TableGen BackEnds¶
Introduction¶
TableGen backends are at the core of TableGen’s functionality. The source files provide the semantics to a generated (in memory) structure, but it’s up to the backend to print this out in a way that is meaningful to the user (normally a C program including a file or a textual list of warnings, options and error messages).
TableGen is used by both LLVM and Clang with very different goals. LLVM uses it as a way to automate the generation of massive amounts of information regarding instructions, schedules, cores and architecture features. Some backends generate output that is consumed by more than one source file, so they need to be created in a way that is easy to use pre-processor tricks. Some backends can also print C code structures, so that they can be directly included as-is.
Clang, on the other hand, uses it mainly for diagnostic messages (errors, warnings, tips) and attributes, so more on the textual end of the scale.
LLVM BackEnds¶
Warning
This document is raw. Each section below needs three sub-sections: description of its purpose with a list of users, output generated from generic input, and finally why it needed a new backend (in case there’s something similar).
Overall, each backend will take the same TableGen file type and transform into similar output for different targets/uses. There is an implicit contract between the TableGen files, the back-ends and their users.
For instance, a global contract is that each back-end produces macro-guarded sections. Based on whether the file is included by a header or a source file, or even in which context of each file the include is being used, you have todefine a macro just before including it, to get the right output:
#define GET_REGINFO_TARGET_DESC
#include "ARMGenRegisterInfo.inc"
And just part of the generated file would be included. This is useful if you need the same information in multiple formats (instantiation, initialization, getter/setter functions, etc) from the same source TableGen file without having to re-compile the TableGen file multiple times.
Sometimes, multiple macros might be defined before the same include file to output multiple blocks:
#define GET_REGISTER_MATCHER
#define GET_SUBTARGET_FEATURE_NAME
#define GET_MATCHER_IMPLEMENTATION
#include "ARMGenAsmMatcher.inc"
The macros will be undef’d automatically as they’re used, in the include file.
On all LLVM back-ends, the llvm-tblgen
binary will be executed on the root
TableGen file <Target>.td
, which should include all others. This guarantees
that all information needed is accessible, and that no duplication is needed
in the TableGen files.
CodeEmitter¶
Purpose: CodeEmitterGen uses the descriptions of instructions and their fields to construct an automated code emitter: a function that, given a MachineInstr, returns the (currently, 32-bit unsigned) value of the instruction.
Output: C++ code, implementing the target’s CodeEmitter
class by overriding the virtual functions as <Target>CodeEmitter::function()
.
Usage: Used to include directly at the end of <Target>MCCodeEmitter.cpp
.
RegisterInfo¶
Purpose: This tablegen backend is responsible for emitting a description of a target register file for a code generator. It uses instances of the Register, RegisterAliases, and RegisterClass classes to gather this information.
Output: C++ code with enums and structures representing the register mappings, properties, masks, etc.
Usage: Both on <Target>BaseRegisterInfo
and <Target>MCTargetDesc
(headers
and source files) with macros defining in which they are for declaration vs.
initialization issues.
InstrInfo¶
Purpose: This tablegen backend is responsible for emitting a description of the target instruction set for the code generator. (what are the differences from CodeEmitter?)
Output: C++ code with enums and structures representing the instruction mappings, properties, masks, etc.
Usage: Both on <Target>BaseInstrInfo
and <Target>MCTargetDesc
(headers
and source files) with macros defining in which they are for declaration vs.
initialization issues.
AsmWriter¶
Purpose: Emits an assembly printer for the current target.
Output: Implementation of <Target>InstPrinter::printInstruction()
, among
other things.
Usage: Included directly into InstPrinter/<Target>InstPrinter.cpp
.
AsmMatcher¶
Purpose: Emits a target specifier matcher for
converting parsed assembly operands in the MCInst structures. It also
emits a matcher for custom operand parsing. Extensive documentation is
written on the AsmMatcherEmitter.cpp
file.
Output: Assembler parsers’ matcher functions, declarations, etc.
Usage: Used in back-ends’ AsmParser/<Target>AsmParser.cpp
for
building the AsmParser class.
Disassembler¶
Purpose: Contains disassembler table emitters for various
architectures. Extensive documentation is written on the
DisassemblerEmitter.cpp
file.
Output: Decoding tables, static decoding functions, etc.
Usage: Directly included in Disassembler/<Target>Disassembler.cpp
to cater for all default decodings, after all hand-made ones.
PseudoLowering¶
Purpose: Generate pseudo instruction lowering.
Output: Implements <Target>AsmPrinter::emitPseudoExpansionLowering()
.
Usage: Included directly into <Target>AsmPrinter.cpp
.
CallingConv¶
Purpose: Responsible for emitting descriptions of the calling conventions supported by this target.
Output: Implement static functions to deal with calling conventions chained by matching styles, returning false on no match.
Usage: Used in ISelLowering and FastIsel as function pointers to implementation returned by a CC selection function.
DAGISel¶
Purpose: Generate a DAG instruction selector.
Output: Creates huge functions for automating DAG selection.
Usage: Included in <Target>ISelDAGToDAG.cpp
inside the target’s
implementation of SelectionDAGISel
.
DFAPacketizer¶
Purpose: This class parses the Schedule.td file and produces an API that can be used to reason about whether an instruction can be added to a packet on a VLIW architecture. The class internally generates a deterministic finite automaton (DFA) that models all possible mappings of machine instructions to functional units as instructions are added to a packet.
Output: Scheduling tables for GPU back-ends (Hexagon, AMD).
Usage: Included directly on <Target>InstrInfo.cpp
.
FastISel¶
Purpose: This tablegen backend emits code for use by the “fast” instruction selection algorithm. See the comments at the top of lib/CodeGen/SelectionDAG/FastISel.cpp for background. This file scans through the target’s tablegen instruction-info files and extracts instructions with obvious-looking patterns, and it emits code to look up these instructions by type and operator.
Output: Generates Predicate
and FastEmit
methods.
Usage: Implements private methods of the targets’ implementation
of FastISel
class.
Subtarget¶
Purpose: Generate subtarget enumerations.
Output: Enums, globals, local tables for sub-target information.
Usage: Populates <Target>Subtarget
and
MCTargetDesc/<Target>MCTargetDesc
files (both headers and source).
OptParserDefs¶
Purpose: Print enum values for a class.
SearchableTables¶
Purpose: Generate custom searchable tables.
Output: Enums, global tables and lookup helper functions.
Usage: This backend allows generating free-form, target-specific tables from TableGen records. The ARM and AArch64 targets use this backend to generate tables of system registers; the AMDGPU target uses it to generate meta-data about complex image and memory buffer instructions.
More documentation is available in include/llvm/TableGen/SearchableTable.td
,
which also contains the definitions of TableGen classes which must be
instantiated in order to define the enums and tables emitted by this backend.
CTags¶
Purpose: This tablegen backend emits an index of definitions in ctags(1) format. A helper script, utils/TableGen/tdtags, provides an easier-to-use interface; run ‘tdtags -H’ for documentation.
X86EVEX2VEX¶
Purpose: This X86 specific tablegen backend emits tables that map EVEX encoded instructions to their VEX encoded identical instruction.
Clang BackEnds¶
ClangAttrClasses¶
Purpose: Creates Attrs.inc, which contains semantic attribute class
declarations for any attribute in Attr.td
that has not set ASTNode = 0
.
This file is included as part of Attr.h
.
ClangAttrParserStringSwitches¶
Purpose: Creates AttrParserStringSwitches.inc, which contains
StringSwitch::Case statements for parser-related string switches. Each switch
is given its own macro (such as CLANG_ATTR_ARG_CONTEXT_LIST
, or
CLANG_ATTR_IDENTIFIER_ARG_LIST
), which is expected to be defined before
including AttrParserStringSwitches.inc, and undefined after.
ClangAttrImpl¶
Purpose: Creates AttrImpl.inc, which contains semantic attribute class
definitions for any attribute in Attr.td
that has not set ASTNode = 0
.
This file is included as part of AttrImpl.cpp
.
ClangAttrList¶
Purpose: Creates AttrList.inc, which is used when a list of semantic
attribute identifiers is required. For instance, AttrKinds.h
includes this
file to generate the list of attr::Kind
enumeration values. This list is
separated out into multiple categories: attributes, inheritable attributes, and
inheritable parameter attributes. This categorization happens automatically
based on information in Attr.td
and is used to implement the classof
functionality required for dyn_cast
and similar APIs.
ClangAttrPCHRead¶
Purpose: Creates AttrPCHRead.inc, which is used to deserialize attributes
in the ASTReader::ReadAttributes
function.
ClangAttrPCHWrite¶
Purpose: Creates AttrPCHWrite.inc, which is used to serialize attributes in
the ASTWriter::WriteAttributes
function.
ClangAttrSpellings¶
Purpose: Creates AttrSpellings.inc, which is used to implement the
__has_attribute
feature test macro.
ClangAttrSpellingListIndex¶
Purpose: Creates AttrSpellingListIndex.inc, which is used to map parsed
attribute spellings (including which syntax or scope was used) to an attribute
spelling list index. These spelling list index values are internal
implementation details exposed via
AttributeList::getAttributeSpellingListIndex
.
ClangAttrVisitor¶
Purpose: Creates AttrVisitor.inc, which is used when implementing recursive AST visitors.
ClangAttrTemplateInstantiate¶
Purpose: Creates AttrTemplateInstantiate.inc, which implements the
instantiateTemplateAttribute
function, used when instantiating a template
that requires an attribute to be cloned.
ClangAttrParsedAttrList¶
Purpose: Creates AttrParsedAttrList.inc, which is used to generate the
AttributeList::Kind
parsed attribute enumeration.
ClangAttrParsedAttrImpl¶
Purpose: Creates AttrParsedAttrImpl.inc, which is used by
AttributeList.cpp
to implement several functions on the AttributeList
class. This functionality is implemented via the AttrInfoMap ParsedAttrInfo
array, which contains one element per parsed attribute object.
ClangAttrParsedAttrKinds¶
Purpose: Creates AttrParsedAttrKinds.inc, which is used to implement the
AttributeList::getKind
function, mapping a string (and syntax) to a parsed
attribute AttributeList::Kind
enumeration.
ClangAttrDump¶
Purpose: Creates AttrDump.inc, which dumps information about an attribute.
It is used to implement ASTDumper::dumpAttr
.
ClangDiagsDefs¶
Generate Clang diagnostics definitions.
ClangDiagGroups¶
Generate Clang diagnostic groups.
ClangDiagsIndexName¶
Generate Clang diagnostic name index.
ClangCommentNodes¶
Generate Clang AST comment nodes.
ClangDeclNodes¶
Generate Clang AST declaration nodes.
ClangStmtNodes¶
Generate Clang AST statement nodes.
ClangSACheckers¶
Generate Clang Static Analyzer checkers.
ClangCommentHTMLTags¶
Generate efficient matchers for HTML tag names that are used in documentation comments.
ClangCommentHTMLTagsProperties¶
Generate efficient matchers for HTML tag properties.
ClangCommentHTMLNamedCharacterReferences¶
Generate function to translate named character references to UTF-8 sequences.
ClangCommentCommandInfo¶
Generate command properties for commands that are used in documentation comments.
ClangCommentCommandList¶
Generate list of commands that are used in documentation comments.
ArmNeonSema¶
Generate ARM NEON sema support for clang.
ArmNeonTest¶
Generate ARM NEON tests for clang.
General BackEnds¶
JSON¶
Purpose: Output all the values in every def
, as a JSON data
structure that can be easily parsed by a variety of languages. Useful
for writing custom backends without having to modify TableGen itself,
or for performing auxiliary analysis on the same TableGen data passed
to a built-in backend.
Output:
The root of the output file is a JSON object (i.e. dictionary), containing the following fixed keys:
!tablegen_json_version
: a numeric version field that will increase if an incompatible change is ever made to the structure of this data. The format described here corresponds to version 1.!instanceof
: a dictionary whose keys are the class names defined in the TableGen input. For each key, the corresponding value is an array of strings giving the names ofdef
records that derive from that class. Soroot["!instanceof"]["Instruction"]
, for example, would list the names of all the records deriving from the classInstruction
.
For each def
record, the root object also has a key for the record
name. The corresponding value is a subsidiary object containing the
following fixed keys:
!superclasses
: an array of strings giving the names of all the classes that this record derives from.!fields
: an array of strings giving the names of all the variables in this record that were defined with thefield
keyword.!name
: a string giving the name of the record. This is always identical to the key in the JSON root object corresponding to this record’s dictionary. (If the record is anonymous, the name is arbitrary.)!anonymous
: a boolean indicating whether the record’s name was specified by the TableGen input (if it isfalse
), or invented by TableGen itself (iftrue
).
For each variable defined in a record, the def
object for that
record also has a key for the variable name. The corresponding value
is a translation into JSON of the variable’s value, using the
conventions described below.
Some TableGen data types are translated directly into the corresponding JSON type:
A completely undefined value (e.g. for a variable declared without initializer in some superclass of this record, and never initialized by the record itself or any other superclass) is emitted as the JSON
null
value.int
andbit
values are emitted as numbers. Note that TableGenint
values are capable of holding integers too large to be exactly representable in IEEE double precision. The integer literal in the JSON output will show the full exact integer value. So if you need to retrieve large integers with full precision, you should use a JSON reader capable of translating such literals back into 64-bit integers without losing precision, such as Python’s standardjson
module.string
andcode
values are emitted as JSON strings.list<T>
values, for any element typeT
, are emitted as JSON arrays. Each element of the array is represented in turn using these same conventions.bits
values are also emitted as arrays. Abits
array is ordered from least-significant bit to most-significant. So the element with indexi
corresponds to the bit described asx{i}
in TableGen source. However, note that this means that scripting languages are likely to display the array in the opposite order from the way it appears in the TableGen source or in the diagnostic-print-records
output.
All other TableGen value types are emitted as a JSON object,
containing two standard fields: kind
is a discriminator describing
which kind of value the object represents, and printable
is a
string giving the same representation of the value that would appear
in -print-records
.
A reference to a
def
object haskind=="def"
, and has an extra fielddef
giving the name of the object referred to.A reference to another variable in the same record has
kind=="var"
, and has an extra fieldvar
giving the name of the variable referred to.A reference to a specific bit of a
bits
-typed variable in the same record haskind=="varbit"
, and has two extra fields:var
gives the name of the variable referred to, andindex
gives the index of the bit.A value of type
dag
haskind=="dag"
, and has two extra fields.operator
gives the initial value after the opening parenthesis of the dag initializer;args
is an array giving the following arguments. The elements ofargs
are arrays of length 2, giving the value of each argument followed by its colon-suffixed name (if any). For example, in the JSON representation of the dag value(Op 22, "hello":$foo)
(assuming thatOp
is the name of a record defined elsewhere with adef
statement):operator
will be an object in whichkind=="def"
anddef=="Op"
args
will be the array[[22, null], ["hello", "foo"]]
.
If any other kind of value or complicated expression appears in the output, it will have
kind=="complex"
, and no additional fields. These values are not expected to be needed by backends. The standardprintable
field can be used to extract a representation of them in TableGen source syntax if necessary.
How to write a back-end¶
TODO.
Until we get a step-by-step HowTo for writing TableGen backends, you can at least grab the boilerplate (build system, new files, etc.) from Clang’s r173931.
TODO: How they work, how to write one. This section should not contain details
about any particular backend, except maybe -print-enums
as an example. This
should highlight the APIs in TableGen/Record.h
.