| name | mlir |
| description | MLIR skill for multi-level intermediate representation. Use when writing custom dialects, defining ops with ODS, writing lowering passes, running mlir-opt, or building ML compilers with Torch-MLIR/IREE. Activates on queries about MLIR, dialect, ODS, mlir-opt, linalg, lowering pass, or Torch-MLIR. |
MLIR
Purpose
Guide agents through MLIR (Multi-Level IR): ops, regions, blocks, and values; built-in dialects (arith, func, memref, affine, linalg); writing custom dialects with ODS; lowering passes with ConversionPattern; mlir-opt CLI; and ML compiler use cases (Torch-MLIR, IREE).
When to Use
- Building a domain-specific compiler IR (graphics, ML, hardware DSL)
- Lowering high-level ops to LLVM or GPU dialects
- Writing progressive lowering pipelines (linalg → loops → LLVM)
- Integrating with IREE or Torch-MLIR for ML deployment
- Creating reusable transformation passes across dialects
- Prototyping compiler optimizations at the right abstraction level
Workflow
1. MLIR structure
Module
└── func.func @main()
└── region
└── block ^bb0:
└── operations (ops) producing SSA values
Key concepts:
- Operation — instruction-like node (
arith.addi, memref.load)
- Region — container of blocks (functions, control flow)
- Block — CFG node with ordered ops
- Value — SSA result of an op or block argument
2. Built-in dialects
| Dialect | Purpose |
|---|
arith | Integer/float arithmetic |
func | Function definitions and calls |
memref | Buffer abstraction with shapes/strides |
affine | Affine loop nests, map/set constraints |
linalg | Structured linear algebra ops |
scf | Structured control flow (for, if) |
llvm | LLVM IR dialect for final lowering |
gpu | GPU kernel launches |
// example.mlir
func.func @add(%a: memref<4xf32>, %b: memref<4xf32>, %c: memref<4xf32>) {
%c0 = arith.constant 0 : index
%c4 = arith.constant 4 : index
scf.for %i = %c0 to %c4 step %c1 {
%av = memref.load %a[%i] : memref<4xf32>
%bv = memref.load %b[%i] : memref<4xf32>
%sum = arith.addf %av, %bv : f32
memref.store %sum, %c[%i] : memref<4xf32>
}
return
}
3. mlir-opt CLI
mlir-opt example.mlir
mlir-opt example.mlir -canonicalize
mlir-opt affine.mlir -lower-affine
mlir-opt input.mlir \
--linalg-bufferize \
--convert-linalg-to-loops \
--convert-scf-to-cf \
--convert-arith-to-llvm \
--convert-memref-to-llvm \
--convert-func-to-llvm \
-o llvm.mlir
4. ODS — Operation Definition Specification
// MyOps.td
include "mlir/IR/OpBase.td"
def My_Dialect : Dialect {
let name = "my";
let summary = "My custom dialect";
}
class My_Op<string mnemonic, list<Trait> traits = []> :
Op<My_Dialect, mnemonic, traits>;
def AddOp : My_Op<"add", [Pure]> {
let summary = "Add two values";
let arguments = (ins AnyType:$lhs, AnyType:$rhs);
let results = (outs AnyType:$result);
let assemblyFormat = "$lhs `,` $rhs attr-dict `:` type($result)";
}
mlir-tblgen -gen-op-defs MyOps.td -I include/ -o MyOps.cpp.inc
5. Custom dialect C++ implementation
#include "mlir/IR/DialectImplementation.h"
#include "MyDialect.h"
#include "MyOps.cpp.inc"
void MyDialect::initialize() {
addOperations<
#define GET_OP_LIST
#include "MyOps.cpp.inc"
>();
}
#define GET_OP_CLASSES
#include "MyOps.cpp.inc"
6. Lowering passes
#include "mlir/Conversion/LLVMCommon/ConversionTarget.h"
#include "mlir/Transforms/DialectConversion.h"
struct AddOpLowering : OpConversionPattern<my::AddOp> {
using OpConversionPattern::OpConversionPattern;
LogicalResult matchAndRewrite(my::AddOp op, OpAdaptor adaptor,
ConversionPatternRewriter &rewriter) const override {
rewriter.replaceOpWithNewOp<arith::AddIOp>(op, adaptor.getLhs(), adaptor.getRhs());
return success();
}
};
void populateLoweringPatterns(RewritePatternSet &patterns) {
patterns.add<AddOpLowering>(patterns.getContext());
}
mlir::ConversionTarget target(*context);
target.addIllegalDialect<my::MyDialect>();
target.addLegalDialect<arith::ArithDialect>();
if (failed(applyPartialConversion(module, target, std::move(patterns))))
signalPassFailure();
7. linalg for ML compilers
%0 = linalg.matmul ins(%A, %B : tensor<128x256xf32>, tensor<256x64xf32>)
outs(%C : tensor<128x64xf32>) -> tensor<128x64xf32>
Lowering path: linalg → scf loops → affine → llvm
8. Torch-MLIR and IREE
python -m torch_mlir.tools.import-onnx --onnx-model model.onnx -o model.mlir
iree-compile --iree-hal-target-backends=llvm-cpu model.mlir -o model.vmfb
iree-run-module --module=model.vmfb --function=main
Common Problems
| Symptom | Cause | Fix |
|---|
| Dialect not registered | Missing registerDialect | Register in tool/pass init |
| ODS build failure | TableGen include path | Check -I for mlir/IR/OpBase.td |
| Lowering incomplete | Illegal ops remain | Debug with --mlir-print-ir-after-failure |
| Type mismatch in pattern | Wrong adaptor types | Use OpAdaptor typed accessors |
| mlir-opt crash | Invalid IR | Run -verify-each |
| Empty function after lowering | All ops illegal, none converted | Add missing patterns |
Related Skills
skills/compiler-internals/llvm-passes — LLVM pass equivalents
skills/compiler-internals/compiler-frontend — AST to MLIR import
skills/compiler-internals/jit-compilation — JIT compiled MLIR→LLVM
skills/compilers/llvm — LLVM IR output target
skills/gpu/cuda — GPU dialect lowering targets
skills/gpu/triton-lang — alternative GPU kernel IR