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1126 lines
47 KiB
ReStructuredText
====================================
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JITLink and ORC's ObjectLinkingLayer
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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 API
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of the JITLink library. It assumes some familiarity with linking and
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relocatable object files, but should not require deep expertise. If you know
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what a section, symbol, and relocation are you should find this document
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accessible. If it is not, please submit a patch (:doc:`Contributing`) or file a
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bug (:doc:`HowToSubmitABug`).
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JITLink is a library for :ref:`jit_linking`. It was built to support the ORC JIT
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APIs and is most commonly accessed via ORC's ObjectLinkingLayer API. JITLink was
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developed with the aim of supporting the full set of features provided by each
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object format; including static initializers, exception handling, thread local
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variables, and language runtime registration. Supporting these features enables
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ORC to execute code generated from source languages which rely on these features
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(e.g. C++ requires object format support for static initializers to support
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static constructors, eh-frame registration for exceptions, and TLV support for
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thread locals; Swift and Objective-C require language runtime registration for
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many features). For some object format features support is provided entirely
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within JITLink, and for others it is provided in cooperation with the
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(prototype) ORC runtime.
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JITLink aims to support the following features, some of which are still under
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development:
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1. Cross-process and cross-architecture linking of single relocatable objects
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into a target *executor* process.
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2. Support for all object format features.
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3. Open linker data structures (``LinkGraph``) and pass system.
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JITLink and ObjectLinkingLayer
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==============================
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``ObjectLinkingLayer`` is ORCs wrapper for JITLink. It is an ORC layer that
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allows objects to be added to a ``JITDylib``, or emitted from some higher level
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program representation. When an object is emitted, ``ObjectLinkingLayer`` uses
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JITLink to construct a ``LinkGraph`` (see :ref:`constructing_linkgraphs`) and
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calls JITLink's ``link`` function to link the graph into the executor process.
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The ``ObjectLinkingLayer`` class provides a plugin API,
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``ObjectLinkingLayer::Plugin``, which users can subclass in order to inspect and
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modify ``LinkGraph`` instances at link time, and react to important JIT events
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(such as an object being emitted into target memory). This enables many features
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and optimizations that were not possible under MCJIT or RuntimeDyld.
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ObjectLinkingLayer Plugins
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--------------------------
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The ``ObjectLinkingLayer::Plugin`` class provides the following methods:
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* ``modifyPassConfig`` is called each time a LinkGraph is about to be linked. It
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can be overridden to install JITLink *Passes* to run during the link process.
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.. code-block:: c++
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void modifyPassConfig(MaterializationResponsibility &MR,
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const Triple &TT,
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jitlink::PassConfiguration &Config)
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* ``notifyLoaded`` is called before the link begins, and can be overridden to
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set up any initial state for the given ``MaterializationResponsibility`` if
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needed.
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.. code-block:: c++
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void notifyLoaded(MaterializationResponsibility &MR)
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* ``notifyEmitted`` is called after the link is complete and code has been
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emitted to the executor process. It can be overridden to finalize state
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for the ``MaterializationResponsibility`` if needed.
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.. code-block:: c++
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Error notifyEmitted(MaterializationResponsibility &MR)
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* ``notifyFailed`` is called if the link fails at any point. It can be
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overridden to react to the failure (e.g. to deallocate any already allocated
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resources).
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.. code-block:: c++
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Error notifyFailed(MaterializationResponsibility &MR)
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* ``notifyRemovingResources`` is called when a request is made to remove any
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resources associated with the ``ResourceKey`` *K* for the
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``MaterializationResponsibility``.
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.. code-block:: c++
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Error notifyRemovingResources(ResourceKey K)
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* ``notifyTransferringResources`` is called if/when a request is made to
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transfer tracking of any resources associated with ``ResourceKey``
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*SrcKey* to *DstKey*.
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.. code-block:: c++
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void notifyTransferringResources(ResourceKey DstKey,
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ResourceKey SrcKey)
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Plugin authors are required to implement the ``notifyFailed``,
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``notifyRemovingResources``, and ``notifyTransferringResources`` methods in
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order to safely manage resources in the case of resource removal or transfer,
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or link failure. If no resources are managed by the plugin then these methods
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can be implemented as no-ops returning ``Error::success()``.
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Plugin instances are added to an ``ObjectLinkingLayer`` by
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calling the ``addPlugin`` method [1]_. E.g.
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.. code-block:: c++
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// Plugin class to print the set of defined symbols in an object when that
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// object is linked.
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class MyPlugin : public ObjectLinkingLayer::Plugin {
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public:
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// Add passes to print the set of defined symbols after dead-stripping.
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void modifyPassConfig(MaterializationResponsibility &MR,
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const Triple &TT,
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jitlink::PassConfiguration &Config) override {
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Config.PostPrunePasses.push_back([this](jitlink::LinkGraph &G) {
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return printAllSymbols(G);
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});
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}
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// Implement mandatory overrides:
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Error notifyFailed(MaterializationResponsibility &MR) override {
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return Error::success();
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}
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Error notifyRemovingResources(ResourceKey K) override {
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return Error::success();
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}
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void notifyTransferringResources(ResourceKey DstKey,
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ResourceKey SrcKey) override {}
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// JITLink pass to print all defined symbols in G.
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Error printAllSymbols(LinkGraph &G) {
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for (auto *Sym : G.defined_symbols())
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if (Sym->hasName())
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dbgs() << Sym->getName() << "\n";
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return Error::success();
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}
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};
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// Create our LLJIT instance using a custom object linking layer setup.
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// This gives us a chance to install our plugin.
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auto J = ExitOnErr(LLJITBuilder()
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.setObjectLinkingLayerCreator(
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[](ExecutionSession &ES, const Triple &T) {
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// Manually set up the ObjectLinkingLayer for our LLJIT
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// instance.
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auto OLL = std::make_unique<ObjectLinkingLayer>(
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ES, std::make_unique<jitlink::InProcessMemoryManager>());
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// Install our plugin:
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OLL->addPlugin(std::make_unique<MyPlugin>());
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return OLL;
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})
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.create());
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// Add an object to the JIT. Nothing happens here: linking isn't triggered
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// until we look up some symbol in our object.
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ExitOnErr(J->addObject(loadFromDisk("main.o")));
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// Plugin triggers here when our lookup of main triggers linking of main.o
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auto MainSym = J->lookup("main");
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LinkGraph
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=========
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JITLink maps all relocatable object formats to a generic ``LinkGraph`` type
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that is designed to make linking fast and easy (``LinkGraph`` instances can
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also be created manually. See :ref:`constructing_linkgraphs`).
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Relocatable object formats (e.g. COFF, ELF, MachO) differ in their details,
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but share a common goal: to represent machine level code and data with
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annotations that allow them to be relocated in a virtual address space. To
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this end they usually contain names (symbols) for content defined inside the
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file or externally, chunks of content that must be moved as a unit (sections
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or subsections, depending on the format), and annotations describing how to
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patch content based on the final address of some target symbol/section
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(relocations).
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At a high level, the ``LinkGraph`` type represents these concepts as a decorated
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graph. Nodes in the graph represent symbols and content, and edges represent
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relocations. Each of the elements of the graph is listed here:
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* ``Addressable`` -- A node in the link graph that can be assigned an address
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in the executor process's virtual address space.
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Absolute and external symbols are represented using plain ``Addressable``
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instances. Content defined inside the object file is represented using the
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``Block`` subclass.
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* ``Block`` -- An ``Addressable`` node that has ``Content`` (or is marked as
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zero-filled), a parent ``Section``, a ``Size``, an ``Alignment`` (and an
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``AlignmentOffset``), and a list of ``Edge`` instances.
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Blocks provide a container for binary content which must remain contiguous in
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the target address space (a *layout unit*). Many interesting low level
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operations on ``LinkGraph`` instances involve inspecting or mutating block
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content or edges.
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* ``Content`` is represented as an ``llvm::StringRef``, and accessible via
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the ``getContent`` method. Content is only available for content blocks,
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and not for zero-fill blocks (use ``isZeroFill`` to check, and prefer
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``getSize`` when only the block size is needed as it works for both
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zero-fill and content blocks).
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* ``Section`` is represented as a ``Section&`` reference, and accessible via
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the ``getSection`` method. The ``Section`` class is described in more detail
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below.
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* ``Size`` is represented as a ``size_t``, and is accessible via the
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``getSize`` method for both content and zero-filled blocks.
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* ``Alignment`` is represented as a ``uint64_t``, and available via the
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``getAlignment`` method. It represents the minimum alignment requirement (in
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bytes) of the start of the block.
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* ``AlignmentOffset`` is represented as a ``uint64_t``, and accessible via the
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``getAlignmentOffset`` method. It represents the offset from the alignment
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required for the start of the block. This is required to support blocks
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whose minimum alignment requirement comes from data at some non-zero offset
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inside the block. E.g. if a block consists of a single byte (with byte
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alignment) followed by a uint64_t (with 8-byte alignment), then the block
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will have 8-byte alignment with an alignment offset of 7.
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* list of ``Edge`` instances. An iterator range for this list is returned by
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the ``edges`` method. The ``Edge`` class is described in more detail below.
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* ``Symbol`` -- An offset from an ``Addressable`` (often a ``Block``), with an
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optional ``Name``, a ``Linkage``, a ``Scope``, a ``Callable`` flag, and a
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``Live`` flag.
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Symbols make it possible to name content (blocks and addressables are
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anonymous), or target content with an ``Edge``.
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* ``Name`` is represented as an ``llvm::StringRef`` (equal to
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``llvm::StringRef()`` if the symbol has no name), and accessible via the
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``getName`` method.
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* ``Linkage`` is one of *Strong* or *Weak*, and is accessible via the
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``getLinkage`` method. The ``JITLinkContext`` can use this flag to determine
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whether this symbol definition should be kept or dropped.
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* ``Scope`` is one of *Default*, *Hidden*, or *Local*, and is accessible via
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the ``getScope`` method. The ``JITLinkContext`` can use this to determine
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who should be able to see the symbol. A symbol with default scope should be
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globally visible. A symbol with hidden scope should be visible to other
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definitions within the same simulated dylib (e.g. ORC ``JITDylib``) or
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executable, but not from elsewhere. A symbol with local scope should only be
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visible within the current ``LinkGraph``.
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* ``Callable`` is a boolean which is set to true if this symbol can be called,
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and is accessible via the ``isCallable`` method. This can be used to
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automate the introduction of call-stubs for lazy compilation.
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* ``Live`` is a boolean that can be set to mark this symbol as root for
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dead-stripping purposes (see :ref:`generic_link_algorithm`). JITLink's
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dead-stripping algorithm will propagate liveness flags through the graph to
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all reachable symbols before deleting any symbols (and blocks) that are not
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marked live.
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* ``Edge`` -- A quad of an ``Offset`` (implicitly from the start of the
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containing ``Block``), a ``Kind`` (describing the relocation type), a
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``Target``, and an ``Addend``.
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Edges represent relocations, and occasionally other relationships, between
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blocks and symbols.
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* ``Offset``, accessible via ``getOffset``, is an offset from the start of the
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``Block`` containing the ``Edge``.
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* ``Kind``, accessible via ``getKind`` is a relocation type -- it describes
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what kinds of changes (if any) should be made to block content at the given
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``Offset`` based on the address of the ``Target``.
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* ``Target``, accessible via ``getTarget``, is a pointer to a ``Symbol``,
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representing whose address is relevant to the fixup calculation specified by
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the edge's ``Kind``.
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* ``Addend``, accessible via ``getAddend``, is a constant whose interpretation
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is determined by the edge's ``Kind``.
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* ``Section`` -- A set of ``Symbol`` instances, plus a set of ``Block``
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instances, with a ``Name``, a set of ``ProtectionFlags``, and an ``Ordinal``.
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Sections make it easy to iterate over the symbols or blocks associated with
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a particular section in the source object file.
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* ``blocks()`` returns an iterator over the set of blocks defined in the
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section (as ``Block*`` pointers).
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* ``symbols()`` returns an iterator over the set of symbols defined in the
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section (as ``Symbol*`` pointers).
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* ``Name`` is represented as an ``llvm::StringRef``, and is accessible via the
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``getName`` method.
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* ``ProtectionFlags`` are represented as a sys::Memory::ProtectionFlags enum,
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and accessible via the ``getProtectionFlags`` method. These flags describe
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whether the section is readable, writable, executable, or some combination
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of these. The most common combinations are ``RW-`` for writable data,
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``R--`` for constant data, and ``R-X`` for code.
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* ``SectionOrdinal``, accessible via ``getOrdinal``, is a number used to order
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the section relative to others. It is usually used to preserve section
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order within a segment (a set of sections with the same memory protections)
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when laying out memory.
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For the graph-theorists: The ``LinkGraph`` is bipartite, with one set of
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``Symbol`` nodes and one set of ``Addressable`` nodes. Each ``Symbol`` node has
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one (implicit) edge to its target ``Addressable``. Each ``Block`` has a set of
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edges (possibly empty, represented as ``Edge`` instances) back to elements of
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the ``Symbol`` set. For convenience and performance of common algorithms,
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symbols and blocks are further grouped into ``Sections``.
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The ``LinkGraph`` itself provides operations for constructing, removing, and
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iterating over sections, symbols, and blocks. It also provides metadata
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and utilities relevant to the linking process:
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* Graph element operations
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* ``sections`` returns an iterator over all sections in the graph.
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* ``findSectionByName`` returns a pointer to the section with the given
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name (as a ``Section*``) if it exists, otherwise returns a nullptr.
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* ``blocks`` returns an iterator over all blocks in the graph (across all
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sections).
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* ``defined_symbols`` returns an iterator over all defined symbols in the
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graph (across all sections).
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* ``external_symbols`` returns an iterator over all external symbols in the
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graph.
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* ``absolute_symbols`` returns an iterator over all absolute symbols in the
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graph.
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* ``createSection`` creates a section with a given name and protection flags.
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* ``createContentBlock`` creates a block with the given initial content,
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parent section, address, alignment, and alignment offset.
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* ``createZeroFillBlock`` creates a zero-fill block with the given size,
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parent section, address, alignment, and alignment offset.
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* ``addExternalSymbol`` creates a new addressable and symbol with a given
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name, size, and linkage.
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* ``addAbsoluteSymbol`` creates a new addressable and symbol with a given
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name, address, size, linkage, scope, and liveness.
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* ``addCommonSymbol`` convenience function for creating a zero-filled block
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and weak symbol with a given name, scope, section, initial address, size,
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alignment and liveness.
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* ``addAnonymousSymbol`` creates a new anonymous symbol for a given block,
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offset, size, callable-ness, and liveness.
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* ``addDefinedSymbol`` creates a new symbol for a given block with a name,
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offset, size, linkage, scope, callable-ness and liveness.
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* ``makeExternal`` transforms a formerly defined symbol into an external one
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by creating a new addressable and pointing the symbol at it. The existing
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block is not deleted, but can be manually removed (if unreferenced) by
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calling ``removeBlock``. All edges to the symbol remain valid, but the
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symbol must now be defined outside this ``LinkGraph``.
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* ``removeExternalSymbol`` removes an external symbol and its target
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addressable. The target addressable must not be referenced by any other
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symbols.
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* ``removeAbsoluteSymbol`` removes an absolute symbol and its target
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addressable. The target addressable must not be referenced by any other
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symbols.
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* ``removeDefinedSymbol`` removes a defined symbol, but *does not* remove
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its target block.
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* ``removeBlock`` removes the given block.
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* ``splitBlock`` split a given block in two at a given index (useful where
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it is known that a block contains decomposable records, e.g. CFI records
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in an eh-frame section).
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* Graph utility operations
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* ``getName`` returns the name of this graph, which is usually based on the
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name of the input object file.
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* ``getTargetTriple`` returns an `llvm::Triple` for the executor process.
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* ``getPointerSize`` returns the size of a pointer (in bytes) in the executor
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process.
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* ``getEndinaness`` returns the endianness of the executor process.
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* ``allocateString`` copies data from a given ``llvm::Twine`` into the
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link graph's internal allocator. This can be used to ensure that content
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created inside a pass outlives that pass's execution.
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.. _generic_link_algorithm:
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Generic Link Algorithm
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======================
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JITLink provides a generic link algorithm which can be extended / modified at
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certain points by the introduction of JITLink :ref:`passes`:
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#. Phase 1
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This phase is called immediately by the ``link`` function as soon as the
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initial configuration (including the pass pipeline setup) is complete.
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#. Run pre-prune passes.
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These passes are called on the graph before it is pruned. At this stage
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``LinkGraph`` nodes still have their original vmaddrs. A mark-live pass
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(supplied by the ``JITLinkContext``) will be run at the end of this
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sequence to mark the initial set of live symbols.
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Notable use cases: marking nodes live, accessing/copying graph data that
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will be pruned (e.g. metadata that's important for the JIT, but not needed
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for the link process).
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#. Prune (dead-strip) the ``LinkGraph``.
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Removes all symbols and blocks not reachable from the initial set of live
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symbols.
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This allows JITLink to remove unreachable symbols / content, including
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overridden weak and redundant ODR definitions.
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#. Run post-prune passes.
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These passes are run on the graph after dead-stripping, but before memory
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is allocated or nodes assigned their final target vmaddrs.
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Passes run at this stage benefit from pruning, as dead functions and data
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have been stripped from the graph. However new content can still be added
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to the graph, as target and working memory have not been allocated yet.
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Notable use cases: Building Global Offset Table (GOT), Procedure Linkage
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Table (PLT), and Thread Local Variable (TLV) entries.
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#. Sort blocks into segments.
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Sorts all blocks by ordinal and then address. Collects sections with
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matching permissions into segments and computes the size of these
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segments for memory allocation.
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#. Allocate segment memory, update node addresses.
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Calls the ``JITLinkContext``'s ``JITLinkMemoryManager`` to allocate both
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working and target memory for the graph, then updates all node addresses
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to their assigned target address.
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Note: This step only updates the addresses of nodes defined in this graph.
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External symbols will still have null addresses.
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#. Run post-allocation passes.
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These passes are run on the graph after working and target memory have
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been allocated, but before the ``JITLinkContext`` is notified of the
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final addresses of the symbols in the graph. This gives these passes a
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chance to set up data structures associated with target addresses before
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any JITLink clients (especially ORC queries for symbol resolution) can
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attempt to access them.
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|
|
Notable use cases: Setting up mappings between target addresses and
|
|
JIT data structures, such as a mapping between ``__dso_handle`` and
|
|
``JITDylib*``.
|
|
|
|
#. Notify the ``JITLinkContext`` of the assigned symbol addresses.
|
|
|
|
Calls ``JITLinkContext::notifyResolved`` on the link graph, allowing
|
|
clients to react to the symbol address assignments made for this graph.
|
|
In ORC this is used to notify any pending queries for *resolved* symbols,
|
|
including pending queries from concurrently running JITLink instances that
|
|
have reached the next step and are waiting on the address of a symbol in
|
|
this graph to proceed with their link.
|
|
|
|
#. Identify external symbols and resolve their addresses asynchronously.
|
|
|
|
Calls the ``JITLinkContext`` to resolve the target address of any external
|
|
symbols in the graph. This step is asynchronous -- JITLink will pack the
|
|
link state into a *continuation* to be run once the symbols are resolved.
|
|
|
|
This is the final step of Phase 1.
|
|
|
|
#. Phase 2
|
|
|
|
This phase is called by the continuation constructed at the end of the
|
|
external symbol resolution step above.
|
|
|
|
#. Apply external symbol resolution results.
|
|
|
|
This updates the addresses of all external symbols. At this point all
|
|
nodes in the graph have their final target addresses, however node
|
|
content still points back to the original data in the object file.
|
|
|
|
#. Run pre-fixup passes.
|
|
|
|
These passes are called on the graph after all nodes have been assigned
|
|
their final target addresses, but before node content is copied into
|
|
working memory and fixed up. Passes run at this stage can make late
|
|
optimizations to the graph and content based on address layout.
|
|
|
|
Notable use cases: GOT and PLT relaxation, where GOT and PLT accesses are
|
|
bypassed for fixup targets that are directly accessible under the assigned
|
|
memory layout.
|
|
|
|
#. Copy block content to working memory and apply fixups.
|
|
|
|
Copies all block content into allocated working memory (following the
|
|
target layout) and applies fixups. Graph blocks are updated to point at
|
|
the fixed up content.
|
|
|
|
#. Run post-fixup passes.
|
|
|
|
These passes are called on the graph after fixups have been applied and
|
|
blocks updated to point to the fixed up content.
|
|
|
|
Post-fixup passes can inspect blocks contents to see the exact bytes that
|
|
will be copied to the assigned target addresses.
|
|
|
|
#. Finalize memory asynchronously.
|
|
|
|
Calls the ``JITLinkMemoryManager`` to copy working memory to the executor
|
|
process and apply the requested permissions. This step is asynchronous --
|
|
JITLink will pack the link state into a *continuation* to be run once
|
|
memory has been copied and protected.
|
|
|
|
This is the final step of Phase 2.
|
|
|
|
#. Phase 3.
|
|
|
|
This phase is called by the continuation constructed at the end of the
|
|
memory finalization step above.
|
|
|
|
#. Notify the context that the graph has been emitted.
|
|
|
|
Calls ``JITLinkContext::notifyFinalized`` and hands off the
|
|
``JITLinkMemoryManager::Allocation`` object for this graph's memory
|
|
allocation. This allows the context to track/hold memory allocations and
|
|
react to the newly emitted definitions. In ORC this is used to update the
|
|
``ExecutionSession`` instance's dependence graph, which may result in
|
|
these symbols (and possibly others) becoming *Ready* if all of their
|
|
dependencies have also been emitted.
|
|
|
|
.. _passes:
|
|
|
|
Passes
|
|
------
|
|
|
|
JITLink passes are ``std::function<Error(LinkGraph&)>`` instances. They are free
|
|
to inspect and modify the given ``LinkGraph`` subject to the constraints of
|
|
whatever phase they are running in (see :ref:`generic_link_algorithm`). If a
|
|
pass returns ``Error::success()`` then linking continues. If a pass returns
|
|
a failure value then linking is stopped and the ``JITLinkContext`` is notified
|
|
that the link failed.
|
|
|
|
Passes may be used by both JITLink backends (e.g. MachO/x86-64 implements GOT
|
|
and PLT construction as a pass), and external clients like
|
|
``ObjectLinkingLayer::Plugin``.
|
|
|
|
In combination with the open ``LinkGraph`` API, JITLink passes enable the
|
|
implementation of powerful new features. For example:
|
|
|
|
* Relaxation optimizations -- A pre-fixup pass can inspect GOT accesses and PLT
|
|
calls and identify situations where the addresses of the entry target and the
|
|
access are close enough to be accessed directly. In this case the pass can
|
|
rewrite the instruction stream of the containing block and update the fixup
|
|
edges to make the access direct.
|
|
|
|
Code for this looks like:
|
|
|
|
.. code-block:: c++
|
|
|
|
Error relaxGOTEdges(LinkGraph &G) {
|
|
for (auto *B : G.blocks())
|
|
for (auto &E : B->edges())
|
|
if (E.getKind() == x86_64::GOTLoad) {
|
|
auto &GOTTarget = getGOTEntryTarget(E.getTarget());
|
|
if (isInRange(B.getFixupAddress(E), GOTTarget)) {
|
|
// Rewrite B.getContent() at fixup address from
|
|
// MOVQ to LEAQ
|
|
|
|
// Update edge target and kind.
|
|
E.setTarget(GOTTarget);
|
|
E.setKind(x86_64::PCRel32);
|
|
}
|
|
}
|
|
|
|
return Error::success();
|
|
}
|
|
|
|
* Metadata registration -- Post allocation passes can be used to record the
|
|
address range of sections in the target. This can be used to register the
|
|
metadata (e.g exception handling frames, language metadata) in the target
|
|
once memory has been finalized.
|
|
|
|
.. code-block:: c++
|
|
|
|
Error registerEHFrameSection(LinkGraph &G) {
|
|
if (auto *Sec = G.findSectionByName("__eh_frame")) {
|
|
SectionRange SR(*Sec);
|
|
registerEHFrameSection(SR.getStart(), SR.getEnd());
|
|
}
|
|
|
|
return Error::success();
|
|
}
|
|
|
|
* Record call sites for later mutation -- A post-allocation pass can record
|
|
the call sites of all calls to a particular function, allowing those call
|
|
sites to be updated later at runtime (e.g. for instrumentation, or to
|
|
enable the function to be lazily compiled but still called directly after
|
|
compilation).
|
|
|
|
.. code-block:: c++
|
|
|
|
StringRef FunctionName = "foo";
|
|
std::vector<JITTargetAddress> CallSitesForFunction;
|
|
|
|
auto RecordCallSites =
|
|
[&](LinkGraph &G) -> Error {
|
|
for (auto *B : G.blocks())
|
|
for (auto &E : B.edges())
|
|
if (E.getKind() == CallEdgeKind &&
|
|
E.getTarget().hasName() &&
|
|
E.getTraget().getName() == FunctionName)
|
|
CallSitesForFunction.push_back(B.getFixupAddress(E));
|
|
return Error::success();
|
|
};
|
|
|
|
Memory Management with JITLinkMemoryManager
|
|
-------------------------------------------
|
|
|
|
JIT linking requires allocation of two kinds of memory: working memory in the
|
|
JIT process and target memory in the execution process (these processes and
|
|
memory allocations may be one and the same, depending on how the user wants
|
|
to build their JIT). It also requires that these allocations conform to the
|
|
requested code model in the target process (e.g. MachO/x86-64's Small code
|
|
model requires that all code and data for a simulated dylib is allocated within
|
|
4Gb). Finally, it is natural to make the memory manager responsible for
|
|
transferring memory to the target address space and applying memory protections,
|
|
since the memory manager must know how to communicate with the executor, and
|
|
since sharing and protection assignment can often be efficiently managed (in
|
|
the common case of running across processes on the same machine for security)
|
|
via the host operating system's virtual memory management APIs.
|
|
|
|
To satisfy these requirements ``JITLinkMemoryManager`` adopts the following
|
|
design: The memory manager itself has just one virtual method that returns a
|
|
``JITLinkMemoryManager::Allocation``:
|
|
|
|
.. code-block:: c++
|
|
|
|
virtual Expected<std::unique_ptr<Allocation>>
|
|
allocate(const JITLinkDylib *JD, const SegmentsRequestMap &Request) = 0;
|
|
|
|
This method takes a ``JITLinkDylib*`` representing the target simulated
|
|
dylib, and the full set of sections that must be allocated for this object.
|
|
``JITLinkMemoryManager`` implementations can (optionally) use the ``JD``
|
|
argument to manage a per-simulated-dylib memory pool (since code model
|
|
constraints are typically imposed on a per-dylib basis, and not across
|
|
dylibs) [2]_. The ``Request`` argument, by describing all sections in the current
|
|
object up-front, allows the implementer to allocate those sections as a
|
|
single slab, either within a pre-allocated per-jitdylib pool or directly
|
|
from system memory.
|
|
|
|
All subsequent operations are provided by the
|
|
``JITLinkMemoryManager::Allocation`` interface:
|
|
|
|
* ``virtual MutableArrayRef<char> getWorkingMemory(ProtectionFlags Seg)``
|
|
|
|
Should be overriden to return the address in working memory of the segment
|
|
with the given protection flags.
|
|
|
|
* ``virtual JITTargetAddress getTargetMemory(ProtectionFlags Seg)``
|
|
|
|
Should be overriden to return the address in the executor's address space of
|
|
the segment with the given protection flags.
|
|
|
|
* ``virtual void finalizeAsync(FinalizeContinuation OnFinalize)``
|
|
|
|
Should be overridden to copy the contents of working memory to the target
|
|
address space and apply memory protections for all segments. Where working
|
|
memory and target memory are separate, this method should deallocate the
|
|
working memory.
|
|
|
|
* ``virtual Error deallocate()``
|
|
|
|
Should be overriden to deallocate memory in the target address space.
|
|
|
|
JITLink provides a simple in-process implementation of this interface:
|
|
``InProcessMemoryManager``. It allocates pages once and re-uses them as both
|
|
working and target memory.
|
|
|
|
ORC provides a cross-process ``JITLinkMemoryManager`` based on an ORC-RPC-based
|
|
implementation of the ``orc::TargetProcessControl`` API:
|
|
``OrcRPCTPCJITLinkMemoryManager``. This API uses TargetProcessControl API calls
|
|
to allocate and manage memory in a remote process. The underlying communication
|
|
channel is determined by the ORC-RPC channel type. Common options include unix
|
|
sockets or TCP.
|
|
|
|
JITLinkMemoryManager and Security
|
|
---------------------------------
|
|
|
|
JITLink's ability to link JIT'd code for a separate executor process can be
|
|
used to improve the security of a JIT system: The executor process can be
|
|
sandboxed, run within a VM, or even run on a fully separate machine.
|
|
|
|
JITLink's memory manager interface is flexible enough to allow for a range of
|
|
trade-offs between performance and security. For example, on a system where code
|
|
pages must be signed (preventing code from being updated), the memory manager
|
|
can deallocate working memory pages after linking to free memory in the process
|
|
running JITLink. Alternatively, on a system that allows RWX pages, the memory
|
|
manager may use the same pages for both working and target memory by marking
|
|
them as RWX, allowing code to be modified in place without further overhead.
|
|
Finally, if RWX pages are not permitted but dual-virtual-mappings of
|
|
physical memory pages are, then the memory manager can dual map physical pages
|
|
as RW- in the JITLink process and R-X in the executor process, allowing
|
|
modification from the JITLink process but not from the executor (at the cost of
|
|
extra administrative overhead for the dual mapping).
|
|
|
|
Error Handling
|
|
--------------
|
|
|
|
JITLink makes extensive use of the ``llvm::Error`` type (see the error handling
|
|
section of :doc:`ProgrammersManual` for details). The link process itself, all
|
|
passes, the memory manager interface, and operations on the ``JITLinkContext``
|
|
are all permitted to fail. Link graph construction utilities (especially parsers
|
|
for object formats) are encouraged to validate input, and validate fixups
|
|
(e.g. with range checks) before application.
|
|
|
|
Any error will halt the link process and notify the context of failure. In ORC,
|
|
reported failures are propagated to queries pending on definitions provided by
|
|
the failing link, and also through edges of the dependence graph to any queries
|
|
waiting on dependent symbols.
|
|
|
|
.. _connection_to_orc_runtime:
|
|
|
|
Connection to the ORC Runtime
|
|
=============================
|
|
|
|
The ORC Runtime (currently under development) aims to provide runtime support
|
|
for advanced JIT features, including object format features that require
|
|
non-trivial action in the executor (e.g. running initializers, managing thread
|
|
local storage, registering with language runtimes, etc.).
|
|
|
|
ORC Runtime support for object format features typically requires cooperation
|
|
between the runtime (which executes in the executor process) and JITLink (which
|
|
runs in the JIT process and can inspect LinkGraphs to determine what actions
|
|
must be taken in the executor). For example: Execution of MachO static
|
|
initializers in the ORC runtime is performed by the ``jit_dlopen`` function,
|
|
which calls back to the JIT process to ask for the list of address ranges of
|
|
``__mod_init`` sections to walk. This list is collated by the
|
|
``MachOPlatformPlugin``, which installs a pass to record this information for
|
|
each object as it is linked into the target.
|
|
|
|
.. _constructing_linkgraphs:
|
|
|
|
Constructing LinkGraphs
|
|
=======================
|
|
|
|
Clients usually access and manipulate ``LinkGraph`` instances that were created
|
|
for them by an ``ObjectLinkingLayer`` instance, but they can be created manually:
|
|
|
|
#. By directly constructing and populating a ``LinkGraph`` instance.
|
|
|
|
#. By using the ``createLinkGraph`` family of functions to create a
|
|
``LinkGraph`` from an in-memory buffer containing an object file. This is how
|
|
``ObjectLinkingLayer`` usually creates ``LinkGraphs``.
|
|
|
|
#. ``createLinkGraph_<Object-Format>_<Architecture>`` can be used when
|
|
both the object format and architecture are known ahead of time.
|
|
|
|
#. ``createLinkGraph_<Object-Format>`` can be used when the object format is
|
|
known ahead of time, but the architecture is not. In this case the
|
|
architecture will be determined by inspection of the object header.
|
|
|
|
#. ``createLinkGraph`` can be used when neither the object format nor
|
|
the architecture are known ahead of time. In this case the object header
|
|
will be inspected to determine both the format and architecture.
|
|
|
|
.. _jit_linking:
|
|
|
|
JIT Linking
|
|
===========
|
|
|
|
The JIT linker concept was introduced in LLVM's earlier generation of JIT APIs,
|
|
MCJIT. In MCJIT the *RuntimeDyld* component enabled re-use of LLVM as an
|
|
in-memory compiler by adding an in-memory link step to the end of the usual
|
|
compiler pipeline. Rather than dumping relocatable objects to disk as a compiler
|
|
usually would, MCJIT passed them to RuntimeDyld to be linked into a target
|
|
process.
|
|
|
|
This approach to linking differs from standard *static* or *dynamic* linking:
|
|
|
|
A *static linker* takes one or more relocatable object files as input and links
|
|
them into an executable or dynamic library on disk.
|
|
|
|
A *dynamic linker* applies relocations to executables and dynamic libraries that
|
|
have been loaded into memory.
|
|
|
|
A *JIT linker* takes a single relocatable object file at a time and links it
|
|
into a target process, usually using a context object to allow the linked code
|
|
to resolve symbols in the target.
|
|
|
|
RuntimeDyld
|
|
-----------
|
|
|
|
In order to keep RuntimeDyld's implementation simple MCJIT imposed some
|
|
restrictions on compiled code:
|
|
|
|
#. It had to use the Large code model, and often restricted available relocation
|
|
models in order to limit the kinds of relocations that had to be supported.
|
|
|
|
#. It required strong linkage and default visibility on all symbols -- behavior
|
|
for other linkages/visibilities was not well defined.
|
|
|
|
#. It constrained and/or prohibited the use of features requiring runtime
|
|
support, e.g. static initializers or thread local storage.
|
|
|
|
As a result of these restrictions not all language features supported by LLVM
|
|
worked under MCJIT, and objects to be loaded under the JIT had to be compiled to
|
|
target it (precluding the use of precompiled code from other sources under the
|
|
JIT).
|
|
|
|
RuntimeDyld also provided very limited visibility into the linking process
|
|
itself: Clients could access conservative estimates of section size
|
|
(RuntimeDyld bundled stub size and padding estimates into the section size
|
|
value) and the final relocated bytes, but could not access RuntimeDyld's
|
|
internal object representations.
|
|
|
|
Eliminating these restrictions and limitations was one of the primary motivations
|
|
for the development of JITLink.
|
|
|
|
The llvm-jitlink tool
|
|
=====================
|
|
|
|
The ``llvm-jitlink`` tool is a command line wrapper for the JITLink library.
|
|
It loads some set of relocatable object files and then links them using
|
|
JITLink. Depending on the options used it will then execute them, or validate
|
|
the linked memory.
|
|
|
|
The ``llvm-jitlink`` tool was originally designed to aid JITLink development by
|
|
providing a simple environment for testing.
|
|
|
|
Basic usage
|
|
-----------
|
|
|
|
By default, ``llvm-jitlink`` will link the set of objects passed on the command
|
|
line, then search for a "main" function and execute it:
|
|
|
|
.. code-block:: sh
|
|
|
|
% cat hello-world.c
|
|
#include <stdio.h>
|
|
|
|
int main(int argc, char *argv[]) {
|
|
printf("hello, world!\n");
|
|
return 0;
|
|
}
|
|
|
|
% clang -c -o hello-world.o hello-world.c
|
|
% llvm-jitlink hello-world.o
|
|
Hello, World!
|
|
|
|
Multiple objects may be specified, and arguments may be provided to the JIT'd
|
|
main function using the -args option:
|
|
|
|
.. code-block:: sh
|
|
|
|
% cat print-args.c
|
|
#include <stdio.h>
|
|
|
|
void print_args(int argc, char *argv[]) {
|
|
for (int i = 0; i != argc; ++i)
|
|
printf("arg %i is \"%s\"\n", i, argv[i]);
|
|
}
|
|
|
|
% cat print-args-main.c
|
|
void print_args(int argc, char *argv[]);
|
|
|
|
int main(int argc, char *argv[]) {
|
|
print_args(argc, argv);
|
|
return 0;
|
|
}
|
|
|
|
% clang -c -o print-args.o print-args.c
|
|
% clang -c -o print-args-main.o print-args-main.c
|
|
% llvm-jitlink print-args.o print-args-main.o -args a b c
|
|
arg 0 is "a"
|
|
arg 1 is "b"
|
|
arg 2 is "c"
|
|
|
|
Alternative entry points may be specified using the ``-entry <entry point
|
|
name>`` option.
|
|
|
|
Other options can be found by calling ``llvm-jitlink -help``.
|
|
|
|
llvm-jitlink as a regression testing utility
|
|
--------------------------------------------
|
|
|
|
One of the primary aims of ``llvm-jitlink`` was to enable readable regression
|
|
tests for JITLink. To do this it supports two options:
|
|
|
|
The ``-noexec`` option tells llvm-jitlink to stop after looking up the entry
|
|
point, and before attempting to execute it. Since the linked code is not
|
|
executed, this can be used to link for other targets even if you do not have
|
|
access to the target being linked (the ``-define-abs`` or ``-phony-externals``
|
|
options can be used to supply any missing definitions in this case).
|
|
|
|
The ``-check <check-file>`` option can be used to run a set of ``jitlink-check``
|
|
expressions against working memory. It is typically used in conjunction with
|
|
``-noexec``, since the aim is to validate JIT'd memory rather than to run the
|
|
code and ``-noexec`` allows us to link for any supported target architecture
|
|
from the current process. In ``-check`` mode, ``llvm-jitlink`` will scan the
|
|
given check-file for lines of the form ``# jitlink-check: <expr>``. See
|
|
examples of this usage in ``llvm/test/ExecutionEngine/JITLink``.
|
|
|
|
Remote execution via llvm-jitlink-executor
|
|
------------------------------------------
|
|
|
|
By default ``llvm-jitlink`` will link the given objects into its own process,
|
|
but this can be overridden by two options:
|
|
|
|
The ``-oop-executor[=/path/to/executor]`` option tells ``llvm-jitlink`` to
|
|
execute the given executor (which defaults to ``llvm-jitlink-executor``) and
|
|
communicate with it via file descriptors which it passes to the executor
|
|
as the first argument with the format ``filedescs=<in-fd>,<out-fd>``.
|
|
|
|
The ``-oop-executor-connect=<host>:<port>`` option tells ``llvm-jitlink`` to
|
|
connect to an already running executor via TCP on the given host and port. To
|
|
use this option you will need to start ``llvm-jitlink-executor`` manually with
|
|
``listen=<host>:<port>`` as the first argument.
|
|
|
|
Harness mode
|
|
------------
|
|
|
|
The ``-harness`` option allows a set of input objects to be designated as a test
|
|
harness, with the regular object files implicitly treated as objects to be
|
|
tested. Definitions of symbols in the harness set override definitions in the
|
|
test set, and external references from the harness cause automatic scope
|
|
promotion of local symbols in the test set (these modifications to the usual
|
|
linker rules are accomplished via an ``ObjectLinkingLayer::Plugin`` installed by
|
|
``llvm-jitlink`` when it sees the ``-harness`` option).
|
|
|
|
With these modifications in place we can selectively test functions in an object
|
|
file by mocking those function's callees. For example, suppose we have an object
|
|
file, ``test_code.o``, compiled from the following C source (which we need not
|
|
have access to):
|
|
|
|
.. code-block:: c
|
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void irrelevant_function() { irrelevant_external(); }
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int function_to_mock(int X) {
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return /* some function of X */;
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}
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static void function_to_test() {
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...
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int Y = function_to_mock();
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printf("Y is %i\n", Y);
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}
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If we want to know how ``function_to_test`` behaves when we change the behavior
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of ``function_to_mock`` we can test it by writing a test harness:
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.. code-block:: c
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void function_to_test();
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int function_to_mock(int X) {
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printf("used mock utility function\n");
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return 42;
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}
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int main(int argc, char *argv[]) {
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function_to_test():
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return 0;
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}
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Under normal circumstances these objects could not be linked together:
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``function_to_test`` is static and could not be resolved outside
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``test_code.o``, the two ``function_to_mock`` functions would result in a
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duplicate definition error, and ``irrelevant_external`` is undefined.
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However, using ``-harness`` and ``-phony-externals`` we can run this code
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with:
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.. code-block:: sh
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% clang -c -o test_code_harness.o test_code_harness.c
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% llvm-jitlink -phony-externals test_code.o -harness test_code_harness.o
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used mock utility function
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Y is 42
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The ``-harness`` option may be of interest to people who want to perform some
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very late testing on build products to verify that compiled code behaves as
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expected. On basic C test cases this is relatively straightforward. Mocks for
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more complicated languages (e.g. C++) are much tricker: Any code involving
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classes tends to have a lot of non-trivial surface area (e.g. vtables) that
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would require great care to mock.
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Tips for JITLink backend developers
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-----------------------------------
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#. Make liberal use of assert and ``llvm::Error``. Do *not* assume that the input
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object is well formed: Return any errors produced by libObject (or your own
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object parsing code) and validate as you construct. Think carefully about the
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distinction between contract (which should be validated with asserts and
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llvm_unreachable) and environmental errors (which should generate
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``llvm::Error`` instances).
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#. Don't assume you're linking in-process. Use libSupport's sized,
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endian-specific types when reading/writing content in the ``LinkGraph``.
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As a "minimum viable" JITLink wrapper, the ``llvm-jitlink`` tool is an
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invaluable resource for developers bringing in a new JITLink backend. A standard
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workflow is to start by throwing an unsupported object at the tool and seeing
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what error is returned, then fixing that (you can often make a reasonable guess
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at what should be done based on existing code for other formats or
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architectures).
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In debug builds of LLVM, the ``-debug-only=jitlink`` option dumps logs from the
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JITLink library during the link process. These can be useful for spotting some bugs at
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a glance. The ``-debug-only=llvm_jitlink`` option dumps logs from the ``llvm-jitlink``
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tool, which can be useful for debugging both testcases (it is often less verbose than
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``-debug-only=jitlink``) and the tool itself.
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The ``-oop-executor`` and ``-oop-executor-connect`` options are helpful for testing
|
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handling of cross-process and cross-architecture use cases.
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Roadmap
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=======
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JITLink is under active development. Work so far has focused on the MachO
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implementation. In LLVM 12 there is limited support for ELF on x86-64.
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Major outstanding projects include:
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* Refactor architecture support to maximize sharing across formats.
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All formats should be able to share the bulk of the architecture specific
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code (especially relocations) for each supported architecture.
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* Refactor ELF link graph construction.
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ELF's link graph construction is currently implemented in the `ELF_x86_64.cpp`
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file, and tied to the x86-64 relocation parsing code. The bulk of the code is
|
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generic and should be split into an ELFLinkGraphBuilder base class along the
|
|
same lines as the existing generic MachOLinkGraphBuilder.
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* Implement ELF support for arm64.
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Once the architecture support code has been refactored to enable sharing and
|
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ELF link graph construction has been refactored to allow re-use we should be
|
|
able to construct an ELF / arm64 JITLink implementation by combining
|
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these existing pieces.
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* Implement support for new architectures.
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* Implement support for COFF.
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|
There is no COFF implementation of JITLink yet. Such an implementation should
|
|
follow the MachO and ELF paths: a generic COFFLinkGraphBuilder base class that
|
|
can be specialized for each architecture.
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* Design and implement a shared-memory based JITLinkMemoryManager.
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|
One use-case that is expected to be common is out-of-process linking targeting
|
|
another process on the same machine. This allows JITs to sandbox JIT'd code.
|
|
For this use case a shared-memory based JITLinkMemoryManager would provide the
|
|
most efficient form of allocation. Creating one will require designing a
|
|
generic API for shared memory though, as LLVM does not currently have one.
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|
|
JITLink Availability and Feature Status
|
|
---------------------------------------
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|
|
|
.. list-table:: Availability and Status
|
|
:widths: 10 30 30 30
|
|
:header-rows: 1
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|
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* - Architecture
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- ELF
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- COFF
|
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- MachO
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|
* - arm64
|
|
-
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|
-
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|
- Partial (small code model, PIC relocation model only)
|
|
* - x86-64
|
|
- Partial
|
|
-
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|
- Full (except TLV and debugging)
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|
|
.. [1] See ``llvm/examples/OrcV2Examples/LLJITWithObjectLinkingLayerPlugin`` for
|
|
a full worked example.
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|
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|
.. [2] If not for *hidden* scoped symbols we could eliminate the
|
|
``JITLinkDylib*`` argument to ``JITLinkMemoryManager::allocate`` and
|
|
treat every object as a separate simulated dylib for the purposes of
|
|
memory layout. Hidden symbols break this by generating in-range accesses
|
|
to external symbols, requiring the access and symbol to be allocated
|
|
within range of one another. That said, providing a pre-reserved address
|
|
range pool for each simulated dylib guarantees that the relaxation
|
|
optimizations will kick in for all intra-dylib references, which is good
|
|
for performance (at the cost of whatever overhead is introduced by
|
|
reserving the address-range up-front).
|