[Mlir-commits] [mlir] Add a tutorial on mlir-opt (PR #96105)
Jeremy Kun
llvmlistbot at llvm.org
Wed Jul 24 16:50:03 PDT 2024
https://github.com/j2kun updated https://github.com/llvm/llvm-project/pull/96105
>From f78800ed9e62bd43f5bbda5bed6395801db7bc68 Mon Sep 17 00:00:00 2001
From: Jeremy Kun <j2kun at users.noreply.github.com>
Date: Mon, 29 Apr 2024 10:29:23 -0700
Subject: [PATCH 01/12] start writing mlir-opt tutorial
---
mlir/docs/Tutorials/MlirOpt.md | 200 +++++++++++++++++++++++++++++++++
1 file changed, 200 insertions(+)
create mode 100644 mlir/docs/Tutorials/MlirOpt.md
diff --git a/mlir/docs/Tutorials/MlirOpt.md b/mlir/docs/Tutorials/MlirOpt.md
new file mode 100644
index 0000000000000..dea61fc81a38a
--- /dev/null
+++ b/mlir/docs/Tutorials/MlirOpt.md
@@ -0,0 +1,200 @@
+# Using `mlir-opt`
+
+`mlir-opt` is the command-line entry point for running passes and lowerings on MLIR code.
+This tutorial will explain how to use `mlir-opt` to run passes, and explain
+some details about MLIR's built-in dialects along the way.
+
+Prerequisites:
+
+- [Building MLIR from source](/getting_started/)
+
+[TOC]
+
+## Overview
+
+We start with a brief summary of context that helps to frame
+the uses of `mlir-opt` detailed in this article.
+For a deeper dive on motivation and design,
+see [the MLIR paper](https://arxiv.org/abs/2002.11054).
+
+Two of the central concepts in MLIR are *dialects* and *lowerings*.
+In traditional compilers, there is typically one "dialect,"
+called an *intermediate representation*, or IR,
+that is the textual or data-structural description of a program
+within the scope of the compiler's execution.
+For example, in GCC the IR is called GIMPLE,
+and in LLVM it's called LLVM-IR.
+Compilers typically convert an input program to their IR,
+run optimization passes,
+and then convert the optimized IR to machine code.
+
+MLIR's philosophy is to split the job into smaller steps.
+First, MLIR allows one to define many IRs called *dialects*,
+some considered "high level" and some "low level,"
+but each with a set of types, operations, metadata,
+and semantics that defines what the operations do.
+Different dialects may coexist in the same program.
+Then, one writes a set of *lowering passes*
+that incrementally converts different parts of the program
+from higher level dialects to lower and lower dialects
+until you get to machine code
+(or, in many cases, LLVM, which finishes the job).
+Along the way,
+*optimizing passes* are run to make the code more efficient.
+The main point here is that the high level dialects exist
+*so that* they make it easy to write these important optimizing passes.
+
+The main motivation for building MLIR
+was to build the `affine` dialect,
+which is designed to enable [polyhedral optimizations](https://polyhedral.info/)
+for loop transformations.
+Compiler engineers had previously implemented polyhedral optimizations in LLVM and GCC (without an `affine` dialect),
+and it was difficult because they had to take a reconstruct a well-structured loop nest
+from a much more complicated set of low-level operations.
+MLIR instead keeps the structure in the higher level operations for optimizations,
+and then discards it during lowering passes.
+
+The `mlir-opt` tool can run both
+optimization passes and lowerings,
+though the final code generation
+is performed by a different tool called `mlir-translate`.
+In particular, `mlir-opt` consumes MLIR as input and produce MLIR as output,
+while `mlir-translate` consumes MLIR as input
+and produces non-MLIR program representations as output.
+
+## Two example programs
+
+Here are two MLIR programs
+that define a function that counts the leading zeroes of a 32-bit integer (`i32`).
+The first uses the [`math` dialect's](/docs/Dialects/MathOps/) `ctlz` operation and just returns the result.
+
+```mlir
+func.func @main(%arg0: i32) -> i32 {
+ %0 = math.ctlz %arg0 : i32
+ func.return %0 : i32
+}
+```
+
+This shows the basic structure of an MLIR operation
+([see here](https://mlir.llvm.org/docs/LangRef/#operations) for a more complete spec).
+Variable names are prefixed with `%`,
+functions by `@`,
+and each variable/value in a program has a type,
+often expressed after a colon.
+In this case all the types are `i32`,
+except for the function type which is `(i32) -> i32`
+(not specified explicitly above, but you'll see it in the `func.call` later).
+
+Each statement is anchored around an expression like `math.ctlz`
+which specifies the dialect [`math`](https://mlir.llvm.org/docs/Dialects/MathOps/) via a namespace,
+and the operation [`ctlz`](https://mlir.llvm.org/docs/Dialects/MathOps/#mathctlz-mathcountleadingzerosop) after the `.`.
+The rest of the syntax of the operation
+is determined by a parser defined by the dialect,
+and so many operations will have different syntaxes.
+In the case of `math.ctlz`,
+the sole argument is an integer whose leading zeros are to be counted,
+and the trailing ` : i32` denotes the output type storing the count.
+
+It's important to note that [`func`](https://mlir.llvm.org/docs/Dialects/Func/) is itself a dialect,
+and [`func.func`](https://mlir.llvm.org/docs/Dialects/Func/#funcfunc-funcfuncop) is considered an "operation,"
+where the braces and the function's body is part of the syntax.
+In MLIR a list of operations within braces is called a [*region*](https://mlir.llvm.org/docs/LangRef/#regions),
+and an operation can have zero regions like `math.ctlz`,
+one region like `func.func`,
+or multiple regions like [`scf.if`](https://mlir.llvm.org/docs/Dialects/SCFDialect/#scfif-scfifop),
+which has a region for each of its two control flow branches.
+
+The second program is a sequence of two loops
+that exhibit poor cache locality.
+
+```mlir
+
+```
+
+## Lowering `ctlz`
+
+The second version of this program has a software implementation of the `ctlz` function and calls it.
+
+```mlir
+func.func @main(%arg0: i32) -> i32 {
+ %0 = func.call @my_ctlz(%arg0) : (i32) -> i32
+ func.return %0 : i32
+}
+func.func @my_ctlz(%arg0: i32) -> i32 {
+ %c32_i32 = arith.constant 32 : i32
+ %c0_i32 = arith.constant 0 : i32
+ %0 = arith.cmpi eq, %arg0, %c0_i32 : i32
+ %1 = scf.if %0 -> (i32) {
+ scf.yield %c32_i32 : i32
+ } else {
+ %c1 = arith.constant 1 : index
+ %c1_i32 = arith.constant 1 : i32
+ %c32 = arith.constant 32 : index
+ %c0_i32_0 = arith.constant 0 : i32
+ %2:2 = scf.for %arg1 = %c1 to %c32 step %c1 iter_args(%arg2 = %arg0, %arg3 = %c0_i32_0) -> (i32, i32) {
+ %3 = arith.cmpi slt, %arg2, %c0_i32 : i32
+ %4:2 = scf.if %3 -> (i32, i32) {
+ scf.yield %arg2, %arg3 : i32, i32
+ } else {
+ %5 = arith.addi %arg3, %c1_i32 : i32
+ %6 = arith.shli %arg2, %c1_i32 : i32
+ scf.yield %6, %5 : i32, i32
+ }
+ scf.yield %4#0, %4#1 : i32, i32
+ }
+ scf.yield %2#1 : i32
+ }
+ func.return %1 : i32
+}
+```
+
+The algorithm above is not relevant to this post, but either way it is quite simple: count the leading zeros by shifting the input left one bit at a time until it becomes negative (as a signed integer), because that occurs exactly when its leading bit is a 1. Then add a special case to handle zero, which would loop infinitely otherwise.
+
+Here you can see two more MLIR dialects. [`arith`](https://mlir.llvm.org/docs/Dialects/ArithOps/) is for low-level arithmetic and boolean conditions on integers and floats. You can define constants, compare integers with `arith.cmpi`, and do things like add and bit shift (`arith.shli` is a left shift). [`scf`](https://mlir.llvm.org/docs/Dialects/SCFDialect/), short for "structured control flow," defines for loops, while loops, and control flow branching. `scf.yield` defines the "output" value from each region of an if/else operation or loop body which is necessary here because, as you can see, an `if` operation has a result value.
+
+Two other minor aspects of the syntax are on display. First is the syntax `%4:2`, which defines a variable `%4` which is a tuple of two values. The corresponding `%4#1` accesses the second entry in the tuple. Second, you'll notice there's a type called `index` that is different from `i32`. Though they both represent integers, `index` is intended to be a platform-dependent integer type which is suitable for indexing arrays, representing sizes and dimensions of things, and, in our case, being loop counters and iteration bounds. More details on [`index` in the MLIR docs](https://mlir.llvm.org/docs/Rationale/Rationale/#integer-signedness-semantics).
+
+## Lowerings and the math-to-funcs pass
+
+We have two versions of the same program because one is a lowered version of the other. In most cases, the machine you're going to run a program on has a "count leading zeros" function, so the lowering would simply map `math.ctlz` to the corresponding machine instruction. But if there is no `ctlz` instruction, a lowering can provide an implementation in terms of lower level dialects and ops. Specifically, this one lowers ctlz to {`func`, `arith`, `scf`}.
+
+The second version of this code was actually generated by the `mlir-opt` command line tool, which is the main entry-point to running MLIR passes on specific MLIR code. For starters, one can take the `mlir-opt` tool and run it with no arguments on any MLIR code, and it will parse it, verify it is well formed, and print it back out with some slight normalizations. In this case, it will wrap the code in a `module`, which is a namespace isolation mechanism.
+
+```bash
+$ echo 'func.func @main(%arg0: i32) -> i32 {
+ %0 = math.ctlz %arg0 : i32
+ func.return %0 : i32
+}' > ctlz.mlir
+$ bazel run @llvm-project//mlir:mlir-opt -- $(pwd)/ctlz.mlir
+<... snip ...>
+module {
+ func.func @main(%arg0: i32) -> i32 {
+ %0 = math.ctlz %arg0 : i32
+ return %0 : i32
+ }
+}
+```
+
+**Aside:** The `-- $(pwd)/ctlz.mlir` is a quirk of bazel. When one program runs another program, the `--` is the standard mechanism to separate CLI flags from the runner program (`bazel`) and the run program (`mlir-opt`). Everything after `--` goes to `mlir-opt`. Also, the need for `$(pwd)` is because when bazel runs `mlir-opt`, it runs it with a working directory that is in some temporary, isolated location on the filesystem. So we need to give it an absolute path to the MLIR file to input. Or we could pipe from standard in. Or we could run the `mlir-opt` binary directly from `bazel-bin/external/llvm-project/mlir/mlir-opt`.
+
+Next we can run our first lowering, which is already built-in to `mlir-opt`, and which generates the long program above.
+
+```bash
+$ bazel run @llvm-project//mlir:mlir-opt -- --convert-math-to-funcs=convert-ctlz $(pwd)/ctlz.mlir
+<... snip ...>
+module {
+ func.func @main(%arg0: i32) {
+ %0 = call @__mlir_math_ctlz_i32(%arg0) : (i32) -> i32
+ return
+ }
+ func.func private @__mlir_math_ctlz_i32(%arg0: i32) -> i32 attributes {llvm.linkage = #llvm.linkage<linkonce_odr>} {
+<... snip ...>
+```
+
+Each pass gets its own command line flag, some are grouped into pipelines, and the `--pass-pipeline` command line flag can be used to provide a (serialized version of) an ordered list of passes to run on the input MLIR.1
+
+We won't cover the internal workings of the `math-to-funcs` pass in this or a future article, but next time we will actually write our own, simpler pass that does something nontrivial. Until then, I'll explain a bit about how testing works in MLIR, using these two ctlz programs as example test cases.
+
+For those who are interested, the MLIR documentation contains a [complete list of passes](https://mlir.llvm.org/docs/Passes/) owned by the upstream MLIR project, which can be used by invoking the corresponding command line flag or nesting it inside of a larger `--pass-pipeline`.
+
+## Optimizing `affine.for`
>From 105b1ffa6be81ea4e1a61390fdd157858cbb3bc4 Mon Sep 17 00:00:00 2001
From: Jeremy Kun <j2kun at users.noreply.github.com>
Date: Tue, 30 Apr 2024 09:58:57 -0700
Subject: [PATCH 02/12] find the right program for affine-loop-fusion
---
mlir/docs/Tutorials/MlirOpt.md | 41 ++++++++++++++++++++++++++++++----
1 file changed, 37 insertions(+), 4 deletions(-)
diff --git a/mlir/docs/Tutorials/MlirOpt.md b/mlir/docs/Tutorials/MlirOpt.md
index dea61fc81a38a..c4a72948f8b79 100644
--- a/mlir/docs/Tutorials/MlirOpt.md
+++ b/mlir/docs/Tutorials/MlirOpt.md
@@ -104,14 +104,47 @@ one region like `func.func`,
or multiple regions like [`scf.if`](https://mlir.llvm.org/docs/Dialects/SCFDialect/#scfif-scfifop),
which has a region for each of its two control flow branches.
-The second program is a sequence of two loops
-that exhibit poor cache locality.
+The second program is a sequence of loops
+that exhibits poor cache locality.
```mlir
-
+func.func @producer_consumer_fusion(%arg0: memref<10xf32>, %arg1: memref<10xf32>) {
+ %0 = memref.alloc() : memref<10xf32>
+ %1 = memref.alloc() : memref<10xf32>
+ %cst = arith.constant 0.000000e+00 : f32
+ affine.for %arg2 = 0 to 10 {
+ affine.store %cst, %0[%arg2] : memref<10xf32>
+ affine.store %cst, %1[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %2 = affine.load %0[%arg2] : memref<10xf32>
+ %3 = arith.addf %2, %2 : f32
+ affine.store %3, %arg0[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %2 = affine.load %1[%arg2] : memref<10xf32>
+ %3 = arith.mulf %2, %2 : f32
+ affine.store %3, %arg1[%arg2] : memref<10xf32>
+ }
+ return
+}
```
-## Lowering `ctlz`
+This program introduces some additional dialects.
+The [`affine` dialect](https://mlir.llvm.org/docs/Dialects/Affine/) mentioned in the introduction
+represents well-structured loop nests,
+and the [`affine.for` operation](https://mlir.llvm.org/docs/Dialects/Affine/#affinefor-affineaffineforop)
+whose region corresponds to the loop body.
+`affine.for` also showcases some custom-defined syntax
+to represent the loop bounds and loop induction variable.
+The [`memref` dialect](https://mlir.llvm.org/docs/Dialects/MemRef/)
+defines types and operations related to memory management
+with pointer semantics.
+Note also that while `memref` has store and load operations,
+`affine` has its own that limit what types of memory accesses are allowed,
+so as to ensure the well-structuredness of the loop nest.
+
+## Lowering `ctlz` in two ways
The second version of this program has a software implementation of the `ctlz` function and calls it.
>From 818961d80ce2ff5a1692a8c4fa698a181ccbbd19 Mon Sep 17 00:00:00 2001
From: Jeremy Kun <j2kun at users.noreply.github.com>
Date: Fri, 31 May 2024 22:04:01 -0700
Subject: [PATCH 03/12] finish first draft of tutorial
---
mlir/docs/Tutorials/MlirOpt.md | 323 +++++++++++++++----
mlir/test/Examples/mlir-opt/ctlz.mlir | 4 +
mlir/test/Examples/mlir-opt/loop-fusion.mlir | 20 ++
3 files changed, 284 insertions(+), 63 deletions(-)
create mode 100644 mlir/test/Examples/mlir-opt/ctlz.mlir
create mode 100644 mlir/test/Examples/mlir-opt/loop-fusion.mlir
diff --git a/mlir/docs/Tutorials/MlirOpt.md b/mlir/docs/Tutorials/MlirOpt.md
index c4a72948f8b79..f8a4f312a87dd 100644
--- a/mlir/docs/Tutorials/MlirOpt.md
+++ b/mlir/docs/Tutorials/MlirOpt.md
@@ -44,14 +44,16 @@ Along the way,
The main point here is that the high level dialects exist
*so that* they make it easy to write these important optimizing passes.
-The main motivation for building MLIR
+A central motivation for building MLIR
was to build the `affine` dialect,
which is designed to enable [polyhedral optimizations](https://polyhedral.info/)
for loop transformations.
-Compiler engineers had previously implemented polyhedral optimizations in LLVM and GCC (without an `affine` dialect),
-and it was difficult because they had to take a reconstruct a well-structured loop nest
+Compiler engineers had previously implemented polyhedral optimizations
+in LLVM and GCC (without an `affine` dialect),
+and it was difficult because they had to reconstruct well-structured loop nests
from a much more complicated set of low-level operations.
-MLIR instead keeps the structure in the higher level operations for optimizations,
+Having a higher level `affine` dialect preserves the loop nest structure
+at an abstraction layer that makes it easier to write optimizations,
and then discards it during lowering passes.
The `mlir-opt` tool can run both
@@ -64,9 +66,9 @@ and produces non-MLIR program representations as output.
## Two example programs
-Here are two MLIR programs
-that define a function that counts the leading zeroes of a 32-bit integer (`i32`).
-The first uses the [`math` dialect's](/docs/Dialects/MathOps/) `ctlz` operation and just returns the result.
+Here are two MLIR programs.
+The first defines a function that counts the leading zeroes of a 32-bit integer (`i32`)
+using the [`math` dialect's](/docs/Dialects/MathOps/) `ctlz` operation.
```mlir
func.func @main(%arg0: i32) -> i32 {
@@ -96,7 +98,7 @@ the sole argument is an integer whose leading zeros are to be counted,
and the trailing ` : i32` denotes the output type storing the count.
It's important to note that [`func`](https://mlir.llvm.org/docs/Dialects/Func/) is itself a dialect,
-and [`func.func`](https://mlir.llvm.org/docs/Dialects/Func/#funcfunc-funcfuncop) is considered an "operation,"
+and [`func.func`](https://mlir.llvm.org/docs/Dialects/Func/#funcfunc-funcfuncop) is an operation,
where the braces and the function's body is part of the syntax.
In MLIR a list of operations within braces is called a [*region*](https://mlir.llvm.org/docs/LangRef/#regions),
and an operation can have zero regions like `math.ctlz`,
@@ -134,7 +136,7 @@ This program introduces some additional dialects.
The [`affine` dialect](https://mlir.llvm.org/docs/Dialects/Affine/) mentioned in the introduction
represents well-structured loop nests,
and the [`affine.for` operation](https://mlir.llvm.org/docs/Dialects/Affine/#affinefor-affineaffineforop)
-whose region corresponds to the loop body.
+whose region corresponds to the loop's body.
`affine.for` also showcases some custom-defined syntax
to represent the loop bounds and loop induction variable.
The [`memref` dialect](https://mlir.llvm.org/docs/Dialects/MemRef/)
@@ -144,90 +146,285 @@ Note also that while `memref` has store and load operations,
`affine` has its own that limit what types of memory accesses are allowed,
so as to ensure the well-structuredness of the loop nest.
-## Lowering `ctlz` in two ways
+## Running `mlir-opt`
-The second version of this program has a software implementation of the `ctlz` function and calls it.
+After building the MLIR project,
+the `mlir-opt` binary (located in `build/bin`)
+is the entry point for running passes and lowerings,
+as well as emitting debug and diagnostic data.
+
+Running `mlir-opt` with no flags will consume MLIR input
+from standard in, parse and run verifiers on it,
+and write the MLIR back to standard out.
+This is a good way to test if an input MLIR is well-formed.
+
+`mlir-opt --help` shows a complete list of flags
+(there are nearly 1000).
+Each pass gets its own flag.
+
+## Lowering `ctlz`
+
+Next we will show two of MLIR's lowering passes.
+The first, `convert-math-to-llvm`, converts the `ctlz` op
+to the `llvm` dialect's [`intr.ctlz` op](https://mlir.llvm.org/docs/Dialects/LLVM/#llvmintrctlz-llvmcountleadingzerosop)
+which is an LLVM intrinsic.
+Note that `llvm` here is MLIR's `llvm` dialect,
+which would still need to be processed through `mlir-translate`
+to generate LLVM-IR.
+
+Recall our ctlz program:
```mlir
+# mlir/test/Examples/mlir-opt/ctlz.mlir
func.func @main(%arg0: i32) -> i32 {
- %0 = func.call @my_ctlz(%arg0) : (i32) -> i32
+ %0 = math.ctlz %arg0 : i32
func.return %0 : i32
}
-func.func @my_ctlz(%arg0: i32) -> i32 {
- %c32_i32 = arith.constant 32 : i32
- %c0_i32 = arith.constant 0 : i32
- %0 = arith.cmpi eq, %arg0, %c0_i32 : i32
- %1 = scf.if %0 -> (i32) {
- scf.yield %c32_i32 : i32
- } else {
- %c1 = arith.constant 1 : index
- %c1_i32 = arith.constant 1 : i32
- %c32 = arith.constant 32 : index
- %c0_i32_0 = arith.constant 0 : i32
- %2:2 = scf.for %arg1 = %c1 to %c32 step %c1 iter_args(%arg2 = %arg0, %arg3 = %c0_i32_0) -> (i32, i32) {
- %3 = arith.cmpi slt, %arg2, %c0_i32 : i32
- %4:2 = scf.if %3 -> (i32, i32) {
- scf.yield %arg2, %arg3 : i32, i32
- } else {
- %5 = arith.addi %arg3, %c1_i32 : i32
- %6 = arith.shli %arg2, %c1_i32 : i32
- scf.yield %6, %5 : i32, i32
- }
- scf.yield %4#0, %4#1 : i32, i32
- }
- scf.yield %2#1 : i32
- }
- func.return %1 : i32
-}
```
-The algorithm above is not relevant to this post, but either way it is quite simple: count the leading zeros by shifting the input left one bit at a time until it becomes negative (as a signed integer), because that occurs exactly when its leading bit is a 1. Then add a special case to handle zero, which would loop infinitely otherwise.
+After building MLIR, and from the `llvm-project` base directory, run
-Here you can see two more MLIR dialects. [`arith`](https://mlir.llvm.org/docs/Dialects/ArithOps/) is for low-level arithmetic and boolean conditions on integers and floats. You can define constants, compare integers with `arith.cmpi`, and do things like add and bit shift (`arith.shli` is a left shift). [`scf`](https://mlir.llvm.org/docs/Dialects/SCFDialect/), short for "structured control flow," defines for loops, while loops, and control flow branching. `scf.yield` defines the "output" value from each region of an if/else operation or loop body which is necessary here because, as you can see, an `if` operation has a result value.
+```bash
+build/bin/mlir-opt --convert-math-to-llvm mlir/test/Examples/mlir-opt/ctlz.mlir
+```
-Two other minor aspects of the syntax are on display. First is the syntax `%4:2`, which defines a variable `%4` which is a tuple of two values. The corresponding `%4#1` accesses the second entry in the tuple. Second, you'll notice there's a type called `index` that is different from `i32`. Though they both represent integers, `index` is intended to be a platform-dependent integer type which is suitable for indexing arrays, representing sizes and dimensions of things, and, in our case, being loop counters and iteration bounds. More details on [`index` in the MLIR docs](https://mlir.llvm.org/docs/Rationale/Rationale/#integer-signedness-semantics).
+which produces
-## Lowerings and the math-to-funcs pass
+```mlir
+module {
+ func.func @main(%arg0: i32) -> i32 {
+ %0 = "llvm.intr.ctlz"(%arg0) <{is_zero_poison = false}> : (i32) -> i32
+ return %0 : i32
+ }
+}
+```
-We have two versions of the same program because one is a lowered version of the other. In most cases, the machine you're going to run a program on has a "count leading zeros" function, so the lowering would simply map `math.ctlz` to the corresponding machine instruction. But if there is no `ctlz` instruction, a lowering can provide an implementation in terms of lower level dialects and ops. Specifically, this one lowers ctlz to {`func`, `arith`, `scf`}.
+As you can see, the `math` dialect was the only thing that changed
+due to the lowering.
+The `func` dialect was left alone,
+even though it also needs to be converted to the `llvm` dialect
+to generate LLVM-IR.
-The second version of this code was actually generated by the `mlir-opt` command line tool, which is the main entry-point to running MLIR passes on specific MLIR code. For starters, one can take the `mlir-opt` tool and run it with no arguments on any MLIR code, and it will parse it, verify it is well formed, and print it back out with some slight normalizations. In this case, it will wrap the code in a `module`, which is a namespace isolation mechanism.
+What if the target machine does not have a `ctlz` intrinsic?
+In this case, one can run the `--convert-math-to-funcs`
+pass, which replaces the op with an implementation using
+other MLIR dialects.
```bash
-$ echo 'func.func @main(%arg0: i32) -> i32 {
- %0 = math.ctlz %arg0 : i32
- func.return %0 : i32
-}' > ctlz.mlir
-$ bazel run @llvm-project//mlir:mlir-opt -- $(pwd)/ctlz.mlir
-<... snip ...>
+build/bin/mlir-opt --convert-math-to-funcs=convert-ctlz mlir/test/Examples/mlir-opt/ctlz.mlir
+```
+
+You will see something similar to:
+
+```mlir
module {
func.func @main(%arg0: i32) -> i32 {
- %0 = math.ctlz %arg0 : i32
+ %0 = call @__mlir_math_ctlz_i32(%arg0) : (i32) -> i32
return %0 : i32
}
+ func.func private @__mlir_math_ctlz_i32(%arg0: i32) -> i32 attributes {llvm.linkage = #llvm.linkage<linkonce_odr>} {
+ %c32_i32 = arith.constant 32 : i32
+ %c0_i32 = arith.constant 0 : i32
+ %0 = arith.cmpi eq, %arg0, %c0_i32 : i32
+ %1 = scf.if %0 -> (i32) {
+ scf.yield %c32_i32 : i32
+ } else {
+ %c1 = arith.constant 1 : index
+ %c1_i32 = arith.constant 1 : i32
+ %c32 = arith.constant 32 : index
+ %c0_i32_0 = arith.constant 0 : i32
+ %2:2 = scf.for %arg1 = %c1 to %c32 step %c1 iter_args(%arg2 = %arg0, %arg3 = %c0_i32_0) -> (i32, i32) {
+ %3 = arith.cmpi slt, %arg2, %c0_i32 : i32
+ %4:2 = scf.if %3 -> (i32, i32) {
+ scf.yield %arg2, %arg3 : i32, i32
+ } else {
+ %5 = arith.addi %arg3, %c1_i32 : i32
+ %6 = arith.shli %arg2, %c1_i32 : i32
+ scf.yield %6, %5 : i32, i32
+ }
+ scf.yield %4#0, %4#1 : i32, i32
+ }
+ scf.yield %2#1 : i32
+ }
+ return %1 : i32
+ }
}
```
-**Aside:** The `-- $(pwd)/ctlz.mlir` is a quirk of bazel. When one program runs another program, the `--` is the standard mechanism to separate CLI flags from the runner program (`bazel`) and the run program (`mlir-opt`). Everything after `--` goes to `mlir-opt`. Also, the need for `$(pwd)` is because when bazel runs `mlir-opt`, it runs it with a working directory that is in some temporary, isolated location on the filesystem. So we need to give it an absolute path to the MLIR file to input. Or we could pipe from standard in. Or we could run the `mlir-opt` binary directly from `bazel-bin/external/llvm-project/mlir/mlir-opt`.
+The algorithm above is not relevant to this tutorial,
+but either way it is quite simple:
+count the leading zeros by shifting the input left one bit at a time
+until it becomes negative (as a signed integer),
+because that occurs exactly when its leading bit is a 1.
+Then add a special case to handle zero,
+which would loop infinitely otherwise.
+
+Here you can see two more MLIR dialects.
+[`arith`](https://mlir.llvm.org/docs/Dialects/ArithOps/)
+is for low-level arithmetic
+and boolean conditions on integers and floats.
+You can define constants,
+compare integers with `arith.cmpi`,
+and do things like add and bit shift (`arith.shli` is a left shift).
+[`scf`](https://mlir.llvm.org/docs/Dialects/SCFDialect/),
+short for "structured control flow,"
+defines for loops, while loops,
+and control flow branching using regions.
+`scf.yield` defines the "output" value
+from each region of an if/else operation or loop body
+which is necessary here because an `if` operation has a result value.
+The "structured" in `scf` is in contrast to
+[`cf`](https://mlir.llvm.org/docs/Dialects/ControlFlowDialect/),
+for "(unstructured) control flow,"
+which does low-level, region-free control flow
+that jumps between SSA blocks on a control flow graph.
+
+Two other minor aspects of the syntax are on display.
+First is the syntax `%4:2`,
+which defines a variable `%4` as a tuple of two values.
+The corresponding `%4#1` accesses the second entry in the tuple.
+Second, there's a type called `index` that is different from `i32`.
+Though they both represent integers,
+[`index`](https://mlir.llvm.org/docs/Rationale/Rationale/#integer-signedness-semantics) is a platform-dependent integer type
+suitable for indexing arrays,
+representing sizes and dimensions of things,
+and, in the above program,
+being loop counters and iteration bounds.
+
+## Optimizing loop nests
+
+Recall our second program, the poorly-tuned loops.
-Next we can run our first lowering, which is already built-in to `mlir-opt`, and which generates the long program above.
+```mlir
+// mlir/test/Examples/mlir-opt/loop-fusion.mlir
+func.func @producer_consumer_fusion(%arg0: memref<10xf32>, %arg1: memref<10xf32>) {
+ %0 = memref.alloc() : memref<10xf32>
+ %1 = memref.alloc() : memref<10xf32>
+ %cst = arith.constant 0.000000e+00 : f32
+ affine.for %arg2 = 0 to 10 {
+ affine.store %cst, %0[%arg2] : memref<10xf32>
+ affine.store %cst, %1[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %2 = affine.load %0[%arg2] : memref<10xf32>
+ %3 = arith.addf %2, %2 : f32
+ affine.store %3, %arg0[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %2 = affine.load %1[%arg2] : memref<10xf32>
+ %3 = arith.mulf %2, %2 : f32
+ affine.store %3, %arg1[%arg2] : memref<10xf32>
+ }
+ return
+}
+```
+
+Running this with the [`affine-loop-fusion`](https://mlir.llvm.org/docs/Passes/#-affine-loop-fusion) pass
+produces a fused loop.
```bash
-$ bazel run @llvm-project//mlir:mlir-opt -- --convert-math-to-funcs=convert-ctlz $(pwd)/ctlz.mlir
-<... snip ...>
+build/bin/mlir-opt --affine-loop-fusion mlir/test/Examples/mlir-opt/loop-fusion.mlir
+```
+
+```mlir
module {
- func.func @main(%arg0: i32) {
- %0 = call @__mlir_math_ctlz_i32(%arg0) : (i32) -> i32
+ func.func @producer_consumer_fusion(%arg0: memref<10xf32>, %arg1: memref<10xf32>) {
+ %alloc = memref.alloc() : memref<1xf32>
+ %alloc_0 = memref.alloc() : memref<1xf32>
+ %cst = arith.constant 0.000000e+00 : f32
+ affine.for %arg2 = 0 to 10 {
+ affine.store %cst, %alloc[0] : memref<1xf32>
+ affine.store %cst, %alloc_0[0] : memref<1xf32>
+ %0 = affine.load %alloc_0[0] : memref<1xf32>
+ %1 = arith.mulf %0, %0 : f32
+ affine.store %1, %arg1[%arg2] : memref<10xf32>
+ %2 = affine.load %alloc[0] : memref<1xf32>
+ %3 = arith.addf %2, %2 : f32
+ affine.store %3, %arg0[%arg2] : memref<10xf32>
+ }
return
}
- func.func private @__mlir_math_ctlz_i32(%arg0: i32) -> i32 attributes {llvm.linkage = #llvm.linkage<linkonce_odr>} {
-<... snip ...>
+}
+```
+
+This pass has options that allow the user to configure its behavior.
+For example, the `fusion-compute-tolerance` option
+is described as the "fractional increase in additional computation tolerated while fusing."
+If this value is set to zero on the command line,
+the pass will not fuse the loops.
+
+```bash
+build/bin/mlir-opt --affine-loop-fusion='fusion-compute-tolerance=0' mlir/test/Examples/mlir-opt/loop-fusion.mlir
+```
+
+```mlir
+module {
+ func.func @producer_consumer_fusion(%arg0: memref<10xf32>, %arg1: memref<10xf32>) {
+ %alloc = memref.alloc() : memref<10xf32>
+ %alloc_0 = memref.alloc() : memref<10xf32>
+ %cst = arith.constant 0.000000e+00 : f32
+ affine.for %arg2 = 0 to 10 {
+ affine.store %cst, %alloc[%arg2] : memref<10xf32>
+ affine.store %cst, %alloc_0[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %0 = affine.load %alloc[%arg2] : memref<10xf32>
+ %1 = arith.addf %0, %0 : f32
+ affine.store %1, %arg0[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %0 = affine.load %alloc_0[%arg2] : memref<10xf32>
+ %1 = arith.mulf %0, %0 : f32
+ affine.store %1, %arg1[%arg2] : memref<10xf32>
+ }
+ return
+ }
+}
+```
+
+Options passed to a pass
+should come in the form of a quoted string
+(to join all options into a single shell argument)
+with space-separated `key=value` pairs.
+
+## Building a pass pipeline on the command line
+
+One can combine passes on the command line in two ways.
+
+First, by simply placing the pass flags one after the other,
+they will be run in order.
+
+```bash
+build/bin/mlir-opt --convert-math-to-llvm --convert-func-to-llvm mlir/test/Examples/mlir-opt/ctlz.mlir
+```
+
+Passes can also be configured to run
+in a way that is limited to a particular sub-IR
+nested under scope-isolated ops like functions.
+For example, one could run `--convert-math-to-llvm`
+on each `func` separately, by running
+
+```bash
+build/bin/mlir-opt mlir/test/Examples/mlir-opt/ctlz.mlir --pass-pipeline='
+ builtin.module(
+ convert-math-to-funcs{convert-ctlz=1},
+ func.func(cse,canonicalize),
+ convert-scf-to-cf,
+ convert-to-llvm
+ )'
```
-Each pass gets its own command line flag, some are grouped into pipelines, and the `--pass-pipeline` command line flag can be used to provide a (serialized version of) an ordered list of passes to run on the input MLIR.1
+The outer nesting tells `mlir-opt` to run the pass pipeline
+on each `module` op,
+and then within that to run `convert-math-to-funcs`,
+then (on each `func.func` op), the [`cse`](https://mlir.llvm.org/docs/Passes/#-cse)
+and [`canonicalize`](https://mlir.llvm.org/docs/Passes/#-canonicalize) passes,
+and then convert the rest to the `llvm` dialect.
-We won't cover the internal workings of the `math-to-funcs` pass in this or a future article, but next time we will actually write our own, simpler pass that does something nontrivial. Until then, I'll explain a bit about how testing works in MLIR, using these two ctlz programs as example test cases.
+For a spec of the pass-pipeline textual description language,
+see [the docs](https://mlir.llvm.org/docs/PassManagement/#textual-pass-pipeline-specification).
-For those who are interested, the MLIR documentation contains a [complete list of passes](https://mlir.llvm.org/docs/Passes/) owned by the upstream MLIR project, which can be used by invoking the corresponding command line flag or nesting it inside of a larger `--pass-pipeline`.
+## Further readering
-## Optimizing `affine.for`
+- [List of passes](https://mlir.llvm.org/docs/Passes/)
+- [List of dialects](https://mlir.llvm.org/docs/Dialects/)
diff --git a/mlir/test/Examples/mlir-opt/ctlz.mlir b/mlir/test/Examples/mlir-opt/ctlz.mlir
new file mode 100644
index 0000000000000..9c3393c259bf8
--- /dev/null
+++ b/mlir/test/Examples/mlir-opt/ctlz.mlir
@@ -0,0 +1,4 @@
+func.func @main(%arg0: i32) -> i32 {
+ %0 = math.ctlz %arg0 : i32
+ func.return %0 : i32
+}
diff --git a/mlir/test/Examples/mlir-opt/loop-fusion.mlir b/mlir/test/Examples/mlir-opt/loop-fusion.mlir
new file mode 100644
index 0000000000000..0f9e37faa6860
--- /dev/null
+++ b/mlir/test/Examples/mlir-opt/loop-fusion.mlir
@@ -0,0 +1,20 @@
+func.func @producer_consumer_fusion(%arg0: memref<10xf32>, %arg1: memref<10xf32>) {
+ %0 = memref.alloc() : memref<10xf32>
+ %1 = memref.alloc() : memref<10xf32>
+ %cst = arith.constant 0.000000e+00 : f32
+ affine.for %arg2 = 0 to 10 {
+ affine.store %cst, %0[%arg2] : memref<10xf32>
+ affine.store %cst, %1[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %2 = affine.load %0[%arg2] : memref<10xf32>
+ %3 = arith.addf %2, %2 : f32
+ affine.store %3, %arg0[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %2 = affine.load %1[%arg2] : memref<10xf32>
+ %3 = arith.mulf %2, %2 : f32
+ affine.store %3, %arg1[%arg2] : memref<10xf32>
+ }
+ return
+}
>From 46e2396a5ff8dc5c0a4e5644c64727962d9b201e Mon Sep 17 00:00:00 2001
From: Jeremy Kun <j2kun at users.noreply.github.com>
Date: Tue, 18 Jun 2024 16:35:27 -0700
Subject: [PATCH 04/12] Fix up test files
---
mlir/docs/Tutorials/MlirOpt.md | 6 ++---
mlir/test/Examples/mlir-opt/ctlz.mlir | 5 ++++
mlir/test/Examples/mlir-opt/ctlz_funcs.mlir | 10 ++++++++
mlir/test/Examples/mlir-opt/ctlz_llvm.mlir | 8 ++++++
.../test/Examples/mlir-opt/ctlz_pipeline.mlir | 15 +++++++++++
mlir/test/Examples/mlir-opt/loop_fusion.mlir | 25 +++++++++++++++++++
...p-fusion.mlir => loop_fusion_default.mlir} | 4 +++
.../mlir-opt/loop_fusion_options.mlir | 24 ++++++++++++++++++
8 files changed, 94 insertions(+), 3 deletions(-)
create mode 100644 mlir/test/Examples/mlir-opt/ctlz_funcs.mlir
create mode 100644 mlir/test/Examples/mlir-opt/ctlz_llvm.mlir
create mode 100644 mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir
create mode 100644 mlir/test/Examples/mlir-opt/loop_fusion.mlir
rename mlir/test/Examples/mlir-opt/{loop-fusion.mlir => loop_fusion_default.mlir} (84%)
create mode 100644 mlir/test/Examples/mlir-opt/loop_fusion_options.mlir
diff --git a/mlir/docs/Tutorials/MlirOpt.md b/mlir/docs/Tutorials/MlirOpt.md
index f8a4f312a87dd..95babc939e427 100644
--- a/mlir/docs/Tutorials/MlirOpt.md
+++ b/mlir/docs/Tutorials/MlirOpt.md
@@ -296,7 +296,7 @@ being loop counters and iteration bounds.
Recall our second program, the poorly-tuned loops.
```mlir
-// mlir/test/Examples/mlir-opt/loop-fusion.mlir
+// mlir/test/Examples/mlir-opt/loop_fusion.mlir
func.func @producer_consumer_fusion(%arg0: memref<10xf32>, %arg1: memref<10xf32>) {
%0 = memref.alloc() : memref<10xf32>
%1 = memref.alloc() : memref<10xf32>
@@ -323,7 +323,7 @@ Running this with the [`affine-loop-fusion`](https://mlir.llvm.org/docs/Passes/#
produces a fused loop.
```bash
-build/bin/mlir-opt --affine-loop-fusion mlir/test/Examples/mlir-opt/loop-fusion.mlir
+build/bin/mlir-opt --affine-loop-fusion mlir/test/Examples/mlir-opt/loop_fusion.mlir
```
```mlir
@@ -354,7 +354,7 @@ If this value is set to zero on the command line,
the pass will not fuse the loops.
```bash
-build/bin/mlir-opt --affine-loop-fusion='fusion-compute-tolerance=0' mlir/test/Examples/mlir-opt/loop-fusion.mlir
+build/bin/mlir-opt --affine-loop-fusion='fusion-compute-tolerance=0' mlir/test/Examples/mlir-opt/loop_fusion.mlir
```
```mlir
diff --git a/mlir/test/Examples/mlir-opt/ctlz.mlir b/mlir/test/Examples/mlir-opt/ctlz.mlir
index 9c3393c259bf8..f9b667851792c 100644
--- a/mlir/test/Examples/mlir-opt/ctlz.mlir
+++ b/mlir/test/Examples/mlir-opt/ctlz.mlir
@@ -1,3 +1,8 @@
+// This file is left in-tree despite having no assertions so it can be
+// referenced by the tutorial text.
+
+// RUN: mlir-opt %s
+
func.func @main(%arg0: i32) -> i32 {
%0 = math.ctlz %arg0 : i32
func.return %0 : i32
diff --git a/mlir/test/Examples/mlir-opt/ctlz_funcs.mlir b/mlir/test/Examples/mlir-opt/ctlz_funcs.mlir
new file mode 100644
index 0000000000000..894f24d56dc8a
--- /dev/null
+++ b/mlir/test/Examples/mlir-opt/ctlz_funcs.mlir
@@ -0,0 +1,10 @@
+// RUN: mlir-opt --convert-math-to-funcs=convert-ctlz %s | FileCheck %s
+
+// CHECK-LABEL: @main
+// CHECK-NEXT: call @__mlir_math_ctlz_i32
+
+// CHECK-LABEL: func.func private @__mlir_math_ctlz_i32
+func.func @main(%arg0: i32) -> i32 {
+ %0 = math.ctlz %arg0 : i32
+ func.return %0 : i32
+}
diff --git a/mlir/test/Examples/mlir-opt/ctlz_llvm.mlir b/mlir/test/Examples/mlir-opt/ctlz_llvm.mlir
new file mode 100644
index 0000000000000..d8c5b7550be0c
--- /dev/null
+++ b/mlir/test/Examples/mlir-opt/ctlz_llvm.mlir
@@ -0,0 +1,8 @@
+// RUN: mlir-opt --convert-math-to-llvm %s | FileCheck %s
+
+// CHECK-LABEL: @main
+// CHECK-NEXT: llvm.intr.ctlz
+func.func @main(%arg0: i32) -> i32 {
+ %0 = math.ctlz %arg0 : i32
+ func.return %0 : i32
+}
diff --git a/mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir b/mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir
new file mode 100644
index 0000000000000..2b5ce3408e1fd
--- /dev/null
+++ b/mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir
@@ -0,0 +1,15 @@
+// RUN: mlir-opt --pass-pipeline='
+// RUN: builtin.module(
+// RUN: convert-math-to-funcs{convert-ctlz=1},
+// RUN: func.func(cse,canonicalize),
+// RUN: convert-scf-to-cf,
+// RUN: convert-to-llvm
+// RUN: )' %s | FileCheck %s
+
+// CHECK-LABEL: @main
+// CHECK: llvm
+func.func @main(%arg0: i32) -> i32 {
+ %0 = math.ctlz %arg0 : i32
+ func.return %0 : i32
+}
+
diff --git a/mlir/test/Examples/mlir-opt/loop_fusion.mlir b/mlir/test/Examples/mlir-opt/loop_fusion.mlir
new file mode 100644
index 0000000000000..24a44d8a53f31
--- /dev/null
+++ b/mlir/test/Examples/mlir-opt/loop_fusion.mlir
@@ -0,0 +1,25 @@
+// This file is left in-tree despite having no assertions so it can be
+// referenced by the tutorial text.
+
+// RUN: mlir-opt %s
+
+func.func @producer_consumer_fusion(%arg0: memref<10xf32>, %arg1: memref<10xf32>) {
+ %0 = memref.alloc() : memref<10xf32>
+ %1 = memref.alloc() : memref<10xf32>
+ %cst = arith.constant 0.000000e+00 : f32
+ affine.for %arg2 = 0 to 10 {
+ affine.store %cst, %0[%arg2] : memref<10xf32>
+ affine.store %cst, %1[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %2 = affine.load %0[%arg2] : memref<10xf32>
+ %3 = arith.addf %2, %2 : f32
+ affine.store %3, %arg0[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %2 = affine.load %1[%arg2] : memref<10xf32>
+ %3 = arith.mulf %2, %2 : f32
+ affine.store %3, %arg1[%arg2] : memref<10xf32>
+ }
+ return
+}
diff --git a/mlir/test/Examples/mlir-opt/loop-fusion.mlir b/mlir/test/Examples/mlir-opt/loop_fusion_default.mlir
similarity index 84%
rename from mlir/test/Examples/mlir-opt/loop-fusion.mlir
rename to mlir/test/Examples/mlir-opt/loop_fusion_default.mlir
index 0f9e37faa6860..b22bb2546d49e 100644
--- a/mlir/test/Examples/mlir-opt/loop-fusion.mlir
+++ b/mlir/test/Examples/mlir-opt/loop_fusion_default.mlir
@@ -1,3 +1,7 @@
+// RUN: mlir-opt --affine-loop-fusion %s | FileCheck %s
+
+// CHECK-LABEL: @producer_consumer_fusion
+// CHECK-COUNT-1: affine.for
func.func @producer_consumer_fusion(%arg0: memref<10xf32>, %arg1: memref<10xf32>) {
%0 = memref.alloc() : memref<10xf32>
%1 = memref.alloc() : memref<10xf32>
diff --git a/mlir/test/Examples/mlir-opt/loop_fusion_options.mlir b/mlir/test/Examples/mlir-opt/loop_fusion_options.mlir
new file mode 100644
index 0000000000000..47e75ae86fc9b
--- /dev/null
+++ b/mlir/test/Examples/mlir-opt/loop_fusion_options.mlir
@@ -0,0 +1,24 @@
+// RUN: mlir-opt --affine-loop-fusion='fusion-compute-tolerance=0' %s | FileCheck %s
+
+// CHECK-LABEL: @producer_consumer_fusion
+// CHECK-COUNT-3: affine.for
+func.func @producer_consumer_fusion(%arg0: memref<10xf32>, %arg1: memref<10xf32>) {
+ %0 = memref.alloc() : memref<10xf32>
+ %1 = memref.alloc() : memref<10xf32>
+ %cst = arith.constant 0.000000e+00 : f32
+ affine.for %arg2 = 0 to 10 {
+ affine.store %cst, %0[%arg2] : memref<10xf32>
+ affine.store %cst, %1[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %2 = affine.load %0[%arg2] : memref<10xf32>
+ %3 = arith.addf %2, %2 : f32
+ affine.store %3, %arg0[%arg2] : memref<10xf32>
+ }
+ affine.for %arg2 = 0 to 10 {
+ %2 = affine.load %1[%arg2] : memref<10xf32>
+ %3 = arith.mulf %2, %2 : f32
+ affine.store %3, %arg1[%arg2] : memref<10xf32>
+ }
+ return
+}
>From c5252cd109151f6947972ab14cad2a293b13b4fa Mon Sep 17 00:00:00 2001
From: Jeremy Kun <j2kun at users.noreply.github.com>
Date: Wed, 19 Jun 2024 12:21:12 -0700
Subject: [PATCH 05/12] fix RUN directive for pipeline
---
mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir | 8 +-------
1 file changed, 1 insertion(+), 7 deletions(-)
diff --git a/mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir b/mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir
index 2b5ce3408e1fd..70b639a09062f 100644
--- a/mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir
+++ b/mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir
@@ -1,10 +1,4 @@
-// RUN: mlir-opt --pass-pipeline='
-// RUN: builtin.module(
-// RUN: convert-math-to-funcs{convert-ctlz=1},
-// RUN: func.func(cse,canonicalize),
-// RUN: convert-scf-to-cf,
-// RUN: convert-to-llvm
-// RUN: )' %s | FileCheck %s
+// RUN: mlir-opt --pass-pipeline=' builtin.module( convert-math-to-funcs{convert-ctlz=1}, func.func(cse,canonicalize), convert-scf-to-cf, convert-to-llvm)' %s | FileCheck %s
// CHECK-LABEL: @main
// CHECK: llvm
>From 7d4d56e86a9fec42953cdb29bb1df6852096a897 Mon Sep 17 00:00:00 2001
From: Jeremy Kun <j2kun at users.noreply.github.com>
Date: Wed, 19 Jun 2024 13:07:37 -0700
Subject: [PATCH 06/12] fix comments
---
mlir/docs/Tutorials/MlirOpt.md | 4 +++-
1 file changed, 3 insertions(+), 1 deletion(-)
diff --git a/mlir/docs/Tutorials/MlirOpt.md b/mlir/docs/Tutorials/MlirOpt.md
index 95babc939e427..06cb8f8c8016d 100644
--- a/mlir/docs/Tutorials/MlirOpt.md
+++ b/mlir/docs/Tutorials/MlirOpt.md
@@ -71,6 +71,7 @@ The first defines a function that counts the leading zeroes of a 32-bit integer
using the [`math` dialect's](/docs/Dialects/MathOps/) `ctlz` operation.
```mlir
+// mlir/test/Examples/mlir-opt/ctlz.mlir
func.func @main(%arg0: i32) -> i32 {
%0 = math.ctlz %arg0 : i32
func.return %0 : i32
@@ -110,6 +111,7 @@ The second program is a sequence of loops
that exhibits poor cache locality.
```mlir
+// mlir/test/Examples/mlir-opt/loop_fusion.mlir
func.func @producer_consumer_fusion(%arg0: memref<10xf32>, %arg1: memref<10xf32>) {
%0 = memref.alloc() : memref<10xf32>
%1 = memref.alloc() : memref<10xf32>
@@ -175,7 +177,7 @@ to generate LLVM-IR.
Recall our ctlz program:
```mlir
-# mlir/test/Examples/mlir-opt/ctlz.mlir
+// mlir/test/Examples/mlir-opt/ctlz.mlir
func.func @main(%arg0: i32) -> i32 {
%0 = math.ctlz %arg0 : i32
func.return %0 : i32
>From 9f4832d8be9a7768c51807df95acef6006012dc9 Mon Sep 17 00:00:00 2001
From: Jeremy Kun <kun.jeremy at gmail.com>
Date: Wed, 19 Jun 2024 15:21:42 -0700
Subject: [PATCH 07/12] Update mlir/docs/Tutorials/MlirOpt.md
Co-authored-by: Mehdi Amini <joker.eph at gmail.com>
---
mlir/docs/Tutorials/MlirOpt.md | 2 +-
1 file changed, 1 insertion(+), 1 deletion(-)
diff --git a/mlir/docs/Tutorials/MlirOpt.md b/mlir/docs/Tutorials/MlirOpt.md
index 06cb8f8c8016d..e1efc30e6d7eb 100644
--- a/mlir/docs/Tutorials/MlirOpt.md
+++ b/mlir/docs/Tutorials/MlirOpt.md
@@ -20,7 +20,7 @@ see [the MLIR paper](https://arxiv.org/abs/2002.11054).
Two of the central concepts in MLIR are *dialects* and *lowerings*.
In traditional compilers, there is typically one "dialect,"
called an *intermediate representation*, or IR,
-that is the textual or data-structural description of a program
+that is the textual or data-structural representation of a program
within the scope of the compiler's execution.
For example, in GCC the IR is called GIMPLE,
and in LLVM it's called LLVM-IR.
>From c94e76c7061e41af73a2d87f94f15a57493b378c Mon Sep 17 00:00:00 2001
From: Jeremy Kun <kun.jeremy at gmail.com>
Date: Wed, 19 Jun 2024 15:24:25 -0700
Subject: [PATCH 08/12] Update mlir/docs/Tutorials/MlirOpt.md
Co-authored-by: Mehdi Amini <joker.eph at gmail.com>
---
mlir/docs/Tutorials/MlirOpt.md | 2 +-
1 file changed, 1 insertion(+), 1 deletion(-)
diff --git a/mlir/docs/Tutorials/MlirOpt.md b/mlir/docs/Tutorials/MlirOpt.md
index e1efc30e6d7eb..e1d592443924e 100644
--- a/mlir/docs/Tutorials/MlirOpt.md
+++ b/mlir/docs/Tutorials/MlirOpt.md
@@ -66,7 +66,7 @@ and produces non-MLIR program representations as output.
## Two example programs
-Here are two MLIR programs.
+Here are the textual representation of two MLIR programs.
The first defines a function that counts the leading zeroes of a 32-bit integer (`i32`)
using the [`math` dialect's](/docs/Dialects/MathOps/) `ctlz` operation.
>From 93e28ebc047dfe0b4b906bba444aa2d15ed208b1 Mon Sep 17 00:00:00 2001
From: Jeremy Kun <kun.jeremy at gmail.com>
Date: Wed, 19 Jun 2024 15:41:02 -0700
Subject: [PATCH 09/12] Update mlir/docs/Tutorials/MlirOpt.md
Co-authored-by: Mehdi Amini <joker.eph at gmail.com>
---
mlir/docs/Tutorials/MlirOpt.md | 2 +-
1 file changed, 1 insertion(+), 1 deletion(-)
diff --git a/mlir/docs/Tutorials/MlirOpt.md b/mlir/docs/Tutorials/MlirOpt.md
index e1d592443924e..e71dbe4ada396 100644
--- a/mlir/docs/Tutorials/MlirOpt.md
+++ b/mlir/docs/Tutorials/MlirOpt.md
@@ -157,7 +157,7 @@ as well as emitting debug and diagnostic data.
Running `mlir-opt` with no flags will consume MLIR input
from standard in, parse and run verifiers on it,
-and write the MLIR back to standard out.
+and write the textual format back to standard out.
This is a good way to test if an input MLIR is well-formed.
`mlir-opt --help` shows a complete list of flags
>From cf530f5eedb515edb14a27eaf9c69872c2464b15 Mon Sep 17 00:00:00 2001
From: Jeremy Kun <kun.jeremy at gmail.com>
Date: Wed, 19 Jun 2024 15:41:56 -0700
Subject: [PATCH 10/12] Update mlir/docs/Tutorials/MlirOpt.md
Co-authored-by: Mehdi Amini <joker.eph at gmail.com>
---
mlir/docs/Tutorials/MlirOpt.md | 2 +-
1 file changed, 1 insertion(+), 1 deletion(-)
diff --git a/mlir/docs/Tutorials/MlirOpt.md b/mlir/docs/Tutorials/MlirOpt.md
index e71dbe4ada396..eaee70ac3c210 100644
--- a/mlir/docs/Tutorials/MlirOpt.md
+++ b/mlir/docs/Tutorials/MlirOpt.md
@@ -155,7 +155,7 @@ the `mlir-opt` binary (located in `build/bin`)
is the entry point for running passes and lowerings,
as well as emitting debug and diagnostic data.
-Running `mlir-opt` with no flags will consume MLIR input
+Running `mlir-opt` with no flags will consume textual or bytecode IR
from standard in, parse and run verifiers on it,
and write the textual format back to standard out.
This is a good way to test if an input MLIR is well-formed.
>From adcece80be9b13eb892b8dbc0f04979eda431a24 Mon Sep 17 00:00:00 2001
From: Jeremy Kun <j2kun at users.noreply.github.com>
Date: Wed, 24 Jul 2024 16:46:10 -0700
Subject: [PATCH 11/12] simplify presentation to just mlir-opt details
---
mlir/docs/Tutorials/MlirOpt.md | 291 +++------------------
mlir/test/Examples/mlir-opt/ctlz_llvm.mlir | 4 +-
2 files changed, 43 insertions(+), 252 deletions(-)
diff --git a/mlir/docs/Tutorials/MlirOpt.md b/mlir/docs/Tutorials/MlirOpt.md
index eaee70ac3c210..7b37040462385 100644
--- a/mlir/docs/Tutorials/MlirOpt.md
+++ b/mlir/docs/Tutorials/MlirOpt.md
@@ -1,154 +1,22 @@
# Using `mlir-opt`
-`mlir-opt` is the command-line entry point for running passes and lowerings on MLIR code.
-This tutorial will explain how to use `mlir-opt` to run passes, and explain
-some details about MLIR's built-in dialects along the way.
+`mlir-opt` is a command-line entry point for running passes and lowerings on MLIR code.
+This tutorial will explain how to use `mlir-opt`, show some examples of its usage,
+and mention some useful tips for working with it.
Prerequisites:
- [Building MLIR from source](/getting_started/)
+- [MLIR Language Reference](/docs/LangRef/)
[TOC]
-## Overview
-
-We start with a brief summary of context that helps to frame
-the uses of `mlir-opt` detailed in this article.
-For a deeper dive on motivation and design,
-see [the MLIR paper](https://arxiv.org/abs/2002.11054).
-
-Two of the central concepts in MLIR are *dialects* and *lowerings*.
-In traditional compilers, there is typically one "dialect,"
-called an *intermediate representation*, or IR,
-that is the textual or data-structural representation of a program
-within the scope of the compiler's execution.
-For example, in GCC the IR is called GIMPLE,
-and in LLVM it's called LLVM-IR.
-Compilers typically convert an input program to their IR,
-run optimization passes,
-and then convert the optimized IR to machine code.
-
-MLIR's philosophy is to split the job into smaller steps.
-First, MLIR allows one to define many IRs called *dialects*,
-some considered "high level" and some "low level,"
-but each with a set of types, operations, metadata,
-and semantics that defines what the operations do.
-Different dialects may coexist in the same program.
-Then, one writes a set of *lowering passes*
-that incrementally converts different parts of the program
-from higher level dialects to lower and lower dialects
-until you get to machine code
-(or, in many cases, LLVM, which finishes the job).
-Along the way,
-*optimizing passes* are run to make the code more efficient.
-The main point here is that the high level dialects exist
-*so that* they make it easy to write these important optimizing passes.
-
-A central motivation for building MLIR
-was to build the `affine` dialect,
-which is designed to enable [polyhedral optimizations](https://polyhedral.info/)
-for loop transformations.
-Compiler engineers had previously implemented polyhedral optimizations
-in LLVM and GCC (without an `affine` dialect),
-and it was difficult because they had to reconstruct well-structured loop nests
-from a much more complicated set of low-level operations.
-Having a higher level `affine` dialect preserves the loop nest structure
-at an abstraction layer that makes it easier to write optimizations,
-and then discards it during lowering passes.
-
-The `mlir-opt` tool can run both
-optimization passes and lowerings,
-though the final code generation
-is performed by a different tool called `mlir-translate`.
-In particular, `mlir-opt` consumes MLIR as input and produce MLIR as output,
-while `mlir-translate` consumes MLIR as input
-and produces non-MLIR program representations as output.
-
-## Two example programs
-
-Here are the textual representation of two MLIR programs.
-The first defines a function that counts the leading zeroes of a 32-bit integer (`i32`)
-using the [`math` dialect's](/docs/Dialects/MathOps/) `ctlz` operation.
+## `mlir-opt` basics
-```mlir
-// mlir/test/Examples/mlir-opt/ctlz.mlir
-func.func @main(%arg0: i32) -> i32 {
- %0 = math.ctlz %arg0 : i32
- func.return %0 : i32
-}
-```
-
-This shows the basic structure of an MLIR operation
-([see here](https://mlir.llvm.org/docs/LangRef/#operations) for a more complete spec).
-Variable names are prefixed with `%`,
-functions by `@`,
-and each variable/value in a program has a type,
-often expressed after a colon.
-In this case all the types are `i32`,
-except for the function type which is `(i32) -> i32`
-(not specified explicitly above, but you'll see it in the `func.call` later).
-
-Each statement is anchored around an expression like `math.ctlz`
-which specifies the dialect [`math`](https://mlir.llvm.org/docs/Dialects/MathOps/) via a namespace,
-and the operation [`ctlz`](https://mlir.llvm.org/docs/Dialects/MathOps/#mathctlz-mathcountleadingzerosop) after the `.`.
-The rest of the syntax of the operation
-is determined by a parser defined by the dialect,
-and so many operations will have different syntaxes.
-In the case of `math.ctlz`,
-the sole argument is an integer whose leading zeros are to be counted,
-and the trailing ` : i32` denotes the output type storing the count.
-
-It's important to note that [`func`](https://mlir.llvm.org/docs/Dialects/Func/) is itself a dialect,
-and [`func.func`](https://mlir.llvm.org/docs/Dialects/Func/#funcfunc-funcfuncop) is an operation,
-where the braces and the function's body is part of the syntax.
-In MLIR a list of operations within braces is called a [*region*](https://mlir.llvm.org/docs/LangRef/#regions),
-and an operation can have zero regions like `math.ctlz`,
-one region like `func.func`,
-or multiple regions like [`scf.if`](https://mlir.llvm.org/docs/Dialects/SCFDialect/#scfif-scfifop),
-which has a region for each of its two control flow branches.
-
-The second program is a sequence of loops
-that exhibits poor cache locality.
-
-```mlir
-// mlir/test/Examples/mlir-opt/loop_fusion.mlir
-func.func @producer_consumer_fusion(%arg0: memref<10xf32>, %arg1: memref<10xf32>) {
- %0 = memref.alloc() : memref<10xf32>
- %1 = memref.alloc() : memref<10xf32>
- %cst = arith.constant 0.000000e+00 : f32
- affine.for %arg2 = 0 to 10 {
- affine.store %cst, %0[%arg2] : memref<10xf32>
- affine.store %cst, %1[%arg2] : memref<10xf32>
- }
- affine.for %arg2 = 0 to 10 {
- %2 = affine.load %0[%arg2] : memref<10xf32>
- %3 = arith.addf %2, %2 : f32
- affine.store %3, %arg0[%arg2] : memref<10xf32>
- }
- affine.for %arg2 = 0 to 10 {
- %2 = affine.load %1[%arg2] : memref<10xf32>
- %3 = arith.mulf %2, %2 : f32
- affine.store %3, %arg1[%arg2] : memref<10xf32>
- }
- return
-}
-```
-
-This program introduces some additional dialects.
-The [`affine` dialect](https://mlir.llvm.org/docs/Dialects/Affine/) mentioned in the introduction
-represents well-structured loop nests,
-and the [`affine.for` operation](https://mlir.llvm.org/docs/Dialects/Affine/#affinefor-affineaffineforop)
-whose region corresponds to the loop's body.
-`affine.for` also showcases some custom-defined syntax
-to represent the loop bounds and loop induction variable.
-The [`memref` dialect](https://mlir.llvm.org/docs/Dialects/MemRef/)
-defines types and operations related to memory management
-with pointer semantics.
-Note also that while `memref` has store and load operations,
-`affine` has its own that limit what types of memory accesses are allowed,
-so as to ensure the well-structuredness of the loop nest.
-
-## Running `mlir-opt`
+The `mlir-opt` tool loads a textual IR or bytecode into an in-memory structure,
+and optionally executes a sequence of passes
+before serializing back the IR (textual form by default).
+It is intended as a testing and debugging utility.
After building the MLIR project,
the `mlir-opt` binary (located in `build/bin`)
@@ -164,17 +32,11 @@ This is a good way to test if an input MLIR is well-formed.
(there are nearly 1000).
Each pass gets its own flag.
-## Lowering `ctlz`
-
-Next we will show two of MLIR's lowering passes.
-The first, `convert-math-to-llvm`, converts the `ctlz` op
-to the `llvm` dialect's [`intr.ctlz` op](https://mlir.llvm.org/docs/Dialects/LLVM/#llvmintrctlz-llvmcountleadingzerosop)
-which is an LLVM intrinsic.
-Note that `llvm` here is MLIR's `llvm` dialect,
-which would still need to be processed through `mlir-translate`
-to generate LLVM-IR.
+## Running a pass
-Recall our ctlz program:
+Next we run [`--convert-to-llvm`](/docs/Passes/#-convert-to-llvm),
+which converts all supported dialects to the `llvm` dialect,
+on the following IR:
```mlir
// mlir/test/Examples/mlir-opt/ctlz.mlir
@@ -201,101 +63,14 @@ module {
}
```
-As you can see, the `math` dialect was the only thing that changed
-due to the lowering.
-The `func` dialect was left alone,
-even though it also needs to be converted to the `llvm` dialect
+Note that `llvm` here is MLIR's `llvm` dialect,
+which would still need to be processed through `mlir-translate`
to generate LLVM-IR.
-What if the target machine does not have a `ctlz` intrinsic?
-In this case, one can run the `--convert-math-to-funcs`
-pass, which replaces the op with an implementation using
-other MLIR dialects.
+## Running a pass with options
-```bash
-build/bin/mlir-opt --convert-math-to-funcs=convert-ctlz mlir/test/Examples/mlir-opt/ctlz.mlir
-```
-
-You will see something similar to:
-
-```mlir
-module {
- func.func @main(%arg0: i32) -> i32 {
- %0 = call @__mlir_math_ctlz_i32(%arg0) : (i32) -> i32
- return %0 : i32
- }
- func.func private @__mlir_math_ctlz_i32(%arg0: i32) -> i32 attributes {llvm.linkage = #llvm.linkage<linkonce_odr>} {
- %c32_i32 = arith.constant 32 : i32
- %c0_i32 = arith.constant 0 : i32
- %0 = arith.cmpi eq, %arg0, %c0_i32 : i32
- %1 = scf.if %0 -> (i32) {
- scf.yield %c32_i32 : i32
- } else {
- %c1 = arith.constant 1 : index
- %c1_i32 = arith.constant 1 : i32
- %c32 = arith.constant 32 : index
- %c0_i32_0 = arith.constant 0 : i32
- %2:2 = scf.for %arg1 = %c1 to %c32 step %c1 iter_args(%arg2 = %arg0, %arg3 = %c0_i32_0) -> (i32, i32) {
- %3 = arith.cmpi slt, %arg2, %c0_i32 : i32
- %4:2 = scf.if %3 -> (i32, i32) {
- scf.yield %arg2, %arg3 : i32, i32
- } else {
- %5 = arith.addi %arg3, %c1_i32 : i32
- %6 = arith.shli %arg2, %c1_i32 : i32
- scf.yield %6, %5 : i32, i32
- }
- scf.yield %4#0, %4#1 : i32, i32
- }
- scf.yield %2#1 : i32
- }
- return %1 : i32
- }
-}
-```
-
-The algorithm above is not relevant to this tutorial,
-but either way it is quite simple:
-count the leading zeros by shifting the input left one bit at a time
-until it becomes negative (as a signed integer),
-because that occurs exactly when its leading bit is a 1.
-Then add a special case to handle zero,
-which would loop infinitely otherwise.
-
-Here you can see two more MLIR dialects.
-[`arith`](https://mlir.llvm.org/docs/Dialects/ArithOps/)
-is for low-level arithmetic
-and boolean conditions on integers and floats.
-You can define constants,
-compare integers with `arith.cmpi`,
-and do things like add and bit shift (`arith.shli` is a left shift).
-[`scf`](https://mlir.llvm.org/docs/Dialects/SCFDialect/),
-short for "structured control flow,"
-defines for loops, while loops,
-and control flow branching using regions.
-`scf.yield` defines the "output" value
-from each region of an if/else operation or loop body
-which is necessary here because an `if` operation has a result value.
-The "structured" in `scf` is in contrast to
-[`cf`](https://mlir.llvm.org/docs/Dialects/ControlFlowDialect/),
-for "(unstructured) control flow,"
-which does low-level, region-free control flow
-that jumps between SSA blocks on a control flow graph.
-
-Two other minor aspects of the syntax are on display.
-First is the syntax `%4:2`,
-which defines a variable `%4` as a tuple of two values.
-The corresponding `%4#1` accesses the second entry in the tuple.
-Second, there's a type called `index` that is different from `i32`.
-Though they both represent integers,
-[`index`](https://mlir.llvm.org/docs/Rationale/Rationale/#integer-signedness-semantics) is a platform-dependent integer type
-suitable for indexing arrays,
-representing sizes and dimensions of things,
-and, in the above program,
-being loop counters and iteration bounds.
-
-## Optimizing loop nests
-
-Recall our second program, the poorly-tuned loops.
+Next we will show how to run a pass that takes configuration options.
+Consider the following IR containing loops with poor cache locality.
```mlir
// mlir/test/Examples/mlir-opt/loop_fusion.mlir
@@ -356,7 +131,8 @@ If this value is set to zero on the command line,
the pass will not fuse the loops.
```bash
-build/bin/mlir-opt --affine-loop-fusion='fusion-compute-tolerance=0' mlir/test/Examples/mlir-opt/loop_fusion.mlir
+build/bin/mlir-opt --affine-loop-fusion='fusion-compute-tolerance=0' \
+mlir/test/Examples/mlir-opt/loop_fusion.mlir
```
```mlir
@@ -387,7 +163,7 @@ module {
Options passed to a pass
should come in the form of a quoted string
(to join all options into a single shell argument)
-with space-separated `key=value` pairs.
+with space-separated `key=value` pairs for each option.
## Building a pass pipeline on the command line
@@ -397,7 +173,7 @@ First, by simply placing the pass flags one after the other,
they will be run in order.
```bash
-build/bin/mlir-opt --convert-math-to-llvm --convert-func-to-llvm mlir/test/Examples/mlir-opt/ctlz.mlir
+build/bin/mlir-opt --convert-to-llvm --canonicalize mlir/test/Examples/mlir-opt/ctlz.mlir
```
Passes can also be configured to run
@@ -409,23 +185,38 @@ on each `func` separately, by running
```bash
build/bin/mlir-opt mlir/test/Examples/mlir-opt/ctlz.mlir --pass-pipeline='
builtin.module(
- convert-math-to-funcs{convert-ctlz=1},
func.func(cse,canonicalize),
- convert-scf-to-cf,
convert-to-llvm
)'
```
The outer nesting tells `mlir-opt` to run the pass pipeline
on each `module` op,
-and then within that to run `convert-math-to-funcs`,
-then (on each `func.func` op), the [`cse`](https://mlir.llvm.org/docs/Passes/#-cse)
+and then within that to run (on each `func.func` op),
+the [`cse`](https://mlir.llvm.org/docs/Passes/#-cse)
and [`canonicalize`](https://mlir.llvm.org/docs/Passes/#-canonicalize) passes,
and then convert the rest to the `llvm` dialect.
For a spec of the pass-pipeline textual description language,
see [the docs](https://mlir.llvm.org/docs/PassManagement/#textual-pass-pipeline-specification).
+## Useful CLI flags
+
+- `--debug` prints all debug information produced by `LLVM_DEBUG` calls.
+- `--debug-only="my-tag"` prints only the debug information produced by `LLVM_DEBUG`
+ in files that have the macro `#define DEBUG_TYPE "my-tag"`.
+ This often allows you to print only debug information associated with a specific pass.
+ - `"greedy-rewriter"` only prints debug information
+ for patterns applied with the greedy rewriter engine.
+ - `"dialect-conversion"` only prints debug information
+ for the dialect conversion framework.
+ - `--emit-bytecode` emits MLIR in the bytecode format.
+ - `--mlir-pass-statistics` print statistics about the passes run.
+ These are generated via [pass statistics](https://mlir.llvm.org/docs/PassManagement/#pass-statistics).
+ - `--mlir-print-ir-after-all` prints the IR after each pass.
+ See also `--mlir-print-ir-after-change` and `--mlir-print-ir-after-failure`
+ - `--mlir-timing` displays execution times of each pass.
+
## Further readering
- [List of passes](https://mlir.llvm.org/docs/Passes/)
diff --git a/mlir/test/Examples/mlir-opt/ctlz_llvm.mlir b/mlir/test/Examples/mlir-opt/ctlz_llvm.mlir
index d8c5b7550be0c..01d6c2748f59a 100644
--- a/mlir/test/Examples/mlir-opt/ctlz_llvm.mlir
+++ b/mlir/test/Examples/mlir-opt/ctlz_llvm.mlir
@@ -1,7 +1,7 @@
-// RUN: mlir-opt --convert-math-to-llvm %s | FileCheck %s
+// RUN: mlir-opt --convert-to-llvm %s | FileCheck %s
// CHECK-LABEL: @main
-// CHECK-NEXT: llvm.intr.ctlz
+// CHECK: llvm.intr.ctlz
func.func @main(%arg0: i32) -> i32 {
%0 = math.ctlz %arg0 : i32
func.return %0 : i32
>From 5c91b9bde408cdfc3c1caa95fad859aecf5c05e7 Mon Sep 17 00:00:00 2001
From: Jeremy Kun <j2kun at users.noreply.github.com>
Date: Wed, 24 Jul 2024 16:49:52 -0700
Subject: [PATCH 12/12] simplify tests
---
mlir/test/Examples/mlir-opt/ctlz.mlir | 7 +++----
mlir/test/Examples/mlir-opt/ctlz_funcs.mlir | 10 ----------
mlir/test/Examples/mlir-opt/ctlz_llvm.mlir | 8 --------
mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir | 2 +-
4 files changed, 4 insertions(+), 23 deletions(-)
delete mode 100644 mlir/test/Examples/mlir-opt/ctlz_funcs.mlir
delete mode 100644 mlir/test/Examples/mlir-opt/ctlz_llvm.mlir
diff --git a/mlir/test/Examples/mlir-opt/ctlz.mlir b/mlir/test/Examples/mlir-opt/ctlz.mlir
index f9b667851792c..01d6c2748f59a 100644
--- a/mlir/test/Examples/mlir-opt/ctlz.mlir
+++ b/mlir/test/Examples/mlir-opt/ctlz.mlir
@@ -1,8 +1,7 @@
-// This file is left in-tree despite having no assertions so it can be
-// referenced by the tutorial text.
-
-// RUN: mlir-opt %s
+// RUN: mlir-opt --convert-to-llvm %s | FileCheck %s
+// CHECK-LABEL: @main
+// CHECK: llvm.intr.ctlz
func.func @main(%arg0: i32) -> i32 {
%0 = math.ctlz %arg0 : i32
func.return %0 : i32
diff --git a/mlir/test/Examples/mlir-opt/ctlz_funcs.mlir b/mlir/test/Examples/mlir-opt/ctlz_funcs.mlir
deleted file mode 100644
index 894f24d56dc8a..0000000000000
--- a/mlir/test/Examples/mlir-opt/ctlz_funcs.mlir
+++ /dev/null
@@ -1,10 +0,0 @@
-// RUN: mlir-opt --convert-math-to-funcs=convert-ctlz %s | FileCheck %s
-
-// CHECK-LABEL: @main
-// CHECK-NEXT: call @__mlir_math_ctlz_i32
-
-// CHECK-LABEL: func.func private @__mlir_math_ctlz_i32
-func.func @main(%arg0: i32) -> i32 {
- %0 = math.ctlz %arg0 : i32
- func.return %0 : i32
-}
diff --git a/mlir/test/Examples/mlir-opt/ctlz_llvm.mlir b/mlir/test/Examples/mlir-opt/ctlz_llvm.mlir
deleted file mode 100644
index 01d6c2748f59a..0000000000000
--- a/mlir/test/Examples/mlir-opt/ctlz_llvm.mlir
+++ /dev/null
@@ -1,8 +0,0 @@
-// RUN: mlir-opt --convert-to-llvm %s | FileCheck %s
-
-// CHECK-LABEL: @main
-// CHECK: llvm.intr.ctlz
-func.func @main(%arg0: i32) -> i32 {
- %0 = math.ctlz %arg0 : i32
- func.return %0 : i32
-}
diff --git a/mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir b/mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir
index 70b639a09062f..0d0966f8bd320 100644
--- a/mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir
+++ b/mlir/test/Examples/mlir-opt/ctlz_pipeline.mlir
@@ -1,4 +1,4 @@
-// RUN: mlir-opt --pass-pipeline=' builtin.module( convert-math-to-funcs{convert-ctlz=1}, func.func(cse,canonicalize), convert-scf-to-cf, convert-to-llvm)' %s | FileCheck %s
+// RUN: mlir-opt --pass-pipeline=' builtin.module(convert-math-to-funcs{convert-ctlz=1}, func.func(cse,canonicalize), convert-scf-to-cf, convert-to-llvm)' %s | FileCheck %s
// CHECK-LABEL: @main
// CHECK: llvm
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