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===============================
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ORC Design and Implementation
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===============================
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.. contents::
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:local:
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Introduction
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============
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This document aims to provide a high-level overview of the design and
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implementation of the ORC JIT APIs. Except where otherwise stated all discussion
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refers to the modern ORCv2 APIs (available since LLVM 7). Clients wishing to
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transition from OrcV1 should see Section :ref:`transitioning_orcv1_to_orcv2`.
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Use-cases
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=========
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ORC provides a modular API for building JIT compilers. There are a number
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of use cases for such an API. For example:
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1. The LLVM tutorials use a simple ORC-based JIT class to execute expressions
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compiled from a toy language: Kaleidoscope.
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2. The LLVM debugger, LLDB, uses a cross-compiling JIT for expression
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evaluation. In this use case, cross compilation allows expressions compiled
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in the debugger process to be executed on the debug target process, which may
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be on a different device/architecture.
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3. In high-performance JITs (e.g. JVMs, Julia) that want to make use of LLVM's
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optimizations within an existing JIT infrastructure.
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4. In interpreters and REPLs, e.g. Cling (C++) and the Swift interpreter.
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By adopting a modular, library-based design we aim to make ORC useful in as many
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of these contexts as possible.
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Features
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========
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ORC provides the following features:
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**JIT-linking**
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ORC provides APIs to link relocatable object files (COFF, ELF, MachO) [1]_
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into a target process at runtime. The target process may be the same process
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that contains the JIT session object and jit-linker, or may be another process
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(even one running on a different machine or architecture) that communicates
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with the JIT via RPC.
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**LLVM IR compilation**
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ORC provides off the shelf components (IRCompileLayer, SimpleCompiler,
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ConcurrentIRCompiler) that make it easy to add LLVM IR to a JIT'd process.
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**Eager and lazy compilation**
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By default, ORC will compile symbols as soon as they are looked up in the JIT
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session object (``ExecutionSession``). Compiling eagerly by default makes it
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easy to use ORC as an in-memory compiler for an existing JIT (similar to how
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MCJIT is commonly used). However ORC also provides built-in support for lazy
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compilation via lazy-reexports (see :ref:`Laziness`).
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**Support for Custom Compilers and Program Representations**
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Clients can supply custom compilers for each symbol that they define in their
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JIT session. ORC will run the user-supplied compiler when the a definition of
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a symbol is needed. ORC is actually fully language agnostic: LLVM IR is not
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treated specially, and is supported via the same wrapper mechanism (the
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``MaterializationUnit`` class) that is used for custom compilers.
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**Concurrent JIT'd code** and **Concurrent Compilation**
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JIT'd code may be executed in multiple threads, may spawn new threads, and may
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re-enter the ORC (e.g. to request lazy compilation) concurrently from multiple
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threads. Compilers launched my ORC can run concurrently (provided the client
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sets up an appropriate dispatcher). Built-in dependency tracking ensures that
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ORC does not release pointers to JIT'd code or data until all dependencies
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have also been JIT'd and they are safe to call or use.
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**Removable Code**
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Resources for JIT'd program representations
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**Orthogonality** and **Composability**
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Each of the features above can be used independently. It is possible to put
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ORC components together to make a non-lazy, in-process, single threaded JIT
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or a lazy, out-of-process, concurrent JIT, or anything in between.
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LLJIT and LLLazyJIT
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===================
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ORC provides two basic JIT classes off-the-shelf. These are useful both as
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examples of how to assemble ORC components to make a JIT, and as replacements
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for earlier LLVM JIT APIs (e.g. MCJIT).
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The LLJIT class uses an IRCompileLayer and RTDyldObjectLinkingLayer to support
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compilation of LLVM IR and linking of relocatable object files. All operations
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are performed eagerly on symbol lookup (i.e. a symbol's definition is compiled
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as soon as you attempt to look up its address). LLJIT is a suitable replacement
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for MCJIT in most cases (note: some more advanced features, e.g.
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JITEventListeners are not supported yet).
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The LLLazyJIT extends LLJIT and adds a CompileOnDemandLayer to enable lazy
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compilation of LLVM IR. When an LLVM IR module is added via the addLazyIRModule
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method, function bodies in that module will not be compiled until they are first
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called. LLLazyJIT aims to provide a replacement of LLVM's original (pre-MCJIT)
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JIT API.
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LLJIT and LLLazyJIT instances can be created using their respective builder
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classes: LLJITBuilder and LLazyJITBuilder. For example, assuming you have a
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module ``M`` loaded on a ThreadSafeContext ``Ctx``:
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.. code-block:: c++
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// Try to detect the host arch and construct an LLJIT instance.
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auto JIT = LLJITBuilder().create();
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// If we could not construct an instance, return an error.
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if (!JIT)
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return JIT.takeError();
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// Add the module.
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if (auto Err = JIT->addIRModule(TheadSafeModule(std::move(M), Ctx)))
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return Err;
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// Look up the JIT'd code entry point.
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auto EntrySym = JIT->lookup("entry");
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if (!EntrySym)
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return EntrySym.takeError();
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// Cast the entry point address to a function pointer.
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auto *Entry = (void(*)())EntrySym.getAddress();
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// Call into JIT'd code.
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Entry();
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The builder classes provide a number of configuration options that can be
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specified before the JIT instance is constructed. For example:
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.. code-block:: c++
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// Build an LLLazyJIT instance that uses four worker threads for compilation,
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// and jumps to a specific error handler (rather than null) on lazy compile
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// failures.
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void handleLazyCompileFailure() {
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// JIT'd code will jump here if lazy compilation fails, giving us an
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// opportunity to exit or throw an exception into JIT'd code.
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throw JITFailed();
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}
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auto JIT = LLLazyJITBuilder()
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.setNumCompileThreads(4)
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.setLazyCompileFailureAddr(
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toJITTargetAddress(&handleLazyCompileFailure))
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.create();
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// ...
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For users wanting to get started with LLJIT a minimal example program can be
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found at ``llvm/examples/HowToUseLLJIT``.
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Design Overview
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===============
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ORC's JIT program model aims to emulate the linking and symbol resolution
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rules used by the static and dynamic linkers. This allows ORC to JIT
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arbitrary LLVM IR, including IR produced by an ordinary static compiler (e.g.
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clang) that uses constructs like symbol linkage and visibility, and weak [3]_
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and common symbol definitions.
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To see how this works, imagine a program ``foo`` which links against a pair
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of dynamic libraries: ``libA`` and ``libB``. On the command line, building this
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program might look like:
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.. code-block:: bash
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$ clang++ -shared -o libA.dylib a1.cpp a2.cpp
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$ clang++ -shared -o libB.dylib b1.cpp b2.cpp
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$ clang++ -o myapp myapp.cpp -L. -lA -lB
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$ ./myapp
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In ORC, this would translate into API calls on a hypothetical CXXCompilingLayer
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(with error checking omitted for brevity) as:
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.. code-block:: c++
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ExecutionSession ES;
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RTDyldObjectLinkingLayer ObjLinkingLayer(
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ES, []() { return std::make_unique<SectionMemoryManager>(); });
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CXXCompileLayer CXXLayer(ES, ObjLinkingLayer);
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// Create JITDylib "A" and add code to it using the CXX layer.
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auto &LibA = ES.createJITDylib("A");
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CXXLayer.add(LibA, MemoryBuffer::getFile("a1.cpp"));
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CXXLayer.add(LibA, MemoryBuffer::getFile("a2.cpp"));
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// Create JITDylib "B" and add code to it using the CXX layer.
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auto &LibB = ES.createJITDylib("B");
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CXXLayer.add(LibB, MemoryBuffer::getFile("b1.cpp"));
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CXXLayer.add(LibB, MemoryBuffer::getFile("b2.cpp"));
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// Create and specify the search order for the main JITDylib. This is
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// equivalent to a "links against" relationship in a command-line link.
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auto &MainJD = ES.createJITDylib("main");
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MainJD.addToLinkOrder(&LibA);
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MainJD.addToLinkOrder(&LibB);
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CXXLayer.add(MainJD, MemoryBuffer::getFile("main.cpp"));
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// Look up the JIT'd main, cast it to a function pointer, then call it.
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auto MainSym = ExitOnErr(ES.lookup({&MainJD}, "main"));
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auto *Main = (int(*)(int, char*[]))MainSym.getAddress();
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int Result = Main(...);
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This example tells us nothing about *how* or *when* compilation will happen.
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That will depend on the implementation of the hypothetical CXXCompilingLayer.
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The same linker-based symbol resolution rules will apply regardless of that
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implementation, however. For example, if a1.cpp and a2.cpp both define a
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function "foo" then ORCv2 will generate a duplicate definition error. On the
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other hand, if a1.cpp and b1.cpp both define "foo" there is no error (different
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dynamic libraries may define the same symbol). If main.cpp refers to "foo", it
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should bind to the definition in LibA rather than the one in LibB, since
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main.cpp is part of the "main" dylib, and the main dylib links against LibA
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before LibB.
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Many JIT clients will have no need for this strict adherence to the usual
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ahead-of-time linking rules, and should be able to get by just fine by putting
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all of their code in a single JITDylib. However, clients who want to JIT code
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for languages/projects that traditionally rely on ahead-of-time linking (e.g.
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C++) will find that this feature makes life much easier.
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Symbol lookup in ORC serves two other important functions, beyond providing
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addresses for symbols: (1) It triggers compilation of the symbol(s) searched for
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(if they have not been compiled already), and (2) it provides the
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synchronization mechanism for concurrent compilation. The pseudo-code for the
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lookup process is:
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.. code-block:: none
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construct a query object from a query set and query handler
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lock the session
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lodge query against requested symbols, collect required materializers (if any)
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unlock the session
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dispatch materializers (if any)
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In this context a materializer is something that provides a working definition
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of a symbol upon request. Usually materializers are just wrappers for compilers,
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but they may also wrap a jit-linker directly (if the program representation
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backing the definitions is an object file), or may even be a class that writes
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bits directly into memory (for example, if the definitions are
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stubs). Materialization is the blanket term for any actions (compiling, linking,
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splatting bits, registering with runtimes, etc.) that are required to generate a
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symbol definition that is safe to call or access.
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As each materializer completes its work it notifies the JITDylib, which in turn
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notifies any query objects that are waiting on the newly materialized
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definitions. Each query object maintains a count of the number of symbols that
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it is still waiting on, and once this count reaches zero the query object calls
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the query handler with a *SymbolMap* (a map of symbol names to addresses)
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describing the result. If any symbol fails to materialize the query immediately
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calls the query handler with an error.
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The collected materialization units are sent to the ExecutionSession to be
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dispatched, and the dispatch behavior can be set by the client. By default each
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materializer is run on the calling thread. Clients are free to create new
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threads to run materializers, or to send the work to a work queue for a thread
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pool (this is what LLJIT/LLLazyJIT do).
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Top Level APIs
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==============
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Many of ORC's top-level APIs are visible in the example above:
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- *ExecutionSession* represents the JIT'd program and provides context for the
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JIT: It contains the JITDylibs, error reporting mechanisms, and dispatches the
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materializers.
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- *JITDylibs* provide the symbol tables.
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- *Layers* (ObjLinkingLayer and CXXLayer) are wrappers around compilers and
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allow clients to add uncompiled program representations supported by those
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compilers to JITDylibs.
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Several other important APIs are used explicitly. JIT clients need not be aware
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of them, but Layer authors will use them:
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- *MaterializationUnit* - When XXXLayer::add is invoked it wraps the given
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program representation (in this example, C++ source) in a MaterializationUnit,
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which is then stored in the JITDylib. MaterializationUnits are responsible for
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describing the definitions they provide, and for unwrapping the program
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representation and passing it back to the layer when compilation is required
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(this ownership shuffle makes writing thread-safe layers easier, since the
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ownership of the program representation will be passed back on the stack,
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rather than having to be fished out of a Layer member, which would require
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synchronization).
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- *MaterializationResponsibility* - When a MaterializationUnit hands a program
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representation back to the layer it comes with an associated
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MaterializationResponsibility object. This object tracks the definitions
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that must be materialized and provides a way to notify the JITDylib once they
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are either successfully materialized or a failure occurs.
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Absolute Symbols, Aliases, and Reexports
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========================================
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ORC makes it easy to define symbols with absolute addresses, or symbols that
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are simply aliases of other symbols:
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Absolute Symbols
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----------------
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Absolute symbols are symbols that map directly to addresses without requiring
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further materialization, for example: "foo" = 0x1234. One use case for
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absolute symbols is allowing resolution of process symbols. E.g.
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.. code-block: c++
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JD.define(absoluteSymbols(SymbolMap({
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{ Mangle("printf"),
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{ pointerToJITTargetAddress(&printf),
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JITSymbolFlags::Callable } }
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});
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With this mapping established code added to the JIT can refer to printf
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symbolically rather than requiring the address of printf to be "baked in".
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This in turn allows cached versions of the JIT'd code (e.g. compiled objects)
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to be re-used across JIT sessions as the JIT'd code no longer changes, only the
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absolute symbol definition does.
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For process and library symbols the DynamicLibrarySearchGenerator utility (See
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:ref:`How to Add Process and Library Symbols to JITDylibs
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<ProcessAndLibrarySymbols>`) can be used to automatically build absolute
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symbol mappings for you. However the absoluteSymbols function is still useful
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for making non-global objects in your JIT visible to JIT'd code. For example,
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imagine that your JIT standard library needs access to your JIT object to make
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some calls. We could bake the address of your object into the library, but then
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it would need to be recompiled for each session:
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.. code-block: c++
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// From standard library for JIT'd code:
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class MyJIT {
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public:
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void log(const char *Msg);
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};
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void log(const char *Msg) { ((MyJIT*)0x1234)->log(Msg); }
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We can turn this into a symbolic reference in the JIT standard library:
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.. code-block: c++
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extern MyJIT *__MyJITInstance;
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void log(const char *Msg) { __MyJITInstance->log(Msg); }
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And then make our JIT object visible to the JIT standard library with an
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absolute symbol definition when the JIT is started:
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.. code-block: c++
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MyJIT J = ...;
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auto &JITStdLibJD = ... ;
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JITStdLibJD.define(absoluteSymbols(SymbolMap({
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{ Mangle("__MyJITInstance"),
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{ pointerToJITTargetAddress(&J), JITSymbolFlags() } }
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});
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Aliases and Reexports
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---------------------
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Aliases and reexports allow you to define new symbols that map to existing
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symbols. This can be useful for changing linkage relationships between symbols
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across sessions without having to recompile code. For example, imagine that
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JIT'd code has access to a log function, ``void log(const char*)`` for which
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there are two implementations in the JIT standard library: ``log_fast`` and
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``log_detailed``. Your JIT can choose which one of these definitions will be
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used when the ``log`` symbol is referenced by setting up an alias at JIT startup
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time:
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.. code-block: c++
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auto &JITStdLibJD = ... ;
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auto LogImplementationSymbol =
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Verbose ? Mangle("log_detailed") : Mangle("log_fast");
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JITStdLibJD.define(
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symbolAliases(SymbolAliasMap({
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{ Mangle("log"),
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{ LogImplementationSymbol
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JITSymbolFlags::Exported | JITSymbolFlags::Callable } }
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});
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The ``symbolAliases`` function allows you to define aliases within a single
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JITDylib. The ``reexports`` function provides the same functionality, but
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operates across JITDylib boundaries. E.g.
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.. code-block: c++
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auto &JD1 = ... ;
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auto &JD2 = ... ;
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// Make 'bar' in JD2 an alias for 'foo' from JD1.
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JD2.define(
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reexports(JD1, SymbolAliasMap({
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{ Mangle("bar"), { Mangle("foo"), JITSymbolFlags::Exported } }
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});
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The reexports utility can be handy for composing a single JITDylib interface by
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re-exporting symbols from several other JITDylibs.
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.. _Laziness:
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Laziness
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========
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Laziness in ORC is provided by a utility called "lazy reexports". A lazy
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reexport is similar to a regular reexport or alias: It provides a new name for
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an existing symbol. Unlike regular reexports however, lookups of lazy reexports
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do not trigger immediate materialization of the reexported symbol. Instead, they
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only trigger materialization of a function stub. This function stub is
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initialized to point at a *lazy call-through*, which provides reentry into the
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JIT. If the stub is called at runtime then the lazy call-through will look up
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the reexported symbol (triggering materialization for it if necessary), update
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the stub (to call directly to the reexported symbol on subsequent calls), and
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then return via the reexported symbol. By re-using the existing symbol lookup
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mechanism, lazy reexports inherit the same concurrency guarantees: calls to lazy
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reexports can be made from multiple threads concurrently, and the reexported
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symbol can be any state of compilation (uncompiled, already in the process of
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being compiled, or already compiled) and the call will succeed. This allows
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laziness to be safely mixed with features like remote compilation, concurrent
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compilation, concurrent JIT'd code, and speculative compilation.
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There is one other key difference between regular reexports and lazy reexports
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that some clients must be aware of: The address of a lazy reexport will be
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*different* from the address of the reexported symbol (whereas a regular
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reexport is guaranteed to have the same address as the reexported symbol).
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Clients who care about pointer equality will generally want to use the address
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of the reexport as the canonical address of the reexported symbol. This will
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allow the address to be taken without forcing materialization of the reexport.
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Usage example:
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If JITDylib ``JD`` contains definitions for symbols ``foo_body`` and
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``bar_body``, we can create lazy entry points ``Foo`` and ``Bar`` in JITDylib
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``JD2`` by calling:
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.. code-block:: c++
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auto ReexportFlags = JITSymbolFlags::Exported | JITSymbolFlags::Callable;
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JD2.define(
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lazyReexports(CallThroughMgr, StubsMgr, JD,
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SymbolAliasMap({
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{ Mangle("foo"), { Mangle("foo_body"), ReexportedFlags } },
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{ Mangle("bar"), { Mangle("bar_body"), ReexportedFlags } }
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}));
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A full example of how to use lazyReexports with the LLJIT class can be found at
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``llvm_project/llvm/examples/LLJITExamples/LLJITWithLazyReexports``.
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Supporting Custom Compilers
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===========================
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TBD.
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.. _transitioning_orcv1_to_orcv2:
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Transitioning from ORCv1 to ORCv2
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=================================
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Since LLVM 7.0, new ORC development work has focused on adding support for
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concurrent JIT compilation. The new APIs (including new layer interfaces and
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implementations, and new utilities) that support concurrency are collectively
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referred to as ORCv2, and the original, non-concurrent layers and utilities
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are now referred to as ORCv1.
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The majority of the ORCv1 layers and utilities were renamed with a 'Legacy'
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prefix in LLVM 8.0, and have deprecation warnings attached in LLVM 9.0. In LLVM
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12.0 ORCv1 will be removed entirely.
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Transitioning from ORCv1 to ORCv2 should be easy for most clients. Most of the
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ORCv1 layers and utilities have ORCv2 counterparts [2]_ that can be directly
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substituted. However there are some design differences between ORCv1 and ORCv2
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to be aware of:
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1. ORCv2 fully adopts the JIT-as-linker model that began with MCJIT. Modules
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(and other program representations, e.g. Object Files) are no longer added
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directly to JIT classes or layers. Instead, they are added to ``JITDylib``
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instances *by* layers. The ``JITDylib`` determines *where* the definitions
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reside, the layers determine *how* the definitions will be compiled.
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Linkage relationships between ``JITDylibs`` determine how inter-module
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references are resolved, and symbol resolvers are no longer used. See the
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section `Design Overview`_ for more details.
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Unless multiple JITDylibs are needed to model linkage relationships, ORCv1
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clients should place all code in a single JITDylib.
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MCJIT clients should use LLJIT (see `LLJIT and LLLazyJIT`_), and can place
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code in LLJIT's default created main JITDylib (See
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``LLJIT::getMainJITDylib()``).
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2. All JIT stacks now need an ``ExecutionSession`` instance. ExecutionSession
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manages the string pool, error reporting, synchronization, and symbol
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lookup.
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3. ORCv2 uses uniqued strings (``SymbolStringPtr`` instances) rather than
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string values in order to reduce memory overhead and improve lookup
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performance. See the subsection `How to manage symbol strings`_.
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4. IR layers require ThreadSafeModule instances, rather than
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std::unique_ptr<Module>s. ThreadSafeModule is a wrapper that ensures that
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Modules that use the same LLVMContext are not accessed concurrently.
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See `How to use ThreadSafeModule and ThreadSafeContext`_.
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5. Symbol lookup is no longer handled by layers. Instead, there is a
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``lookup`` method on JITDylib that takes a list of JITDylibs to scan.
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.. code-block:: c++
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ExecutionSession ES;
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JITDylib &JD1 = ...;
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JITDylib &JD2 = ...;
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auto Sym = ES.lookup({&JD1, &JD2}, ES.intern("_main"));
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6. Module removal is not yet supported. There is no equivalent of the
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layer concept removeModule/removeObject methods. Work on resource tracking
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and removal in ORCv2 is ongoing.
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For code examples and suggestions of how to use the ORCv2 APIs, please see
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the section `How-tos`_.
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How-tos
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=======
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How to manage symbol strings
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----------------------------
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Symbol strings in ORC are uniqued to improve lookup performance, reduce memory
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overhead, and allow symbol names to function as efficient keys. To get the
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unique ``SymbolStringPtr`` for a string value, call the
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``ExecutionSession::intern`` method:
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.. code-block:: c++
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ExecutionSession ES;
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/// ...
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auto MainSymbolName = ES.intern("main");
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If you wish to perform lookup using the C/IR name of a symbol you will also
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need to apply the platform linker-mangling before interning the string. On
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Linux this mangling is a no-op, but on other platforms it usually involves
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adding a prefix to the string (e.g. '_' on Darwin). The mangling scheme is
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based on the DataLayout for the target. Given a DataLayout and an
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ExecutionSession, you can create a MangleAndInterner function object that
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will perform both jobs for you:
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.. code-block:: c++
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ExecutionSession ES;
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const DataLayout &DL = ...;
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MangleAndInterner Mangle(ES, DL);
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// ...
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// Portable IR-symbol-name lookup:
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auto Sym = ES.lookup({&MainJD}, Mangle("main"));
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How to create JITDylibs and set up linkage relationships
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--------------------------------------------------------
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In ORC, all symbol definitions reside in JITDylibs. JITDylibs are created by
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calling the ``ExecutionSession::createJITDylib`` method with a unique name:
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.. code-block:: c++
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ExecutionSession ES;
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auto &JD = ES.createJITDylib("libFoo.dylib");
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The JITDylib is owned by the ``ExecutionEngine`` instance and will be freed
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when it is destroyed.
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How to use ThreadSafeModule and ThreadSafeContext
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-------------------------------------------------
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ThreadSafeModule and ThreadSafeContext are wrappers around Modules and
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LLVMContexts respectively. A ThreadSafeModule is a pair of a
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std::unique_ptr<Module> and a (possibly shared) ThreadSafeContext value. A
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ThreadSafeContext is a pair of a std::unique_ptr<LLVMContext> and a lock.
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This design serves two purposes: providing a locking scheme and lifetime
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management for LLVMContexts. The ThreadSafeContext may be locked to prevent
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accidental concurrent access by two Modules that use the same LLVMContext.
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The underlying LLVMContext is freed once all ThreadSafeContext values pointing
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to it are destroyed, allowing the context memory to be reclaimed as soon as
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the Modules referring to it are destroyed.
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ThreadSafeContexts can be explicitly constructed from a
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std::unique_ptr<LLVMContext>:
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.. code-block:: c++
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ThreadSafeContext TSCtx(std::make_unique<LLVMContext>());
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ThreadSafeModules can be constructed from a pair of a std::unique_ptr<Module>
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and a ThreadSafeContext value. ThreadSafeContext values may be shared between
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multiple ThreadSafeModules:
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.. code-block:: c++
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ThreadSafeModule TSM1(
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std::make_unique<Module>("M1", *TSCtx.getContext()), TSCtx);
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ThreadSafeModule TSM2(
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std::make_unique<Module>("M2", *TSCtx.getContext()), TSCtx);
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Before using a ThreadSafeContext, clients should ensure that either the context
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is only accessible on the current thread, or that the context is locked. In the
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example above (where the context is never locked) we rely on the fact that both
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``TSM1`` and ``TSM2``, and TSCtx are all created on one thread. If a context is
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going to be shared between threads then it must be locked before any accessing
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or creating any Modules attached to it. E.g.
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.. code-block:: c++
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ThreadSafeContext TSCtx(std::make_unique<LLVMContext>());
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ThreadPool TP(NumThreads);
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JITStack J;
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for (auto &ModulePath : ModulePaths) {
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TP.async(
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[&]() {
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auto Lock = TSCtx.getLock();
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auto M = loadModuleOnContext(ModulePath, TSCtx.getContext());
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J.addModule(ThreadSafeModule(std::move(M), TSCtx));
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});
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}
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TP.wait();
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To make exclusive access to Modules easier to manage the ThreadSafeModule class
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provides a convenience function, ``withModuleDo``, that implicitly (1) locks the
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associated context, (2) runs a given function object, (3) unlocks the context,
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and (3) returns the result generated by the function object. E.g.
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.. code-block:: c++
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ThreadSafeModule TSM = getModule(...);
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// Dump the module:
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size_t NumFunctionsInModule =
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TSM.withModuleDo(
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[](Module &M) { // <- Context locked before entering lambda.
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return M.size();
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} // <- Context unlocked after leaving.
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);
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Clients wishing to maximize possibilities for concurrent compilation will want
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to create every new ThreadSafeModule on a new ThreadSafeContext. For this
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reason a convenience constructor for ThreadSafeModule is provided that implicitly
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constructs a new ThreadSafeContext value from a std::unique_ptr<LLVMContext>:
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.. code-block:: c++
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// Maximize concurrency opportunities by loading every module on a
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// separate context.
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for (const auto &IRPath : IRPaths) {
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auto Ctx = std::make_unique<LLVMContext>();
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auto M = std::make_unique<LLVMContext>("M", *Ctx);
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CompileLayer.add(MainJD, ThreadSafeModule(std::move(M), std::move(Ctx)));
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}
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Clients who plan to run single-threaded may choose to save memory by loading
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all modules on the same context:
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.. code-block:: c++
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// Save memory by using one context for all Modules:
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ThreadSafeContext TSCtx(std::make_unique<LLVMContext>());
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for (const auto &IRPath : IRPaths) {
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ThreadSafeModule TSM(parsePath(IRPath, *TSCtx.getContext()), TSCtx);
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CompileLayer.add(MainJD, ThreadSafeModule(std::move(TSM));
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}
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.. _ProcessAndLibrarySymbols:
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How to Add Process and Library Symbols to the JITDylibs
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=======================================================
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JIT'd code typically needs access to symbols in the host program or in
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supporting libraries. References to process symbols can be "baked in" to code
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as it is compiled by turning external references into pre-resolved integer
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constants, however this ties the JIT'd code to the current process's virtual
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memory layout (meaning that it can not be cached between runs) and makes
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debugging lower level program representations difficult (as all external
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references are opaque integer values). A bettor solution is to maintain symbolic
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external references and let the jit-linker bind them for you at runtime. To
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allow the JIT linker to find these external definitions their addresses must
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be added to a JITDylib that the JIT'd definitions link against.
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Adding definitions for external symbols could be done using the absoluteSymbols
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function:
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.. code-block:: c++
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const DataLayout &DL = getDataLayout();
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MangleAndInterner Mangle(ES, DL);
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auto &JD = ES.createJITDylib("main");
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JD.define(
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absoluteSymbols({
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{ Mangle("puts"), pointerToJITTargetAddress(&puts)},
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{ Mangle("gets"), pointerToJITTargetAddress(&getS)}
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}));
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Manually adding absolute symbols for a large or changing interface is cumbersome
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however, so ORC provides an alternative to generate new definitions on demand:
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*definition generators*. If a definition generator is attached to a JITDylib,
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then any unsuccessful lookup on that JITDylib will fall back to calling the
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definition generator, and the definition generator may choose to generate a new
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definition for the missing symbols. Of particular use here is the
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``DynamicLibrarySearchGenerator`` utility. This can be used to reflect the whole
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exported symbol set of the process or a specific dynamic library, or a subset
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of either of these determined by a predicate.
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For example, to load the whole interface of a runtime library:
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.. code-block:: c++
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const DataLayout &DL = getDataLayout();
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auto &JD = ES.createJITDylib("main");
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JD.setGenerator(DynamicLibrarySearchGenerator::Load("/path/to/lib"
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DL.getGlobalPrefix()));
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// IR added to JD can now link against all symbols exported by the library
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// at '/path/to/lib'.
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CompileLayer.add(JD, loadModule(...));
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Or, to expose an allowed set of symbols from the main process:
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.. code-block:: c++
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const DataLayout &DL = getDataLayout();
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MangleAndInterner Mangle(ES, DL);
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auto &JD = ES.createJITDylib("main");
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DenseSet<SymbolStringPtr> AllowList({
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Mangle("puts"),
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Mangle("gets")
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});
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// Use GetForCurrentProcess with a predicate function that checks the
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// allowed list.
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JD.setGenerator(
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DynamicLibrarySearchGenerator::GetForCurrentProcess(
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DL.getGlobalPrefix(),
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[&](const SymbolStringPtr &S) { return AllowList.count(S); }));
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// IR added to JD can now link against any symbols exported by the process
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// and contained in the list.
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CompileLayer.add(JD, loadModule(...));
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Roadmap
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=======
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ORC is still undergoing active development. Some current and future works are
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listed below.
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Current Work
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------------
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1. **TargetProcessControl: Improvements to in-tree support for out-of-process
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execution**
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The ``TargetProcessControl`` API provides various operations on the JIT
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target process (the one which will execute the JIT'd code), including
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memory allocation, memory writes, function execution, and process queries
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(e.g. for the target triple). By targeting this API new components can be
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developed which will work equally well for in-process and out-of-process
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JITing.
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2. **ORC RPC based TargetProcessControl implementation**
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An ORC RPC based implementation of the ``TargetProcessControl`` API is
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currently under development to enable easy out-of-process JITing via
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file descriptors / sockets.
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3. **Core State Machine Cleanup**
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The core ORC state machine is currently implemented between JITDylib and
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ExecutionSession. Methods are slowly being moved to `ExecutionSession`. This
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will tidy up the code base, and also allow us to support asynchronous removal
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of JITDylibs (in practice deleting an associated state object in
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ExecutionSession and leaving the JITDylib instance in a defunct state until
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all references to it have been released).
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4. **JITLink improvements**
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TBD. We really need a separate JITLink design document.
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Near Future Work
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----------------
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1. **ORC JIT Runtime Libraries**
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We need a runtime library for JIT'd code. This would include things like
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TLS registration, reentry functions, registration code for language runtimes
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(e.g. Objective C and Swift) and other JIT specific runtime code. This should
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be built in a similar manner to compiler-rt (possibly even as part of it).
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2. **Remote jit_dlopen / jit_dlclose**
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To more fully mimic the environment that static programs operate in we would
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like JIT'd code to be able to "dlopen" and "dlclose" JITDylibs, running all of
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their initializers/deinitializers on the current thread. This would require
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support from the runtime library described above.
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3. **Debugging support**
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ORC currently supports the GDBRegistrationListener API when using RuntimeDyld
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as the underlying JIT linker. We will need a new solution for JITLink based
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platforms.
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Further Future Work
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-------------------
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1. **Speculative Compilation**
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ORC's support for concurrent compilation allows us to easily enable
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*speculative* JIT compilation: compilation of code that is not needed yet,
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but which we have reason to believe will be needed in the future. This can be
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used to hide compile latency and improve JIT throughput. A proof-of-concept
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exmaple of speculative compilation with ORC has already been developed (see
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``llvm/examples/SpeculativeJIT``). Future work on this is likely to focus on
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re-using and improving existing profiling support (currently used by PGO) to
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feed speculation decisions, as well as built-in tools to simplify use of
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speculative compilation.
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.. [1] Formats/architectures vary in terms of supported features. MachO and
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ELF tend to have better support than COFF. Patches very welcome!
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.. [2] The ``LazyEmittingLayer``, ``RemoteObjectClientLayer`` and
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``RemoteObjectServerLayer`` do not have counterparts in the new
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system. In the case of ``LazyEmittingLayer`` it was simply no longer
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needed: in ORCv2, deferring compilation until symbols are looked up is
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the default. The removal of ``RemoteObjectClientLayer`` and
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``RemoteObjectServerLayer`` means that JIT stacks can no longer be split
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across processes, however this functionality appears not to have been
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used.
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.. [3] Weak definitions are currently handled correctly within dylibs, but if
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multiple dylibs provide a weak definition of a symbol then each will end
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up with its own definition (similar to how weak definitions are handled
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in Windows DLLs). This will be fixed in the future.
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