration manager.
Configuration manager is a platform specific module
that implements the configuration manager protocol.
Table generators use this interface to retrieve the
hardware information from the configuration manager.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The dynamic tables frameworks core communicates with the
platform specific implementation using the configuration
manager protocol interface. The dynamic tables framework
core uses this interface to retrieve information required
for generating the firmware tables. This information is
represented in the form of objects, which are classified
as standard namespace objects, Arm namespace objects or
as Custom/OEM namespace objects.
The configuration manager objects provides a convenient
way for wrapping up the namespaces using a well defined
configuration manager object Id.
The configuration manager is a platform specific component
that collates the platform information required for generating
firmware tables and represents them as configuration manager
objects.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The dynamic tables frameworks core communicates with the
platform specific implementation using the configuration
manager protocol interface. The dynamic tables framework
core uses this interface to retrieve information required
for generating the firmware tables. This information is
represented in the form of objects, which are classified
as standard namespace objects, Arm namespace objects or
as Custom/OEM namespace objects.
This patch introduces the definitions for the Arm namespace
objects.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
The dynamic tables frameworks core communicates with the
platform specific implementation using the configuration
manager protocol interface. The dynamic tables framework
core uses this interface to retrieve information required
for generating the firmware tables. This information is
represented in the form of objects, which are classified
as standard namespace objects, Arm namespace objects or
as Custom/OEM namespace objects.
This patch introduces the definitions for standard
namespace objects.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This patch introduces the interfaces and definitions for
implementing a Device Tree table generator.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This patch introduces the required interfaces and definitions
for implementing a SMBIOS table generator.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
This patch introduces the required interfaces and definitions
for implementing an ACPI table generator.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
A Table generator is a component that implements the logic
for building a firmware table. This is typically implemented
as a library and registers itself with a table factory.
Table generators are further classified based on type of table
it generates, a namespace that signifies if the implementation
is standard or an OEM specific implementation and a table Id.
This patch introduces the definitions used for describing a
table generator.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>
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.
This patch introduces Dynamic Tables Framework which also provides
mechanisms to reduce the amount of effort required in porting
firmware to new platforms. A more detailed description is in
the Readme.md file.
Contributed-under: TianoCore Contribution Agreement 1.1
Signed-off-by: Sami Mujawar <sami.mujawar@arm.com>
Reviewed-by: Alexei Fedorov <alexei.fedorov@arm.com>