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Vidyasagar Ananthan 920acd2c12 [rocm-libraries] ROCm/rocm-libraries#5168 (commit 8b5afcb) 
[CK] [CK_Tile] Add GroupConv to Kernel Dispatcher

## Motivation

This PR adds CK Tile group convolution (forward, backward-data,
backward-weight) support to the kernel dispatcher, matching and unifying
with the existing dispatcher GEMM infrastructure in architecture and
usability. The dispatcher provides a unified kernel dispatch system with
both C++ and Python frontends, and until now only supported GEMM
operations. This PR enables framework integrators to use the same
declarative kernel workflow for convolutions as they do for GEMM:
declare kernels, build a registry JIT, select kernels within the
registry at runtime, and dispatch to GPU. Future PRs will include
runtime kernel selection heuristics for autotuning of kernel parameters
based on (problem, hardware arch).

## Technical Details

Grouped convolution support has been added to the CK Tile Dispatcher
with generated_conv_backend.hpp enabling dispatcher.run(in, wei, out,
problem) for all 6 conv variants (fwd/bwdd/bwdw x 2D/3D), runtime
heuristic kernel selection, and GroupedConvKernelKey with full
ConvConfigBase fields. Python side adds parallel JIT via
registry.build(max_workers) and heuristic registry.select(). Includes 7
C++ and 6 Python examples covering all directions with CPU reference
validation, and shared infrastructure improvements (BaseRegistry CRTP,
structured exceptions). As a sanity check, JIT compile times for a
single kernel remains the same and for multiple kernels there is better
parallelism:
Kernels | 1 worker | 8 workers
1 | 7.7 s | 7.7 s
2 | 15.9 s | 8.2 s
4 | 33.4 s | 9.7 s
6 | 52.3 s | 10.2 s

## Test Plan

145 ephemeral unit tests have been added to test basic functionality.
All 30 examples/integration tests run end-to-end on gfx950 (MI350): 7
C++ conv, 7 C++ GEMM, 6 Python conv, 10 Python GEMM. CPU reference
validation for forward, backward-data, and backward-weight (2D) in both
C++ and Python examples pass.

## Test Result

30 examples pass. Peak performance: 132 TFLOPS (Batch-32 forward 56x56),
53 TFLOPS (pointwise 1x1). CPU reference accuracy: max_abs_diff < 0.002
for all directions (fp16 vs fp32 reference).

## Submission Checklist

- [x] Look over the contributing guidelines at
https://github.com/ROCm/ROCm/blob/develop/CONTRIBUTING.md#pull-requests.
2026-04-09 17:39:35 +00:00

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# CK Tile Dispatcher
A unified kernel dispatch system for AMD GPUs with C++ and Python frontends, supporting GEMM and Grouped Convolution operations.
**Validated Platform:** AMD Instinct MI300 series (gfx942)
---
## Table of Contents
1. [Quick Start](#quick-start)
2. [Docker Setup](#docker-setup-recommended)
3. [Prerequisites](#prerequisites)
4. [Step-by-Step Build Guide](#step-by-step-build-guide)
5. [Running Examples](#running-examples)
6. [External Integration](#external-integration)
7. [Core Concepts](#core-concepts)
8. [Operation Support Matrix](#operation-support-matrix)
9. [Troubleshooting](#troubleshooting)
10. [File Structure](#file-structure)
---
## Quick Start
**Complete setup from scratch (5 minutes):**
```bash
# From the composable_kernel root directory
cd dispatcher
# Step 1: Create build directory
mkdir -p build && cd build
# Step 2: Configure CMake
cmake .. \
-DCMAKE_PREFIX_PATH=/opt/rocm \
-DCMAKE_CXX_COMPILER=/opt/rocm/bin/hipcc \
-DCMAKE_BUILD_TYPE=Release \
-DGPU_TARGETS="gfx942" \
-DBUILD_DISPATCHER_EXAMPLES=ON
# Step 3: Generate kernels and build (CMake handles this automatically)
make -j$(nproc)
# Step 4: Run C++ examples
./examples/gemm_01_basic
# Step 5: Build Python libraries (required for Python examples)
make python_libs
# Step 6: Run Python examples (from dispatcher directory)
cd ..
python3 examples/gemm/python/01_basic_gemm.py
```
---
## Docker Setup (Recommended)
For a reproducible build environment, use the official ROCm Docker image:
### Step 1: Pull and Run Container
```bash
# Pull the CK Docker image
docker pull rocm/composable_kernel:ck_ub24.04_rocm7.0.1
# Run container with GPU access
docker run \
-it \
--privileged \
--device=/dev/kfd \
--device=/dev/dri \
--group-add video \
--group-add render \
-w /root/workspace \
-v $(pwd):/root/workspace \
rocm/composable_kernel:ck_ub24.04_rocm7.0.1 \
/bin/bash
```
> **Note:** Omit `--device` flags if building without GPU access.
### Step 2: Clone and Build
```bash
# Inside the container
git clone https://github.com/ROCm/composable_kernel.git
cd composable_kernel
git checkout builder-dispatch-tile-gemm
# Set up Python environment
python3 -m venv .venv
source .venv/bin/activate
pip install numpy
# Build dispatcher
cd dispatcher
mkdir -p build && cd build
cmake .. \
-DCMAKE_PREFIX_PATH=/opt/rocm \
-DCMAKE_CXX_COMPILER=/opt/rocm/bin/hipcc \
-DCMAKE_BUILD_TYPE=Release \
-DGPU_TARGETS="gfx942" \
-DBUILD_DISPATCHER_EXAMPLES=ON
make -j$(nproc)
```
### One-Liner Build (inside container)
```bash
git clone https://github.com/ROCm/composable_kernel.git && \
cd composable_kernel && git checkout builder-dispatch-tile-gemm && \
python3 -m venv .venv && source .venv/bin/activate && pip install numpy && \
cd dispatcher && mkdir -p build && cd build && \
cmake .. -DCMAKE_PREFIX_PATH=/opt/rocm -DCMAKE_CXX_COMPILER=/opt/rocm/bin/hipcc \
-DCMAKE_BUILD_TYPE=Release -DGPU_TARGETS="gfx942" -DBUILD_DISPATCHER_EXAMPLES=ON && \
make -j$(nproc)
```
---
## Prerequisites
### Required Software
| Software | Minimum Version | Check Command |
|----------|-----------------|---------------|
| ROCm | 6.4+ | `rocminfo` |
| CMake | 3.16+ | `cmake --version` |
| Python | 3.8+ | `python3 --version` |
| NumPy | 1.20+ | `pip show numpy` |
| hipcc | (from ROCm) | `/opt/rocm/bin/hipcc --version` |
> **Note:** Newer GPU targets (gfx950, gfx1201) require ROCm 6.3+. For ROCm 6.4+, you can also use `amdclang++` instead of `hipcc`.
### Check Your GPU Architecture
```bash
# Find your GPU architecture
rocminfo | grep -i "gfx"
# Example output: "gfx942"
```
**Supported architectures:**
- **gfx942** - MI300X, MI300A, MI308, MI325 (Instinct MI300 series)
- **gfx90a** - MI200 series (MI250, MI250X)
- **gfx950** - MI350 series
- **gfx1101** - RDNA3 series
- **gfx1201** - RDNA4 series
### Install Python Dependencies
#### Core Dependencies (Required)
NumPy is required for Python examples and kernel generation. We recommend using a virtual environment:
**Option 1: Using standard venv**
```bash
# Create virtual environment
python3 -m venv .venv
# Activate virtual environment
source .venv/bin/activate # Linux/macOS
# .venv\Scripts\activate # Windows
# Install core dependencies
pip install -r python/requirements.txt
```
**Option 2: Using uv (faster alternative)**
```bash
# Install uv if not already installed
curl -LsSf https://astral.sh/uv/install.sh | sh
# Create and activate virtual environment
uv venv .venv
source .venv/bin/activate # Linux/macOS
# .venv\Scripts\activate # Windows
# Install core dependencies
uv pip install -r python/requirements.txt
```
**Option 3: System-wide install (not recommended)**
```bash
pip install -r python/requirements.txt
```
> **Note:** Always activate your virtual environment before running CMake or Python examples.
#### ML Heuristics Dependencies (Optional)
For ML-based kernel selection (examples 09-11), install additional dependencies:
```bash
# Activate your virtual environment first
source .venv/bin/activate
# Install ML dependencies (LightGBM, pandas, pyarrow, scikit-learn)
pip install -r requirements-ml.txt
```
**Why separate?** ML dependencies are large (especially pyarrow) and not needed for basic dispatcher usage. Install only if you need:
- ML-based kernel selection (`examples/gemm/python/09_ml_heuristic.py`)
- Model training (`heuristics/train.py`)
- Model evaluation (`heuristics/evaluate.py`)
- Automated benchmark analysis
**Core dependencies:** ~50 MB (NumPy only)
**With ML dependencies:** ~500 MB (includes LightGBM, pandas, pyarrow, scikit-learn)
### Supported Data Types
CK Tile supports a wide range of data types for GEMM operations:
| A dtype | B dtype | Acc dtype | Warp Tile Sizes | Notes |
|---------|---------|-----------|-----------------|-------|
| `fp32` | `fp32` | `fp32` | 16x16x4, 16x16x16 | Full precision |
| `fp16` | `fp16` | `fp32` | 32x32x8, 32x32x16, 16x16x16, 16x16x32 | Standard half |
| `bf16` | `bf16` | `fp32` | 32x32x8, 32x32x16, 16x16x16, 16x16x32 | Brain float 16 |
| `fp8` | `fp8` | `fp32` | 32x32x16, 32x32x32, 16x16x32, 16x16x64 | FP8 E4M3 |
| `fp8` | `bf8` | `fp32` | 32x32x16, 16x16x32 | Mixed FP8/BF8 |
| `bf8` | `fp8` | `fp32` | 32x32x16, 16x16x128 | Mixed BF8/FP8 |
| `bf8` | `bf8` | `fp32` | 32x32x16, 32x32x32, 16x16x32 | BF8 E5M2 |
| `int8` | `int8` | `int32` | 32x32x16, 16x16x32, 16x16x16 | Integer GEMM |
| `pk_fp4` | `pk_fp4` | `fp32` | 16x16x128 | Packed 4-bit float |
**Notes:**
- Accumulator is always `fp32` except for `int8` which uses `int32`
- FP8 types: `fp8` = E4M3, `bf8` = E5M2
- `pk_fp4` = Packed 4-bit float (2 values per byte)
- Some dtypes require specific GPU architectures (e.g., FP8 requires MI300+)
---
## Step-by-Step Build Guide
### Step 1: Navigate to Dispatcher Directory
```bash
# From composable_kernel root
cd dispatcher
# Verify you're in the right place
ls CMakeLists.txt # Should exist
```
### Step 2: Create Build Directory
```bash
mkdir -p build
cd build
```
### Step 3: Configure CMake
**Basic configuration (library only):**
```bash
cmake .. \
-DCMAKE_PREFIX_PATH=/opt/rocm \
-DCMAKE_CXX_COMPILER=/opt/rocm/bin/hipcc \
-DCMAKE_BUILD_TYPE=Release \
-DGPU_TARGETS="gfx942"
```
**Full configuration (with examples and tests):**
```bash
cmake .. \
-DCMAKE_PREFIX_PATH=/opt/rocm \
-DCMAKE_CXX_COMPILER=/opt/rocm/bin/hipcc \
-DCMAKE_BUILD_TYPE=Release \
-DGPU_TARGETS="gfx942" \
-DBUILD_DISPATCHER_EXAMPLES=ON \
-DBUILD_DISPATCHER_TESTS=ON
```
**Expected output:**
```
-- Found hip: /opt/rocm (found suitable version "6.x.x")
-- Generating GEMM kernels...
-- Built: gemm_01 through gemm_06, dispatcher_gemm_lib.so
-- Configuring done
```
### Step 4: Build
```bash
# Build all targets (generates kernels automatically, then compiles)
make -j$(nproc)
# Or build specific targets
make gemm_01_basic # Single GEMM example
make dispatcher_gemm_lib # GEMM shared library for Python
# Build ONLY Python libraries (faster if you don't need C++ examples)
make python_libs -j$(nproc)
```
### Kernel Generation Targets
Kernels are generated automatically during `make`, but you can also control generation explicitly:
```bash
# Generate all kernels only (no compilation)
make generate_all_kernels
# Generate GEMM kernels only
make generate_gemm_kernels
# Force regenerate (even if kernels exist)
make regenerate_all_kernels
make regenerate_gemm_kernels
# Generate for specific GPU architecture
make generate_kernels_gfx942 # MI300X
make generate_kernels_gfx90a # MI200
make generate_kernels_gfx1100 # RDNA3
```
### Step 5: Verify Build
```bash
# Check executables were built
ls examples/gemm_*
# Check shared libraries were built
ls examples/libdispatcher_gemm_lib.so
```
### CMake Options Reference
| Flag | Default | Description |
|------|---------|-------------|
| `CMAKE_BUILD_TYPE` | Debug | **Use `Release` for performance!** |
| `GPU_TARGETS` | None | Target GPU: `"gfx942"`, `"gfx90a"`, etc. |
| `BUILD_DISPATCHER_EXAMPLES` | OFF | Build C++ examples and Python libs |
| `BUILD_DISPATCHER_TESTS` | OFF | Build unit tests |
| `CMAKE_PREFIX_PATH` | - | ROCm installation path |
| `CMAKE_CXX_COMPILER` | - | Path to hipcc compiler |
WARNING: **Important:** Always use `-DCMAKE_BUILD_TYPE=Release` for benchmarking. Debug builds are slower.
WARNING: **Important:** Note that the current system provides single GPU target support for architecture-based kernel filtering, please do not use multiple GPU targets at a time (if necessary, please compile into different build directories).
---
## Running Examples
### C++ Examples
After building, executables are in `build/examples/`:
```bash
cd build/examples
# GEMM Examples
./gemm_01_basic # Basic GEMM with autofill/autocorrect
./gemm_02_multi_size # Wildcard expansion
./gemm_03_benchmark_validation # Benchmarking + validation
./gemm_04_heuristics # Heuristic kernel selection
./gemm_05_json_export # Registry JSON export
./gemm_06_multi_registry # Multiple registries
# Grouped Convolution Examples
./grouped_conv_01_basic # Declaration patterns + GPU execution
./grouped_conv_02_all_dirs # Forward/BwdData/BwdWeight with GPU
./grouped_conv_03_bench_val # Benchmark + CPU reference validation
./grouped_conv_04_registry_json # Heuristic selection + JSON export
./grouped_conv_05_bwd_data # Backward data + CPU validation
./grouped_conv_06_bwd_weight # Backward weight + CPU validation
./grouped_conv_07_benchmark # Multi-tile ResNet benchmark
```
### Python Examples
Run from the `dispatcher` directory:
```bash
cd /path/to/composable_kernel/dispatcher
# GEMM Examples
python3 examples/gemm/python/01_basic_gemm.py # Basic multi-kernel GEMM
python3 examples/gemm/python/04_validation.py # CPU reference validation
python3 examples/gemm/python/07_stress_test.py # Stress test
python3 examples/gemm/python/08_heuristics.py # Heuristic selection
# Grouped Convolution Examples
python3 examples/grouped_conv/python/01_basic_grouped_conv.py # Config patterns + registry + GPU
python3 examples/grouped_conv/python/02_forward.py # Forward 2D/3D + CPU ref
python3 examples/grouped_conv/python/03_bwd_data.py # Backward data + CPU ref
python3 examples/grouped_conv/python/04_bwd_weight.py # Backward weight + CPU ref
python3 examples/grouped_conv/python/05_benchmark.py # Multi-problem benchmark
python3 examples/grouped_conv/python/06_registry_json.py # Heuristic selection + JSON
```
### Example Output
**Expected C++ output (`gemm_01_basic`):**
```
======================================================================
Example 01: Basic GEMM with Declarative Kernel Definition
======================================================================
Step 1: Declared Kernels
------------------------
Kernel Set: fp16_gemm_kernels
Architecture: gfx942
Configurations: 1
- gemm_fp16_rcr_compv4_cshuffle_intrawave_128x128x32
Step 2: Create Registry and Dispatcher
--------------------------------------
Registered 1 kernels
Step 3: Define Problem
----------------------
M=1024, N=1024, K=1024
Step 4: GPU Execution
---------------------
*** GPU EXECUTION ***
Time: <varies> ms
TFLOPS: <varies>
```
> **Note:** Timing values vary by GPU model and system configuration.
---
## Benchmark Parameters
The dispatcher supports fine-grained control over benchmarking, matching CK Tile's `stream_config`:
### Available Parameters
| Parameter | Type | Default | Description |
|-----------|------|---------|-------------|
| `warmup` | int | 5 | Warmup iterations (discarded from timing) |
| `repeat` | int | 20 | Benchmark iterations (averaged) |
| `flush_cache` | bool | false | Flush GPU L2 cache between iterations |
| `rotating_count` | int | 1 | Rotating buffer count (for cache simulation) |
| `timer` | string | "gpu" | Timer type: "gpu" (HIP events) or "cpu" |
| `init` | string | "random" | Matrix initialization: "random", "linear", "constant" |
| `split_k` | int | 1 | Split-K parallelism factor |
### Python Usage
```python
from ctypes_utils import DispatcherLib
# Basic usage (default benchmark settings)
lib = DispatcherLib.load()
# Advanced benchmark settings via command line
python3 examples/gemm/python/10_advanced_benchmark.py \
--warmup 10 \
--repeat 100 \
--flush-cache
```
### C++ Usage
```cpp
// Basic timing
ck_tile::stream_config cfg{nullptr, true};
// Advanced benchmark settings
ck_tile::stream_config cfg{
nullptr, // stream_id (nullptr = default stream)
true, // time_kernel
1, // log_level
10, // cold_niters (warmup)
100, // nrepeat
true, // is_gpu_timer
true, // flush_cache
4 // rotating_count
};
float avg_time = kernel.run(args, cfg);
```
### Command Line (Python Examples)
```bash
# Basic run
python3 examples/gemm/python/10_advanced_benchmark.py
# With benchmark parameters
python3 examples/gemm/python/10_advanced_benchmark.py \
--warmup 10 \
--repeat 100 \
--flush-cache \
--rotating-count 4 \
--timer gpu
```
### When to Use Each Parameter
| Use Case | Recommended Settings |
|----------|---------------------|
| Quick test | `warmup=1, repeat=3` |
| Stable benchmark | `warmup=10, repeat=100` |
| Memory-bound analysis | `flush_cache=True, rotating_count=4` |
| Compute-bound analysis | `flush_cache=False` (default) |
| Debug timing | `timer="cpu"` |
| Production | `timer="gpu"` (default) |
---
## ML-Based Kernel Selection (Optional)
The dispatcher includes ML heuristics for automated kernel selection using trained LightGBM models.
**Prerequisites:** Install ML dependencies first:
```bash
pip install -r requirements-ml.txt # ~500 MB (LightGBM, pandas, pyarrow, scikit-learn)
```
**Documentation:** See [heuristics/README.md](heuristics/README.md) for:
- Training and evaluating models
- Feature engineering (72 features)
- Using pre-trained models
- Python API reference
**Examples:**
```bash
python3 examples/gemm/python/09_ml_heuristic.py # ML-based kernel selection
python3 examples/gemm/python/10_rank_kernels.py # Kernel ranking
```
**Model Compression:** Trained models are stored in compressed `.lgbm.gz` format to save space (~67% size reduction). Python tools automatically decompress models on first use. For C++ examples, decompress manually:
```bash
# If you have compressed models
cd heuristics/models/gemm_universal_fp16_gfx950
gunzip model_tflops.lgbm.gz
# Then use in C++ example
cd ../../../build
./gemm_09_ml_heuristic --model ../heuristics/models/gemm_universal_fp16_gfx950/model_tflops.lgbm
```
---
## External Integration
### Using Dispatcher in Your Own Project
#### Option 1: CMake Integration (Recommended)
Add to your `CMakeLists.txt`:
```cmake
# Set path to composable_kernel
set(CK_ROOT "/path/to/composable_kernel")
# Add dispatcher subdirectory
add_subdirectory(${CK_ROOT}/dispatcher dispatcher_build)
# Link to your target
target_link_libraries(your_target PRIVATE ck_tile_dispatcher)
target_include_directories(your_target PRIVATE
${CK_ROOT}/dispatcher/include
${CK_ROOT}/include
)
```
#### Option 2: Include as Pre-built Library
```cmake
# Find the pre-built library
find_library(CK_DISPATCHER ck_tile_dispatcher
PATHS /path/to/composable_kernel/dispatcher/build)
# Include directories
set(CK_INCLUDE_DIRS
/path/to/composable_kernel/include
/path/to/composable_kernel/dispatcher/include
)
target_link_libraries(your_target PRIVATE ${CK_DISPATCHER})
target_include_directories(your_target PRIVATE ${CK_INCLUDE_DIRS})
```
#### Option 3: Python Integration
```python
import sys
sys.path.insert(0, "/path/to/composable_kernel/dispatcher/examples/gemm/python")
# For GEMM
from ctypes_utils import DispatcherLib, Dispatcher, KernelConfig
```
### Required Include Paths
When integrating, you need these include paths:
```
/path/to/composable_kernel/include # CK Tile core headers
/path/to/composable_kernel/dispatcher/include # Dispatcher headers
/path/to/composable_kernel/dispatcher/build/generated_kernels # Generated kernels
```
### Required Compile Flags
```bash
# Minimum flags for hipcc
-std=c++17
-D__HIP_PLATFORM_AMD__=1
--offload-arch=gfx942 # Your target GPU
# Recommended flags
-O3
-mllvm -enable-noalias-to-md-conversion=0
-Wno-undefined-func-template
-Wno-float-equal
-Wall
-Werror
```
### Python Path Setup
For Python scripts outside the dispatcher directory:
```bash
# Option 1: Environment variable
export PYTHONPATH="/path/to/composable_kernel/dispatcher/examples/gemm/python:$PYTHONPATH"
# Option 2: In your Python script
import sys
sys.path.insert(0, "/path/to/composable_kernel/dispatcher/examples/gemm/python")
```
### Library Search Paths
The Python utilities search for the shared library in these locations:
```python
# For GEMM (ctypes_utils.py)
SEARCH_PATHS = [
"build/examples/libdispatcher_gemm_lib.so",
"../build/examples/libdispatcher_gemm_lib.so",
"../../build/examples/libdispatcher_gemm_lib.so",
]
```
If using from a different location, set the library path explicitly:
```python
# GEMM
from ctypes_utils import DispatcherLib
lib = DispatcherLib.load("/absolute/path/to/libdispatcher_gemm_lib.so")
```
---
## Core Concepts
### Data Flow
```
KernelConfig -> Registry -> Dispatcher -> GPU Execution
```
1. **KernelConfig**: Defines kernel parameters (tile sizes, data types, layouts)
2. **Registry**: Stores multiple kernel configurations
3. **Dispatcher**: Selects best kernel for a given problem and executes it
### GEMM Layouts
| Layout | A | B | C | Use Case |
|--------|---|---|---|----------|
| RCR | Row | Col | Row | Most common (PyTorch default) |
| RRR | Row | Row | Row | Both inputs row-major |
| CRR | Col | Row | Row | A transposed |
| CCR | Col | Col | Row | Both inputs column-major |
### Split-K Support
Split-K divides the K dimension across multiple thread blocks, useful for large K dimensions.
**Usage (C++):**
```cpp
// GEMM with 4-way K split
auto problem = ProblemBuilder()
.m(1024).n(1024).k(8192)
.split_k(4)
.build();
```
---
## Operation Support Matrix
This matrix shows all CK Tile operations with per-data-type, per-layout, and per-GPU support status. It uses a three-state convention: ✅ = supported by both CK Tile and the dispatcher, ❌ = supported by CK Tile but not yet in the dispatcher, blank = not supported by CK Tile itself.
| | | | | | **Data Types** | | | | | **Layouts** | | | | **GPU Targets** | | |
|:---:|---|:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:|:---:|
| **Op** | **CK Tile Kernel** | **fp16** | **fp8** | **bf16** | **bf8** | **int8** | **fp4** | **fp6** | **rcr** | **rrr** | **ccr** | **crr** | **90a** | **942** | **950** | **1201** |
| GEMM | gemm_multi_d [5]<br>engine: `dispatcher/`<br>example: `19_gemm_multi_d/` | ✅ | ✅ | ✅ | ✅ | ✅ | ✅ | | ✅ | ✅ | ✅ | ✅ | ✅ | ✅ | ✅ | ✅ |
| GEMM | gemm_preshuffle [1][2]<br>engine: `dispatcher/` | ✅ | ✅ | ✅ | ✅ | ✅ | | | ✅ | | | | ✅ | ✅ | ✅ | ❌ |
| GEMM | gemm_universal [3][4][7][8]<br>engine: `dispatcher/`<br>example: `03_gemm/` | ✅ | ✅ | ✅ | ✅ | ✅ | ✅ | | ✅ | ✅ | ✅ | ✅ | ✅ | ✅ | ✅ | ✅ |
| GEMM | batched_contraction<br>example: `41_batched_contraction/` | ❌ | | | | | | | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ |
| GEMM | batched_gemm<br>example: `16_batched_gemm/` | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ |
| GEMM | block_scale_gemm<br>example: `38_block_scale_gemm/` | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ |
| GEMM | flatmm<br>example: `18_flatmm/` | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ |
| GEMM | gemm_multi_abd<br>example: `22_gemm_multi_abd/` | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ |
| GEMM | gemm_quant | | ❌ | ❌ | ❌ | ❌ | ❌ | | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ |
| GEMM | grouped_gemm<br>example: `17_grouped_gemm/` | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ |
| GEMM | grouped_gemm_quant | | ❌ | ❌ | ❌ | ❌ | ❌ | | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ |
| GEMM | streamk_gemm<br>example: `40_streamk_gemm/` | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ |
| Reduce | multi_reduce2d<br>example: `05_reduce/` | ❌ | | ❌ | | | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Reduce | reduce2d<br>example: `05_reduce/` | ❌ | | ❌ | | | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Attention | fmha<br>example: `01_fmha/` | ❌ | ❌ | ❌ | ❌ | ❌ | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Attention | sparse_attn<br>example: `50_sparse_attn/` | ❌ | | ❌ | | ❌ | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Activation | softmax | ❌ | | ❌ | | | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Activation | topk_softmax<br>example: `09_topk_softmax/` | ❌ | ❌ | ❌ | | | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Conv | grouped_conv [6]<br>example: `20_grouped_convolution/` | ❌ | ❌ | ❌ | ❌ | | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Data Move | batched_transpose<br>example: `35_batched_transpose/` | ❌ | ❌ | ❌ | | | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Data Move | image_to_column<br>example: `04_img2col/` | ❌ | | | | | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Data Move | permute<br>example: `06_permute/` | ❌ | ❌ | ❌ | | ❌ | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Elementwise | elementwise<br>example: `21_elementwise/` | ❌ | ❌ | ❌ | ❌ | ❌ | ❌ | | | | | | ❌ | ❌ | ❌ | ❌ |
| MoE | fused_moe<br>example: `15_fused_moe/` | ❌ | ❌ | ❌ | ❌ | ❌ | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Norm | add_rmsnorm2d_rdquant<br>example: `11_add_rmsnorm2d_rdquant/` | ❌ | ❌ | ❌ | ❌ | ❌ | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Norm | layernorm2d<br>example: `02_layernorm2d/` | ❌ | ❌ | ❌ | ❌ | ❌ | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Norm | norm_reduce | ❌ | | ❌ | | | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Norm | rmsnorm2d<br>example: `10_rmsnorm2d/` | ❌ | ❌ | ❌ | ❌ | ❌ | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Pooling | pooling<br>example: `36_pooling/` | ❌ | | | | | | | | | | | ❌ | ❌ | ❌ | ❌ |
| Quant | smoothquant<br>example: `12_smoothquant/` | ❌ | ❌ | ❌ | ❌ | ❌ | | | | | | | ❌ | ❌ | ❌ | ❌ |
**Notes:**
- [1] **gemm_preshuffle:** Supports only `rcr` layout. Uses fixed `preshufflev2` pipeline, `Auto` scheduler, and `cshuffle` epilogue.
- [2] **gemm_preshuffle:** `int8` preshuffle support is limited to gfx942 and gfx950 (entries in `preshuffle_warp_tile_combos`).
- [3] **gemm_universal:** `fp4` (pk_fp4) support is only available on gfx950.
- [4] **gemm_universal:** `fp32` GEMM is supported by the dispatcher (`fp32_fp32_fp32` warp tile combos exist) but is omitted from matrix columns for consistency with the tile engine matrix format.
- [5] **gemm_multi_d:** Codegen supports `MultiDAdd` and `MultiDMultiply` element-wise ops. Preselected kernel sets also test `Relu`, `Gelu`, `FastGelu`.
- [6] **grouped_conv:** `arch_filter.py` defines conv operator types (`CONV_FWD`, `CONV_BWD_DATA`, `CONV_BWD_WEIGHT`, `CONV3D_*`) but dispatcher infrastructure is incomplete (ctypes bindings are stubs, `conv_utils.hpp` does not exist).
- [7] **(all dispatcher ops):** gfx908, gfx1100, and gfx1200 also have `warp_tile_combos` in `arch_specs.json` but are not shown in the matrix's 4 GPU columns.
- [8] **(all dispatcher ops):** `int4`, `fp32`, `fp64` are valid dispatcher data types (defined in `kernel_key.hpp` `DataType` enum) but have no dedicated matrix columns.
### Dispatcher GEMM Configuration Detail
#### Per-Variant Configuration
| GEMM Variant | Pipelines | Schedulers | Epilogues | Element-wise Ops | Output Dtype |
|:---:|:---:|:---:|:---:|:---:|:---:|
| gemm_universal | mem, compv3, compv4 | intrawave, interwave | cshuffle, default | PassThrough | Same as input (fp8/bf8 -> fp16) |
| gemm_preshuffle | preshufflev2 | Auto | cshuffle | PassThrough | Same as input (fp8/bf8 -> fp16) |
| gemm_multi_d | mem, compv3, compv4 | intrawave, interwave | cshuffle, default | MultiDAdd, MultiDMultiply | Same as input (fp8/bf8 -> fp16) |
#### Warp Tile Combinations per GPU
| GPU | fp16 | bf16 | fp8 | bf8 | int8 | pk_fp4 |
|:---:|:---:|:---:|:---:|:---:|:---:|:---:|
| gfx1100 | 16x16x16 | 16x16x16 | -- | -- | 16x16x16 | -- |
| gfx1200 | 16x16x16 | 16x16x16 | 16x16x16 | 16x16x16 | 16x16x16 | -- |
| gfx1201 | 16x16x16 | 16x16x16 | 16x16x16 | 16x16x16 | 16x16x16 | -- |
| gfx908 | 32x32x8, 16x16x16, 32x32x16, 16x16x32 | 32x32x8, 16x16x16, 32x32x16, 16x16x32 | -- | -- | 32x32x16, 16x16x32 | -- |
| gfx90a | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 4x64x16, 64x4x16 | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 4x64x16, 64x4x16 | 32x32x16, 32x32x32 | 32x32x16, 32x32x32 | 32x32x16, 16x16x32 | -- |
| gfx942 | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 4x64x16, 64x4x16 | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 4x64x16, 64x4x16 | 32x32x16, 32x32x32, 16x16x32, 16x16x64 | 32x32x16, 32x32x32, 16x16x32, 16x16x64 | 32x32x16, 16x16x32 | -- |
| gfx950 | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 4x64x16, 64x4x16 | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 4x64x16, 64x4x16 | 32x32x16, 32x32x32, 16x16x32, 16x16x64, 16x16x128, 32x32x64 | 32x32x16, 32x32x32, 16x16x32, 16x16x64, 16x16x128, 32x32x64 | 32x32x16, 16x16x32 | 16x16x128 |
#### Preshuffle Warp Tile Combinations
| GPU | fp16 | bf16 | fp8 | bf8 | int8 |
|:---:|:---:|:---:|:---:|:---:|:---:|
| gfx90a | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 64x4x16 | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 64x4x16 | 32x32x16, 32x32x32 | 32x32x16, 32x32x32 | -- |
| gfx942 | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 64x4x16 | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 64x4x16 | 32x32x16, 32x32x32, 16x16x32, 16x16x64 | 32x32x16, 32x32x32, 16x16x64, 16x16x32 | 16x16x32, 32x32x16 |
| gfx950 | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 64x4x16 | 32x32x8, 16x16x16, 32x32x16, 16x16x32, 64x4x16 | 32x32x16, 32x32x32, 16x16x32, 16x16x64, 16x16x128, 32x32x64 | 32x32x16, 32x32x32, 16x16x64, 16x16x32, 16x16x128, 32x32x64 | -- |
**Legend:**
- **CK Tile Kernel column:** First line is the kernel name. Lines prefixed with "engine:" show the dispatcher directory. Lines prefixed with "example:" show the CK Tile example directory under `example/ck_tile/`.
- **Green cell** (✅): CK Tile implementation exists **and** the dispatcher supports it.
- **Red cell** (❌): CK Tile implementation exists **but** the dispatcher does **not** support it.
- **Grey cell** (blank): No CK Tile implementation exists for this combination.
**Layout codes:** Each 3-character layout code specifies the memory layout for tensors A, B, and C:
- `r` = row-major, `c` = column-major
- Example: `rcr` means A is row-major, B is column-major, C is row-major
- `gemm_multi_d` uses 4-character codes internally (e.g., `rcrr`) where the 4th character is the D tensor layout (always `r`). The matrix shows only the 3-character A/B/C portion.
**Data type mapping per config label:**
| Config Label | A (source) | B (source) | Acc | C (output) |
|:---:|:---:|:---:|:---:|:---:|
| fp16 | fp16 | fp16 | fp32 | fp16 |
| bf16 | bf16 | bf16 | fp32 | bf16 |
| int8 | int8 | int8 | int32 | int32 |
| fp8 | fp8 | fp8 | fp32 | fp16 |
| bf8 | bf8 | bf8 | fp32 | fp16 |
| fp6 | fp6 | fp6 | fp32 | fp32 |
| fp4 | fp16 or bf16 | fp4 | fp32 | fp16 or bf16 |
## Troubleshooting
### Build Issues
| Problem | Solution |
|---------|----------|
| `hipcc not found` | Set `-DCMAKE_CXX_COMPILER=/opt/rocm/bin/hipcc` |
| `hip not found` | Set `-DCMAKE_PREFIX_PATH=/opt/rocm` |
| Very slow performance | Use `-DCMAKE_BUILD_TYPE=Release` |
| `gfx942 not supported` | Check ROCm version (need 6.0+) |
| Kernel generation fails | Ensure Python 3.8+ with NumPy installed in active venv |
| Build errors | First verify CK builds without dispatcher (see main CK README) |
### Runtime Issues
| Problem | Solution |
|---------|----------|
| `Library not found` | Build with `-DBUILD_DISPATCHER_EXAMPLES=ON` |
| `No kernel found` | Check GPU arch matches build target |
| Python `ModuleNotFoundError` | Add paths to `PYTHONPATH` (see above) |
| Wrong results | Verify layout matches your data |
### Debug Commands
```bash
# Check ROCm installation
rocminfo | head -20
# Check GPU architecture
rocminfo | grep "Name:"
# Verify library exists
ls -la build/examples/libdispatcher_*.so
# Run with verbose output
./build/examples/gemm_01_basic 2>&1
# Python: Check library loading
python3 -c "
import ctypes
lib = ctypes.CDLL('/path/to/libdispatcher_gemm_lib.so')
print('Library loaded successfully')
"
```
### Clean Rebuild
If you encounter issues, try a clean rebuild:
```bash
cd dispatcher
rm -rf build
mkdir build && cd build
cmake .. [your options]
make -j$(nproc)
```
---
## File Structure
```
dispatcher/
|---- README.md # This file
|---- CMakeLists.txt # Build configuration
|
|---- include/ck_tile/dispatcher/ # C++ headers
| |---- dispatcher.hpp # Main dispatcher include
| |---- registry.hpp # GEMM kernel registry
| |---- kernel_key.hpp # Kernel configuration
| |---- grouped_conv_config.hpp # Grouped conv configuration
| |---- grouped_conv_problem.hpp # Grouped conv problem (with builder)
| |---- grouped_conv_kernel_decl.hpp # Grouped conv kernel declarations
| |---- grouped_conv_registry.hpp # Grouped conv registry (thread-safe)
| +---- grouped_conv_utils.hpp # Grouped conv utilities
|
|---- src/ # C++ implementation
|
|---- codegen/ # Kernel generation
| |---- codegen_common.py # Shared: TileConfig, TraitConfigBase, type mappings
| |---- unified_gemm_codegen.py # GEMM kernel generator
| |---- unified_grouped_conv_codegen.py # Grouped conv kernel generator
| +---- arch_specs.json # GPU specifications
|
|---- python/ # Python utilities
| |---- dispatcher_common.py # Shared: paths, validation, Colors, phased output
| |---- ctypes_utils.py # GEMM ctypes utilities
| +---- grouped_conv_utils.py # Grouped conv utilities
|
|---- scripts/ # Build scripts
| |---- compile_gemm_examples.py # GEMM build script
| +---- compile_grouped_conv_examples.py # Grouped conv build script
|
|---- bindings/ctypes/ # Python ctypes interface
| |---- gemm_ctypes_lib.cpp # GEMM Python library
| +---- conv_ctypes_lib.cpp # Grouped conv Python library
|
|---- examples/ # Examples
| |---- gemm/
| | |---- cpp/ # C++ GEMM examples (01-07)
| | +---- python/ # Python GEMM examples (01-11)
| +---- grouped_conv/
| |---- cpp/ # C++ Grouped Conv examples (01-07)
| +---- python/ # Python Grouped Conv examples (01-06)
|
+---- tests/ # Unit tests (C++ and Python)
```
---
## Example Documentation
| Directory | README |
|-----------|--------|
| GEMM C++ | [examples/gemm/cpp/README.md](examples/gemm/cpp/README.md) |
| GEMM Python | [examples/gemm/python/README.md](examples/gemm/python/README.md) |
| Codegen | [codegen/README.md](codegen/README.md) |
| Python Utils | [python/README.md](python/README.md) |
| C++ Headers | [include/ck_tile/dispatcher/README.md](include/ck_tile/dispatcher/README.md) |
---
## Grouped Convolution Support
Grouped convolution is fully supported alongside GEMM, with shared infrastructure to eliminate duplication.
### Python
```bash
# Generate grouped conv kernels
python3 codegen/unified_grouped_conv_codegen.py \
--output-dir build/generated_kernels \
--datatype fp16 --variant forward --ndim-spatial 2
# Build grouped conv examples
python3 scripts/compile_grouped_conv_examples.py examples/grouped_conv/cpp/01_basic_grouped_conv.cpp
```
### Key Files
| Component | File |
|-----------|------|
| C++ Headers | `include/ck_tile/dispatcher/grouped_conv_*.hpp` |
| Python Codegen | `codegen/unified_grouped_conv_codegen.py` |
| Python Utils | `python/grouped_conv_utils.py` |
| Build Script | `scripts/compile_grouped_conv_examples.py` |
| Shared Codegen | `codegen/codegen_common.py` |
| Shared Utils | `python/dispatcher_common.py` |
### Variants
- **Forward** (`grouped_conv_fwd`) - Standard grouped convolution
- **Backward Data** (`grouped_conv_bwd_data`) - Gradient w.r.t. input
- **Backward Weight** (`grouped_conv_bwd_weight`) - Gradient w.r.t. weights
### Shared Infrastructure
GEMM and grouped convolution share common code to avoid duplication:
- `codegen/codegen_common.py` - TileConfig, TraitConfigBase, type mappings, parallel generation, arch-aware expansion
- `python/dispatcher_common.py` - Path helpers, validation, auto-correction, Colors, phased output
---
## License
MIT License - Copyright (c) 2025, Advanced Micro Devices, Inc.
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