569 lines
22 KiB
ReStructuredText
569 lines
22 KiB
ReStructuredText
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========================================
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Kaleidoscope: Code generation to LLVM IR
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========================================
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.. contents::
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:local:
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Chapter 3 Introduction
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======================
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Welcome to Chapter 3 of the "`Implementing a language with
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LLVM <index.html>`_" tutorial. This chapter shows you how to transform
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the `Abstract Syntax Tree <LangImpl02.html>`_, built in Chapter 2, into
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LLVM IR. This will teach you a little bit about how LLVM does things, as
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well as demonstrate how easy it is to use. It's much more work to build
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a lexer and parser than it is to generate LLVM IR code. :)
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**Please note**: the code in this chapter and later require LLVM 3.7 or
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later. LLVM 3.6 and before will not work with it. Also note that you
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need to use a version of this tutorial that matches your LLVM release:
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If you are using an official LLVM release, use the version of the
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documentation included with your release or on the `llvm.org releases
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page <https://llvm.org/releases/>`_.
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Code Generation Setup
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=====================
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In order to generate LLVM IR, we want some simple setup to get started.
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First we define virtual code generation (codegen) methods in each AST
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class:
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.. code-block:: c++
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/// ExprAST - Base class for all expression nodes.
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class ExprAST {
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public:
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virtual ~ExprAST() {}
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virtual Value *codegen() = 0;
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};
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/// NumberExprAST - Expression class for numeric literals like "1.0".
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class NumberExprAST : public ExprAST {
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double Val;
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public:
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NumberExprAST(double Val) : Val(Val) {}
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virtual Value *codegen();
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};
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...
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The codegen() method says to emit IR for that AST node along with all
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the things it depends on, and they all return an LLVM Value object.
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"Value" is the class used to represent a "`Static Single Assignment
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(SSA) <http://en.wikipedia.org/wiki/Static_single_assignment_form>`_
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register" or "SSA value" in LLVM. The most distinct aspect of SSA values
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is that their value is computed as the related instruction executes, and
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it does not get a new value until (and if) the instruction re-executes.
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In other words, there is no way to "change" an SSA value. For more
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information, please read up on `Static Single
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Assignment <http://en.wikipedia.org/wiki/Static_single_assignment_form>`_
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- the concepts are really quite natural once you grok them.
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Note that instead of adding virtual methods to the ExprAST class
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hierarchy, it could also make sense to use a `visitor
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pattern <http://en.wikipedia.org/wiki/Visitor_pattern>`_ or some other
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way to model this. Again, this tutorial won't dwell on good software
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engineering practices: for our purposes, adding a virtual method is
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simplest.
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The second thing we want is a "LogError" method like we used for the
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parser, which will be used to report errors found during code generation
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(for example, use of an undeclared parameter):
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.. code-block:: c++
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static LLVMContext TheContext;
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static IRBuilder<> Builder(TheContext);
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static std::unique_ptr<Module> TheModule;
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static std::map<std::string, Value *> NamedValues;
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Value *LogErrorV(const char *Str) {
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LogError(Str);
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return nullptr;
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}
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The static variables will be used during code generation. ``TheContext``
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is an opaque object that owns a lot of core LLVM data structures, such as
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the type and constant value tables. We don't need to understand it in
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detail, we just need a single instance to pass into APIs that require it.
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The ``Builder`` object is a helper object that makes it easy to generate
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LLVM instructions. Instances of the
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`IRBuilder <https://llvm.org/doxygen/IRBuilder_8h_source.html>`_
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class template keep track of the current place to insert instructions
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and has methods to create new instructions.
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``TheModule`` is an LLVM construct that contains functions and global
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variables. In many ways, it is the top-level structure that the LLVM IR
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uses to contain code. It will own the memory for all of the IR that we
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generate, which is why the codegen() method returns a raw Value\*,
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rather than a unique_ptr<Value>.
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The ``NamedValues`` map keeps track of which values are defined in the
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current scope and what their LLVM representation is. (In other words, it
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is a symbol table for the code). In this form of Kaleidoscope, the only
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things that can be referenced are function parameters. As such, function
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parameters will be in this map when generating code for their function
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body.
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With these basics in place, we can start talking about how to generate
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code for each expression. Note that this assumes that the ``Builder``
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has been set up to generate code *into* something. For now, we'll assume
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that this has already been done, and we'll just use it to emit code.
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Expression Code Generation
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==========================
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Generating LLVM code for expression nodes is very straightforward: less
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than 45 lines of commented code for all four of our expression nodes.
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First we'll do numeric literals:
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.. code-block:: c++
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Value *NumberExprAST::codegen() {
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return ConstantFP::get(TheContext, APFloat(Val));
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}
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In the LLVM IR, numeric constants are represented with the
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``ConstantFP`` class, which holds the numeric value in an ``APFloat``
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internally (``APFloat`` has the capability of holding floating point
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constants of Arbitrary Precision). This code basically just creates
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and returns a ``ConstantFP``. Note that in the LLVM IR that constants
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are all uniqued together and shared. For this reason, the API uses the
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"foo::get(...)" idiom instead of "new foo(..)" or "foo::Create(..)".
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.. code-block:: c++
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Value *VariableExprAST::codegen() {
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// Look this variable up in the function.
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Value *V = NamedValues[Name];
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if (!V)
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LogErrorV("Unknown variable name");
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return V;
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}
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References to variables are also quite simple using LLVM. In the simple
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version of Kaleidoscope, we assume that the variable has already been
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emitted somewhere and its value is available. In practice, the only
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values that can be in the ``NamedValues`` map are function arguments.
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This code simply checks to see that the specified name is in the map (if
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not, an unknown variable is being referenced) and returns the value for
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it. In future chapters, we'll add support for `loop induction
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variables <LangImpl05.html#for-loop-expression>`_ in the symbol table, and for `local
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variables <LangImpl07.html#user-defined-local-variables>`_.
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.. code-block:: c++
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Value *BinaryExprAST::codegen() {
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Value *L = LHS->codegen();
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Value *R = RHS->codegen();
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if (!L || !R)
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return nullptr;
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switch (Op) {
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case '+':
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return Builder.CreateFAdd(L, R, "addtmp");
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case '-':
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return Builder.CreateFSub(L, R, "subtmp");
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case '*':
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return Builder.CreateFMul(L, R, "multmp");
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case '<':
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L = Builder.CreateFCmpULT(L, R, "cmptmp");
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// Convert bool 0/1 to double 0.0 or 1.0
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return Builder.CreateUIToFP(L, Type::getDoubleTy(TheContext),
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"booltmp");
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default:
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return LogErrorV("invalid binary operator");
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}
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}
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Binary operators start to get more interesting. The basic idea here is
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that we recursively emit code for the left-hand side of the expression,
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then the right-hand side, then we compute the result of the binary
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expression. In this code, we do a simple switch on the opcode to create
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the right LLVM instruction.
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In the example above, the LLVM builder class is starting to show its
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value. IRBuilder knows where to insert the newly created instruction,
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all you have to do is specify what instruction to create (e.g. with
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``CreateFAdd``), which operands to use (``L`` and ``R`` here) and
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optionally provide a name for the generated instruction.
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One nice thing about LLVM is that the name is just a hint. For instance,
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if the code above emits multiple "addtmp" variables, LLVM will
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automatically provide each one with an increasing, unique numeric
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suffix. Local value names for instructions are purely optional, but it
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makes it much easier to read the IR dumps.
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`LLVM instructions <../../LangRef.html#instruction-reference>`_ are constrained by strict
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rules: for example, the Left and Right operators of an `add
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instruction <../../LangRef.html#add-instruction>`_ must have the same type, and the
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result type of the add must match the operand types. Because all values
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in Kaleidoscope are doubles, this makes for very simple code for add,
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sub and mul.
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On the other hand, LLVM specifies that the `fcmp
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instruction <../../LangRef.html#fcmp-instruction>`_ always returns an 'i1' value (a
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one bit integer). The problem with this is that Kaleidoscope wants the
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value to be a 0.0 or 1.0 value. In order to get these semantics, we
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combine the fcmp instruction with a `uitofp
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instruction <../../LangRef.html#uitofp-to-instruction>`_. This instruction converts its
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input integer into a floating point value by treating the input as an
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unsigned value. In contrast, if we used the `sitofp
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instruction <../../LangRef.html#sitofp-to-instruction>`_, the Kaleidoscope '<' operator
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would return 0.0 and -1.0, depending on the input value.
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.. code-block:: c++
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Value *CallExprAST::codegen() {
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// Look up the name in the global module table.
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Function *CalleeF = TheModule->getFunction(Callee);
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if (!CalleeF)
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return LogErrorV("Unknown function referenced");
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// If argument mismatch error.
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if (CalleeF->arg_size() != Args.size())
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return LogErrorV("Incorrect # arguments passed");
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std::vector<Value *> ArgsV;
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for (unsigned i = 0, e = Args.size(); i != e; ++i) {
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ArgsV.push_back(Args[i]->codegen());
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if (!ArgsV.back())
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return nullptr;
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}
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return Builder.CreateCall(CalleeF, ArgsV, "calltmp");
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}
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Code generation for function calls is quite straightforward with LLVM. The code
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above initially does a function name lookup in the LLVM Module's symbol table.
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Recall that the LLVM Module is the container that holds the functions we are
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JIT'ing. By giving each function the same name as what the user specifies, we
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can use the LLVM symbol table to resolve function names for us.
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Once we have the function to call, we recursively codegen each argument
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that is to be passed in, and create an LLVM `call
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instruction <../../LangRef.html#call-instruction>`_. Note that LLVM uses the native C
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calling conventions by default, allowing these calls to also call into
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standard library functions like "sin" and "cos", with no additional
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effort.
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This wraps up our handling of the four basic expressions that we have so
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far in Kaleidoscope. Feel free to go in and add some more. For example,
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by browsing the `LLVM language reference <../../LangRef.html>`_ you'll find
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several other interesting instructions that are really easy to plug into
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our basic framework.
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Function Code Generation
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========================
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Code generation for prototypes and functions must handle a number of
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details, which make their code less beautiful than expression code
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generation, but allows us to illustrate some important points. First,
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let's talk about code generation for prototypes: they are used both for
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function bodies and external function declarations. The code starts
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with:
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.. code-block:: c++
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Function *PrototypeAST::codegen() {
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// Make the function type: double(double,double) etc.
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std::vector<Type*> Doubles(Args.size(),
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Type::getDoubleTy(TheContext));
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FunctionType *FT =
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FunctionType::get(Type::getDoubleTy(TheContext), Doubles, false);
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Function *F =
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Function::Create(FT, Function::ExternalLinkage, Name, TheModule.get());
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This code packs a lot of power into a few lines. Note first that this
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function returns a "Function\*" instead of a "Value\*". Because a
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"prototype" really talks about the external interface for a function
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(not the value computed by an expression), it makes sense for it to
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return the LLVM Function it corresponds to when codegen'd.
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The call to ``FunctionType::get`` creates the ``FunctionType`` that
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should be used for a given Prototype. Since all function arguments in
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Kaleidoscope are of type double, the first line creates a vector of "N"
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LLVM double types. It then uses the ``Functiontype::get`` method to
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create a function type that takes "N" doubles as arguments, returns one
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double as a result, and that is not vararg (the false parameter
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indicates this). Note that Types in LLVM are uniqued just like Constants
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are, so you don't "new" a type, you "get" it.
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The final line above actually creates the IR Function corresponding to
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the Prototype. This indicates the type, linkage and name to use, as
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well as which module to insert into. "`external
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linkage <../../LangRef.html#linkage>`_" means that the function may be
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defined outside the current module and/or that it is callable by
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functions outside the module. The Name passed in is the name the user
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specified: since "``TheModule``" is specified, this name is registered
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in "``TheModule``"s symbol table.
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.. code-block:: c++
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// Set names for all arguments.
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unsigned Idx = 0;
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for (auto &Arg : F->args())
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Arg.setName(Args[Idx++]);
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return F;
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Finally, we set the name of each of the function's arguments according to the
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names given in the Prototype. This step isn't strictly necessary, but keeping
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the names consistent makes the IR more readable, and allows subsequent code to
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refer directly to the arguments for their names, rather than having to look up
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them up in the Prototype AST.
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At this point we have a function prototype with no body. This is how LLVM IR
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represents function declarations. For extern statements in Kaleidoscope, this
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is as far as we need to go. For function definitions however, we need to
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codegen and attach a function body.
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.. code-block:: c++
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Function *FunctionAST::codegen() {
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// First, check for an existing function from a previous 'extern' declaration.
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Function *TheFunction = TheModule->getFunction(Proto->getName());
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if (!TheFunction)
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TheFunction = Proto->codegen();
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if (!TheFunction)
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return nullptr;
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if (!TheFunction->empty())
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return (Function*)LogErrorV("Function cannot be redefined.");
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For function definitions, we start by searching TheModule's symbol table for an
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existing version of this function, in case one has already been created using an
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'extern' statement. If Module::getFunction returns null then no previous version
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exists, so we'll codegen one from the Prototype. In either case, we want to
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assert that the function is empty (i.e. has no body yet) before we start.
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.. code-block:: c++
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// Create a new basic block to start insertion into.
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BasicBlock *BB = BasicBlock::Create(TheContext, "entry", TheFunction);
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Builder.SetInsertPoint(BB);
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// Record the function arguments in the NamedValues map.
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NamedValues.clear();
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for (auto &Arg : TheFunction->args())
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NamedValues[Arg.getName()] = &Arg;
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Now we get to the point where the ``Builder`` is set up. The first line
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creates a new `basic block <http://en.wikipedia.org/wiki/Basic_block>`_
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(named "entry"), which is inserted into ``TheFunction``. The second line
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then tells the builder that new instructions should be inserted into the
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end of the new basic block. Basic blocks in LLVM are an important part
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of functions that define the `Control Flow
|
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Graph <http://en.wikipedia.org/wiki/Control_flow_graph>`_. Since we
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don't have any control flow, our functions will only contain one block
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at this point. We'll fix this in `Chapter 5 <LangImpl05.html>`_ :).
|
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Next we add the function arguments to the NamedValues map (after first clearing
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it out) so that they're accessible to ``VariableExprAST`` nodes.
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.. code-block:: c++
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if (Value *RetVal = Body->codegen()) {
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// Finish off the function.
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Builder.CreateRet(RetVal);
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// Validate the generated code, checking for consistency.
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verifyFunction(*TheFunction);
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return TheFunction;
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}
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Once the insertion point has been set up and the NamedValues map populated,
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we call the ``codegen()`` method for the root expression of the function. If no
|
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error happens, this emits code to compute the expression into the entry block
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and returns the value that was computed. Assuming no error, we then create an
|
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LLVM `ret instruction <../../LangRef.html#ret-instruction>`_, which completes the function.
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Once the function is built, we call ``verifyFunction``, which is
|
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provided by LLVM. This function does a variety of consistency checks on
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the generated code, to determine if our compiler is doing everything
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right. Using this is important: it can catch a lot of bugs. Once the
|
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function is finished and validated, we return it.
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.. code-block:: c++
|
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// Error reading body, remove function.
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TheFunction->eraseFromParent();
|
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return nullptr;
|
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}
|
||
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|
||
|
The only piece left here is handling of the error case. For simplicity,
|
||
|
we handle this by merely deleting the function we produced with the
|
||
|
``eraseFromParent`` method. This allows the user to redefine a function
|
||
|
that they incorrectly typed in before: if we didn't delete it, it would
|
||
|
live in the symbol table, with a body, preventing future redefinition.
|
||
|
|
||
|
This code does have a bug, though: If the ``FunctionAST::codegen()`` method
|
||
|
finds an existing IR Function, it does not validate its signature against the
|
||
|
definition's own prototype. This means that an earlier 'extern' declaration will
|
||
|
take precedence over the function definition's signature, which can cause
|
||
|
codegen to fail, for instance if the function arguments are named differently.
|
||
|
There are a number of ways to fix this bug, see what you can come up with! Here
|
||
|
is a testcase:
|
||
|
|
||
|
::
|
||
|
|
||
|
extern foo(a); # ok, defines foo.
|
||
|
def foo(b) b; # Error: Unknown variable name. (decl using 'a' takes precedence).
|
||
|
|
||
|
Driver Changes and Closing Thoughts
|
||
|
===================================
|
||
|
|
||
|
For now, code generation to LLVM doesn't really get us much, except that
|
||
|
we can look at the pretty IR calls. The sample code inserts calls to
|
||
|
codegen into the "``HandleDefinition``", "``HandleExtern``" etc
|
||
|
functions, and then dumps out the LLVM IR. This gives a nice way to look
|
||
|
at the LLVM IR for simple functions. For example:
|
||
|
|
||
|
::
|
||
|
|
||
|
ready> 4+5;
|
||
|
Read top-level expression:
|
||
|
define double @0() {
|
||
|
entry:
|
||
|
ret double 9.000000e+00
|
||
|
}
|
||
|
|
||
|
Note how the parser turns the top-level expression into anonymous
|
||
|
functions for us. This will be handy when we add `JIT
|
||
|
support <LangImpl04.html#adding-a-jit-compiler>`_ in the next chapter. Also note that the
|
||
|
code is very literally transcribed, no optimizations are being performed
|
||
|
except simple constant folding done by IRBuilder. We will `add
|
||
|
optimizations <LangImpl04.html#trivial-constant-folding>`_ explicitly in the next
|
||
|
chapter.
|
||
|
|
||
|
::
|
||
|
|
||
|
ready> def foo(a b) a*a + 2*a*b + b*b;
|
||
|
Read function definition:
|
||
|
define double @foo(double %a, double %b) {
|
||
|
entry:
|
||
|
%multmp = fmul double %a, %a
|
||
|
%multmp1 = fmul double 2.000000e+00, %a
|
||
|
%multmp2 = fmul double %multmp1, %b
|
||
|
%addtmp = fadd double %multmp, %multmp2
|
||
|
%multmp3 = fmul double %b, %b
|
||
|
%addtmp4 = fadd double %addtmp, %multmp3
|
||
|
ret double %addtmp4
|
||
|
}
|
||
|
|
||
|
This shows some simple arithmetic. Notice the striking similarity to the
|
||
|
LLVM builder calls that we use to create the instructions.
|
||
|
|
||
|
::
|
||
|
|
||
|
ready> def bar(a) foo(a, 4.0) + bar(31337);
|
||
|
Read function definition:
|
||
|
define double @bar(double %a) {
|
||
|
entry:
|
||
|
%calltmp = call double @foo(double %a, double 4.000000e+00)
|
||
|
%calltmp1 = call double @bar(double 3.133700e+04)
|
||
|
%addtmp = fadd double %calltmp, %calltmp1
|
||
|
ret double %addtmp
|
||
|
}
|
||
|
|
||
|
This shows some function calls. Note that this function will take a long
|
||
|
time to execute if you call it. In the future we'll add conditional
|
||
|
control flow to actually make recursion useful :).
|
||
|
|
||
|
::
|
||
|
|
||
|
ready> extern cos(x);
|
||
|
Read extern:
|
||
|
declare double @cos(double)
|
||
|
|
||
|
ready> cos(1.234);
|
||
|
Read top-level expression:
|
||
|
define double @1() {
|
||
|
entry:
|
||
|
%calltmp = call double @cos(double 1.234000e+00)
|
||
|
ret double %calltmp
|
||
|
}
|
||
|
|
||
|
This shows an extern for the libm "cos" function, and a call to it.
|
||
|
|
||
|
.. TODO:: Abandon Pygments' horrible `llvm` lexer. It just totally gives up
|
||
|
on highlighting this due to the first line.
|
||
|
|
||
|
::
|
||
|
|
||
|
ready> ^D
|
||
|
; ModuleID = 'my cool jit'
|
||
|
|
||
|
define double @0() {
|
||
|
entry:
|
||
|
%addtmp = fadd double 4.000000e+00, 5.000000e+00
|
||
|
ret double %addtmp
|
||
|
}
|
||
|
|
||
|
define double @foo(double %a, double %b) {
|
||
|
entry:
|
||
|
%multmp = fmul double %a, %a
|
||
|
%multmp1 = fmul double 2.000000e+00, %a
|
||
|
%multmp2 = fmul double %multmp1, %b
|
||
|
%addtmp = fadd double %multmp, %multmp2
|
||
|
%multmp3 = fmul double %b, %b
|
||
|
%addtmp4 = fadd double %addtmp, %multmp3
|
||
|
ret double %addtmp4
|
||
|
}
|
||
|
|
||
|
define double @bar(double %a) {
|
||
|
entry:
|
||
|
%calltmp = call double @foo(double %a, double 4.000000e+00)
|
||
|
%calltmp1 = call double @bar(double 3.133700e+04)
|
||
|
%addtmp = fadd double %calltmp, %calltmp1
|
||
|
ret double %addtmp
|
||
|
}
|
||
|
|
||
|
declare double @cos(double)
|
||
|
|
||
|
define double @1() {
|
||
|
entry:
|
||
|
%calltmp = call double @cos(double 1.234000e+00)
|
||
|
ret double %calltmp
|
||
|
}
|
||
|
|
||
|
When you quit the current demo (by sending an EOF via CTRL+D on Linux
|
||
|
or CTRL+Z and ENTER on Windows), it dumps out the IR for the entire
|
||
|
module generated. Here you can see the big picture with all the
|
||
|
functions referencing each other.
|
||
|
|
||
|
This wraps up the third chapter of the Kaleidoscope tutorial. Up next,
|
||
|
we'll describe how to `add JIT codegen and optimizer
|
||
|
support <LangImpl04.html>`_ to this so we can actually start running
|
||
|
code!
|
||
|
|
||
|
Full Code Listing
|
||
|
=================
|
||
|
|
||
|
Here is the complete code listing for our running example, enhanced with
|
||
|
the LLVM code generator. Because this uses the LLVM libraries, we need
|
||
|
to link them in. To do this, we use the
|
||
|
`llvm-config <https://llvm.org/cmds/llvm-config.html>`_ tool to inform
|
||
|
our makefile/command line about which options to use:
|
||
|
|
||
|
.. code-block:: bash
|
||
|
|
||
|
# Compile
|
||
|
clang++ -g -O3 toy.cpp `llvm-config --cxxflags --ldflags --system-libs --libs core` -o toy
|
||
|
# Run
|
||
|
./toy
|
||
|
|
||
|
Here is the code:
|
||
|
|
||
|
.. literalinclude:: ../../../examples/Kaleidoscope/Chapter3/toy.cpp
|
||
|
:language: c++
|
||
|
|
||
|
`Next: Adding JIT and Optimizer Support <LangImpl04.html>`_
|
||
|
|