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2140 lines
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================================
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Source Level Debugging with LLVM
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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 is the central repository for all information pertaining to debug
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information in LLVM. It describes the :ref:`actual format that the LLVM debug
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information takes <format>`, which is useful for those interested in creating
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front-ends or dealing directly with the information. Further, this document
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provides specific examples of what debug information for C/C++ looks like.
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Philosophy behind LLVM debugging information
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--------------------------------------------
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The idea of the LLVM debugging information is to capture how the important
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pieces of the source-language's Abstract Syntax Tree map onto LLVM code.
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Several design aspects have shaped the solution that appears here. The
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important ones are:
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* Debugging information should have very little impact on the rest of the
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compiler. No transformations, analyses, or code generators should need to
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be modified because of debugging information.
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* LLVM optimizations should interact in :ref:`well-defined and easily described
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ways <intro_debugopt>` with the debugging information.
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* Because LLVM is designed to support arbitrary programming languages,
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LLVM-to-LLVM tools should not need to know anything about the semantics of
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the source-level-language.
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* Source-level languages are often **widely** different from one another.
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LLVM should not put any restrictions of the flavor of the source-language,
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and the debugging information should work with any language.
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* With code generator support, it should be possible to use an LLVM compiler
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to compile a program to native machine code and standard debugging
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formats. This allows compatibility with traditional machine-code level
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debuggers, like GDB or DBX.
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The approach used by the LLVM implementation is to use a small set of
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:ref:`intrinsic functions <format_common_intrinsics>` to define a mapping
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between LLVM program objects and the source-level objects. The description of
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the source-level program is maintained in LLVM metadata in an
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:ref:`implementation-defined format <ccxx_frontend>` (the C/C++ front-end
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currently uses working draft 7 of the `DWARF 3 standard
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<http://www.eagercon.com/dwarf/dwarf3std.htm>`_).
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When a program is being debugged, a debugger interacts with the user and turns
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the stored debug information into source-language specific information. As
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such, a debugger must be aware of the source-language, and is thus tied to a
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specific language or family of languages.
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Debug information consumers
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---------------------------
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The role of debug information is to provide meta information normally stripped
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away during the compilation process. This meta information provides an LLVM
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user a relationship between generated code and the original program source
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code.
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Currently, there are two backend consumers of debug info: DwarfDebug and
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CodeViewDebug. DwarfDebug produces DWARF suitable for use with GDB, LLDB, and
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other DWARF-based debuggers. :ref:`CodeViewDebug <codeview>` produces CodeView,
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the Microsoft debug info format, which is usable with Microsoft debuggers such
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as Visual Studio and WinDBG. LLVM's debug information format is mostly derived
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from and inspired by DWARF, but it is feasible to translate into other target
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debug info formats such as STABS.
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It would also be reasonable to use debug information to feed profiling tools
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for analysis of generated code, or, tools for reconstructing the original
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source from generated code.
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.. _intro_debugopt:
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Debug information and optimizations
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-----------------------------------
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An extremely high priority of LLVM debugging information is to make it interact
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well with optimizations and analysis. In particular, the LLVM debug
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information provides the following guarantees:
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* LLVM debug information **always provides information to accurately read
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the source-level state of the program**, regardless of which LLVM
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optimizations have been run, and without any modification to the
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optimizations themselves. However, some optimizations may impact the
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ability to modify the current state of the program with a debugger, such
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as setting program variables, or calling functions that have been
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deleted.
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* As desired, LLVM optimizations can be upgraded to be aware of debugging
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information, allowing them to update the debugging information as they
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perform aggressive optimizations. This means that, with effort, the LLVM
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optimizers could optimize debug code just as well as non-debug code.
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* LLVM debug information does not prevent optimizations from
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happening (for example inlining, basic block reordering/merging/cleanup,
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tail duplication, etc).
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* LLVM debug information is automatically optimized along with the rest of
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the program, using existing facilities. For example, duplicate
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information is automatically merged by the linker, and unused information
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is automatically removed.
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Basically, the debug information allows you to compile a program with
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"``-O0 -g``" and get full debug information, allowing you to arbitrarily modify
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the program as it executes from a debugger. Compiling a program with
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"``-O3 -g``" gives you full debug information that is always available and
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accurate for reading (e.g., you get accurate stack traces despite tail call
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elimination and inlining), but you might lose the ability to modify the program
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and call functions which were optimized out of the program, or inlined away
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completely.
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The :doc:`LLVM test-suite <TestSuiteMakefileGuide>` provides a framework to
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test the optimizer's handling of debugging information. It can be run like
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this:
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.. code-block:: bash
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% cd llvm/projects/test-suite/MultiSource/Benchmarks # or some other level
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% make TEST=dbgopt
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This will test impact of debugging information on optimization passes. If
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debugging information influences optimization passes then it will be reported
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as a failure. See :doc:`TestingGuide` for more information on LLVM test
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infrastructure and how to run various tests.
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.. _format:
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Debugging information format
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============================
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LLVM debugging information has been carefully designed to make it possible for
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the optimizer to optimize the program and debugging information without
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necessarily having to know anything about debugging information. In
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particular, the use of metadata avoids duplicated debugging information from
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the beginning, and the global dead code elimination pass automatically deletes
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debugging information for a function if it decides to delete the function.
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To do this, most of the debugging information (descriptors for types,
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variables, functions, source files, etc) is inserted by the language front-end
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in the form of LLVM metadata.
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Debug information is designed to be agnostic about the target debugger and
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debugging information representation (e.g. DWARF/Stabs/etc). It uses a generic
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pass to decode the information that represents variables, types, functions,
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namespaces, etc: this allows for arbitrary source-language semantics and
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type-systems to be used, as long as there is a module written for the target
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debugger to interpret the information.
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To provide basic functionality, the LLVM debugger does have to make some
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assumptions about the source-level language being debugged, though it keeps
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these to a minimum. The only common features that the LLVM debugger assumes
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exist are `source files <LangRef.html#difile>`_, and `program objects
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<LangRef.html#diglobalvariable>`_. These abstract objects are used by a
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debugger to form stack traces, show information about local variables, etc.
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This section of the documentation first describes the representation aspects
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common to any source-language. :ref:`ccxx_frontend` describes the data layout
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conventions used by the C and C++ front-ends.
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Debug information descriptors are `specialized metadata nodes
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<LangRef.html#specialized-metadata>`_, first-class subclasses of ``Metadata``.
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.. _format_common_intrinsics:
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Debugger intrinsic functions
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----------------------------
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LLVM uses several intrinsic functions (name prefixed with "``llvm.dbg``") to
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track source local variables through optimization and code generation.
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``llvm.dbg.addr``
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^^^^^^^^^^^^^^^^^^^^
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.. code-block:: llvm
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void @llvm.dbg.addr(metadata, metadata, metadata)
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This intrinsic provides information about a local element (e.g., variable).
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The first argument is metadata holding the address of variable, typically a
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static alloca in the function entry block. The second argument is a
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`local variable <LangRef.html#dilocalvariable>`_ containing a description of
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the variable. The third argument is a `complex expression
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<LangRef.html#diexpression>`_. An `llvm.dbg.addr` intrinsic describes the
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*address* of a source variable.
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.. code-block:: text
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%i.addr = alloca i32, align 4
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call void @llvm.dbg.addr(metadata i32* %i.addr, metadata !1,
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metadata !DIExpression()), !dbg !2
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!1 = !DILocalVariable(name: "i", ...) ; int i
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!2 = !DILocation(...)
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...
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%buffer = alloca [256 x i8], align 8
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; The address of i is buffer+64.
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call void @llvm.dbg.addr(metadata [256 x i8]* %buffer, metadata !3,
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metadata !DIExpression(DW_OP_plus, 64)), !dbg !4
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!3 = !DILocalVariable(name: "i", ...) ; int i
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!4 = !DILocation(...)
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A frontend should generate exactly one call to ``llvm.dbg.addr`` at the point
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of declaration of a source variable. Optimization passes that fully promote the
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variable from memory to SSA values will replace this call with possibly
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multiple calls to `llvm.dbg.value`. Passes that delete stores are effectively
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partial promotion, and they will insert a mix of calls to ``llvm.dbg.value``
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and ``llvm.dbg.addr`` to track the source variable value when it is available.
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After optimization, there may be multiple calls to ``llvm.dbg.addr`` describing
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the program points where the variables lives in memory. All calls for the same
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concrete source variable must agree on the memory location.
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``llvm.dbg.declare``
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^^^^^^^^^^^^^^^^^^^^
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.. code-block:: llvm
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void @llvm.dbg.declare(metadata, metadata, metadata)
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This intrinsic is identical to `llvm.dbg.addr`, except that there can only be
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one call to `llvm.dbg.declare` for a given concrete `local variable
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<LangRef.html#dilocalvariable>`_. It is not control-dependent, meaning that if
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a call to `llvm.dbg.declare` exists and has a valid location argument, that
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address is considered to be the true home of the variable across its entire
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lifetime. This makes it hard for optimizations to preserve accurate debug info
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in the presence of ``llvm.dbg.declare``, so we are transitioning away from it,
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and we plan to deprecate it in future LLVM releases.
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``llvm.dbg.value``
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^^^^^^^^^^^^^^^^^^
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.. code-block:: llvm
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void @llvm.dbg.value(metadata, metadata, metadata)
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This intrinsic provides information when a user source variable is set to a new
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value. The first argument is the new value (wrapped as metadata). The second
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argument is a `local variable <LangRef.html#dilocalvariable>`_ containing a
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description of the variable. The third argument is a `complex expression
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<LangRef.html#diexpression>`_.
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An `llvm.dbg.value` intrinsic describes the *value* of a source variable
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directly, not its address. Note that the value operand of this intrinsic may
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be indirect (i.e, a pointer to the source variable), provided that interpreting
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the complex expression derives the direct value.
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Object lifetimes and scoping
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============================
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In many languages, the local variables in functions can have their lifetimes or
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scopes limited to a subset of a function. In the C family of languages, for
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example, variables are only live (readable and writable) within the source
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block that they are defined in. In functional languages, values are only
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readable after they have been defined. Though this is a very obvious concept,
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it is non-trivial to model in LLVM, because it has no notion of scoping in this
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sense, and does not want to be tied to a language's scoping rules.
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In order to handle this, the LLVM debug format uses the metadata attached to
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llvm instructions to encode line number and scoping information. Consider the
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following C fragment, for example:
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.. code-block:: c
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1. void foo() {
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2. int X = 21;
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3. int Y = 22;
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4. {
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5. int Z = 23;
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6. Z = X;
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7. }
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8. X = Y;
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9. }
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.. FIXME: Update the following example to use llvm.dbg.addr once that is the
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default in clang.
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Compiled to LLVM, this function would be represented like this:
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.. code-block:: text
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; Function Attrs: nounwind ssp uwtable
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define void @foo() #0 !dbg !4 {
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entry:
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%X = alloca i32, align 4
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%Y = alloca i32, align 4
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%Z = alloca i32, align 4
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call void @llvm.dbg.declare(metadata i32* %X, metadata !11, metadata !13), !dbg !14
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store i32 21, i32* %X, align 4, !dbg !14
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call void @llvm.dbg.declare(metadata i32* %Y, metadata !15, metadata !13), !dbg !16
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store i32 22, i32* %Y, align 4, !dbg !16
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call void @llvm.dbg.declare(metadata i32* %Z, metadata !17, metadata !13), !dbg !19
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store i32 23, i32* %Z, align 4, !dbg !19
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%0 = load i32, i32* %X, align 4, !dbg !20
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store i32 %0, i32* %Z, align 4, !dbg !21
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%1 = load i32, i32* %Y, align 4, !dbg !22
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store i32 %1, i32* %X, align 4, !dbg !23
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ret void, !dbg !24
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}
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; Function Attrs: nounwind readnone
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declare void @llvm.dbg.declare(metadata, metadata, metadata) #1
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attributes #0 = { nounwind ssp uwtable "less-precise-fpmad"="false" "no-frame-pointer-elim"="true" "no-frame-pointer-elim-non-leaf" "no-infs-fp-math"="false" "no-nans-fp-math"="false" "stack-protector-buffer-size"="8" "unsafe-fp-math"="false" "use-soft-float"="false" }
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attributes #1 = { nounwind readnone }
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!llvm.dbg.cu = !{!0}
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!llvm.module.flags = !{!7, !8, !9}
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!llvm.ident = !{!10}
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!0 = !DICompileUnit(language: DW_LANG_C99, file: !1, producer: "clang version 3.7.0 (trunk 231150) (llvm/trunk 231154)", isOptimized: false, runtimeVersion: 0, emissionKind: FullDebug, enums: !2, retainedTypes: !2, subprograms: !3, globals: !2, imports: !2)
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!1 = !DIFile(filename: "/dev/stdin", directory: "/Users/dexonsmith/data/llvm/debug-info")
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!2 = !{}
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!3 = !{!4}
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!4 = distinct !DISubprogram(name: "foo", scope: !1, file: !1, line: 1, type: !5, isLocal: false, isDefinition: true, scopeLine: 1, isOptimized: false, variables: !2)
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!5 = !DISubroutineType(types: !6)
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!6 = !{null}
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!7 = !{i32 2, !"Dwarf Version", i32 2}
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!8 = !{i32 2, !"Debug Info Version", i32 3}
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!9 = !{i32 1, !"PIC Level", i32 2}
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!10 = !{!"clang version 3.7.0 (trunk 231150) (llvm/trunk 231154)"}
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!11 = !DILocalVariable(name: "X", scope: !4, file: !1, line: 2, type: !12)
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!12 = !DIBasicType(name: "int", size: 32, align: 32, encoding: DW_ATE_signed)
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!13 = !DIExpression()
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!14 = !DILocation(line: 2, column: 9, scope: !4)
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!15 = !DILocalVariable(name: "Y", scope: !4, file: !1, line: 3, type: !12)
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!16 = !DILocation(line: 3, column: 9, scope: !4)
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!17 = !DILocalVariable(name: "Z", scope: !18, file: !1, line: 5, type: !12)
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!18 = distinct !DILexicalBlock(scope: !4, file: !1, line: 4, column: 5)
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!19 = !DILocation(line: 5, column: 11, scope: !18)
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!20 = !DILocation(line: 6, column: 11, scope: !18)
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!21 = !DILocation(line: 6, column: 9, scope: !18)
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!22 = !DILocation(line: 8, column: 9, scope: !4)
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!23 = !DILocation(line: 8, column: 7, scope: !4)
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!24 = !DILocation(line: 9, column: 3, scope: !4)
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This example illustrates a few important details about LLVM debugging
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information. In particular, it shows how the ``llvm.dbg.declare`` intrinsic and
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location information, which are attached to an instruction, are applied
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together to allow a debugger to analyze the relationship between statements,
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variable definitions, and the code used to implement the function.
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.. code-block:: llvm
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call void @llvm.dbg.declare(metadata i32* %X, metadata !11, metadata !13), !dbg !14
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; [debug line = 2:7] [debug variable = X]
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The first intrinsic ``%llvm.dbg.declare`` encodes debugging information for the
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variable ``X``. The metadata ``!dbg !14`` attached to the intrinsic provides
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scope information for the variable ``X``.
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.. code-block:: text
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!14 = !DILocation(line: 2, column: 9, scope: !4)
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!4 = distinct !DISubprogram(name: "foo", scope: !1, file: !1, line: 1, type: !5,
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isLocal: false, isDefinition: true, scopeLine: 1,
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isOptimized: false, variables: !2)
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Here ``!14`` is metadata providing `location information
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<LangRef.html#dilocation>`_. In this example, scope is encoded by ``!4``, a
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`subprogram descriptor <LangRef.html#disubprogram>`_. This way the location
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information attached to the intrinsics indicates that the variable ``X`` is
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declared at line number 2 at a function level scope in function ``foo``.
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Now lets take another example.
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.. code-block:: llvm
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call void @llvm.dbg.declare(metadata i32* %Z, metadata !17, metadata !13), !dbg !19
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; [debug line = 5:9] [debug variable = Z]
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The third intrinsic ``%llvm.dbg.declare`` encodes debugging information for
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variable ``Z``. The metadata ``!dbg !19`` attached to the intrinsic provides
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scope information for the variable ``Z``.
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.. code-block:: text
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!18 = distinct !DILexicalBlock(scope: !4, file: !1, line: 4, column: 5)
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!19 = !DILocation(line: 5, column: 11, scope: !18)
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Here ``!19`` indicates that ``Z`` is declared at line number 5 and column
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number 11 inside of lexical scope ``!18``. The lexical scope itself resides
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inside of subprogram ``!4`` described above.
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The scope information attached with each instruction provides a straightforward
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way to find instructions covered by a scope.
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Object lifetime in optimized code
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=================================
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In the example above, every variable assignment uniquely corresponds to a
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memory store to the variable's position on the stack. However in heavily
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optimized code LLVM promotes most variables into SSA values, which can
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eventually be placed in physical registers or memory locations. To track SSA
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values through compilation, when objects are promoted to SSA values an
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``llvm.dbg.value`` intrinsic is created for each assignment, recording the
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variable's new location. Compared with the ``llvm.dbg.declare`` intrinsic:
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* A dbg.value terminates the effect of any preceeding dbg.values for (any
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overlapping fragments of) the specified variable.
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* The dbg.value's position in the IR defines where in the instruction stream
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the variable's value changes.
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* Operands can be constants, indicating the variable is assigned a
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constant value.
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Care must be taken to update ``llvm.dbg.value`` intrinsics when optimization
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passes alter or move instructions and blocks -- the developer could observe such
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changes reflected in the value of variables when debugging the program. For any
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execution of the optimized program, the set of variable values presented to the
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developer by the debugger should not show a state that would never have existed
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in the execution of the unoptimized program, given the same input. Doing so
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risks misleading the developer by reporting a state that does not exist,
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damaging their understanding of the optimized program and undermining their
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trust in the debugger.
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Sometimes perfectly preserving variable locations is not possible, often when a
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redundant calculation is optimized out. In such cases, a ``llvm.dbg.value``
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with operand ``undef`` should be used, to terminate earlier variable locations
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and let the debugger present ``optimized out`` to the developer. Withholding
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these potentially stale variable values from the developer diminishes the
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amount of available debug information, but increases the reliability of the
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remaining information.
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To illustrate some potential issues, consider the following example:
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.. code-block:: llvm
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define i32 @foo(i32 %bar, i1 %cond) {
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entry:
|
|
call @llvm.dbg.value(metadata i32 0, metadata !1, metadata !2)
|
|
br i1 %cond, label %truebr, label %falsebr
|
|
truebr:
|
|
%tval = add i32 %bar, 1
|
|
call @llvm.dbg.value(metadata i32 %tval, metadata !1, metadata !2)
|
|
%g1 = call i32 @gazonk()
|
|
br label %exit
|
|
falsebr:
|
|
%fval = add i32 %bar, 2
|
|
call @llvm.dbg.value(metadata i32 %fval, metadata !1, metadata !2)
|
|
%g2 = call i32 @gazonk()
|
|
br label %exit
|
|
exit:
|
|
%merge = phi [ %tval, %truebr ], [ %fval, %falsebr ]
|
|
%g = phi [ %g1, %truebr ], [ %g2, %falsebr ]
|
|
call @llvm.dbg.value(metadata i32 %merge, metadata !1, metadata !2)
|
|
call @llvm.dbg.value(metadata i32 %g, metadata !3, metadata !2)
|
|
%plusten = add i32 %merge, 10
|
|
%toret = add i32 %plusten, %g
|
|
call @llvm.dbg.value(metadata i32 %toret, metadata !1, metadata !2)
|
|
ret i32 %toret
|
|
}
|
|
|
|
Containing two source-level variables in ``!1`` and ``!3``. The function could,
|
|
perhaps, be optimized into the following code:
|
|
|
|
.. code-block:: llvm
|
|
|
|
define i32 @foo(i32 %bar, i1 %cond) {
|
|
entry:
|
|
%g = call i32 @gazonk()
|
|
%addoper = select i1 %cond, i32 11, i32 12
|
|
%plusten = add i32 %bar, %addoper
|
|
%toret = add i32 %plusten, %g
|
|
ret i32 %toret
|
|
}
|
|
|
|
What ``llvm.dbg.value`` intrinsics should be placed to represent the original variable
|
|
locations in this code? Unfortunately the the second, third and fourth
|
|
dbg.values for ``!1`` in the source function have had their operands
|
|
(%tval, %fval, %merge) optimized out. Assuming we cannot recover them, we
|
|
might consider this placement of dbg.values:
|
|
|
|
.. code-block:: llvm
|
|
|
|
define i32 @foo(i32 %bar, i1 %cond) {
|
|
entry:
|
|
call @llvm.dbg.value(metadata i32 0, metadata !1, metadata !2)
|
|
%g = call i32 @gazonk()
|
|
call @llvm.dbg.value(metadata i32 %g, metadata !3, metadata !2)
|
|
%addoper = select i1 %cond, i32 11, i32 12
|
|
%plusten = add i32 %bar, %addoper
|
|
%toret = add i32 %plusten, %g
|
|
call @llvm.dbg.value(metadata i32 %toret, metadata !1, metadata !2)
|
|
ret i32 %toret
|
|
}
|
|
|
|
However, this will cause ``!3`` to have the return value of ``@gazonk()`` at
|
|
the same time as ``!1`` has the constant value zero -- a pair of assignments
|
|
that never occurred in the unoptimized program. To avoid this, we must terminate
|
|
the range that ``!1`` has the constant value assignment by inserting an undef
|
|
dbg.value before the dbg.value for ``!3``:
|
|
|
|
.. code-block:: llvm
|
|
|
|
define i32 @foo(i32 %bar, i1 %cond) {
|
|
entry:
|
|
call @llvm.dbg.value(metadata i32 0, metadata !1, metadata !2)
|
|
%g = call i32 @gazonk()
|
|
call @llvm.dbg.value(metadata i32 undef, metadata !1, metadata !2)
|
|
call @llvm.dbg.value(metadata i32 %g, metadata !3, metadata !2)
|
|
%addoper = select i1 %cond, i32 11, i32 12
|
|
%plusten = add i32 %bar, %addoper
|
|
%toret = add i32 %plusten, %g
|
|
call @llvm.dbg.value(metadata i32 %toret, metadata !1, metadata !2)
|
|
ret i32 %toret
|
|
}
|
|
|
|
In general, if any dbg.value has its operand optimized out and cannot be
|
|
recovered, then an undef dbg.value is necessary to terminate earlier variable
|
|
locations. Additional undef dbg.values may be necessary when the debugger can
|
|
observe re-ordering of assignments.
|
|
|
|
How variable location metadata is transformed during CodeGen
|
|
============================================================
|
|
|
|
LLVM preserves debug information throughout mid-level and backend passes,
|
|
ultimately producing a mapping between source-level information and
|
|
instruction ranges. This
|
|
is relatively straightforwards for line number information, as mapping
|
|
instructions to line numbers is a simple association. For variable locations
|
|
however the story is more complex. As each ``llvm.dbg.value`` intrinsic
|
|
represents a source-level assignment of a value to a source variable, the
|
|
variable location intrinsics effectively embed a small imperative program
|
|
within the LLVM IR. By the end of CodeGen, this becomes a mapping from each
|
|
variable to their machine locations over ranges of instructions.
|
|
From IR to object emission, the major transformations which affect variable
|
|
location fidelity are:
|
|
|
|
1. Instruction Selection
|
|
2. Register allocation
|
|
3. Block layout
|
|
|
|
each of which are discussed below. In addition, instruction scheduling can
|
|
significantly change the ordering of the program, and occurs in a number of
|
|
different passes.
|
|
|
|
Some variable locations are not transformed during CodeGen. Stack locations
|
|
specified by ``llvm.dbg.declare`` are valid and unchanging for the entire
|
|
duration of the function, and are recorded in a simple MachineFunction table.
|
|
Location changes in the prologue and epilogue of a function are also ignored:
|
|
frame setup and destruction may take several instructions, require a
|
|
disproportionate amount of debugging information in the output binary to
|
|
describe, and should be stepped over by debuggers anyway.
|
|
|
|
Variable locations in Instruction Selection and MIR
|
|
---------------------------------------------------
|
|
|
|
Instruction selection creates a MIR function from an IR function, and just as
|
|
it transforms ``intermediate`` instructions into machine instructions, so must
|
|
``intermediate`` variable locations become machine variable locations.
|
|
Within IR, variable locations are always identified by a Value, but in MIR
|
|
there can be different types of variable locations. In addition, some IR
|
|
locations become unavailable, for example if the operation of multiple IR
|
|
instructions are combined into one machine instruction (such as
|
|
multiply-and-accumulate) then intermediate Values are lost. To track variable
|
|
locations through instruction selection, they are first separated into
|
|
locations that do not depend on code generation (constants, stack locations,
|
|
allocated virtual registers) and those that do. For those that do, debug
|
|
metadata is attached to SDNodes in SelectionDAGs. After instruction selection
|
|
has occurred and a MIR function is created, if the SDNode associated with debug
|
|
metadata is allocated a virtual register, that virtual register is used as the
|
|
variable location. If the SDNode is folded into a machine instruction or
|
|
otherwise transformed into a non-register, the variable location becomes
|
|
unavailable.
|
|
|
|
Locations that are unavailable are treated as if they have been optimized out:
|
|
in IR the location would be assigned ``undef`` by a debug intrinsic, and in MIR
|
|
the equivalent location is used.
|
|
|
|
After MIR locations are assigned to each variable, machine pseudo-instructions
|
|
corresponding to each ``llvm.dbg.value`` and ``llvm.dbg.addr`` intrinsic are
|
|
inserted. These ``DBG_VALUE`` instructions appear thus:
|
|
|
|
.. code-block:: text
|
|
|
|
DBG_VALUE %1, $noreg, !123, !DIExpression()
|
|
|
|
And have the following operands:
|
|
* The first operand can record the variable location as a register,
|
|
a frame index, an immediate, or the base address register if the original
|
|
debug intrinsic referred to memory. ``$noreg`` indicates the variable
|
|
location is undefined, equivalent to an ``undef`` dbg.value operand.
|
|
* The type of the second operand indicates whether the variable location is
|
|
directly referred to by the DBG_VALUE, or whether it is indirect. The
|
|
``$noreg`` register signifies the former, an immediate operand (0) the
|
|
latter.
|
|
* Operand 3 is the Variable field of the original debug intrinsic.
|
|
* Operand 4 is the Expression field of the original debug intrinsic.
|
|
|
|
The position at which the DBG_VALUEs are inserted should correspond to the
|
|
positions of their matching ``llvm.dbg.value`` intrinsics in the IR block. As
|
|
with optimization, LLVM aims to preserve the order in which variable
|
|
assignments occurred in the source program. However SelectionDAG performs some
|
|
instruction scheduling, which can reorder assignments (discussed below).
|
|
Function parameter locations are moved to the beginning of the function if
|
|
they're not already, to ensure they're immediately available on function entry.
|
|
|
|
To demonstrate variable locations during instruction selection, consider
|
|
the following example:
|
|
|
|
.. code-block:: llvm
|
|
|
|
define i32 @foo(i32* %addr) {
|
|
entry:
|
|
call void @llvm.dbg.value(metadata i32 0, metadata !3, metadata !DIExpression()), !dbg !5
|
|
br label %bb1, !dbg !5
|
|
|
|
bb1: ; preds = %bb1, %entry
|
|
%bar.0 = phi i32 [ 0, %entry ], [ %add, %bb1 ]
|
|
call void @llvm.dbg.value(metadata i32 %bar.0, metadata !3, metadata !DIExpression()), !dbg !5
|
|
%addr1 = getelementptr i32, i32 *%addr, i32 1, !dbg !5
|
|
call void @llvm.dbg.value(metadata i32 *%addr1, metadata !3, metadata !DIExpression()), !dbg !5
|
|
%loaded1 = load i32, i32* %addr1, !dbg !5
|
|
%addr2 = getelementptr i32, i32 *%addr, i32 %bar.0, !dbg !5
|
|
call void @llvm.dbg.value(metadata i32 *%addr2, metadata !3, metadata !DIExpression()), !dbg !5
|
|
%loaded2 = load i32, i32* %addr2, !dbg !5
|
|
%add = add i32 %bar.0, 1, !dbg !5
|
|
call void @llvm.dbg.value(metadata i32 %add, metadata !3, metadata !DIExpression()), !dbg !5
|
|
%added = add i32 %loaded1, %loaded2
|
|
%cond = icmp ult i32 %added, %bar.0, !dbg !5
|
|
br i1 %cond, label %bb1, label %bb2, !dbg !5
|
|
|
|
bb2: ; preds = %bb1
|
|
ret i32 0, !dbg !5
|
|
}
|
|
|
|
If one compiles this IR with ``llc -o - -start-after=codegen-prepare -stop-after=expand-isel-pseudos -mtriple=x86_64--``, the following MIR is produced:
|
|
|
|
.. code-block:: text
|
|
|
|
bb.0.entry:
|
|
successors: %bb.1(0x80000000)
|
|
liveins: $rdi
|
|
|
|
%2:gr64 = COPY $rdi
|
|
%3:gr32 = MOV32r0 implicit-def dead $eflags
|
|
DBG_VALUE 0, $noreg, !3, !DIExpression(), debug-location !5
|
|
|
|
bb.1.bb1:
|
|
successors: %bb.1(0x7c000000), %bb.2(0x04000000)
|
|
|
|
%0:gr32 = PHI %3, %bb.0, %1, %bb.1
|
|
DBG_VALUE %0, $noreg, !3, !DIExpression(), debug-location !5
|
|
DBG_VALUE %2, $noreg, !3, !DIExpression(DW_OP_plus_uconst, 4, DW_OP_stack_value), debug-location !5
|
|
%4:gr32 = MOV32rm %2, 1, $noreg, 4, $noreg, debug-location !5 :: (load 4 from %ir.addr1)
|
|
%5:gr64_nosp = MOVSX64rr32 %0, debug-location !5
|
|
DBG_VALUE $noreg, $noreg, !3, !DIExpression(), debug-location !5
|
|
%1:gr32 = INC32r %0, implicit-def dead $eflags, debug-location !5
|
|
DBG_VALUE %1, $noreg, !3, !DIExpression(), debug-location !5
|
|
%6:gr32 = ADD32rm %4, %2, 4, killed %5, 0, $noreg, implicit-def dead $eflags :: (load 4 from %ir.addr2)
|
|
%7:gr32 = SUB32rr %6, %0, implicit-def $eflags, debug-location !5
|
|
JB_1 %bb.1, implicit $eflags, debug-location !5
|
|
JMP_1 %bb.2, debug-location !5
|
|
|
|
bb.2.bb2:
|
|
%8:gr32 = MOV32r0 implicit-def dead $eflags
|
|
$eax = COPY %8, debug-location !5
|
|
RET 0, $eax, debug-location !5
|
|
|
|
Observe first that there is a DBG_VALUE instruction for every ``llvm.dbg.value``
|
|
intrinsic in the source IR, ensuring no source level assignments go missing.
|
|
Then consider the different ways in which variable locations have been recorded:
|
|
|
|
* For the first dbg.value an immediate operand is used to record a zero value.
|
|
* The dbg.value of the PHI instruction leads to a DBG_VALUE of virtual register
|
|
``%0``.
|
|
* The first GEP has its effect folded into the first load instruction
|
|
(as a 4-byte offset), but the variable location is salvaged by folding
|
|
the GEPs effect into the DIExpression.
|
|
* The second GEP is also folded into the corresponding load. However, it is
|
|
insufficiently simple to be salvaged, and is emitted as a ``$noreg``
|
|
DBG_VALUE, indicating that the variable takes on an undefined location.
|
|
* The final dbg.value has its Value placed in virtual register ``%1``.
|
|
|
|
Instruction Scheduling
|
|
----------------------
|
|
|
|
A number of passes can reschedule instructions, notably instruction selection
|
|
and the pre-and-post RA machine schedulers. Instruction scheduling can
|
|
significantly change the nature of the program -- in the (very unlikely) worst
|
|
case the instruction sequence could be completely reversed. In such
|
|
circumstances LLVM follows the principle applied to optimizations, that it is
|
|
better for the debugger not to display any state than a misleading state.
|
|
Thus, whenever instructions are advanced in order of execution, any
|
|
corresponding DBG_VALUE is kept in its original position, and if an instruction
|
|
is delayed then the variable is given an undefined location for the duration
|
|
of the delay. To illustrate, consider this pseudo-MIR:
|
|
|
|
.. code-block:: text
|
|
|
|
%1:gr32 = MOV32rm %0, 1, $noreg, 4, $noreg, debug-location !5 :: (load 4 from %ir.addr1)
|
|
DBG_VALUE %1, $noreg, !1, !2
|
|
%4:gr32 = ADD32rr %3, %2, implicit-def dead $eflags
|
|
DBG_VALUE %4, $noreg, !3, !4
|
|
%7:gr32 = SUB32rr %6, %5, implicit-def dead $eflags
|
|
DBG_VALUE %7, $noreg, !5, !6
|
|
|
|
Imagine that the SUB32rr were moved forward to give us the following MIR:
|
|
|
|
.. code-block:: text
|
|
|
|
%7:gr32 = SUB32rr %6, %5, implicit-def dead $eflags
|
|
%1:gr32 = MOV32rm %0, 1, $noreg, 4, $noreg, debug-location !5 :: (load 4 from %ir.addr1)
|
|
DBG_VALUE %1, $noreg, !1, !2
|
|
%4:gr32 = ADD32rr %3, %2, implicit-def dead $eflags
|
|
DBG_VALUE %4, $noreg, !3, !4
|
|
DBG_VALUE %7, $noreg, !5, !6
|
|
|
|
In this circumstance LLVM would leave the MIR as shown above. Were we to move
|
|
the DBG_VALUE of virtual register %7 upwards with the SUB32rr, we would re-order
|
|
assignments and introduce a new state of the program. Wheras with the solution
|
|
above, the debugger will see one fewer combination of variable values, because
|
|
``!3`` and ``!5`` will change value at the same time. This is preferred over
|
|
misrepresenting the original program.
|
|
|
|
In comparison, if one sunk the MOV32rm, LLVM would produce the following:
|
|
|
|
.. code-block:: text
|
|
|
|
DBG_VALUE $noreg, $noreg, !1, !2
|
|
%4:gr32 = ADD32rr %3, %2, implicit-def dead $eflags
|
|
DBG_VALUE %4, $noreg, !3, !4
|
|
%7:gr32 = SUB32rr %6, %5, implicit-def dead $eflags
|
|
DBG_VALUE %7, $noreg, !5, !6
|
|
%1:gr32 = MOV32rm %0, 1, $noreg, 4, $noreg, debug-location !5 :: (load 4 from %ir.addr1)
|
|
DBG_VALUE %1, $noreg, !1, !2
|
|
|
|
Here, to avoid presenting a state in which the first assignment to ``!1``
|
|
disappears, the DBG_VALUE at the top of the block assigns the variable the
|
|
undefined location, until its value is available at the end of the block where
|
|
an additional DBG_VALUE is added. Were any other DBG_VALUE for ``!1`` to occur
|
|
in the instructions that the MOV32rm was sunk past, the DBG_VALUE for ``%1``
|
|
would be dropped and the debugger would never observe it in the variable. This
|
|
accurately reflects that the value is not available during the corresponding
|
|
portion of the original program.
|
|
|
|
Variable locations during Register Allocation
|
|
---------------------------------------------
|
|
|
|
To avoid debug instructions interfering with the register allocator, the
|
|
LiveDebugVariables pass extracts variable locations from a MIR function and
|
|
deletes the corresponding DBG_VALUE instructions. Some localized copy
|
|
propagation is performed within blocks. After register allocation, the
|
|
VirtRegRewriter pass re-inserts DBG_VALUE instructions in their orignal
|
|
positions, translating virtual register references into their physical
|
|
machine locations. To avoid encoding incorrect variable locations, in this
|
|
pass any DBG_VALUE of a virtual register that is not live, is replaced by
|
|
the undefined location.
|
|
|
|
LiveDebugValues expansion of variable locations
|
|
-----------------------------------------------
|
|
|
|
After all optimizations have run and shortly before emission, the
|
|
LiveDebugValues pass runs to achieve two aims:
|
|
|
|
* To propagate the location of variables through copies and register spills,
|
|
* For every block, to record every valid variable location in that block.
|
|
|
|
After this pass the DBG_VALUE instruction changes meaning: rather than
|
|
corresponding to a source-level assignment where the variable may change value,
|
|
it asserts the location of a variable in a block, and loses effect outside the
|
|
block. Propagating variable locations through copies and spills is
|
|
straightforwards: determining the variable location in every basic block
|
|
requries the consideraton of control flow. Consider the following IR, which
|
|
presents several difficulties:
|
|
|
|
.. code-block:: text
|
|
|
|
define dso_local i32 @foo(i1 %cond, i32 %input) !dbg !12 {
|
|
entry:
|
|
br i1 %cond, label %truebr, label %falsebr
|
|
|
|
bb1:
|
|
%value = phi i32 [ %value1, %truebr ], [ %value2, %falsebr ]
|
|
br label %exit, !dbg !26
|
|
|
|
truebr:
|
|
call void @llvm.dbg.value(metadata i32 %input, metadata !30, metadata !DIExpression()), !dbg !24
|
|
call void @llvm.dbg.value(metadata i32 1, metadata !23, metadata !DIExpression()), !dbg !24
|
|
%value1 = add i32 %input, 1
|
|
br label %bb1
|
|
|
|
falsebr:
|
|
call void @llvm.dbg.value(metadata i32 %input, metadata !30, metadata !DIExpression()), !dbg !24
|
|
call void @llvm.dbg.value(metadata i32 2, metadata !23, metadata !DIExpression()), !dbg !24
|
|
%value = add i32 %input, 2
|
|
br label %bb1
|
|
|
|
exit:
|
|
ret i32 %value, !dbg !30
|
|
}
|
|
|
|
Here the difficulties are:
|
|
|
|
* The control flow is roughly the opposite of basic block order
|
|
* The value of the ``!23`` variable merges into ``%bb1``, but there is no PHI
|
|
node
|
|
|
|
As mentioned above, the ``llvm.dbg.value`` intrinsics essentially form an
|
|
imperative program embedded in the IR, with each intrinsic defining a variable
|
|
location. This *could* be converted to an SSA form by mem2reg, in the same way
|
|
that it uses use-def chains to identify control flow merges and insert phi
|
|
nodes for IR Values. However, because debug variable locations are defined for
|
|
every machine instruction, in effect every IR instruction uses every variable
|
|
location, which would lead to a large number of debugging intrinsics being
|
|
generated.
|
|
|
|
Examining the example above, variable ``!30`` is assigned ``%input`` on both
|
|
conditional paths through the function, while ``!23`` is assigned differing
|
|
constant values on either path. Where control flow merges in ``%bb1`` we would
|
|
want ``!30`` to keep its location (``%input``), but ``!23`` to become undefined
|
|
as we cannot determine at runtime what value it should have in %bb1 without
|
|
inserting a PHI node. mem2reg does not insert the PHI node to avoid changing
|
|
codegen when debugging is enabled, and does not insert the other dbg.values
|
|
to avoid adding very large numbers of intrinsics.
|
|
|
|
Instead, LiveDebugValues determines variable locations when control
|
|
flow merges. A dataflow analysis is used to propagate locations between blocks:
|
|
when control flow merges, if a variable has the same location in all
|
|
predecessors then that location is propagated into the successor. If the
|
|
predecessor locations disagree, the location becomes undefined.
|
|
|
|
Once LiveDebugValues has run, every block should have all valid variable
|
|
locations described by DBG_VALUE instructions within the block. Very little
|
|
effort is then required by supporting classes (such as
|
|
DbgEntityHistoryCalculator) to build a map of each instruction to every
|
|
valid variable location, without the need to consider control flow. From
|
|
the example above, it is otherwise difficult to determine that the location
|
|
of variable ``!30`` should flow "up" into block ``%bb1``, but that the location
|
|
of variable ``!23`` should not flow "down" into the ``%exit`` block.
|
|
|
|
.. _ccxx_frontend:
|
|
|
|
C/C++ front-end specific debug information
|
|
==========================================
|
|
|
|
The C and C++ front-ends represent information about the program in a
|
|
format that is effectively identical to `DWARF <http://www.dwarfstd.org/>`_
|
|
in terms of information content. This allows code generators to
|
|
trivially support native debuggers by generating standard dwarf
|
|
information, and contains enough information for non-dwarf targets to
|
|
translate it as needed.
|
|
|
|
This section describes the forms used to represent C and C++ programs. Other
|
|
languages could pattern themselves after this (which itself is tuned to
|
|
representing programs in the same way that DWARF does), or they could choose
|
|
to provide completely different forms if they don't fit into the DWARF model.
|
|
As support for debugging information gets added to the various LLVM
|
|
source-language front-ends, the information used should be documented here.
|
|
|
|
The following sections provide examples of a few C/C++ constructs and
|
|
the debug information that would best describe those constructs. The
|
|
canonical references are the ``DINode`` classes defined in
|
|
``include/llvm/IR/DebugInfoMetadata.h`` and the implementations of the
|
|
helper functions in ``lib/IR/DIBuilder.cpp``.
|
|
|
|
C/C++ source file information
|
|
-----------------------------
|
|
|
|
``llvm::Instruction`` provides easy access to metadata attached with an
|
|
instruction. One can extract line number information encoded in LLVM IR using
|
|
``Instruction::getDebugLoc()`` and ``DILocation::getLine()``.
|
|
|
|
.. code-block:: c++
|
|
|
|
if (DILocation *Loc = I->getDebugLoc()) { // Here I is an LLVM instruction
|
|
unsigned Line = Loc->getLine();
|
|
StringRef File = Loc->getFilename();
|
|
StringRef Dir = Loc->getDirectory();
|
|
bool ImplicitCode = Loc->isImplicitCode();
|
|
}
|
|
|
|
When the flag ImplicitCode is true then it means that the Instruction has been
|
|
added by the front-end but doesn't correspond to source code written by the user. For example
|
|
|
|
.. code-block:: c++
|
|
|
|
if (MyBoolean) {
|
|
MyObject MO;
|
|
...
|
|
}
|
|
|
|
At the end of the scope the MyObject's destructor is called but it isn't written
|
|
explicitly. This information is useful to avoid to have counters on brackets when
|
|
making code coverage.
|
|
|
|
C/C++ global variable information
|
|
---------------------------------
|
|
|
|
Given an integer global variable declared as follows:
|
|
|
|
.. code-block:: c
|
|
|
|
_Alignas(8) int MyGlobal = 100;
|
|
|
|
a C/C++ front-end would generate the following descriptors:
|
|
|
|
.. code-block:: text
|
|
|
|
;;
|
|
;; Define the global itself.
|
|
;;
|
|
@MyGlobal = global i32 100, align 8, !dbg !0
|
|
|
|
;;
|
|
;; List of debug info of globals
|
|
;;
|
|
!llvm.dbg.cu = !{!1}
|
|
|
|
;; Some unrelated metadata.
|
|
!llvm.module.flags = !{!6, !7}
|
|
!llvm.ident = !{!8}
|
|
|
|
;; Define the global variable itself
|
|
!0 = distinct !DIGlobalVariable(name: "MyGlobal", scope: !1, file: !2, line: 1, type: !5, isLocal: false, isDefinition: true, align: 64)
|
|
|
|
;; Define the compile unit.
|
|
!1 = distinct !DICompileUnit(language: DW_LANG_C99, file: !2,
|
|
producer: "clang version 4.0.0",
|
|
isOptimized: false, runtimeVersion: 0, emissionKind: FullDebug,
|
|
enums: !3, globals: !4)
|
|
|
|
;;
|
|
;; Define the file
|
|
;;
|
|
!2 = !DIFile(filename: "/dev/stdin",
|
|
directory: "/Users/dexonsmith/data/llvm/debug-info")
|
|
|
|
;; An empty array.
|
|
!3 = !{}
|
|
|
|
;; The Array of Global Variables
|
|
!4 = !{!0}
|
|
|
|
;;
|
|
;; Define the type
|
|
;;
|
|
!5 = !DIBasicType(name: "int", size: 32, encoding: DW_ATE_signed)
|
|
|
|
;; Dwarf version to output.
|
|
!6 = !{i32 2, !"Dwarf Version", i32 4}
|
|
|
|
;; Debug info schema version.
|
|
!7 = !{i32 2, !"Debug Info Version", i32 3}
|
|
|
|
;; Compiler identification
|
|
!8 = !{!"clang version 4.0.0"}
|
|
|
|
|
|
The align value in DIGlobalVariable description specifies variable alignment in
|
|
case it was forced by C11 _Alignas(), C++11 alignas() keywords or compiler
|
|
attribute __attribute__((aligned ())). In other case (when this field is missing)
|
|
alignment is considered default. This is used when producing DWARF output
|
|
for DW_AT_alignment value.
|
|
|
|
C/C++ function information
|
|
--------------------------
|
|
|
|
Given a function declared as follows:
|
|
|
|
.. code-block:: c
|
|
|
|
int main(int argc, char *argv[]) {
|
|
return 0;
|
|
}
|
|
|
|
a C/C++ front-end would generate the following descriptors:
|
|
|
|
.. code-block:: text
|
|
|
|
;;
|
|
;; Define the anchor for subprograms.
|
|
;;
|
|
!4 = !DISubprogram(name: "main", scope: !1, file: !1, line: 1, type: !5,
|
|
isLocal: false, isDefinition: true, scopeLine: 1,
|
|
flags: DIFlagPrototyped, isOptimized: false,
|
|
variables: !2)
|
|
|
|
;;
|
|
;; Define the subprogram itself.
|
|
;;
|
|
define i32 @main(i32 %argc, i8** %argv) !dbg !4 {
|
|
...
|
|
}
|
|
|
|
Fortran specific debug information
|
|
==================================
|
|
|
|
Fortran function information
|
|
----------------------------
|
|
|
|
There are a few DWARF attributes defined to support client debugging of Fortran programs. LLVM can generate (or omit) the appropriate DWARF attributes for the prefix-specs of ELEMENTAL, PURE, IMPURE, RECURSIVE, and NON_RECURSIVE. This is done by using the spFlags values: DISPFlagElemental, DISPFlagPure, and DISPFlagRecursive.
|
|
|
|
.. code-block:: fortran
|
|
|
|
elemental function elem_func(a)
|
|
|
|
a Fortran front-end would generate the following descriptors:
|
|
|
|
.. code-block:: text
|
|
|
|
!11 = distinct !DISubprogram(name: "subroutine2", scope: !1, file: !1,
|
|
line: 5, type: !8, scopeLine: 6,
|
|
spFlags: DISPFlagDefinition | DISPFlagElemental, unit: !0,
|
|
retainedNodes: !2)
|
|
|
|
and this will materialize an additional DWARF attribute as:
|
|
|
|
.. code-block:: text
|
|
|
|
DW_TAG_subprogram [3]
|
|
DW_AT_low_pc [DW_FORM_addr] (0x0000000000000010 ".text")
|
|
DW_AT_high_pc [DW_FORM_data4] (0x00000001)
|
|
...
|
|
DW_AT_elemental [DW_FORM_flag_present] (true)
|
|
|
|
Debugging information format
|
|
============================
|
|
|
|
Debugging Information Extension for Objective C Properties
|
|
----------------------------------------------------------
|
|
|
|
Introduction
|
|
^^^^^^^^^^^^
|
|
|
|
Objective C provides a simpler way to declare and define accessor methods using
|
|
declared properties. The language provides features to declare a property and
|
|
to let compiler synthesize accessor methods.
|
|
|
|
The debugger lets developer inspect Objective C interfaces and their instance
|
|
variables and class variables. However, the debugger does not know anything
|
|
about the properties defined in Objective C interfaces. The debugger consumes
|
|
information generated by compiler in DWARF format. The format does not support
|
|
encoding of Objective C properties. This proposal describes DWARF extensions to
|
|
encode Objective C properties, which the debugger can use to let developers
|
|
inspect Objective C properties.
|
|
|
|
Proposal
|
|
^^^^^^^^
|
|
|
|
Objective C properties exist separately from class members. A property can be
|
|
defined only by "setter" and "getter" selectors, and be calculated anew on each
|
|
access. Or a property can just be a direct access to some declared ivar.
|
|
Finally it can have an ivar "automatically synthesized" for it by the compiler,
|
|
in which case the property can be referred to in user code directly using the
|
|
standard C dereference syntax as well as through the property "dot" syntax, but
|
|
there is no entry in the ``@interface`` declaration corresponding to this ivar.
|
|
|
|
To facilitate debugging, these properties we will add a new DWARF TAG into the
|
|
``DW_TAG_structure_type`` definition for the class to hold the description of a
|
|
given property, and a set of DWARF attributes that provide said description.
|
|
The property tag will also contain the name and declared type of the property.
|
|
|
|
If there is a related ivar, there will also be a DWARF property attribute placed
|
|
in the ``DW_TAG_member`` DIE for that ivar referring back to the property TAG
|
|
for that property. And in the case where the compiler synthesizes the ivar
|
|
directly, the compiler is expected to generate a ``DW_TAG_member`` for that
|
|
ivar (with the ``DW_AT_artificial`` set to 1), whose name will be the name used
|
|
to access this ivar directly in code, and with the property attribute pointing
|
|
back to the property it is backing.
|
|
|
|
The following examples will serve as illustration for our discussion:
|
|
|
|
.. code-block:: objc
|
|
|
|
@interface I1 {
|
|
int n2;
|
|
}
|
|
|
|
@property int p1;
|
|
@property int p2;
|
|
@end
|
|
|
|
@implementation I1
|
|
@synthesize p1;
|
|
@synthesize p2 = n2;
|
|
@end
|
|
|
|
This produces the following DWARF (this is a "pseudo dwarfdump" output):
|
|
|
|
.. code-block:: none
|
|
|
|
0x00000100: TAG_structure_type [7] *
|
|
AT_APPLE_runtime_class( 0x10 )
|
|
AT_name( "I1" )
|
|
AT_decl_file( "Objc_Property.m" )
|
|
AT_decl_line( 3 )
|
|
|
|
0x00000110 TAG_APPLE_property
|
|
AT_name ( "p1" )
|
|
AT_type ( {0x00000150} ( int ) )
|
|
|
|
0x00000120: TAG_APPLE_property
|
|
AT_name ( "p2" )
|
|
AT_type ( {0x00000150} ( int ) )
|
|
|
|
0x00000130: TAG_member [8]
|
|
AT_name( "_p1" )
|
|
AT_APPLE_property ( {0x00000110} "p1" )
|
|
AT_type( {0x00000150} ( int ) )
|
|
AT_artificial ( 0x1 )
|
|
|
|
0x00000140: TAG_member [8]
|
|
AT_name( "n2" )
|
|
AT_APPLE_property ( {0x00000120} "p2" )
|
|
AT_type( {0x00000150} ( int ) )
|
|
|
|
0x00000150: AT_type( ( int ) )
|
|
|
|
Note, the current convention is that the name of the ivar for an
|
|
auto-synthesized property is the name of the property from which it derives
|
|
with an underscore prepended, as is shown in the example. But we actually
|
|
don't need to know this convention, since we are given the name of the ivar
|
|
directly.
|
|
|
|
Also, it is common practice in ObjC to have different property declarations in
|
|
the @interface and @implementation - e.g. to provide a read-only property in
|
|
the interface,and a read-write interface in the implementation. In that case,
|
|
the compiler should emit whichever property declaration will be in force in the
|
|
current translation unit.
|
|
|
|
Developers can decorate a property with attributes which are encoded using
|
|
``DW_AT_APPLE_property_attribute``.
|
|
|
|
.. code-block:: objc
|
|
|
|
@property (readonly, nonatomic) int pr;
|
|
|
|
.. code-block:: none
|
|
|
|
TAG_APPLE_property [8]
|
|
AT_name( "pr" )
|
|
AT_type ( {0x00000147} (int) )
|
|
AT_APPLE_property_attribute (DW_APPLE_PROPERTY_readonly, DW_APPLE_PROPERTY_nonatomic)
|
|
|
|
The setter and getter method names are attached to the property using
|
|
``DW_AT_APPLE_property_setter`` and ``DW_AT_APPLE_property_getter`` attributes.
|
|
|
|
.. code-block:: objc
|
|
|
|
@interface I1
|
|
@property (setter=myOwnP3Setter:) int p3;
|
|
-(void)myOwnP3Setter:(int)a;
|
|
@end
|
|
|
|
@implementation I1
|
|
@synthesize p3;
|
|
-(void)myOwnP3Setter:(int)a{ }
|
|
@end
|
|
|
|
The DWARF for this would be:
|
|
|
|
.. code-block:: none
|
|
|
|
0x000003bd: TAG_structure_type [7] *
|
|
AT_APPLE_runtime_class( 0x10 )
|
|
AT_name( "I1" )
|
|
AT_decl_file( "Objc_Property.m" )
|
|
AT_decl_line( 3 )
|
|
|
|
0x000003cd TAG_APPLE_property
|
|
AT_name ( "p3" )
|
|
AT_APPLE_property_setter ( "myOwnP3Setter:" )
|
|
AT_type( {0x00000147} ( int ) )
|
|
|
|
0x000003f3: TAG_member [8]
|
|
AT_name( "_p3" )
|
|
AT_type ( {0x00000147} ( int ) )
|
|
AT_APPLE_property ( {0x000003cd} )
|
|
AT_artificial ( 0x1 )
|
|
|
|
New DWARF Tags
|
|
^^^^^^^^^^^^^^
|
|
|
|
+-----------------------+--------+
|
|
| TAG | Value |
|
|
+=======================+========+
|
|
| DW_TAG_APPLE_property | 0x4200 |
|
|
+-----------------------+--------+
|
|
|
|
New DWARF Attributes
|
|
^^^^^^^^^^^^^^^^^^^^
|
|
|
|
+--------------------------------+--------+-----------+
|
|
| Attribute | Value | Classes |
|
|
+================================+========+===========+
|
|
| DW_AT_APPLE_property | 0x3fed | Reference |
|
|
+--------------------------------+--------+-----------+
|
|
| DW_AT_APPLE_property_getter | 0x3fe9 | String |
|
|
+--------------------------------+--------+-----------+
|
|
| DW_AT_APPLE_property_setter | 0x3fea | String |
|
|
+--------------------------------+--------+-----------+
|
|
| DW_AT_APPLE_property_attribute | 0x3feb | Constant |
|
|
+--------------------------------+--------+-----------+
|
|
|
|
New DWARF Constants
|
|
^^^^^^^^^^^^^^^^^^^
|
|
|
|
+--------------------------------------+-------+
|
|
| Name | Value |
|
|
+======================================+=======+
|
|
| DW_APPLE_PROPERTY_readonly | 0x01 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_getter | 0x02 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_assign | 0x04 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_readwrite | 0x08 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_retain | 0x10 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_copy | 0x20 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_nonatomic | 0x40 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_setter | 0x80 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_atomic | 0x100 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_weak | 0x200 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_strong | 0x400 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_unsafe_unretained | 0x800 |
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_nullability | 0x1000|
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_null_resettable | 0x2000|
|
|
+--------------------------------------+-------+
|
|
| DW_APPLE_PROPERTY_class | 0x4000|
|
|
+--------------------------------------+-------+
|
|
|
|
Name Accelerator Tables
|
|
-----------------------
|
|
|
|
Introduction
|
|
^^^^^^^^^^^^
|
|
|
|
The "``.debug_pubnames``" and "``.debug_pubtypes``" formats are not what a
|
|
debugger needs. The "``pub``" in the section name indicates that the entries
|
|
in the table are publicly visible names only. This means no static or hidden
|
|
functions show up in the "``.debug_pubnames``". No static variables or private
|
|
class variables are in the "``.debug_pubtypes``". Many compilers add different
|
|
things to these tables, so we can't rely upon the contents between gcc, icc, or
|
|
clang.
|
|
|
|
The typical query given by users tends not to match up with the contents of
|
|
these tables. For example, the DWARF spec states that "In the case of the name
|
|
of a function member or static data member of a C++ structure, class or union,
|
|
the name presented in the "``.debug_pubnames``" section is not the simple name
|
|
given by the ``DW_AT_name attribute`` of the referenced debugging information
|
|
entry, but rather the fully qualified name of the data or function member."
|
|
So the only names in these tables for complex C++ entries is a fully
|
|
qualified name. Debugger users tend not to enter their search strings as
|
|
"``a::b::c(int,const Foo&) const``", but rather as "``c``", "``b::c``" , or
|
|
"``a::b::c``". So the name entered in the name table must be demangled in
|
|
order to chop it up appropriately and additional names must be manually entered
|
|
into the table to make it effective as a name lookup table for debuggers to
|
|
use.
|
|
|
|
All debuggers currently ignore the "``.debug_pubnames``" table as a result of
|
|
its inconsistent and useless public-only name content making it a waste of
|
|
space in the object file. These tables, when they are written to disk, are not
|
|
sorted in any way, leaving every debugger to do its own parsing and sorting.
|
|
These tables also include an inlined copy of the string values in the table
|
|
itself making the tables much larger than they need to be on disk, especially
|
|
for large C++ programs.
|
|
|
|
Can't we just fix the sections by adding all of the names we need to this
|
|
table? No, because that is not what the tables are defined to contain and we
|
|
won't know the difference between the old bad tables and the new good tables.
|
|
At best we could make our own renamed sections that contain all of the data we
|
|
need.
|
|
|
|
These tables are also insufficient for what a debugger like LLDB needs. LLDB
|
|
uses clang for its expression parsing where LLDB acts as a PCH. LLDB is then
|
|
often asked to look for type "``foo``" or namespace "``bar``", or list items in
|
|
namespace "``baz``". Namespaces are not included in the pubnames or pubtypes
|
|
tables. Since clang asks a lot of questions when it is parsing an expression,
|
|
we need to be very fast when looking up names, as it happens a lot. Having new
|
|
accelerator tables that are optimized for very quick lookups will benefit this
|
|
type of debugging experience greatly.
|
|
|
|
We would like to generate name lookup tables that can be mapped into memory
|
|
from disk, and used as is, with little or no up-front parsing. We would also
|
|
be able to control the exact content of these different tables so they contain
|
|
exactly what we need. The Name Accelerator Tables were designed to fix these
|
|
issues. In order to solve these issues we need to:
|
|
|
|
* Have a format that can be mapped into memory from disk and used as is
|
|
* Lookups should be very fast
|
|
* Extensible table format so these tables can be made by many producers
|
|
* Contain all of the names needed for typical lookups out of the box
|
|
* Strict rules for the contents of tables
|
|
|
|
Table size is important and the accelerator table format should allow the reuse
|
|
of strings from common string tables so the strings for the names are not
|
|
duplicated. We also want to make sure the table is ready to be used as-is by
|
|
simply mapping the table into memory with minimal header parsing.
|
|
|
|
The name lookups need to be fast and optimized for the kinds of lookups that
|
|
debuggers tend to do. Optimally we would like to touch as few parts of the
|
|
mapped table as possible when doing a name lookup and be able to quickly find
|
|
the name entry we are looking for, or discover there are no matches. In the
|
|
case of debuggers we optimized for lookups that fail most of the time.
|
|
|
|
Each table that is defined should have strict rules on exactly what is in the
|
|
accelerator tables and documented so clients can rely on the content.
|
|
|
|
Hash Tables
|
|
^^^^^^^^^^^
|
|
|
|
Standard Hash Tables
|
|
""""""""""""""""""""
|
|
|
|
Typical hash tables have a header, buckets, and each bucket points to the
|
|
bucket contents:
|
|
|
|
.. code-block:: none
|
|
|
|
.------------.
|
|
| HEADER |
|
|
|------------|
|
|
| BUCKETS |
|
|
|------------|
|
|
| DATA |
|
|
`------------'
|
|
|
|
The BUCKETS are an array of offsets to DATA for each hash:
|
|
|
|
.. code-block:: none
|
|
|
|
.------------.
|
|
| 0x00001000 | BUCKETS[0]
|
|
| 0x00002000 | BUCKETS[1]
|
|
| 0x00002200 | BUCKETS[2]
|
|
| 0x000034f0 | BUCKETS[3]
|
|
| | ...
|
|
| 0xXXXXXXXX | BUCKETS[n_buckets]
|
|
'------------'
|
|
|
|
So for ``bucket[3]`` in the example above, we have an offset into the table
|
|
0x000034f0 which points to a chain of entries for the bucket. Each bucket must
|
|
contain a next pointer, full 32 bit hash value, the string itself, and the data
|
|
for the current string value.
|
|
|
|
.. code-block:: none
|
|
|
|
.------------.
|
|
0x000034f0: | 0x00003500 | next pointer
|
|
| 0x12345678 | 32 bit hash
|
|
| "erase" | string value
|
|
| data[n] | HashData for this bucket
|
|
|------------|
|
|
0x00003500: | 0x00003550 | next pointer
|
|
| 0x29273623 | 32 bit hash
|
|
| "dump" | string value
|
|
| data[n] | HashData for this bucket
|
|
|------------|
|
|
0x00003550: | 0x00000000 | next pointer
|
|
| 0x82638293 | 32 bit hash
|
|
| "main" | string value
|
|
| data[n] | HashData for this bucket
|
|
`------------'
|
|
|
|
The problem with this layout for debuggers is that we need to optimize for the
|
|
negative lookup case where the symbol we're searching for is not present. So
|
|
if we were to lookup "``printf``" in the table above, we would make a 32-bit
|
|
hash for "``printf``", it might match ``bucket[3]``. We would need to go to
|
|
the offset 0x000034f0 and start looking to see if our 32 bit hash matches. To
|
|
do so, we need to read the next pointer, then read the hash, compare it, and
|
|
skip to the next bucket. Each time we are skipping many bytes in memory and
|
|
touching new pages just to do the compare on the full 32 bit hash. All of
|
|
these accesses then tell us that we didn't have a match.
|
|
|
|
Name Hash Tables
|
|
""""""""""""""""
|
|
|
|
To solve the issues mentioned above we have structured the hash tables a bit
|
|
differently: a header, buckets, an array of all unique 32 bit hash values,
|
|
followed by an array of hash value data offsets, one for each hash value, then
|
|
the data for all hash values:
|
|
|
|
.. code-block:: none
|
|
|
|
.-------------.
|
|
| HEADER |
|
|
|-------------|
|
|
| BUCKETS |
|
|
|-------------|
|
|
| HASHES |
|
|
|-------------|
|
|
| OFFSETS |
|
|
|-------------|
|
|
| DATA |
|
|
`-------------'
|
|
|
|
The ``BUCKETS`` in the name tables are an index into the ``HASHES`` array. By
|
|
making all of the full 32 bit hash values contiguous in memory, we allow
|
|
ourselves to efficiently check for a match while touching as little memory as
|
|
possible. Most often checking the 32 bit hash values is as far as the lookup
|
|
goes. If it does match, it usually is a match with no collisions. So for a
|
|
table with "``n_buckets``" buckets, and "``n_hashes``" unique 32 bit hash
|
|
values, we can clarify the contents of the ``BUCKETS``, ``HASHES`` and
|
|
``OFFSETS`` as:
|
|
|
|
.. code-block:: none
|
|
|
|
.-------------------------.
|
|
| HEADER.magic | uint32_t
|
|
| HEADER.version | uint16_t
|
|
| HEADER.hash_function | uint16_t
|
|
| HEADER.bucket_count | uint32_t
|
|
| HEADER.hashes_count | uint32_t
|
|
| HEADER.header_data_len | uint32_t
|
|
| HEADER_DATA | HeaderData
|
|
|-------------------------|
|
|
| BUCKETS | uint32_t[n_buckets] // 32 bit hash indexes
|
|
|-------------------------|
|
|
| HASHES | uint32_t[n_hashes] // 32 bit hash values
|
|
|-------------------------|
|
|
| OFFSETS | uint32_t[n_hashes] // 32 bit offsets to hash value data
|
|
|-------------------------|
|
|
| ALL HASH DATA |
|
|
`-------------------------'
|
|
|
|
So taking the exact same data from the standard hash example above we end up
|
|
with:
|
|
|
|
.. code-block:: none
|
|
|
|
.------------.
|
|
| HEADER |
|
|
|------------|
|
|
| 0 | BUCKETS[0]
|
|
| 2 | BUCKETS[1]
|
|
| 5 | BUCKETS[2]
|
|
| 6 | BUCKETS[3]
|
|
| | ...
|
|
| ... | BUCKETS[n_buckets]
|
|
|------------|
|
|
| 0x........ | HASHES[0]
|
|
| 0x........ | HASHES[1]
|
|
| 0x........ | HASHES[2]
|
|
| 0x........ | HASHES[3]
|
|
| 0x........ | HASHES[4]
|
|
| 0x........ | HASHES[5]
|
|
| 0x12345678 | HASHES[6] hash for BUCKETS[3]
|
|
| 0x29273623 | HASHES[7] hash for BUCKETS[3]
|
|
| 0x82638293 | HASHES[8] hash for BUCKETS[3]
|
|
| 0x........ | HASHES[9]
|
|
| 0x........ | HASHES[10]
|
|
| 0x........ | HASHES[11]
|
|
| 0x........ | HASHES[12]
|
|
| 0x........ | HASHES[13]
|
|
| 0x........ | HASHES[n_hashes]
|
|
|------------|
|
|
| 0x........ | OFFSETS[0]
|
|
| 0x........ | OFFSETS[1]
|
|
| 0x........ | OFFSETS[2]
|
|
| 0x........ | OFFSETS[3]
|
|
| 0x........ | OFFSETS[4]
|
|
| 0x........ | OFFSETS[5]
|
|
| 0x000034f0 | OFFSETS[6] offset for BUCKETS[3]
|
|
| 0x00003500 | OFFSETS[7] offset for BUCKETS[3]
|
|
| 0x00003550 | OFFSETS[8] offset for BUCKETS[3]
|
|
| 0x........ | OFFSETS[9]
|
|
| 0x........ | OFFSETS[10]
|
|
| 0x........ | OFFSETS[11]
|
|
| 0x........ | OFFSETS[12]
|
|
| 0x........ | OFFSETS[13]
|
|
| 0x........ | OFFSETS[n_hashes]
|
|
|------------|
|
|
| |
|
|
| |
|
|
| |
|
|
| |
|
|
| |
|
|
|------------|
|
|
0x000034f0: | 0x00001203 | .debug_str ("erase")
|
|
| 0x00000004 | A 32 bit array count - number of HashData with name "erase"
|
|
| 0x........ | HashData[0]
|
|
| 0x........ | HashData[1]
|
|
| 0x........ | HashData[2]
|
|
| 0x........ | HashData[3]
|
|
| 0x00000000 | String offset into .debug_str (terminate data for hash)
|
|
|------------|
|
|
0x00003500: | 0x00001203 | String offset into .debug_str ("collision")
|
|
| 0x00000002 | A 32 bit array count - number of HashData with name "collision"
|
|
| 0x........ | HashData[0]
|
|
| 0x........ | HashData[1]
|
|
| 0x00001203 | String offset into .debug_str ("dump")
|
|
| 0x00000003 | A 32 bit array count - number of HashData with name "dump"
|
|
| 0x........ | HashData[0]
|
|
| 0x........ | HashData[1]
|
|
| 0x........ | HashData[2]
|
|
| 0x00000000 | String offset into .debug_str (terminate data for hash)
|
|
|------------|
|
|
0x00003550: | 0x00001203 | String offset into .debug_str ("main")
|
|
| 0x00000009 | A 32 bit array count - number of HashData with name "main"
|
|
| 0x........ | HashData[0]
|
|
| 0x........ | HashData[1]
|
|
| 0x........ | HashData[2]
|
|
| 0x........ | HashData[3]
|
|
| 0x........ | HashData[4]
|
|
| 0x........ | HashData[5]
|
|
| 0x........ | HashData[6]
|
|
| 0x........ | HashData[7]
|
|
| 0x........ | HashData[8]
|
|
| 0x00000000 | String offset into .debug_str (terminate data for hash)
|
|
`------------'
|
|
|
|
So we still have all of the same data, we just organize it more efficiently for
|
|
debugger lookup. If we repeat the same "``printf``" lookup from above, we
|
|
would hash "``printf``" and find it matches ``BUCKETS[3]`` by taking the 32 bit
|
|
hash value and modulo it by ``n_buckets``. ``BUCKETS[3]`` contains "6" which
|
|
is the index into the ``HASHES`` table. We would then compare any consecutive
|
|
32 bit hashes values in the ``HASHES`` array as long as the hashes would be in
|
|
``BUCKETS[3]``. We do this by verifying that each subsequent hash value modulo
|
|
``n_buckets`` is still 3. In the case of a failed lookup we would access the
|
|
memory for ``BUCKETS[3]``, and then compare a few consecutive 32 bit hashes
|
|
before we know that we have no match. We don't end up marching through
|
|
multiple words of memory and we really keep the number of processor data cache
|
|
lines being accessed as small as possible.
|
|
|
|
The string hash that is used for these lookup tables is the Daniel J.
|
|
Bernstein hash which is also used in the ELF ``GNU_HASH`` sections. It is a
|
|
very good hash for all kinds of names in programs with very few hash
|
|
collisions.
|
|
|
|
Empty buckets are designated by using an invalid hash index of ``UINT32_MAX``.
|
|
|
|
Details
|
|
^^^^^^^
|
|
|
|
These name hash tables are designed to be generic where specializations of the
|
|
table get to define additional data that goes into the header ("``HeaderData``"),
|
|
how the string value is stored ("``KeyType``") and the content of the data for each
|
|
hash value.
|
|
|
|
Header Layout
|
|
"""""""""""""
|
|
|
|
The header has a fixed part, and the specialized part. The exact format of the
|
|
header is:
|
|
|
|
.. code-block:: c
|
|
|
|
struct Header
|
|
{
|
|
uint32_t magic; // 'HASH' magic value to allow endian detection
|
|
uint16_t version; // Version number
|
|
uint16_t hash_function; // The hash function enumeration that was used
|
|
uint32_t bucket_count; // The number of buckets in this hash table
|
|
uint32_t hashes_count; // The total number of unique hash values and hash data offsets in this table
|
|
uint32_t header_data_len; // The bytes to skip to get to the hash indexes (buckets) for correct alignment
|
|
// Specifically the length of the following HeaderData field - this does not
|
|
// include the size of the preceding fields
|
|
HeaderData header_data; // Implementation specific header data
|
|
};
|
|
|
|
The header starts with a 32 bit "``magic``" value which must be ``'HASH'``
|
|
encoded as an ASCII integer. This allows the detection of the start of the
|
|
hash table and also allows the table's byte order to be determined so the table
|
|
can be correctly extracted. The "``magic``" value is followed by a 16 bit
|
|
``version`` number which allows the table to be revised and modified in the
|
|
future. The current version number is 1. ``hash_function`` is a ``uint16_t``
|
|
enumeration that specifies which hash function was used to produce this table.
|
|
The current values for the hash function enumerations include:
|
|
|
|
.. code-block:: c
|
|
|
|
enum HashFunctionType
|
|
{
|
|
eHashFunctionDJB = 0u, // Daniel J Bernstein hash function
|
|
};
|
|
|
|
``bucket_count`` is a 32 bit unsigned integer that represents how many buckets
|
|
are in the ``BUCKETS`` array. ``hashes_count`` is the number of unique 32 bit
|
|
hash values that are in the ``HASHES`` array, and is the same number of offsets
|
|
are contained in the ``OFFSETS`` array. ``header_data_len`` specifies the size
|
|
in bytes of the ``HeaderData`` that is filled in by specialized versions of
|
|
this table.
|
|
|
|
Fixed Lookup
|
|
""""""""""""
|
|
|
|
The header is followed by the buckets, hashes, offsets, and hash value data.
|
|
|
|
.. code-block:: c
|
|
|
|
struct FixedTable
|
|
{
|
|
uint32_t buckets[Header.bucket_count]; // An array of hash indexes into the "hashes[]" array below
|
|
uint32_t hashes [Header.hashes_count]; // Every unique 32 bit hash for the entire table is in this table
|
|
uint32_t offsets[Header.hashes_count]; // An offset that corresponds to each item in the "hashes[]" array above
|
|
};
|
|
|
|
``buckets`` is an array of 32 bit indexes into the ``hashes`` array. The
|
|
``hashes`` array contains all of the 32 bit hash values for all names in the
|
|
hash table. Each hash in the ``hashes`` table has an offset in the ``offsets``
|
|
array that points to the data for the hash value.
|
|
|
|
This table setup makes it very easy to repurpose these tables to contain
|
|
different data, while keeping the lookup mechanism the same for all tables.
|
|
This layout also makes it possible to save the table to disk and map it in
|
|
later and do very efficient name lookups with little or no parsing.
|
|
|
|
DWARF lookup tables can be implemented in a variety of ways and can store a lot
|
|
of information for each name. We want to make the DWARF tables extensible and
|
|
able to store the data efficiently so we have used some of the DWARF features
|
|
that enable efficient data storage to define exactly what kind of data we store
|
|
for each name.
|
|
|
|
The ``HeaderData`` contains a definition of the contents of each HashData chunk.
|
|
We might want to store an offset to all of the debug information entries (DIEs)
|
|
for each name. To keep things extensible, we create a list of items, or
|
|
Atoms, that are contained in the data for each name. First comes the type of
|
|
the data in each atom:
|
|
|
|
.. code-block:: c
|
|
|
|
enum AtomType
|
|
{
|
|
eAtomTypeNULL = 0u,
|
|
eAtomTypeDIEOffset = 1u, // DIE offset, check form for encoding
|
|
eAtomTypeCUOffset = 2u, // DIE offset of the compiler unit header that contains the item in question
|
|
eAtomTypeTag = 3u, // DW_TAG_xxx value, should be encoded as DW_FORM_data1 (if no tags exceed 255) or DW_FORM_data2
|
|
eAtomTypeNameFlags = 4u, // Flags from enum NameFlags
|
|
eAtomTypeTypeFlags = 5u, // Flags from enum TypeFlags
|
|
};
|
|
|
|
The enumeration values and their meanings are:
|
|
|
|
.. code-block:: none
|
|
|
|
eAtomTypeNULL - a termination atom that specifies the end of the atom list
|
|
eAtomTypeDIEOffset - an offset into the .debug_info section for the DWARF DIE for this name
|
|
eAtomTypeCUOffset - an offset into the .debug_info section for the CU that contains the DIE
|
|
eAtomTypeDIETag - The DW_TAG_XXX enumeration value so you don't have to parse the DWARF to see what it is
|
|
eAtomTypeNameFlags - Flags for functions and global variables (isFunction, isInlined, isExternal...)
|
|
eAtomTypeTypeFlags - Flags for types (isCXXClass, isObjCClass, ...)
|
|
|
|
Then we allow each atom type to define the atom type and how the data for each
|
|
atom type data is encoded:
|
|
|
|
.. code-block:: c
|
|
|
|
struct Atom
|
|
{
|
|
uint16_t type; // AtomType enum value
|
|
uint16_t form; // DWARF DW_FORM_XXX defines
|
|
};
|
|
|
|
The ``form`` type above is from the DWARF specification and defines the exact
|
|
encoding of the data for the Atom type. See the DWARF specification for the
|
|
``DW_FORM_`` definitions.
|
|
|
|
.. code-block:: c
|
|
|
|
struct HeaderData
|
|
{
|
|
uint32_t die_offset_base;
|
|
uint32_t atom_count;
|
|
Atoms atoms[atom_count0];
|
|
};
|
|
|
|
``HeaderData`` defines the base DIE offset that should be added to any atoms
|
|
that are encoded using the ``DW_FORM_ref1``, ``DW_FORM_ref2``,
|
|
``DW_FORM_ref4``, ``DW_FORM_ref8`` or ``DW_FORM_ref_udata``. It also defines
|
|
what is contained in each ``HashData`` object -- ``Atom.form`` tells us how large
|
|
each field will be in the ``HashData`` and the ``Atom.type`` tells us how this data
|
|
should be interpreted.
|
|
|
|
For the current implementations of the "``.apple_names``" (all functions +
|
|
globals), the "``.apple_types``" (names of all types that are defined), and
|
|
the "``.apple_namespaces``" (all namespaces), we currently set the ``Atom``
|
|
array to be:
|
|
|
|
.. code-block:: c
|
|
|
|
HeaderData.atom_count = 1;
|
|
HeaderData.atoms[0].type = eAtomTypeDIEOffset;
|
|
HeaderData.atoms[0].form = DW_FORM_data4;
|
|
|
|
This defines the contents to be the DIE offset (eAtomTypeDIEOffset) that is
|
|
encoded as a 32 bit value (DW_FORM_data4). This allows a single name to have
|
|
multiple matching DIEs in a single file, which could come up with an inlined
|
|
function for instance. Future tables could include more information about the
|
|
DIE such as flags indicating if the DIE is a function, method, block,
|
|
or inlined.
|
|
|
|
The KeyType for the DWARF table is a 32 bit string table offset into the
|
|
".debug_str" table. The ".debug_str" is the string table for the DWARF which
|
|
may already contain copies of all of the strings. This helps make sure, with
|
|
help from the compiler, that we reuse the strings between all of the DWARF
|
|
sections and keeps the hash table size down. Another benefit to having the
|
|
compiler generate all strings as DW_FORM_strp in the debug info, is that
|
|
DWARF parsing can be made much faster.
|
|
|
|
After a lookup is made, we get an offset into the hash data. The hash data
|
|
needs to be able to deal with 32 bit hash collisions, so the chunk of data
|
|
at the offset in the hash data consists of a triple:
|
|
|
|
.. code-block:: c
|
|
|
|
uint32_t str_offset
|
|
uint32_t hash_data_count
|
|
HashData[hash_data_count]
|
|
|
|
If "str_offset" is zero, then the bucket contents are done. 99.9% of the
|
|
hash data chunks contain a single item (no 32 bit hash collision):
|
|
|
|
.. code-block:: none
|
|
|
|
.------------.
|
|
| 0x00001023 | uint32_t KeyType (.debug_str[0x0001023] => "main")
|
|
| 0x00000004 | uint32_t HashData count
|
|
| 0x........ | uint32_t HashData[0] DIE offset
|
|
| 0x........ | uint32_t HashData[1] DIE offset
|
|
| 0x........ | uint32_t HashData[2] DIE offset
|
|
| 0x........ | uint32_t HashData[3] DIE offset
|
|
| 0x00000000 | uint32_t KeyType (end of hash chain)
|
|
`------------'
|
|
|
|
If there are collisions, you will have multiple valid string offsets:
|
|
|
|
.. code-block:: none
|
|
|
|
.------------.
|
|
| 0x00001023 | uint32_t KeyType (.debug_str[0x0001023] => "main")
|
|
| 0x00000004 | uint32_t HashData count
|
|
| 0x........ | uint32_t HashData[0] DIE offset
|
|
| 0x........ | uint32_t HashData[1] DIE offset
|
|
| 0x........ | uint32_t HashData[2] DIE offset
|
|
| 0x........ | uint32_t HashData[3] DIE offset
|
|
| 0x00002023 | uint32_t KeyType (.debug_str[0x0002023] => "print")
|
|
| 0x00000002 | uint32_t HashData count
|
|
| 0x........ | uint32_t HashData[0] DIE offset
|
|
| 0x........ | uint32_t HashData[1] DIE offset
|
|
| 0x00000000 | uint32_t KeyType (end of hash chain)
|
|
`------------'
|
|
|
|
Current testing with real world C++ binaries has shown that there is around 1
|
|
32 bit hash collision per 100,000 name entries.
|
|
|
|
Contents
|
|
^^^^^^^^
|
|
|
|
As we said, we want to strictly define exactly what is included in the
|
|
different tables. For DWARF, we have 3 tables: "``.apple_names``",
|
|
"``.apple_types``", and "``.apple_namespaces``".
|
|
|
|
"``.apple_names``" sections should contain an entry for each DWARF DIE whose
|
|
``DW_TAG`` is a ``DW_TAG_label``, ``DW_TAG_inlined_subroutine``, or
|
|
``DW_TAG_subprogram`` that has address attributes: ``DW_AT_low_pc``,
|
|
``DW_AT_high_pc``, ``DW_AT_ranges`` or ``DW_AT_entry_pc``. It also contains
|
|
``DW_TAG_variable`` DIEs that have a ``DW_OP_addr`` in the location (global and
|
|
static variables). All global and static variables should be included,
|
|
including those scoped within functions and classes. For example using the
|
|
following code:
|
|
|
|
.. code-block:: c
|
|
|
|
static int var = 0;
|
|
|
|
void f ()
|
|
{
|
|
static int var = 0;
|
|
}
|
|
|
|
Both of the static ``var`` variables would be included in the table. All
|
|
functions should emit both their full names and their basenames. For C or C++,
|
|
the full name is the mangled name (if available) which is usually in the
|
|
``DW_AT_MIPS_linkage_name`` attribute, and the ``DW_AT_name`` contains the
|
|
function basename. If global or static variables have a mangled name in a
|
|
``DW_AT_MIPS_linkage_name`` attribute, this should be emitted along with the
|
|
simple name found in the ``DW_AT_name`` attribute.
|
|
|
|
"``.apple_types``" sections should contain an entry for each DWARF DIE whose
|
|
tag is one of:
|
|
|
|
* DW_TAG_array_type
|
|
* DW_TAG_class_type
|
|
* DW_TAG_enumeration_type
|
|
* DW_TAG_pointer_type
|
|
* DW_TAG_reference_type
|
|
* DW_TAG_string_type
|
|
* DW_TAG_structure_type
|
|
* DW_TAG_subroutine_type
|
|
* DW_TAG_typedef
|
|
* DW_TAG_union_type
|
|
* DW_TAG_ptr_to_member_type
|
|
* DW_TAG_set_type
|
|
* DW_TAG_subrange_type
|
|
* DW_TAG_base_type
|
|
* DW_TAG_const_type
|
|
* DW_TAG_file_type
|
|
* DW_TAG_namelist
|
|
* DW_TAG_packed_type
|
|
* DW_TAG_volatile_type
|
|
* DW_TAG_restrict_type
|
|
* DW_TAG_atomic_type
|
|
* DW_TAG_interface_type
|
|
* DW_TAG_unspecified_type
|
|
* DW_TAG_shared_type
|
|
|
|
Only entries with a ``DW_AT_name`` attribute are included, and the entry must
|
|
not be a forward declaration (``DW_AT_declaration`` attribute with a non-zero
|
|
value). For example, using the following code:
|
|
|
|
.. code-block:: c
|
|
|
|
int main ()
|
|
{
|
|
int *b = 0;
|
|
return *b;
|
|
}
|
|
|
|
We get a few type DIEs:
|
|
|
|
.. code-block:: none
|
|
|
|
0x00000067: TAG_base_type [5]
|
|
AT_encoding( DW_ATE_signed )
|
|
AT_name( "int" )
|
|
AT_byte_size( 0x04 )
|
|
|
|
0x0000006e: TAG_pointer_type [6]
|
|
AT_type( {0x00000067} ( int ) )
|
|
AT_byte_size( 0x08 )
|
|
|
|
The DW_TAG_pointer_type is not included because it does not have a ``DW_AT_name``.
|
|
|
|
"``.apple_namespaces``" section should contain all ``DW_TAG_namespace`` DIEs.
|
|
If we run into a namespace that has no name this is an anonymous namespace, and
|
|
the name should be output as "``(anonymous namespace)``" (without the quotes).
|
|
Why? This matches the output of the ``abi::cxa_demangle()`` that is in the
|
|
standard C++ library that demangles mangled names.
|
|
|
|
|
|
Language Extensions and File Format Changes
|
|
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
|
|
|
Objective-C Extensions
|
|
""""""""""""""""""""""
|
|
|
|
"``.apple_objc``" section should contain all ``DW_TAG_subprogram`` DIEs for an
|
|
Objective-C class. The name used in the hash table is the name of the
|
|
Objective-C class itself. If the Objective-C class has a category, then an
|
|
entry is made for both the class name without the category, and for the class
|
|
name with the category. So if we have a DIE at offset 0x1234 with a name of
|
|
method "``-[NSString(my_additions) stringWithSpecialString:]``", we would add
|
|
an entry for "``NSString``" that points to DIE 0x1234, and an entry for
|
|
"``NSString(my_additions)``" that points to 0x1234. This allows us to quickly
|
|
track down all Objective-C methods for an Objective-C class when doing
|
|
expressions. It is needed because of the dynamic nature of Objective-C where
|
|
anyone can add methods to a class. The DWARF for Objective-C methods is also
|
|
emitted differently from C++ classes where the methods are not usually
|
|
contained in the class definition, they are scattered about across one or more
|
|
compile units. Categories can also be defined in different shared libraries.
|
|
So we need to be able to quickly find all of the methods and class functions
|
|
given the Objective-C class name, or quickly find all methods and class
|
|
functions for a class + category name. This table does not contain any
|
|
selector names, it just maps Objective-C class names (or class names +
|
|
category) to all of the methods and class functions. The selectors are added
|
|
as function basenames in the "``.debug_names``" section.
|
|
|
|
In the "``.apple_names``" section for Objective-C functions, the full name is
|
|
the entire function name with the brackets ("``-[NSString
|
|
stringWithCString:]``") and the basename is the selector only
|
|
("``stringWithCString:``").
|
|
|
|
Mach-O Changes
|
|
""""""""""""""
|
|
|
|
The sections names for the apple hash tables are for non-mach-o files. For
|
|
mach-o files, the sections should be contained in the ``__DWARF`` segment with
|
|
names as follows:
|
|
|
|
* "``.apple_names``" -> "``__apple_names``"
|
|
* "``.apple_types``" -> "``__apple_types``"
|
|
* "``.apple_namespaces``" -> "``__apple_namespac``" (16 character limit)
|
|
* "``.apple_objc``" -> "``__apple_objc``"
|
|
|
|
.. _codeview:
|
|
|
|
CodeView Debug Info Format
|
|
==========================
|
|
|
|
LLVM supports emitting CodeView, the Microsoft debug info format, and this
|
|
section describes the design and implementation of that support.
|
|
|
|
Format Background
|
|
-----------------
|
|
|
|
CodeView as a format is clearly oriented around C++ debugging, and in C++, the
|
|
majority of debug information tends to be type information. Therefore, the
|
|
overriding design constraint of CodeView is the separation of type information
|
|
from other "symbol" information so that type information can be efficiently
|
|
merged across translation units. Both type information and symbol information is
|
|
generally stored as a sequence of records, where each record begins with a
|
|
16-bit record size and a 16-bit record kind.
|
|
|
|
Type information is usually stored in the ``.debug$T`` section of the object
|
|
file. All other debug info, such as line info, string table, symbol info, and
|
|
inlinee info, is stored in one or more ``.debug$S`` sections. There may only be
|
|
one ``.debug$T`` section per object file, since all other debug info refers to
|
|
it. If a PDB (enabled by the ``/Zi`` MSVC option) was used during compilation,
|
|
the ``.debug$T`` section will contain only an ``LF_TYPESERVER2`` record pointing
|
|
to the PDB. When using PDBs, symbol information appears to remain in the object
|
|
file ``.debug$S`` sections.
|
|
|
|
Type records are referred to by their index, which is the number of records in
|
|
the stream before a given record plus ``0x1000``. Many common basic types, such
|
|
as the basic integral types and unqualified pointers to them, are represented
|
|
using type indices less than ``0x1000``. Such basic types are built in to
|
|
CodeView consumers and do not require type records.
|
|
|
|
Each type record may only contain type indices that are less than its own type
|
|
index. This ensures that the graph of type stream references is acyclic. While
|
|
the source-level type graph may contain cycles through pointer types (consider a
|
|
linked list struct), these cycles are removed from the type stream by always
|
|
referring to the forward declaration record of user-defined record types. Only
|
|
"symbol" records in the ``.debug$S`` streams may refer to complete,
|
|
non-forward-declaration type records.
|
|
|
|
Working with CodeView
|
|
---------------------
|
|
|
|
These are instructions for some common tasks for developers working to improve
|
|
LLVM's CodeView support. Most of them revolve around using the CodeView dumper
|
|
embedded in ``llvm-readobj``.
|
|
|
|
* Testing MSVC's output::
|
|
|
|
$ cl -c -Z7 foo.cpp # Use /Z7 to keep types in the object file
|
|
$ llvm-readobj --codeview foo.obj
|
|
|
|
* Getting LLVM IR debug info out of Clang::
|
|
|
|
$ clang -g -gcodeview --target=x86_64-windows-msvc foo.cpp -S -emit-llvm
|
|
|
|
Use this to generate LLVM IR for LLVM test cases.
|
|
|
|
* Generate and dump CodeView from LLVM IR metadata::
|
|
|
|
$ llc foo.ll -filetype=obj -o foo.obj
|
|
$ llvm-readobj --codeview foo.obj > foo.txt
|
|
|
|
Use this pattern in lit test cases and FileCheck the output of llvm-readobj
|
|
|
|
Improving LLVM's CodeView support is a process of finding interesting type
|
|
records, constructing a C++ test case that makes MSVC emit those records,
|
|
dumping the records, understanding them, and then generating equivalent records
|
|
in LLVM's backend.
|
|
|
|
Testing Debug Info Preservation in Optimizations
|
|
================================================
|
|
|
|
The following paragraphs are an introduction to the debugify utility
|
|
and examples of how to use it in regression tests to check debug info
|
|
preservation after optimizations.
|
|
|
|
The ``debugify`` utility
|
|
------------------------
|
|
|
|
The ``debugify`` synthetic debug info testing utility consists of two
|
|
main parts. The ``debugify`` pass and the ``check-debugify`` one. They are
|
|
meant to be used with ``opt`` for development purposes.
|
|
|
|
The first applies synthetic debug information to every instruction of the module,
|
|
while the latter checks that this DI is still available after an optimization
|
|
has occurred, reporting any errors/warnings while doing so.
|
|
|
|
The instructions are assigned sequentially increasing line locations,
|
|
and are immediately used by debug value intrinsics when possible.
|
|
|
|
For example, here is a module before:
|
|
|
|
.. code-block:: llvm
|
|
|
|
define void @f(i32* %x) {
|
|
entry:
|
|
%x.addr = alloca i32*, align 8
|
|
store i32* %x, i32** %x.addr, align 8
|
|
%0 = load i32*, i32** %x.addr, align 8
|
|
store i32 10, i32* %0, align 4
|
|
ret void
|
|
}
|
|
|
|
and after running ``opt -debugify`` on it we get:
|
|
|
|
.. code-block:: text
|
|
|
|
define void @f(i32* %x) !dbg !6 {
|
|
entry:
|
|
%x.addr = alloca i32*, align 8, !dbg !12
|
|
call void @llvm.dbg.value(metadata i32** %x.addr, metadata !9, metadata !DIExpression()), !dbg !12
|
|
store i32* %x, i32** %x.addr, align 8, !dbg !13
|
|
%0 = load i32*, i32** %x.addr, align 8, !dbg !14
|
|
call void @llvm.dbg.value(metadata i32* %0, metadata !11, metadata !DIExpression()), !dbg !14
|
|
store i32 10, i32* %0, align 4, !dbg !15
|
|
ret void, !dbg !16
|
|
}
|
|
|
|
!llvm.dbg.cu = !{!0}
|
|
!llvm.debugify = !{!3, !4}
|
|
!llvm.module.flags = !{!5}
|
|
|
|
!0 = distinct !DICompileUnit(language: DW_LANG_C, file: !1, producer: "debugify", isOptimized: true, runtimeVersion: 0, emissionKind: FullDebug, enums: !2)
|
|
!1 = !DIFile(filename: "debugify-sample.ll", directory: "/")
|
|
!2 = !{}
|
|
!3 = !{i32 5}
|
|
!4 = !{i32 2}
|
|
!5 = !{i32 2, !"Debug Info Version", i32 3}
|
|
!6 = distinct !DISubprogram(name: "f", linkageName: "f", scope: null, file: !1, line: 1, type: !7, isLocal: false, isDefinition: true, scopeLine: 1, isOptimized: true, unit: !0, retainedNodes: !8)
|
|
!7 = !DISubroutineType(types: !2)
|
|
!8 = !{!9, !11}
|
|
!9 = !DILocalVariable(name: "1", scope: !6, file: !1, line: 1, type: !10)
|
|
!10 = !DIBasicType(name: "ty64", size: 64, encoding: DW_ATE_unsigned)
|
|
!11 = !DILocalVariable(name: "2", scope: !6, file: !1, line: 3, type: !10)
|
|
!12 = !DILocation(line: 1, column: 1, scope: !6)
|
|
!13 = !DILocation(line: 2, column: 1, scope: !6)
|
|
!14 = !DILocation(line: 3, column: 1, scope: !6)
|
|
!15 = !DILocation(line: 4, column: 1, scope: !6)
|
|
!16 = !DILocation(line: 5, column: 1, scope: !6)
|
|
|
|
The following is an example of the -check-debugify output:
|
|
|
|
.. code-block:: none
|
|
|
|
$ opt -enable-debugify -loop-vectorize llvm/test/Transforms/LoopVectorize/i8-induction.ll -disable-output
|
|
ERROR: Instruction with empty DebugLoc in function f -- %index = phi i32 [ 0, %vector.ph ], [ %index.next, %vector.body ]
|
|
|
|
Errors/warnings can range from instructions with empty debug location to an
|
|
instruction having a type that's incompatible with the source variable it describes,
|
|
all the way to missing lines and missing debug value intrinsics.
|
|
|
|
Fixing errors
|
|
^^^^^^^^^^^^^
|
|
|
|
Each of the errors above has a relevant API available to fix it.
|
|
|
|
* In the case of missing debug location, ``Instruction::setDebugLoc`` or possibly
|
|
``IRBuilder::setCurrentDebugLocation`` when using a Builder and the new location
|
|
should be reused.
|
|
|
|
* When a debug value has incompatible type ``llvm::replaceAllDbgUsesWith`` can be used.
|
|
After a RAUW call an incompatible type error can occur because RAUW does not handle
|
|
widening and narrowing of variables while ``llvm::replaceAllDbgUsesWith`` does. It is
|
|
also capable of changing the DWARF expression used by the debugger to describe the variable.
|
|
It also prevents use-before-def by salvaging or deleting invalid debug values.
|
|
|
|
* When a debug value is missing ``llvm::salvageDebugInfo`` can be used when no replacement
|
|
exists, or ``llvm::replaceAllDbgUsesWith`` when a replacement exists.
|
|
|
|
Using ``debugify``
|
|
------------------
|
|
|
|
In order for ``check-debugify`` to work, the DI must be coming from
|
|
``debugify``. Thus, modules with existing DI will be skipped.
|
|
|
|
The most straightforward way to use ``debugify`` is as follows::
|
|
|
|
$ opt -debugify -pass-to-test -check-debugify sample.ll
|
|
|
|
This will inject synthetic DI to ``sample.ll`` run the ``pass-to-test``
|
|
and then check for missing DI.
|
|
|
|
Some other ways to run debugify are avaliable:
|
|
|
|
.. code-block:: bash
|
|
|
|
# Same as the above example.
|
|
$ opt -enable-debugify -pass-to-test sample.ll
|
|
|
|
# Suppresses verbose debugify output.
|
|
$ opt -enable-debugify -debugify-quiet -pass-to-test sample.ll
|
|
|
|
# Prepend -debugify before and append -check-debugify -strip after
|
|
# each pass on the pipeline (similar to -verify-each).
|
|
$ opt -debugify-each -O2 sample.ll
|
|
|
|
``debugify`` can also be used to test a backend, e.g:
|
|
|
|
.. code-block:: bash
|
|
|
|
$ opt -debugify < sample.ll | llc -o -
|
|
|
|
``debugify`` in regression tests
|
|
^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
|
|
|
|
The ``-debugify`` pass is especially helpful when it comes to testing that
|
|
a given pass preserves DI while transforming the module. For this to work,
|
|
the ``-debugify`` output must be stable enough to use in regression tests.
|
|
Changes to this pass are not allowed to break existing tests.
|
|
|
|
It allows us to test for DI loss in the same tests we check that the
|
|
transformation is actually doing what it should.
|
|
|
|
Here is an example from ``test/Transforms/InstCombine/cast-mul-select.ll``:
|
|
|
|
.. code-block:: llvm
|
|
|
|
; RUN: opt < %s -debugify -instcombine -S | FileCheck %s --check-prefix=DEBUGINFO
|
|
|
|
define i32 @mul(i32 %x, i32 %y) {
|
|
; DBGINFO-LABEL: @mul(
|
|
; DBGINFO-NEXT: [[C:%.*]] = mul i32 {{.*}}
|
|
; DBGINFO-NEXT: call void @llvm.dbg.value(metadata i32 [[C]]
|
|
; DBGINFO-NEXT: [[D:%.*]] = and i32 {{.*}}
|
|
; DBGINFO-NEXT: call void @llvm.dbg.value(metadata i32 [[D]]
|
|
|
|
%A = trunc i32 %x to i8
|
|
%B = trunc i32 %y to i8
|
|
%C = mul i8 %A, %B
|
|
%D = zext i8 %C to i32
|
|
ret i32 %D
|
|
}
|
|
|
|
Here we test that the two ``dbg.value`` instrinsics are preserved and
|
|
are correctly pointing to the ``[[C]]`` and ``[[D]]`` variables.
|
|
|
|
.. note::
|
|
|
|
Note, that when writing this kind of regression tests, it is important
|
|
to make them as robust as possible. That's why we should try to avoid
|
|
hardcoding line/variable numbers in check lines. If for example you test
|
|
for a ``DILocation`` to have a specific line number, and someone later adds
|
|
an instruction before the one we check the test will fail. In the cases this
|
|
can't be avoided (say, if a test wouldn't be precise enough), moving the
|
|
test to its own file is preferred.
|