[TOC]
Passes represent the basic infrastructure for transformation and optimization. This document provides a quickstart to the pass infrastructure in MLIR and how to use it.
See MLIR specification for more information about MLIR and its core aspects, such as the IR structure and operations.
See MLIR Rewrites for a quick start on graph rewriting in MLIR. If your transformation involves pattern matching operation DAGs, this is a great place to start.
In MLIR, the main unit of abstraction and transformation is an
operation. As such, the pass manager is designed to
work on instances of operations at different levels of nesting. The structure of
the pass manager, and the concept of nesting, is detailed
further below. All passes in MLIR derive from OperationPass
and adhere to the
following restrictions; any noncompliance will lead to problematic behavior in
multithreaded and other advanced scenarios:
- Modify anything within the parent block/region/operation/etc, outside of the current operation being operated on. This includes adding or removing operations from the parent block.
- Maintain pass state across invocations of
runOnOperation
. A pass may be run on several different operations with no guarantee of execution order.- When multithreading, a specific pass instance may not even execute on all operations within the module. As such, a pass should not rely on running on all operations.
- Modify the state of another operation not nested within the current
operation being operated on.
- Other threads may be operating on different operations within the module simultaneously.
- Maintain any global mutable state, e.g. static variables within the source file. All mutable state should be maintained by an instance of the pass.
- Must be copy-constructible, multiple instances of the pass may be created by the pass manager to process operations in parallel.
- Inspect the IR of sibling operations. Other threads may be modifying these operations in parallel.
When creating an operation pass, there are two different types to choose from depending on the usage scenario:
An op-specific
operation pass operates explicitly on a given operation type.
This operation type must adhere to the restrictions set by the pass manager for
pass execution.
To define an op-specific operation pass, a derived class must adhere to the following:
- Inherit from the CRTP class
OperationPass
and provide the operation type as an additional template parameter. - Override the virtual
void runOnOperation()
method.
A simple pass may look like:
namespace {
struct MyFunctionPass : public OperationPass<MyFunctionPass, FuncOp> {
void runOnOperation() override {
// Get the current FuncOp operation being operated on.
FuncOp f = getOperation();
// Walk the operations within the function.
f.walk([](Operation *inst) {
....
});
}
};
} // end anonymous namespace
// Register this pass to make it accessible to utilities like mlir-opt.
// (Pass registration is discussed more below)
static PassRegistration<MyFunctionPass> pass(
"flag-name-to-invoke-pass-via-mlir-opt", "Pass description here");
An op-agnostic
pass operates on the operation type of the pass manager that it
is added to. This means that a pass that operates on several different operation
types in the same way only needs one implementation.
To create an operation pass, a derived class must adhere to the following:
- Inherit from the CRTP class
OperationPass
. - Override the virtual
void runOnOperation()
method.
A simple pass may look like:
struct MyOperationPass : public OperationPass<MyOperationPass> {
void runOnOperation() override {
// Get the current operation being operated on.
Operation *op = getOperation();
...
}
};
An important concept, along with transformation passes, are analyses. These are conceptually similar to transformation passes, except that they compute information on a specific operation without modifying it. In MLIR, analyses are not passes but free-standing classes that are computed lazily on-demand and cached to avoid unnecessary recomputation. An analysis in MLIR must adhere to the following:
- Provide a valid constructor taking an
Operation*
. - Must not modify the given operation.
An analysis may provide additional hooks to control various behavior:
bool isInvalidated(const AnalysisManager::PreservedAnalyses &)
Given a preserved analysis set, the analysis returns true if it should truly be invalidated. This allows for more fine-tuned invalidation in cases where an analysis wasn't explicitly marked preserved, but may be preserved (or invalidated) based upon other properties such as analyses sets.
The base OperationPass
class provide utilities for querying and preserving
analyses for the current operation being processed.
- OperationPass automatically provides the following utilities for querying
analyses:
getAnalysis<>
- Get an analysis for the current operation, constructing it if necessary.
getCachedAnalysis<>
- Get an analysis for the current operation, if it already exists.
getCachedParentAnalysis<>
- Get an analysis for a given parent operation, if it exists.
getCachedChildAnalysis<>
- Get an analysis for a given child operation, if it exists.
getChildAnalysis<>
- Get an analysis for a given child operation, constructing it if necessary.
Using the example passes defined above, let's see some examples:
/// An interesting analysis.
struct MyOperationAnalysis {
// Compute this analysis with the provided operation.
MyOperationAnalysis(Operation *op);
};
void MyOperationPass::runOnOperation() {
// Query MyOperationAnalysis for the current operation.
MyOperationAnalysis &myAnalysis = getAnalysis<MyOperationAnalysis>();
// Query a cached instance of MyOperationAnalysis for the current operation.
// It will not be computed if it doesn't exist.
auto optionalAnalysis = getCachedAnalysis<MyOperationAnalysis>();
if (optionalAnalysis)
...
// Query a cached instance of MyOperationAnalysis for the parent operation of
// the current operation. It will not be computed if it doesn't exist.
auto optionalAnalysis = getCachedParentAnalysis<MyOperationAnalysis>();
if (optionalAnalysis)
...
}
Analyses that are constructed after being queried by a pass are cached to avoid unnecessary computation if they are requested again later. To avoid stale analyses, all analyses are assumed to be invalidated by a pass. To avoid invalidation, a pass must specifically mark analyses that are known to be preserved.
- All Pass classes automatically provide the following utilities for
preserving analyses:
markAllAnalysesPreserved
markAnalysesPreserved<>
void MyOperationPass::runOnOperation() {
// Mark all analyses as preserved. This is useful if a pass can guarantee
// that no transformation was performed.
markAllAnalysesPreserved();
// Mark specific analyses as preserved. This is used if some transformation
// was performed, but some analyses were either unaffected or explicitly
// preserved.
markAnalysesPreserved<MyAnalysis, MyAnalyses...>();
}
Passes in MLIR are allowed to gracefully fail. This may happen if some invariant
of the pass was broken, potentially leaving the IR in some invalid state. If
such a situation occurs, the pass can directly signal a failure to the pass
manager. If a pass signaled a failure when executing, no other passes in the
pipeline will execute and the PassManager::run
will return failure. Failure
signaling is provided in the form of a signalPassFailure
method.
void MyPass::runOnOperation() {
// Signal failure on a broken invariant.
if (some_broken_invariant) {
signalPassFailure();
return;
}
}
Above we introduced the different types of passes and their constraints. Now
that we have our pass we need to be able to run it over a specific module. This
is where the pass manager comes into play. The PassManager
class is used to
configure and run a pipeline. The OpPassManager
class is used to schedule
passes to run at a specific level of nesting.
An OpPassManager
is essentially a collection of passes to execute on an
operation of a given type. This operation type must adhere to the following
requirement:
-
Must be registered and marked
IsolatedFromAbove
.- Passes are expected to not modify operations at or above the current operation being processed. If the operation is not isolated, it may inadvertently modify the use-list of an operation it is not supposed to modify.
Passes can be added to a pass manager via addPass
. The pass must either be an
op-specific
pass operating on the same operation type as OpPassManager
, or
an op-agnostic
pass.
An OpPassManager
cannot be created directly, but must be explicitly nested
within another OpPassManager
via the nest<>
method. This method takes the
operation type that the nested pass manager will operate on. At the top-level, a
PassManager
acts as an OpPassManager
that operates on the
module
operation. Nesting in this sense, corresponds to
the structural nesting within Regions of the IR.
For example, the following .mlir
:
module {
spv.module "Logical" "GLSL450" {
func @foo() {
...
}
}
}
Has the nesting structure of:
`module`
`spv.module`
`function`
Below is an example of constructing a pipeline that operates on the above structure:
PassManager pm(ctx);
// Add a pass on the top-level module operation.
pm.addPass(std::make_unique<MyModulePass>());
// Nest a pass manager that operates on spirv module operations nested directly
// under the top-level module.
OpPassManager &nestedModulePM = pm.nest<spirv::ModuleOp>();
nestedModulePM.addPass(std::make_unique<MySPIRVModulePass>());
// Nest a pass manager that operates on functions within the nested SPIRV
// module.
OpPassManager &nestedFunctionPM = nestedModulePM.nest<FuncOp>();
nestedFunctionPM.addPass(std::make_unique<MyFunctionPass>());
// Run the pass manager on the top-level module.
Module m = ...;
if (failed(pm.run(m)))
... // One of the passes signaled a failure.
The above pass manager would contain the following pipeline structure:
OpPassManager<ModuleOp>
MyModulePass
OpPassManager<spirv::ModuleOp>
MySPIRVModulePass
OpPassManager<FuncOp>
MyFunctionPass
These pipelines are then run over a single operation at a time. This means that, for example, given a series of consecutive passes on FuncOp, it will execute all on the first function, then all on the second function, etc. until the entire program has been run through the passes. This provides several benefits:
- This improves the cache behavior of the compiler, because it is only touching a single function at a time, instead of traversing the entire program.
- This improves multi-threading performance by reducing the number of jobs that need to be scheduled, as well as increasing the efficiency of each job. An entire function pipeline can be run on each function asynchronously.
Briefly shown in the example definitions of the various pass types is the
PassRegistration
class. This is a utility to register derived pass classes so
that they may be created, and inspected, by utilities like mlir-opt. Registering
a pass class takes the form:
static PassRegistration<MyPass> pass("command-line-arg", "description");
MyPass
is the name of the derived pass class.- "command-line-arg" is the argument to use on the command line to invoke the
pass from
mlir-opt
. - "description" is a description of the pass.
For passes that cannot be default-constructed, PassRegistration
accepts an
optional third argument that takes a callback to create the pass:
static PassRegistration<MyParametricPass> pass(
"command-line-arg", "description",
[]() -> std::unique_ptr<Pass> {
std::unique_ptr<Pass> p = std::make_unique<MyParametricPass>(/*options*/);
/*... non-trivial-logic to configure the pass ...*/;
return p;
});
This variant of registration can be used, for example, to accept the configuration of a pass from command-line arguments and pass it over to the pass constructor. Make sure that the pass is copy-constructible in a way that does not share data as the pass manager may create copies of the pass to run in parallel.
Described above is the mechanism used for registering a specific derived pass
class. On top of that, MLIR allows for registering custom pass pipelines in a
similar fashion. This allows for custom pipelines to be available to tools like
mlir-opt in the same way that passes are, which is useful for encapsulating
common pipelines like the "-O1" series of passes. Pipelines are registered via a
similar mechanism to passes in the form of PassPipelineRegistration
. Compared
to PassRegistration
, this class takes an additional parameter in the form of a
pipeline builder that modifies a provided OpPassManager
.
void pipelineBuilder(OpPassManager &pm) {
pm.addPass(std::make_unique<MyPass>());
pm.addPass(std::make_unique<MyOtherPass>());
}
// Register an existing pipeline builder function.
static PassPipelineRegistration<> pipeline(
"command-line-arg", "description", pipelineBuilder);
// Register an inline pipeline builder.
static PassPipelineRegistration<> pipeline(
"command-line-arg", "description", [](OpPassManager &pm) {
pm.addPass(std::make_unique<MyPass>());
pm.addPass(std::make_unique<MyOtherPass>());
});
Pipeline registration also allows for simplified registration of specifializations for existing passes:
static PassPipelineRegistration<> foo10(
"foo-10", "Foo Pass 10", [] { return std::make_unique<FooPass>(10); } );
In the previous sections, we showed how to register passes and pass pipelines
with a specific argument and description. Once registered, these can be used on
the command line to configure a pass manager. The limitation of using these
arguments directly is that they cannot build a nested pipeline. For example, if
our module has another module nested underneath, with just -my-module-pass
there is no way to specify that this pass should run on the nested module and
not the top-level module. This is due to the flattened nature of the command
line.
To circumvent this limitation, MLIR also supports a textual description of a pass pipeline. This allows for explicitly specifying the structure of the pipeline to add to the pass manager. This includes the nesting structure, as well as the passes and pass pipelines to run. A textual pipeline is defined as a series of names, each of which may in itself recursively contain a nested pipeline description. The syntax for this specification is as follows:
pipeline ::= op-name `(` pipeline-element (`,` pipeline-element)* `)`
pipeline-element ::= pipeline | (pass-name | pass-pipeline-name) options?
options ::= '{' (key ('=' value)?)+ '}'
op-name
- This corresponds to the mnemonic name of an operation to run passes on,
e.g.
func
ormodule
.
- This corresponds to the mnemonic name of an operation to run passes on,
e.g.
pass-name
|pass-pipeline-name
- This corresponds to the command-line argument of a registered pass or
pass pipeline, e.g.
cse
orcanonicalize
.
- This corresponds to the command-line argument of a registered pass or
pass pipeline, e.g.
options
- Options are pass specific key value pairs that are handled as described in the instance specific pass options section.
For example, the following pipeline:
$ mlir-opt foo.mlir -cse -canonicalize -convert-std-to-llvm
Can also be specified as (via the -pass-pipeline
flag):
$ mlir-opt foo.mlir -pass-pipeline='func(cse, canonicalize), convert-std-to-llvm'
In order to support round-tripping your pass to the textual representation using
OpPassManager::printAsTextualPipeline(raw_ostream&)
, override
Pass::printAsTextualPipeline(raw_ostream&)
to format your pass-name and
options in the format described above.
Options may be specified for a parametric pass. Individual options are defined
using llvm::cl::opt
flag definition rules. These options will then be parsed
at pass construction time independently for each instance of the pass. The
PassRegistration
and PassPipelineRegistration
templates take an additional
optional template parameter that is the Option struct definition to be used for
that pass. To use pass specific options, create a class that inherits from
mlir::PassOptions
and then add a new constructor that takes const MyPassOptions&
and constructs the pass. When using PassPipelineRegistration
,
the constructor now takes a function with the signature void (OpPassManager &pm, const MyPassOptions&)
which should construct the passes from the options
and pass them to the pm. The user code will look like the following:
class MyPass ... {
public:
MyPass(const MyPassOptions& options) ...
};
struct MyPassOptions : public PassOptions<MyPassOptions> {
// These just forward onto llvm::cl::list and llvm::cl::opt respectively.
Option<int> exampleOption{*this, "flag-name", llvm::cl::desc("...")};
List<int> exampleListOption{*this, "list-flag-name", llvm::cl::desc("...")};
};
static PassRegistration<MyPass, MyPassOptions> pass("my-pass", "description");
Statistics are a way to keep track of what the compiler is doing and how
effective various transformations are. It is often useful to see what effect
specific transformations have on a particular program, and how often they
trigger. Pass statistics are instance specific which allow for taking this a
step further as you are able to see the effect of placing a particular
transformation at specific places within the pass pipeline. For example, they
help answer questions like What happens if I run CSE again here?
.
Statistics can be added to a pass by using the 'Pass::Statistic' class. This
class takes as a constructor arguments: the parent pass, a name, and a
description. This class acts like an unsigned integer, and may be incremented
and updated accordingly. These statistics use the same infrastructure as
llvm::Statistic
and thus have similar usage constraints. Collected statistics can be dumped by
the pass manager programmatically via
PassManager::enableStatistics
; or via -pass-statistics
and
-pass-statistics-display
on the command line.
An example is shown below:
struct MyPass : public OperationPass<MyPass> {
Statistic testStat{this, "testStat", "A test statistic"};
void runOnOperation() {
...
// Update our statistic after some invariant was hit.
++testStat;
...
}
};
The collected statistics may be aggregated in two types of views:
A pipeline view that models the structure of the pass manager, this is the default view:
$ mlir-opt -pass-pipeline='func(my-pass,my-pass)' foo.mlir -pass-statistics
===-------------------------------------------------------------------------===
... Pass statistics report ...
===-------------------------------------------------------------------------===
'func' Pipeline
MyPass
(S) 15 testStat - A test statistic
VerifierPass
MyPass
(S) 6 testStat - A test statistic
VerifierPass
VerifierPass
And a list view that aggregates all instances of a specific pass together:
$ mlir-opt -pass-pipeline='func(my-pass, my-pass)' foo.mlir -pass-statistics -pass-statistics-display=list
===-------------------------------------------------------------------------===
... Pass statistics report ...
===-------------------------------------------------------------------------===
MyPass
(S) 21 testStat - A test statistic
MLIR provides a customizable framework to instrument pass execution and analysis
computation. This is provided via the PassInstrumentation
class. This class
provides hooks into the PassManager that observe various pass events:
runBeforePipeline
- This callback is run just before a pass pipeline, i.e. pass manager, is executed.
runAfterPipeline
- This callback is run right after a pass pipeline has been executed, successfully or not.
runBeforePass
- This callback is run just before a pass is executed.
runAfterPass
- This callback is run right after a pass has been successfully executed. If this hook is executed, runAfterPassFailed will not be.
runAfterPassFailed
- This callback is run right after a pass execution fails. If this hook is executed, runAfterPass will not be.
runBeforeAnalysis
- This callback is run just before an analysis is computed.
runAfterAnalysis
- This callback is run right after an analysis is computed.
PassInstrumentation objects can be registered directly with a
PassManager instance via the addInstrumentation
method.
Instrumentations added to the PassManager are run in a stack like fashion, i.e.
the last instrumentation to execute a runBefore*
hook will be the first to
execute the respective runAfter*
hook. Below in an example instrumentation
that counts the number of times DominanceInfo is computed:
struct DominanceCounterInstrumentation : public PassInstrumentation {
unsigned &count;
DominanceCounterInstrumentation(unsigned &count) : count(count) {}
void runAfterAnalysis(llvm::StringRef, AnalysisID *id, Operation *) override {
if (id == AnalysisID::getID<DominanceInfo>())
++count;
}
};
MLIRContext *ctx = ...;
PassManager pm(ctx);
// Add the instrumentation to the pass manager.
unsigned domInfoCount;
pm.addInstrumentation(
std::make_unique<DominanceCounterInstrumentation>(domInfoCount));
// Run the pass manager on a module operation.
ModuleOp m = ...;
if (failed(pm.run(m)))
...
llvm::errs() << "DominanceInfo was computed " << domInfoCount << " times!\n";
MLIR utilizes the pass instrumentation framework to provide a few useful developer tools and utilities. Each of these instrumentations are immediately available to all users of the MLIR pass framework.
The PassTiming instrumentation provides timing information about the execution
of passes and computation of analyses. This provides a quick glimpse into what
passes are taking the most time to execute, as well as how much of an effect
your pass has on the total execution time of the pipeline. Users can enable this
instrumentation directly on the PassManager via enableTiming
. This
instrumentation is also made available in mlir-opt via the -pass-timing
flag.
The PassTiming instrumentation provides several different display modes for the
timing results, each of which is described below:
In this mode, the results are displayed in a list sorted by total time with each
pass/analysis instance aggregated into one unique result. This view is useful
for getting an overview of what analyses/passes are taking the most time in a
pipeline. This display mode is available in mlir-opt via
-pass-timing-display=list
.
$ mlir-opt foo.mlir -disable-pass-threading -pass-pipeline='func(cse,canonicalize)' -convert-std-to-llvm -pass-timing -pass-timing-display=list
===-------------------------------------------------------------------------===
... Pass execution timing report ...
===-------------------------------------------------------------------------===
Total Execution Time: 0.0203 seconds
---Wall Time--- --- Name ---
0.0047 ( 55.9%) Canonicalizer
0.0019 ( 22.2%) VerifierPass
0.0016 ( 18.5%) LLVMLoweringPass
0.0003 ( 3.4%) CSE
0.0002 ( 1.9%) (A) DominanceInfo
0.0084 (100.0%) Total
In this mode, the results are displayed in a nested pipeline view that mirrors the internal pass pipeline that is being executed in the pass manager. This view is useful for understanding specifically which parts of the pipeline are taking the most time, and can also be used to identify when analyses are being invalidated and recomputed. This is the default display mode.
$ mlir-opt foo.mlir -disable-pass-threading -pass-pipeline='func(cse,canonicalize)' -convert-std-to-llvm -pass-timing
===-------------------------------------------------------------------------===
... Pass execution timing report ...
===-------------------------------------------------------------------------===
Total Execution Time: 0.0249 seconds
---Wall Time--- --- Name ---
0.0058 ( 70.8%) 'func' Pipeline
0.0004 ( 4.3%) CSE
0.0002 ( 2.6%) (A) DominanceInfo
0.0004 ( 4.8%) VerifierPass
0.0046 ( 55.4%) Canonicalizer
0.0005 ( 6.2%) VerifierPass
0.0005 ( 5.8%) VerifierPass
0.0014 ( 17.2%) LLVMLoweringPass
0.0005 ( 6.2%) VerifierPass
0.0082 (100.0%) Total
When multi-threading is enabled in the pass manager the meaning of the display
slightly changes. First, a new timing column is added, User Time
, that
displays the total time spent across all threads. Secondly, the Wall Time
column displays the longest individual time spent amongst all of the threads.
This means that the Wall Time
column will continue to give an indicator on the
perceived time, or clock time, whereas the User Time
will display the total
cpu time.
$ mlir-opt foo.mlir -pass-pipeline='func(cse,canonicalize)' -convert-std-to-llvm -pass-timing
===-------------------------------------------------------------------------===
... Pass execution timing report ...
===-------------------------------------------------------------------------===
Total Execution Time: 0.0078 seconds
---User Time--- ---Wall Time--- --- Name ---
0.0177 ( 88.5%) 0.0057 ( 71.3%) 'func' Pipeline
0.0044 ( 22.0%) 0.0015 ( 18.9%) CSE
0.0029 ( 14.5%) 0.0012 ( 15.2%) (A) DominanceInfo
0.0038 ( 18.9%) 0.0015 ( 18.7%) VerifierPass
0.0089 ( 44.6%) 0.0025 ( 31.1%) Canonicalizer
0.0006 ( 3.0%) 0.0002 ( 2.6%) VerifierPass
0.0004 ( 2.2%) 0.0004 ( 5.4%) VerifierPass
0.0013 ( 6.5%) 0.0013 ( 16.3%) LLVMLoweringPass
0.0006 ( 2.8%) 0.0006 ( 7.0%) VerifierPass
0.0200 (100.0%) 0.0081 (100.0%) Total
When debugging it is often useful to dump the IR at various stages of a pass
pipeline. This is where the IR printing instrumentation comes into play. This
instrumentation allows for conditionally printing the IR before and after pass
execution by optionally filtering on the pass being executed. This
instrumentation can be added directly to the PassManager via the
enableIRPrinting
method. mlir-opt
provides a few useful flags for utilizing
this instrumentation:
print-ir-before=(comma-separated-pass-list)
- Print the IR before each of the passes provided within the pass list.
print-ir-before-all
- Print the IR before every pass in the pipeline.
$ mlir-opt foo.mlir -pass-pipeline='func(cse)' -print-ir-before=cse
*** IR Dump Before CSE ***
func @simple_constant() -> (i32, i32) {
%c1_i32 = constant 1 : i32
%c1_i32_0 = constant 1 : i32
return %c1_i32, %c1_i32_0 : i32, i32
}
print-ir-after=(comma-separated-pass-list)
- Print the IR after each of the passes provided within the pass list.
print-ir-after-all
- Print the IR after every pass in the pipeline.
$ mlir-opt foo.mlir -pass-pipeline='func(cse)' -print-ir-after=cse
*** IR Dump After CSE ***
func @simple_constant() -> (i32, i32) {
%c1_i32 = constant 1 : i32
return %c1_i32, %c1_i32 : i32, i32
}
print-ir-after-change
- Only print the IR after a pass if the pass mutated the IR. This helps to reduce the number of IR dumps for "uninteresting" passes.
- Note: Changes are detected by comparing a hash of the operation before and after the pass. This adds additional run-time to compute the hash of the IR, and in some rare cases may result in false-positives depending on the collision rate of the hash algorithm used.
- Note: This option should be used in unison with one of the other 'print-ir-after' options above, as this option alone does not enable printing.
$ mlir-opt foo.mlir -pass-pipeline='func(cse,cse)' -print-ir-after=cse -print-ir-after-change
*** IR Dump After CSE ***
func @simple_constant() -> (i32, i32) {
%c1_i32 = constant 1 : i32
return %c1_i32, %c1_i32 : i32, i32
}
print-ir-module-scope
- Always print the top-level module operation, regardless of pass type or operation nesting level.
- Note: Printing at module scope should only be used when multi-threading
is disabled(
-disable-pass-threading
)
$ mlir-opt foo.mlir -disable-pass-threading -pass-pipeline='func(cse)' -print-ir-after=cse -print-ir-module-scope
*** IR Dump After CSE *** ('func' operation: @bar)
func @bar(%arg0: f32, %arg1: f32) -> f32 {
...
}
func @simple_constant() -> (i32, i32) {
%c1_i32 = constant 1 : i32
%c1_i32_0 = constant 1 : i32
return %c1_i32, %c1_i32_0 : i32, i32
}
*** IR Dump After CSE *** ('func' operation: @simple_constant)
func @bar(%arg0: f32, %arg1: f32) -> f32 {
...
}
func @simple_constant() -> (i32, i32) {
%c1_i32 = constant 1 : i32
return %c1_i32, %c1_i32 : i32, i32
}
The pass manager in MLIR contains a builtin mechanism to
generate reproducibles in the even of a crash, or a
pass failure. This functionality can be enabled via
PassManager::enableCrashReproducerGeneration
or via the command line flag
pass-pipeline-crash-reproducer
. In either case, an argument is provided that
corresponds to the output .mlir
file name that the reproducible should be
written to. The reproducible contains the configuration of the pass manager that
was executing, as well as the initial IR before any passes were run. A potential
reproducible may have the form:
// configuration: -pass-pipeline='func(cse, canonicalize), inline'
// note: verifyPasses=false
module {
func @foo() {
...
}
}