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By using the original-di check with debugify in the combination with the llvm/utils/llvm-original-di-preservation.py it becomes very user friendly tool. An example of the HTML page with the issues related to debug info can be found at [0]. [0] https://djolertrk.github.io/di-checker-html-report-example/ Differential Revision: https://reviews.llvm.org/D82546
482 lines
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ReStructuredText
482 lines
18 KiB
ReStructuredText
=======================================================
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How to Update Debug Info: A Guide for LLVM Pass Authors
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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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Certain kinds of code transformations can inadvertently result in a loss of
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debug info, or worse, make debug info misrepresent the state of a program.
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This document specifies how to correctly update debug info in various kinds of
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code transformations, and offers suggestions for how to create targeted debug
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info tests for arbitrary transformations.
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For more on the philosophy behind LLVM debugging information, see
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:doc:`SourceLevelDebugging`.
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Rules for updating debug locations
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==================================
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.. _WhenToPreserveLocation:
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When to preserve an instruction location
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----------------------------------------
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A transformation should preserve the debug location of an instruction if the
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instruction either remains in its basic block, or if its basic block is folded
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into a predecessor that branches unconditionally. The APIs to use are
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``IRBuilder``, or ``Instruction::setDebugLoc``.
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The purpose of this rule is to ensure that common block-local optimizations
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preserve the ability to set breakpoints on source locations corresponding to
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the instructions they touch. Debugging, crash logs, and SamplePGO accuracy
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would be severely impacted if that ability were lost.
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Examples of transformations that should follow this rule include:
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* Instruction scheduling. Block-local instruction reordering should not drop
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source locations, even though this may lead to jumpy single-stepping
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behavior.
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* Simple jump threading. For example, if block ``B1`` unconditionally jumps to
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``B2``, *and* is its unique predecessor, instructions from ``B2`` can be
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hoisted into ``B1``. Source locations from ``B2`` should be preserved.
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* Peephole optimizations that replace or expand an instruction, like ``(add X
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X) => (shl X 1)``. The location of the ``shl`` instruction should be the same
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as the location of the ``add`` instruction.
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* Tail duplication. For example, if blocks ``B1`` and ``B2`` both
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unconditionally branch to ``B3`` and ``B3`` can be folded into its
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predecessors, source locations from ``B3`` should be preserved.
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Examples of transformations for which this rule *does not* apply include:
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* LICM. E.g., if an instruction is moved from the loop body to the preheader,
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the rule for :ref:`dropping locations<WhenToDropLocation>` applies.
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In addition to the rule above, a transformation should also preserve the debug
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location of an instruction that is moved between basic blocks, if the
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destination block already contains an instruction with an identical debug
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location.
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Examples of transformations that should follow this rule include:
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* Moving instructions between basic blocks. For example, if instruction ``I1``
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in ``BB1`` is moved before ``I2`` in ``BB2``, the source location of ``I1``
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can be preserved if it has the same source location as ``I2``.
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.. _WhenToMergeLocation:
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When to merge instruction locations
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-----------------------------------
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A transformation should merge instruction locations if it replaces multiple
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instructions with a single merged instruction, *and* that merged instruction
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does not correspond to any of the original instructions' locations. The API to
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use is ``Instruction::applyMergedLocation``.
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The purpose of this rule is to ensure that a) the single merged instruction
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has a location with an accurate scope attached, and b) to prevent misleading
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single-stepping (or breakpoint) behavior. Often, merged instructions are memory
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accesses which can trap: having an accurate scope attached greatly assists in
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crash triage by identifying the (possibly inlined) function where the bad
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memory access occurred. This rule is also meant to assist SamplePGO by banning
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scenarios in which a sample of a block containing a merged instruction is
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misattributed to a block containing one of the instructions-to-be-merged.
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Examples of transformations that should follow this rule include:
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* Merging identical loads/stores which occur on both sides of a CFG diamond
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(see the ``MergedLoadStoreMotion`` pass).
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* Merging identical loop-invariant stores (see the LICM utility
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``llvm::promoteLoopAccessesToScalars``).
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* Peephole optimizations which combine multiple instructions together, like
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``(add (mul A B) C) => llvm.fma.f32(A, B, C)``. Note that the location of
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the ``fma`` does not exactly correspond to the locations of either the
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``mul`` or the ``add`` instructions.
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Examples of transformations for which this rule *does not* apply include:
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* Block-local peepholes which delete redundant instructions, like
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``(sext (zext i8 %x to i16) to i32) => (zext i8 %x to i32)``. The inner
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``zext`` is modified but remains in its block, so the rule for
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:ref:`preserving locations<WhenToPreserveLocation>` should apply.
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* Converting an if-then-else CFG diamond into a ``select``. Preserving the
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debug locations of speculated instructions can make it seem like a condition
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is true when it's not (or vice versa), which leads to a confusing
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single-stepping experience. The rule for
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:ref:`dropping locations<WhenToDropLocation>` should apply here.
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* Hoisting identical instructions which appear in several successor blocks into
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a predecessor block (see ``BranchFolder::HoistCommonCodeInSuccs``). In this
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case there is no single merged instruction. The rule for
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:ref:`dropping locations<WhenToDropLocation>` applies.
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.. _WhenToDropLocation:
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When to drop an instruction location
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------------------------------------
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A transformation should drop debug locations if the rules for
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:ref:`preserving<WhenToPreserveLocation>` and
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:ref:`merging<WhenToMergeLocation>` debug locations do not apply. The API to
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use is ``Instruction::dropLocation()``.
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The purpose of this rule is to prevent erratic or misleading single-stepping
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behavior in situations in which an instruction has no clear, unambiguous
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relationship to a source location.
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To handle an instruction without a location, the DWARF generator
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defaults to allowing the last-set location after a label to cascade forward, or
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to setting a line 0 location with viable scope information if no previous
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location is available.
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See the discussion in the section about
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:ref:`merging locations<WhenToMergeLocation>` for examples of when the rule for
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dropping locations applies.
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Rules for updating debug values
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===============================
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Deleting an IR-level Instruction
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--------------------------------
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When an ``Instruction`` is deleted, its debug uses change to ``undef``. This is
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a loss of debug info: the value of one or more source variables becomes
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unavailable, starting with the ``llvm.dbg.value(undef, ...)``. When there is no
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way to reconstitute the value of the lost instruction, this is the best
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possible outcome. However, it's often possible to do better:
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* If the dying instruction can be RAUW'd, do so. The
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``Value::replaceAllUsesWith`` API transparently updates debug uses of the
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dying instruction to point to the replacement value.
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* If the dying instruction cannot be RAUW'd, call ``llvm::salvageDebugInfo`` on
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it. This makes a best-effort attempt to rewrite debug uses of the dying
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instruction by describing its effect as a ``DIExpression``.
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* If one of the **operands** of a dying instruction would become trivially
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dead, use ``llvm::replaceAllDbgUsesWith`` to rewrite the debug uses of that
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operand. Consider the following example function:
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.. code-block:: llvm
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define i16 @foo(i16 %a) {
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%b = sext i16 %a to i32
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%c = and i32 %b, 15
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call void @llvm.dbg.value(metadata i32 %c, ...)
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%d = trunc i32 %c to i16
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ret i16 %d
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}
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Now, here's what happens after the unnecessary truncation instruction ``%d`` is
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replaced with a simplified instruction:
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.. code-block:: llvm
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define i16 @foo(i16 %a) {
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call void @llvm.dbg.value(metadata i32 undef, ...)
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%simplified = and i16 %a, 15
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ret i16 %simplified
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}
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Note that after deleting ``%d``, all uses of its operand ``%c`` become
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trivially dead. The debug use which used to point to ``%c`` is now ``undef``,
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and debug info is needlessly lost.
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To solve this problem, do:
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.. code-block:: cpp
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llvm::replaceAllDbgUsesWith(%c, theSimplifiedAndInstruction, ...)
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This results in better debug info because the debug use of ``%c`` is preserved:
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.. code-block:: llvm
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define i16 @foo(i16 %a) {
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%simplified = and i16 %a, 15
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call void @llvm.dbg.value(metadata i16 %simplified, ...)
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ret i16 %simplified
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}
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You may have noticed that ``%simplified`` is narrower than ``%c``: this is not
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a problem, because ``llvm::replaceAllDbgUsesWith`` takes care of inserting the
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necessary conversion operations into the DIExpressions of updated debug uses.
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Deleting a MIR-level MachineInstr
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---------------------------------
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TODO
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How to automatically convert tests into debug info tests
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========================================================
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.. _IRDebugify:
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Mutation testing for IR-level transformations
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---------------------------------------------
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An IR test case for a transformation can, in many cases, be automatically
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mutated to test debug info handling within that transformation. This is a
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simple way to test for proper debug info handling.
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The ``debugify`` utility pass
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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The ``debugify`` testing utility is just a pair of passes: ``debugify`` and
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``check-debugify``.
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The first applies synthetic debug information to every instruction of the
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module, and the second checks that this DI is still available after an
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optimization has occurred, reporting any errors/warnings while doing so.
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The instructions are assigned sequentially increasing line locations, and are
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immediately used by debug value intrinsics everywhere possible.
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For example, here is a module before:
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.. code-block:: llvm
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define void @f(i32* %x) {
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entry:
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%x.addr = alloca i32*, align 8
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store i32* %x, i32** %x.addr, align 8
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%0 = load i32*, i32** %x.addr, align 8
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store i32 10, i32* %0, align 4
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ret void
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}
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and after running ``opt -debugify``:
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.. code-block:: llvm
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define void @f(i32* %x) !dbg !6 {
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entry:
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%x.addr = alloca i32*, align 8, !dbg !12
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call void @llvm.dbg.value(metadata i32** %x.addr, metadata !9, metadata !DIExpression()), !dbg !12
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store i32* %x, i32** %x.addr, align 8, !dbg !13
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%0 = load i32*, i32** %x.addr, align 8, !dbg !14
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call void @llvm.dbg.value(metadata i32* %0, metadata !11, metadata !DIExpression()), !dbg !14
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store i32 10, i32* %0, align 4, !dbg !15
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ret void, !dbg !16
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}
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!llvm.dbg.cu = !{!0}
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!llvm.debugify = !{!3, !4}
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!llvm.module.flags = !{!5}
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!0 = distinct !DICompileUnit(language: DW_LANG_C, file: !1, producer: "debugify", isOptimized: true, runtimeVersion: 0, emissionKind: FullDebug, enums: !2)
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!1 = !DIFile(filename: "debugify-sample.ll", directory: "/")
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!2 = !{}
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!3 = !{i32 5}
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!4 = !{i32 2}
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!5 = !{i32 2, !"Debug Info Version", i32 3}
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!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)
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!7 = !DISubroutineType(types: !2)
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!8 = !{!9, !11}
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!9 = !DILocalVariable(name: "1", scope: !6, file: !1, line: 1, type: !10)
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!10 = !DIBasicType(name: "ty64", size: 64, encoding: DW_ATE_unsigned)
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!11 = !DILocalVariable(name: "2", scope: !6, file: !1, line: 3, type: !10)
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!12 = !DILocation(line: 1, column: 1, scope: !6)
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!13 = !DILocation(line: 2, column: 1, scope: !6)
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!14 = !DILocation(line: 3, column: 1, scope: !6)
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!15 = !DILocation(line: 4, column: 1, scope: !6)
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!16 = !DILocation(line: 5, column: 1, scope: !6)
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Using ``debugify``
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^^^^^^^^^^^^^^^^^^
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A simple way to use ``debugify`` is as follows:
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.. code-block:: bash
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$ opt -debugify -pass-to-test -check-debugify sample.ll
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This will inject synthetic DI to ``sample.ll`` run the ``pass-to-test`` and
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then check for missing DI. The ``-check-debugify`` step can of course be
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omitted in favor of more customizable FileCheck directives.
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Some other ways to run debugify are available:
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.. code-block:: bash
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# Same as the above example.
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$ opt -enable-debugify -pass-to-test sample.ll
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# Suppresses verbose debugify output.
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$ opt -enable-debugify -debugify-quiet -pass-to-test sample.ll
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# Prepend -debugify before and append -check-debugify -strip after
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# each pass on the pipeline (similar to -verify-each).
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$ opt -debugify-each -O2 sample.ll
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In order for ``check-debugify`` to work, the DI must be coming from
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``debugify``. Thus, modules with existing DI will be skipped.
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``debugify`` can be used to test a backend, e.g:
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.. code-block:: bash
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$ opt -debugify < sample.ll | llc -o -
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There is also a MIR-level debugify pass that can be run before each backend
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pass, see:
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:ref:`Mutation testing for MIR-level transformations<MIRDebugify>`.
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``debugify`` in regression tests
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^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^
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The output of the ``debugify`` pass must be stable enough to use in regression
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tests. Changes to this pass are not allowed to break existing tests.
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.. note::
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Regression tests must be robust. Avoid hardcoding line/variable numbers in
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check lines. In cases where this can't be avoided (say, if a test wouldn't
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be precise enough), moving the test to its own file is preferred.
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.. _MIRDebugify:
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Test original debug info preservation in optimizations
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------------------------------------------------------
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In addition to automatically generating debug info, the checks provided by
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the ``debugify`` utility pass can also be used to test the preservation of
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pre-existing debug info metadata. It could be run as follows:
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.. code-block:: bash
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# Run the pass by checking original Debug Info preservation.
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$ opt -verify-debuginfo-preserve -pass-to-test sample.ll
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# Check the preservation of original Debug Info after each pass.
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$ opt -verify-each-debuginfo-preserve -O2 sample.ll
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Furthermore, there is a way to export the issues that have been found into
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a JSON file as follows:
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.. code-block:: bash
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$ opt -verify-debuginfo-preserve -verify-di-preserve-export=sample.json -pass-to-test sample.ll
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and then use the ``llvm/utils/llvm-original-di-preservation.py`` script
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to generate an HTML page with the issues reported in a more human readable form
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as follows:
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.. code-block:: bash
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$ llvm-original-di-preservation.py sample.json sample.html
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Mutation testing for MIR-level transformations
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----------------------------------------------
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A variant of the ``debugify`` utility described in
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:ref:`Mutation testing for IR-level transformations<IRDebugify>` can be used
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for MIR-level transformations as well: much like the IR-level pass,
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``mir-debugify`` inserts sequentially increasing line locations to each
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``MachineInstr`` in a ``Module``. And the MIR-level ``mir-check-debugify`` is
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similar to IR-level ``check-debugify`` pass.
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For example, here is a snippet before:
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.. code-block:: llvm
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name: test
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body: |
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bb.1 (%ir-block.0):
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%0:_(s32) = IMPLICIT_DEF
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%1:_(s32) = IMPLICIT_DEF
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%2:_(s32) = G_CONSTANT i32 2
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%3:_(s32) = G_ADD %0, %2
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%4:_(s32) = G_SUB %3, %1
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and after running ``llc -run-pass=mir-debugify``:
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.. code-block:: llvm
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name: test
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body: |
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bb.0 (%ir-block.0):
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%0:_(s32) = IMPLICIT_DEF debug-location !12
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DBG_VALUE %0(s32), $noreg, !9, !DIExpression(), debug-location !12
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%1:_(s32) = IMPLICIT_DEF debug-location !13
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DBG_VALUE %1(s32), $noreg, !11, !DIExpression(), debug-location !13
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%2:_(s32) = G_CONSTANT i32 2, debug-location !14
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DBG_VALUE %2(s32), $noreg, !9, !DIExpression(), debug-location !14
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%3:_(s32) = G_ADD %0, %2, debug-location !DILocation(line: 4, column: 1, scope: !6)
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DBG_VALUE %3(s32), $noreg, !9, !DIExpression(), debug-location !DILocation(line: 4, column: 1, scope: !6)
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%4:_(s32) = G_SUB %3, %1, debug-location !DILocation(line: 5, column: 1, scope: !6)
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DBG_VALUE %4(s32), $noreg, !9, !DIExpression(), debug-location !DILocation(line: 5, column: 1, scope: !6)
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By default, ``mir-debugify`` inserts ``DBG_VALUE`` instructions **everywhere**
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it is legal to do so. In particular, every (non-PHI) machine instruction that
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defines a register must be followed by a ``DBG_VALUE`` use of that def. If
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an instruction does not define a register, but can be followed by a debug inst,
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MIRDebugify inserts a ``DBG_VALUE`` that references a constant. Insertion of
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``DBG_VALUE``'s can be disabled by setting ``-debugify-level=locations``.
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To run MIRDebugify once, simply insert ``mir-debugify`` into your ``llc``
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invocation, like:
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.. code-block:: bash
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# Before some other pass.
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$ llc -run-pass=mir-debugify,other-pass ...
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# After some other pass.
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$ llc -run-pass=other-pass,mir-debugify ...
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To run MIRDebugify before each pass in a pipeline, use
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``-debugify-and-strip-all-safe``. This can be combined with ``-start-before``
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and ``-start-after``. For example:
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.. code-block:: bash
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$ llc -debugify-and-strip-all-safe -run-pass=... <other llc args>
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$ llc -debugify-and-strip-all-safe -O1 <other llc args>
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If you want to check it after each pass in a pipeline, use
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``-debugify-check-and-strip-all-safe``. This can also be combined with
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``-start-before`` and ``-start-after``. For example:
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.. code-block:: bash
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$ llc -debugify-check-and-strip-all-safe -run-pass=... <other llc args>
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$ llc -debugify-check-and-strip-all-safe -O1 <other llc args>
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To check all debug info from a test, use ``mir-check-debugify``, like:
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.. code-block:: bash
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$ llc -run-pass=mir-debugify,other-pass,mir-check-debugify
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To strip out all debug info from a test, use ``mir-strip-debug``, like:
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.. code-block:: bash
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$ llc -run-pass=mir-debugify,other-pass,mir-strip-debug
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It can be useful to combine ``mir-debugify``, ``mir-check-debugify`` and/or
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``mir-strip-debug`` to identify backend transformations which break in
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the presence of debug info. For example, to run the AArch64 backend tests
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with all normal passes "sandwiched" in between MIRDebugify and
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MIRStripDebugify mutation passes, run:
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.. code-block:: bash
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$ llvm-lit test/CodeGen/AArch64 -Dllc="llc -debugify-and-strip-all-safe"
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Using LostDebugLocObserver
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--------------------------
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TODO
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