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===========================
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TableGen Language Reference
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===========================
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.. contents::
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:local:
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.. warning::
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This document is extremely rough. If you find something lacking, please
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fix it, file a documentation bug, or ask about it on llvmdev.
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Introduction
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============
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This document is meant to be a normative spec about the TableGen language
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in and of itself (i.e. how to understand a given construct in terms of how
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it affects the final set of records represented by the TableGen file). If
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you are unsure if this document is really what you are looking for, please
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read :doc:`the introduction <index>` first.
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TableGen syntax
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===============
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TableGen doesn't care about the meaning of data (that is up to the backend to
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define), but it does care about syntax, and it enforces a simple type system.
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This section describes the syntax and the constructs allowed in a TableGen file.
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TableGen primitives
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-------------------
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TableGen comments
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^^^^^^^^^^^^^^^^^
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TableGen supports C++ style "``//``" comments, which run to the end of the
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line, and it also supports **nestable** "``/* */``" comments.
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.. _TableGen type:
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The TableGen type system
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^^^^^^^^^^^^^^^^^^^^^^^^
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TableGen files are strongly typed, in a simple (but complete) type-system.
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These types are used to perform automatic conversions, check for errors, and to
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help interface designers constrain the input that they allow. Every `value
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definition`_ is required to have an associated type.
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TableGen supports a mixture of very low-level types (such as ``bit``) and very
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high-level types (such as ``dag``). This flexibility is what allows it to
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describe a wide range of information conveniently and compactly. The TableGen
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types are:
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``bit``
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A 'bit' is a boolean value that can hold either 0 or 1.
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``int``
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The 'int' type represents a simple 32-bit integer value, such as 5.
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``string``
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The 'string' type represents an ordered sequence of characters of arbitrary
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length.
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``bits<n>``
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A 'bits' type is an arbitrary, but fixed, size integer that is broken up
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into individual bits. This type is useful because it can handle some bits
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being defined while others are undefined.
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``list<ty>``
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This type represents a list whose elements are some other type. The
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contained type is arbitrary: it can even be another list type.
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Class type
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Specifying a class name in a type context means that the defined value must
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be a subclass of the specified class. This is useful in conjunction with
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the ``list`` type, for example, to constrain the elements of the list to a
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common base class (e.g., a ``list<Register>`` can only contain definitions
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derived from the "``Register``" class).
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``dag``
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This type represents a nestable directed graph of elements.
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To date, these types have been sufficient for describing things that TableGen
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has been used for, but it is straight-forward to extend this list if needed.
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.. _TableGen expressions:
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TableGen values and expressions
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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TableGen allows for a pretty reasonable number of different expression forms
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when building up values. These forms allow the TableGen file to be written in a
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natural syntax and flavor for the application. The current expression forms
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supported include:
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``?``
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uninitialized field
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``0b1001011``
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binary integer value
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``07654321``
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octal integer value (indicated by a leading 0)
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``7``
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decimal integer value
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``0x7F``
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hexadecimal integer value
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``"foo"``
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string value
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``[{ ... }]``
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usually called a "code fragment", but is just a multiline string literal
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``[ X, Y, Z ]<type>``
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list value. <type> is the type of the list element and is usually optional.
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In rare cases, TableGen is unable to deduce the element type in which case
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the user must specify it explicitly.
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``{ a, b, c }``
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initializer for a "bits<3>" value
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``value``
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value reference
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``value{17}``
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access to one bit of a value
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``value{15-17}``
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access to multiple bits of a value
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``DEF``
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reference to a record definition
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``CLASS<val list>``
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reference to a new anonymous definition of CLASS with the specified template
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arguments.
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``X.Y``
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reference to the subfield of a value
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``list[4-7,17,2-3]``
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A slice of the 'list' list, including elements 4,5,6,7,17,2, and 3 from it.
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Elements may be included multiple times.
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``foreach <var> = [ <list> ] in { <body> }``
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``foreach <var> = [ <list> ] in <def>``
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Replicate <body> or <def>, replacing instances of <var> with each value
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in <list>. <var> is scoped at the level of the ``foreach`` loop and must
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not conflict with any other object introduced in <body> or <def>. Currently
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only ``def``\s are expanded within <body>.
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``foreach <var> = 0-15 in ...``
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``foreach <var> = {0-15,32-47} in ...``
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Loop over ranges of integers. The braces are required for multiple ranges.
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``(DEF a, b)``
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a dag value. The first element is required to be a record definition, the
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remaining elements in the list may be arbitrary other values, including
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nested ```dag``' values.
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``!strconcat(a, b)``
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A string value that is the result of concatenating the 'a' and 'b' strings.
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``str1#str2``
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"#" (paste) is a shorthand for !strconcat. It may concatenate things that
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are not quoted strings, in which case an implicit !cast<string> is done on
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the operand of the paste.
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``!cast<type>(a)``
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A symbol of type *type* obtained by looking up the string 'a' in the symbol
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table. If the type of 'a' does not match *type*, TableGen aborts with an
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error. !cast<string> is a special case in that the argument must be an
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object defined by a 'def' construct.
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``!subst(a, b, c)``
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If 'a' and 'b' are of string type or are symbol references, substitute 'b'
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for 'a' in 'c.' This operation is analogous to $(subst) in GNU make.
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``!foreach(a, b, c)``
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For each member 'b' of dag or list 'a' apply operator 'c.' 'b' is a dummy
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variable that should be declared as a member variable of an instantiated
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class. This operation is analogous to $(foreach) in GNU make.
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``!head(a)``
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The first element of list 'a.'
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``!tail(a)``
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The 2nd-N elements of list 'a.'
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``!empty(a)``
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An integer {0,1} indicating whether list 'a' is empty.
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``!if(a,b,c)``
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'b' if the result of 'int' or 'bit' operator 'a' is nonzero, 'c' otherwise.
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``!eq(a,b)``
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'bit 1' if string a is equal to string b, 0 otherwise. This only operates
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on string, int and bit objects. Use !cast<string> to compare other types of
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objects.
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Note that all of the values have rules specifying how they convert to values
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for different types. These rules allow you to assign a value like "``7``"
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to a "``bits<4>``" value, for example.
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Classes and definitions
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-----------------------
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As mentioned in the :doc:`introduction <index>`, classes and definitions (collectively known as
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'records') in TableGen are the main high-level unit of information that TableGen
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collects. Records are defined with a ``def`` or ``class`` keyword, the record
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name, and an optional list of "`template arguments`_". If the record has
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superclasses, they are specified as a comma separated list that starts with a
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colon character ("``:``"). If `value definitions`_ or `let expressions`_ are
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needed for the class, they are enclosed in curly braces ("``{}``"); otherwise,
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the record ends with a semicolon.
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Here is a simple TableGen file:
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.. code-block:: llvm
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class C { bit V = 1; }
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def X : C;
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def Y : C {
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string Greeting = "hello";
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}
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This example defines two definitions, ``X`` and ``Y``, both of which derive from
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the ``C`` class. Because of this, they both get the ``V`` bit value. The ``Y``
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definition also gets the Greeting member as well.
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In general, classes are useful for collecting together the commonality between a
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group of records and isolating it in a single place. Also, classes permit the
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specification of default values for their subclasses, allowing the subclasses to
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override them as they wish.
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.. _value definition:
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.. _value definitions:
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Value definitions
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^^^^^^^^^^^^^^^^^
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Value definitions define named entries in records. A value must be defined
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before it can be referred to as the operand for another value definition or
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before the value is reset with a `let expression`_. A value is defined by
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specifying a `TableGen type`_ and a name. If an initial value is available, it
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may be specified after the type with an equal sign. Value definitions require
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terminating semicolons.
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.. _let expression:
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.. _let expressions:
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.. _"let" expressions within a record:
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'let' expressions
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^^^^^^^^^^^^^^^^^
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A record-level let expression is used to change the value of a value definition
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in a record. This is primarily useful when a superclass defines a value that a
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derived class or definition wants to override. Let expressions consist of the
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'``let``' keyword followed by a value name, an equal sign ("``=``"), and a new
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value. For example, a new class could be added to the example above, redefining
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the ``V`` field for all of its subclasses:
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.. code-block:: llvm
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class D : C { let V = 0; }
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def Z : D;
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In this case, the ``Z`` definition will have a zero value for its ``V`` value,
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despite the fact that it derives (indirectly) from the ``C`` class, because the
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``D`` class overrode its value.
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.. _template arguments:
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Class template arguments
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^^^^^^^^^^^^^^^^^^^^^^^^
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TableGen permits the definition of parameterized classes as well as normal
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concrete classes. Parameterized TableGen classes specify a list of variable
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bindings (which may optionally have defaults) that are bound when used. Here is
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a simple example:
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.. code-block:: llvm
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class FPFormat<bits<3> val> {
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bits<3> Value = val;
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}
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def NotFP : FPFormat<0>;
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def ZeroArgFP : FPFormat<1>;
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def OneArgFP : FPFormat<2>;
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def OneArgFPRW : FPFormat<3>;
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def TwoArgFP : FPFormat<4>;
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def CompareFP : FPFormat<5>;
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def CondMovFP : FPFormat<6>;
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def SpecialFP : FPFormat<7>;
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In this case, template arguments are used as a space efficient way to specify a
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list of "enumeration values", each with a "``Value``" field set to the specified
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integer.
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The more esoteric forms of `TableGen expressions`_ are useful in conjunction
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with template arguments. As an example:
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.. code-block:: llvm
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class ModRefVal<bits<2> val> {
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bits<2> Value = val;
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}
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def None : ModRefVal<0>;
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def Mod : ModRefVal<1>;
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def Ref : ModRefVal<2>;
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def ModRef : ModRefVal<3>;
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class Value<ModRefVal MR> {
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// Decode some information into a more convenient format, while providing
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// a nice interface to the user of the "Value" class.
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bit isMod = MR.Value{0};
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bit isRef = MR.Value{1};
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// other stuff...
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}
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// Example uses
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def bork : Value<Mod>;
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def zork : Value<Ref>;
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def hork : Value<ModRef>;
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This is obviously a contrived example, but it shows how template arguments can
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be used to decouple the interface provided to the user of the class from the
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actual internal data representation expected by the class. In this case,
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running ``llvm-tblgen`` on the example prints the following definitions:
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.. code-block:: llvm
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def bork { // Value
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bit isMod = 1;
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bit isRef = 0;
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}
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def hork { // Value
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bit isMod = 1;
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bit isRef = 1;
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}
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def zork { // Value
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bit isMod = 0;
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bit isRef = 1;
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}
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This shows that TableGen was able to dig into the argument and extract a piece
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of information that was requested by the designer of the "Value" class. For
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more realistic examples, please see existing users of TableGen, such as the X86
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backend.
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Multiclass definitions and instances
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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While classes with template arguments are a good way to factor commonality
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between two instances of a definition, multiclasses allow a convenient notation
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for defining multiple definitions at once (instances of implicitly constructed
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classes). For example, consider an 3-address instruction set whose instructions
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come in two forms: "``reg = reg op reg``" and "``reg = reg op imm``"
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(e.g. SPARC). In this case, you'd like to specify in one place that this
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commonality exists, then in a separate place indicate what all the ops are.
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Here is an example TableGen fragment that shows this idea:
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.. code-block:: llvm
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def ops;
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def GPR;
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def Imm;
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class inst<int opc, string asmstr, dag operandlist>;
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multiclass ri_inst<int opc, string asmstr> {
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def _rr : inst<opc, !strconcat(asmstr, " $dst, $src1, $src2"),
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(ops GPR:$dst, GPR:$src1, GPR:$src2)>;
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def _ri : inst<opc, !strconcat(asmstr, " $dst, $src1, $src2"),
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(ops GPR:$dst, GPR:$src1, Imm:$src2)>;
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}
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// Instantiations of the ri_inst multiclass.
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defm ADD : ri_inst<0b111, "add">;
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defm SUB : ri_inst<0b101, "sub">;
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defm MUL : ri_inst<0b100, "mul">;
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...
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The name of the resultant definitions has the multidef fragment names appended
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to them, so this defines ``ADD_rr``, ``ADD_ri``, ``SUB_rr``, etc. A defm may
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inherit from multiple multiclasses, instantiating definitions from each
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multiclass. Using a multiclass this way is exactly equivalent to instantiating
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the classes multiple times yourself, e.g. by writing:
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.. code-block:: llvm
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def ops;
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def GPR;
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def Imm;
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class inst<int opc, string asmstr, dag operandlist>;
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class rrinst<int opc, string asmstr>
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: inst<opc, !strconcat(asmstr, " $dst, $src1, $src2"),
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(ops GPR:$dst, GPR:$src1, GPR:$src2)>;
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class riinst<int opc, string asmstr>
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: inst<opc, !strconcat(asmstr, " $dst, $src1, $src2"),
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(ops GPR:$dst, GPR:$src1, Imm:$src2)>;
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// Instantiations of the ri_inst multiclass.
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def ADD_rr : rrinst<0b111, "add">;
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def ADD_ri : riinst<0b111, "add">;
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def SUB_rr : rrinst<0b101, "sub">;
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def SUB_ri : riinst<0b101, "sub">;
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def MUL_rr : rrinst<0b100, "mul">;
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def MUL_ri : riinst<0b100, "mul">;
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...
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A ``defm`` can also be used inside a multiclass providing several levels of
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multiclass instantiations.
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.. code-block:: llvm
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class Instruction<bits<4> opc, string Name> {
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bits<4> opcode = opc;
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string name = Name;
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}
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multiclass basic_r<bits<4> opc> {
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def rr : Instruction<opc, "rr">;
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def rm : Instruction<opc, "rm">;
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}
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multiclass basic_s<bits<4> opc> {
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defm SS : basic_r<opc>;
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defm SD : basic_r<opc>;
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def X : Instruction<opc, "x">;
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}
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multiclass basic_p<bits<4> opc> {
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defm PS : basic_r<opc>;
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defm PD : basic_r<opc>;
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def Y : Instruction<opc, "y">;
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}
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defm ADD : basic_s<0xf>, basic_p<0xf>;
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...
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// Results
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def ADDPDrm { ...
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def ADDPDrr { ...
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def ADDPSrm { ...
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def ADDPSrr { ...
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def ADDSDrm { ...
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def ADDSDrr { ...
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def ADDY { ...
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def ADDX { ...
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``defm`` declarations can inherit from classes too, the rule to follow is that
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the class list must start after the last multiclass, and there must be at least
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one multiclass before them.
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.. code-block:: llvm
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class XD { bits<4> Prefix = 11; }
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class XS { bits<4> Prefix = 12; }
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class I<bits<4> op> {
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bits<4> opcode = op;
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}
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multiclass R {
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def rr : I<4>;
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def rm : I<2>;
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}
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multiclass Y {
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defm SS : R, XD;
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defm SD : R, XS;
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}
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defm Instr : Y;
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// Results
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def InstrSDrm {
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bits<4> opcode = { 0, 0, 1, 0 };
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bits<4> Prefix = { 1, 1, 0, 0 };
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}
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...
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def InstrSSrr {
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bits<4> opcode = { 0, 1, 0, 0 };
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bits<4> Prefix = { 1, 0, 1, 1 };
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}
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File scope entities
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-------------------
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File inclusion
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^^^^^^^^^^^^^^
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TableGen supports the '``include``' token, which textually substitutes the
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specified file in place of the include directive. The filename should be
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specified as a double quoted string immediately after the '``include``' keyword.
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Example:
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.. code-block:: llvm
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include "foo.td"
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'let' expressions
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^^^^^^^^^^^^^^^^^
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"Let" expressions at file scope are similar to `"let" expressions within a
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record`_, except they can specify a value binding for multiple records at a
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time, and may be useful in certain other cases. File-scope let expressions are
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really just another way that TableGen allows the end-user to factor out
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commonality from the records.
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File-scope "let" expressions take a comma-separated list of bindings to apply,
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and one or more records to bind the values in. Here are some examples:
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.. code-block:: llvm
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let isTerminator = 1, isReturn = 1, isBarrier = 1, hasCtrlDep = 1 in
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def RET : I<0xC3, RawFrm, (outs), (ins), "ret", [(X86retflag 0)]>;
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let isCall = 1 in
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// All calls clobber the non-callee saved registers...
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let Defs = [EAX, ECX, EDX, FP0, FP1, FP2, FP3, FP4, FP5, FP6, ST0,
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MM0, MM1, MM2, MM3, MM4, MM5, MM6, MM7,
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XMM0, XMM1, XMM2, XMM3, XMM4, XMM5, XMM6, XMM7, EFLAGS] in {
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def CALLpcrel32 : Ii32<0xE8, RawFrm, (outs), (ins i32imm:$dst,variable_ops),
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"call\t${dst:call}", []>;
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def CALL32r : I<0xFF, MRM2r, (outs), (ins GR32:$dst, variable_ops),
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"call\t{*}$dst", [(X86call GR32:$dst)]>;
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def CALL32m : I<0xFF, MRM2m, (outs), (ins i32mem:$dst, variable_ops),
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"call\t{*}$dst", []>;
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}
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File-scope "let" expressions are often useful when a couple of definitions need
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to be added to several records, and the records do not otherwise need to be
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opened, as in the case with the ``CALL*`` instructions above.
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It's also possible to use "let" expressions inside multiclasses, providing more
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ways to factor out commonality from the records, specially if using several
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levels of multiclass instantiations. This also avoids the need of using "let"
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expressions within subsequent records inside a multiclass.
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.. code-block:: llvm
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multiclass basic_r<bits<4> opc> {
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let Predicates = [HasSSE2] in {
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def rr : Instruction<opc, "rr">;
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def rm : Instruction<opc, "rm">;
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}
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let Predicates = [HasSSE3] in
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def rx : Instruction<opc, "rx">;
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}
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multiclass basic_ss<bits<4> opc> {
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let IsDouble = 0 in
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defm SS : basic_r<opc>;
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let IsDouble = 1 in
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defm SD : basic_r<opc>;
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}
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defm ADD : basic_ss<0xf>;
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Looping
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^^^^^^^
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TableGen supports the '``foreach``' block, which textually replicates the loop
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body, substituting iterator values for iterator references in the body.
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Example:
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.. code-block:: llvm
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foreach i = [0, 1, 2, 3] in {
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def R#i : Register<...>;
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def F#i : Register<...>;
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}
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This will create objects ``R0``, ``R1``, ``R2`` and ``R3``. ``foreach`` blocks
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may be nested. If there is only one item in the body the braces may be
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elided:
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.. code-block:: llvm
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foreach i = [0, 1, 2, 3] in
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def R#i : Register<...>;
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Code Generator backend info
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===========================
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Expressions used by code generator to describe instructions and isel patterns:
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``(implicit a)``
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an implicitly defined physical register. This tells the dag instruction
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selection emitter the input pattern's extra definitions matches implicit
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physical register definitions.
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