![ALT](/media/images/gemm-hierarchy-with-epilogue-no-labels.png "Complete CUDA GEMM decomposition") # CUTLASS 3.4 _CUTLASS 3.4 - February 2024_ CUTLASS is a collection of CUDA C++ template abstractions for implementing high-performance matrix-matrix multiplication (GEMM) and related computations at all levels and scales within CUDA. It incorporates strategies for hierarchical decomposition and data movement similar to those used to implement cuBLAS and cuDNN. CUTLASS decomposes these "moving parts" into reusable, modular software components abstracted by C++ template classes. Primitives for different levels of a conceptual parallelization hierarchy can be specialized and tuned via custom tiling sizes, data types, and other algorithmic policy. The resulting flexibility simplifies their use as building blocks within custom kernels and applications. To support a wide variety of applications, CUTLASS provides extensive support for mixed-precision computations, providing specialized data-movement and multiply-accumulate abstractions for half-precision floating point (FP16), BFloat16 (BF16), Tensor Float 32 (TF32), single-precision floating point (FP32), [FP32 emulation via tensor core instruction](/examples/27_ampere_3xtf32_fast_accurate_tensorop_gemm), double-precision floating point (FP64) types, integer data types (4b and 8b), and binary data types (1b). CUTLASS demonstrates warp-synchronous matrix multiply operations targeting the programmable, high-throughput _Tensor Cores_ implemented by NVIDIA's Volta, Turing, Ampere, and Hopper architectures. See the [Quick Start Guide](/media/docs/quickstart.md) to get started quickly. See the [functionality listing](/media/docs/functionality.md) for the list of operations supported at each level of the execution model hierarchy. CUTLASS 3.0 introduced a new core library, CuTe, to describe and manipulate tensors of threads and data. CuTe is a collection of C++ CUDA template abstractions for defining and operating on hierarchically multidimensional layouts of threads and data. CuTe provides `Layout` and `Tensor` objects that compactly package the type, shape, memory space, and layout of data, while performing the complicated indexing for the user. This lets programmers focus on the logical descriptions of their algorithms while CuTe does the mechanical bookkeeping for them. With these tools, we can quickly design, implement, and modify all dense linear algebra operations. The core abstractions of CuTe are hierarchically multidimensional layouts which can be composed with data arrays to represent tensors. The representation of layouts is powerful enough to represent nearly everything we need to implement efficient dense linear algebra. Layouts can also be combined and manipulated via functional composition, on which we build a large set of common operations such as tiling and partitioning. CUTLASS 3.0 and beyond adopts CuTe throughout the GEMM hierarchy in its templates. This greatly simplifies the design and improves code composability and readability. More documentation specific to CuTe can be found in its [dedicated documentation directory](/media/docs/cute/00_quickstart.md). In addition to GEMMs, CUTLASS implements high-performance convolution via the implicit GEMM algorithm. Implicit GEMM is the formulation of a convolution operation as a GEMM thereby taking advantage of CUTLASS's modular GEMM pipeline. This allows CUTLASS to build convolutions by reusing highly-optimized GEMM components. # What's New in CUTLASS 3.4 CUTLASS 3.4.1 is an update to CUTLASS adding: - Statically available [CUTLASS Version macros](/include/cutlass/version.h) that allow for handling API changes between CUTLASS releases on the users' side. - Improvements for Hopper [Group-GEMM](/examples/57_hopper_grouped_gemm) and [Pointer-Array Batched GEMM](/examples/56_hopper_ptr_array_batched_gemm). - Updates and bugfixes from the community (thanks!). CUTLASS 3.4.0 is an update to CUTLASS adding: - Improved [Mixed-input Hopper GEMMs](/examples/55_hopper_mixed_dtype_gemm) supporting {16-bit, 8-bit} x {8-bit, 4-bit} input types with fast numerical converters and group scaling factors tuned for optimal performance on Hopper H100. - Beta release of [Pointer-Array Batched GEMMs](/examples/56_hopper_ptr_array_batched_gemm) utilizing TMA and Hopper H100 tensor cores now available. (Requires CUDA 12.3 or above) - Beta release of [Group-GEMM](/examples/57_hopper_grouped_gemm) - commonly used in optimization of Mixture-Of-Expert models, is now available on Hopper GPUs taking advantage of TMA and Hopper H100 tensor cores. (Requires CUDA 12.3 or above) - [Ampere Sparse GEMM](/examples/15_ampere_sparse_tensorop_gemm/ampere_sparse_tensorop_gemm_with_visitor.cu) supports Epilogue Visitor Tree (EVT) now. - Improvements to NamedBarriers including details of [ReservedNamedBarriers](/include/cutlass/arch/barrier.h) used within the CUTLASS library. - Improved [CuTe documentation](/media/docs/cute/) including improved clarity and depth of [Quickstart](/media/docs/cute/00_quickstart.md), [CuTe Layout](/media/docs/cute/01_layout.md), and [CuTe Layout Algebra](/media/docs/cute/02_layout_algebra.md). Associated code comments, post-conditions, and details in [CuTe Core Unit Tests](/test/unit/cute/core/) also improved. Minimum requirements: - Architecture: Volta - Compiler: Must support at least C++17 - CUDA Toolkit version: 11.4 Starting from CUTLASS 3.0, CUTLASS removed support for the following: - Maxwell and Pascal GPU architectures - Ubuntu 16.04 - CUDA 10.2 - C++ language versions less than 17. **See the [CHANGELOG](CHANGELOG.md) for a detailed listing of releases and updates.** # Performance

CUTLASS primitives are very efficient. When used to construct device-wide GEMM kernels, they exhibit peak performance comparable to cuBLAS for scalar GEMM computations. The above figure shows CUTLASS performance relative to cuBLAS for large matrix dimensions on an [NVIDIA H100](https://www.nvidia.com/en-us/data-center/h100/) (NVIDIA Hopper architecture), an [NVIDIA L40](https://www.nvidia.com/en-us/data-center/l40/) (NVIDIA Ada architecture), an [NVIDIA A100](https://www.nvidia.com/en-us/data-center/a100/) (NVIDIA Ampere architecture), and an [NVIDIA A40](https://www.nvidia.com/en-us/data-center/a40/) (NVIDIA Ampere architecture). CUTLASS 3.0 was compiled with the [CUDA 12.0 Toolkit](https://developer.nvidia.com/cuda-downloads). Tensor Core operations are implemented using CUDA's [mma](https://docs.nvidia.com/cuda/parallel-thread-execution/index.html#warp-level-matrix-instructions-mma) and [wgmma](https://docs.nvidia.com/cuda/parallel-thread-execution/index.html#asynchronous-warpgroup-level-matrix-instructions) instructions.

When using CUTLASS building blocks to construct device-wide implicit gemm (Fprop, Dgrad, and Wgrad) kernels, CUTLASS performance is also comparable to cuDNN when running Resnet-50 layers on an [NVIDIA A100](https://www.nvidia.com/en-us/data-center/a100/) as shown in the above figure. Tensor Core operations are implemented using CUDA's [mma instruction](https://docs.nvidia.com/cuda/parallel-thread-execution/index.html#warp-level-matrix-instructions-mma). # Compatibility CUTLASS requires a C++17 host compiler and performs best when built with the [**CUDA 12.3.2 Toolkit**](https://developer.nvidia.com/cuda-downloads). It is also compatible with CUDA 11.4, CUDA 11.5, CUDA 11.6, CUDA 11.7, CUDA 11.8, CUDA 12.0, CUDA 12.1, CUDA 12.2.2, CUDA 12.3.1 and CUDA 12.3.2. ## Operating Systems We have tested the following environments. |**Operating System** | **Compiler** | |-----------------|----------| | Ubuntu 18.04 | GCC 7.5.0 | | Ubuntu 20.04 | GCC 10.3.0 | | Ubuntu 22.04 | GCC 11.2.0 | | Ubuntu 22.04 | Clang 10.0.0 | | Ubuntu 22.04 | Clang 14.0.6 | | Ubuntu 22.04 | Clang 17.0.6 | | Windows 10.0 | Visual Studio 2019 v16.11.27 | Note: GCC 8.5.0 has known regressions regarding fold expressions and overloaded operators. Using GCC 7.5.0 or (preferred) GCC >= 9 is recommended. ## Hardware CUTLASS runs successfully on the following NVIDIA GPUs, and it is expected to be efficient on Volta, Turing, Ampere, Ada, and Hopper architecture based NVIDIA GPUs. |**GPU**|**CUDA Compute Capability**|**Minimum CUDA Toolkit Required by CUTLASS-3**| |---|---|---| |NVIDIA V100 Tensor Core GPU |7.0|11.4| |NVIDIA TitanV |7.0|11.4| |NVIDIA GeForce RTX 2080 TI, 2080, 2070 |7.5|11.4| |NVIDIA T4 |7.5|11.4| |NVIDIA A100 Tensor Core GPU |8.0|11.4| |NVIDIA A10 |8.6|11.4| |NVIDIA GeForce RTX 3090 |8.6|11.4| |NVIDIA GeForce RTX 4090 |8.9|11.8| |NVIDIA L40 |8.9|11.8| |NVIDIA H100 Tensor Core GPU |9.0|11.8| ## Target Architecture In general, PTX code generated for one target architecture can be run on future architectures (i.e., it is forward compatible). However, CUDA 12.0 introduced the concept of "architecture-accelerated features" whose PTX does not have forward compatibility guarantees. Several Hopper PTX instructions fall under this category of architecture-accelerated features, and thus require a `sm_90a` target architecture (note the "a" appended). For more details on this and other architecture-accelerated instructions, please refer to the [CUDA Documentation](https://docs.nvidia.com/cuda/cuda-c-programming-guide/index.html#feature-availability). The target architecture information is passed on to CUTLASS via the cmake flag `CUTLASS_NVCC_ARCHS`. In order to maximize performance on Hopper GH100, users are required to build CUTLASS with `90a` as the target architecture. If a user accidentally builds a kernel which uses SM90a features (e.g. Hopper Tensor Core Instructions), using the SM90 target (note the lack of "a"), with either CTK 12 or 11.8, the kernel is expected to fail with a runtime error. ``` cmake .. -DCUTLASS_NVCC_ARCHS="90a" ``` Please refer to the [functionality documentation](media/docs/functionality.md) for details on which kernels require which target architectures. # Documentation CUTLASS is described in the following documents and the accompanying [Doxygen documentation](https://nvidia.github.io/cutlass). - [Quick Start Guide](/media/docs/quickstart.md) - build and run CUTLASS - [Functionality](/media/docs/functionality.md) - summarizes functionality available in CUTLASS - [Efficient GEMM in CUDA](media/docs/efficient_gemm.md) - describes how GEMM kernels may be implemented efficiently in CUDA - [CUTLASS 3.x Design](media/docs/cutlass_3x_design.md) - describes the CUTLASS 3.x design, its benefits, and how CuTe enables us to write much more composable components - [GEMM API 3.x](media/docs/gemm_api_3x.md) - describes the CUTLASS 3.x GEMM model and C++ template concepts - [GEMM API 2.x](media/docs/gemm_api.md) - describes the CUTLASS 2.x GEMM model and C++ template concepts - [Implicit GEMM Convolution](media/docs/implicit_gemm_convolution.md) - describes 2-D and 3-D convolution in CUTLASS - [Code Organization](media/docs/code_organization.md) - describes the organization and contents of the CUTLASS project - [Terminology](media/docs/terminology.md) - describes terms used in the code - [Programming Guidelines](media/docs/programming_guidelines.md) - guidelines for writing efficient modern CUDA C++ - [Fundamental types](media/docs/fundamental_types.md) - describes basic C++ classes used in CUTLASS to represent numeric quantities and arrays - [Layouts](media/docs/layout.md) - describes layouts of matrices and tensors in memory - [Tile Iterators](media/docs/tile_iterator_concept.md) - describes C++ concepts for iterating over tiles of matrices in memory - [CUTLASS Profiler](media/docs/profiler.md) - command-line driven profiling application - [CUTLASS Utilities](media/docs/utilities.md) - additional templates used to facilate rapid development # Resources We have also described the structure of an efficient GEMM in our talk at the [GPU Technology Conference 2018](http://on-demand.gputechconf.com/gtc/2018/presentation/s8854-cutlass-software-primitives-for-dense-linear-algebra-at-all-levels-and-scales-within-cuda.pdf). - [CUTLASS: Software Primitives for Dense Linear Algebra at All Levels and Scales within CUDA](https://www.nvidia.com/en-us/on-demand/session/gtcsiliconvalley2018-s8854/) - [Developing CUDA Kernels to Push Tensor Cores to the Absolute Limit on NVIDIA A100](https://www.nvidia.com/en-us/on-demand/session/gtcsj20-s21745/) - [Accelerating Convolution with Tensor Cores in CUTLASS](https://www.nvidia.com/en-us/on-demand/session/gtcspring21-s31883/) - [Accelerating Backward Data Gradient by Increasing Tensor Core Utilization in CUTLASS](https://www.nvidia.com/en-us/on-demand/session/gtcspring22-s41996/) - [CUTLASS: Python API, Enhancements, and NVIDIA Hopper](https://www.nvidia.com/en-us/on-demand/session/gtcfall22-a41131/) # Building CUTLASS CUTLASS is a header-only template library and does not need to be built to be used by other projects. Client applications should target CUTLASS's `include/` directory in their include paths. CUTLASS unit tests, examples, and utilities can be build with CMake. The minimum version of CMake is given in the [Quickstart guide](media/docs/quickstart.md). Make sure the `CUDACXX` environment variable points to NVCC in the CUDA Toolkit installed on your system. ```bash $ export CUDACXX=${CUDA_INSTALL_PATH}/bin/nvcc ``` Create a build directory within the CUTLASS project, then run CMake. By default CUTLASS will build kernels for CUDA architecture versions 5.0, 6.0, 6.1, 7.0, 7.5, 8.0, 8.6, 8.9, and 9.0. To reduce compile time you can specify the architectures to build CUTLASS for by changing the CMake configuration setting `CUTLASS_NVCC_ARCHS`. ```bash $ mkdir build && cd build $ cmake .. -DCUTLASS_NVCC_ARCHS=80 # compiles for NVIDIA's Ampere Architecture ``` From the `build/` directory, compile and run the CUTLASS unit tests by building the target `test_unit` with make. The unit tests are organized as several binaries mirroring the top-level namespaces of CUTLASS, and they may be executed in parallel via make's `-j` command line argument. ```bash $ make test_unit -j ... ... ... [----------] Global test environment tear-down [==========] 946 tests from 57 test cases ran. (10812 ms total) [ PASSED ] 946 tests. ``` All tests should pass on supported platforms, though the exact number of tests may vary over time. # Project Structure CUTLASS is arranged as a header-only library along with Utilities, Tools, Examples, and unit tests. [Doxygen documentation](https://nvidia.github.io/cutlass) provides a complete list of files, classes, and template concepts defined in the CUTLASS project. A detailed explanation of the source code organization may be found in the [CUTLASS documentation](media/docs/code_organization.md), but several main components are summarized below. ## CUTLASS Template Library ``` include/ # client applications should target this directory in their build's include paths cutlass/ # CUDA Templates for Linear Algebra Subroutines and Solvers - headers only arch/ # direct exposure of architecture features (including instruction-level GEMMs) conv/ # code specialized for convolution epilogue/ # code specialized for the epilogue of gemm/convolution gemm/ # code specialized for general matrix product computations layout/ # layout definitions for matrices, tensors, and other mathematical objects in memory platform/ # CUDA-capable Standard Library components reduction/ # bandwidth-limited reduction kernels that do not fit the "gemm" model thread/ # simt code that can be performed within a CUDA thread transform/ # code specialized for layout, type, and domain transformations * # core vocabulary types, containers, and basic numeric operations cute/ # CuTe Layout, layout algebra, MMA/Copy atoms, tiled MMA/Copy algorithm/ # Definitions of core operations such as copy, gemm, and operations on cute::tuples arch/ # Bare bones PTX wrapper structs for copy and math instructions atom/ # Meta-information either link to or built from arch/ operators mma_atom.hpp # cute::Mma_Atom and cute::TiledMma copy_atom.hpp # cute::Copy_Atom and cute::TiledCopy *sm*.hpp # Arch specific meta-information for copy and math operations * # Core library types such as Shape, Stride, Layout, Tensor, and associated operations ``` ### CUTLASS SDK Examples [CUTLASS SDK examples](/examples) apply CUTLASS templates to implement basic computations. ### Tools ``` tools/ library/ # CUTLASS Instance Library - contains instantiations of all supported CUTLASS templates include/ cutlass/ library/ profiler/ # CUTLASS Profiler - command-line utility for executing operations in the # CUTLASS Library util/ # CUTLASS Utilities - contains numerous helper classes for include/ # manging tensors in device memory, reference cutlass/ # implementations for GEMM, random initialization util/ # of tensors, and I/O. ``` ### Test The `test/unit/` directory consist of unit tests implemented with Google Test that demonstrate basic usage of Core API components and complete tests of the CUTLASS GEMM computations. Instructions for building and running the Unit tests are described in the [Quickstart guide](media/docs/quickstart.md). # Performance Profiling The `tools/profiler/` directory contains a command-line utility for launching each of the GEMM kernels. It can be built as follows: ```bash $ make cutlass_profiler -j16 ``` ## Building all GEMM and Convolution kernels (_long_ build times) By default, only one tile size is instantiated for each data type, math instruction, and layout. To instantiate all, set the following environment variable when running CMake from an empty `build/` directory. Beware, this results in *tens of thousands* of kernels and long build times. This would also result in a large binary size and on some platforms linker to fail on building the library. Therefore, it's highly recommended to generate only a subset of kernels as demonstrated in the sub-section below. ```bash $ cmake .. -DCUTLASS_NVCC_ARCHS=90a -DCUTLASS_LIBRARY_KERNELS=all ... $ make cutlass_profiler -j16 ``` ## Building a subset of GEMM and Convolution kernels (_reduced_ build times) To compile strictly one kernel or a small set of kernels, a comma-delimited list of kernel names with wildcard characters may be used to reduce the set of kernels. The following examples show building exactly one or a subset of kernels for NVIDIA Ampere and Turing architecture: ### Building a subset Tensor Core GEMM kernels To compile a subset of Tensor Core GEMM kernels with FP32 accumulation and FP16 input targeting NVIDIA Ampere and Turing architecture, use the below cmake command line: ```bash $ cmake .. -DCUTLASS_NVCC_ARCHS='75;80' -DCUTLASS_LIBRARY_KERNELS=cutlass_tensorop_s*gemm_f16_*_nt_align8 ... $ make cutlass_profiler -j16 ``` Example command line for profiling a subset of Tensor Core GEMM kernels is as follows: ```bash ./tools/profiler/cutlass_profiler --kernels=cutlass_tensorop_s*gemm_f16_*_nt_align8 --m=3456 --n=4096 --k=4096 ... ============================= Problem ID: 1 Provider: CUTLASS OperationKind: gemm Operation: cutlass_tensorop_s1688gemm_f16_256x128_32x2_nt_align8 Status: Success Verification: ON Disposition: Passed reference_device: Passed cuBLAS: Passed Arguments: --gemm_kind=universal --m=3456 --n=4096 --k=4096 --A=f16:column --B=f16:row --C=f32:column --alpha=1 \ --beta=0 --split_k_slices=1 --batch_count=1 --op_class=tensorop --accum=f32 --cta_m=256 --cta_n=128 \ --cta_k=32 --stages=2 --warps_m=4 --warps_n=2 --warps_k=1 --inst_m=16 --inst_n=8 --inst_k=8 --min_cc=75 \ --max_cc=1024 Bytes: 118489088 bytes FLOPs: 115992428544 flops Runtime: 1.55948 ms Memory: 70.7616 GiB/s Math: 74378.8 GFLOP/s ============================= ... ``` ### Building one CUDA Core GEMM kernel To compile one SGEMM kernel targeting NVIDIA Ampere and Turing architecture, use the below cmake command line: ```bash $ cmake .. -DCUTLASS_NVCC_ARCHS='75;80' -DCUTLASS_LIBRARY_KERNELS=cutlass_simt_sgemm_128x128_8x2_nn_align1 ... $ make cutlass_profiler -j16 ``` Example command line for profiling single SGEMM CUDA kernel is as follows: ```bash $ ./tools/profiler/cutlass_profiler --kernels=sgemm --m=3456 --n=4096 --k=4096 ============================= Problem ID: 1 Provider: CUTLASS OperationKind: gemm Operation: cutlass_simt_sgemm_128x128_8x2_nn_align1 Status: Success Verification: ON Disposition: Passed cuBLAS: Passed Arguments: --m=3456 --n=4096 --k=4096 --A=f32:column --B=f32:column --C=f32:column --alpha=1 --beta=0 --split_k_slices=1 \ --batch_count=1 --op_class=simt --accum=f32 --cta_m=128 --cta_n=128 --cta_k=8 --stages=2 --warps_m=4 \ --warps_n=2 --warps_k=1 --inst_m=1 --inst_n=1 --inst_k=1 --min_cc=50 --max_cc=1024 Bytes: 180355072 bytes FLOPs: 115992428544 flops Runtime: 6.73655 ms Memory: 24.934 GiB/s Math: 17218.4 GFLOP/s ============================= ``` ### Building a subset of Tensor Core Convolution kernels To compile a subset of Tensor core convolution kernels implementing forward propagation (fprop) with FP32 accumulation and FP16 input targeting NVIDIA Ampere and Turing architecture, use the below cmake command line: ```bash $ cmake .. -DCUTLASS_NVCC_ARCHS='75;80' -DCUTLASS_LIBRARY_KERNELS=cutlass_tensorop_s*fprop_optimized_f16 ... $ make cutlass_profiler -j16 ``` Example command line for profiling a subset of Tensor Core convolution kernels is as follows: ```bash $ ./tools/profiler/cutlass_profiler --kernels=cutlass_tensorop_s*fprop_optimized_f16 --n=8 --h=224 --w=224 --c=128 --k=128 --r=3 --s=3 ... ============================= Problem ID: 1 Provider: CUTLASS OperationKind: conv2d Operation: cutlass_tensorop_s16816fprop_optimized_f16_128x128_32x5_nhwc Status: Success Verification: ON Disposition: Passed reference_device: Passed Arguments: --conv_kind=fprop --n=8 --h=224 --w=224 --c=128 --k=128 --r=3 --s=3 --p=224 --q=224 --pad_h=1 --pad_w=1 \ --stride_h=1 --stride_w=1 --dilation_h=1 --dilation_w=1 --Activation=f16:nhwc --Filter=f16:nhwc --Output=f32:nhwc \ --conv_mode=cross --iterator_algorithm=optimized --alpha=1 --beta=0 --split_k_mode=serial --split_k_slices=1 \ --eq_gemm_provider=none --op_class=tensorop --accum=f32 --cta_m=128 --cta_n=128 --cta_k=32 --stages=5 \ --warps_m=2 --warps_n=2 --warps_k=1 --inst_m=16 --inst_n=8 --inst_k=16 --min_cc=80 --max_cc=1024 Bytes: 1130659840 bytes FLOPs: 118482796544 flops Runtime: 0.711496 ms Memory: 1479.99 GiB/s Math: 166526 GFLOP/s ============================= ... ``` ### Building one Convolution CUDA kernel To compile and run one CUDA Core convolution kernel implementing forward propagation (fprop) with F32 accumulation and FP32 input targeting NVIDIA Ampere and Turing architecture, use the below cmake command line: ```bash $ cmake .. -DCUTLASS_NVCC_ARCHS='75;80' -DCUTLASS_LIBRARY_KERNELS=cutlass_simt_sfprop_optimized_128x128_8x2_nhwc ... $ make cutlass_profiler -j16 ``` Example command line for profiling one CUDA Core convolution kernel: ```bash $ ./tools/profiler/cutlass_profiler --kernels=cutlass_simt_sfprop_optimized_128x128_8x2_nhwc --n=8 --h=224 --w=224 --c=128 --k=128 --r=3 --s=3 ============================= Problem ID: 1 Provider: CUTLASS OperationKind: conv2d Operation: cutlass_simt_sfprop_optimized_128x128_8x2_nhwc Status: Success Verification: ON Disposition: Passed reference_device: Passed Arguments: --conv_kind=fprop --n=8 --h=224 --w=224 --c=128 --k=128 --r=3 --s=3 --p=224 --q=224 --pad_h=1 --pad_w=1 \ --stride_h=1 --stride_w=1 --dilation_h=1 --dilation_w=1 --Activation=f32:nhwc --Filter=f32:nhwc --Output=f32:nhwc \ --conv_mode=cross --iterator_algorithm=optimized --alpha=1 --beta=0 --split_k_mode=serial --split_k_slices=1 \ --eq_gemm_provider=none --op_class=simt --accum=f32 --cta_m=128 --cta_n=128 --cta_k=8 --stages=2 --warps_m=4 \ --warps_n=2 --warps_k=1 --inst_m=1 --inst_n=1 --inst_k=1 --min_cc=50 --max_cc=1024 Bytes: 2055798784 bytes FLOPs: 118482796544 flops Runtime: 7.34266 ms Memory: 260.752 GiB/s Math: 16136.2 GFLOP/s ============================= ``` ## More Details on Compiling CUTLASS Kernels and CUTLASS Profiler - Please follow the links for more CMake examples on selectively compiling CUTLASS kernels: - [GEMM CMake Examples](media/docs/quickstart.md#gemm-cmake-examples) - [Implicit GEMM convolution CMake Examples](media/docs/quickstart.md#convolution-cmake-examples) - [Further details about the CUTLASS Profiler are described here.](media/docs/profiler.md) # About CUTLASS is released by NVIDIA Corporation as Open Source software under the [3-clause "New" BSD license](LICENSE.txt). # Contributors The official list of CUTLASS developers and contributors is available here: [CONTRIBUTORS](CONTRIBUTORS.md). # Copyright Copyright (c) 2017 - 2024 NVIDIA CORPORATION & AFFILIATES. All rights reserved. SPDX-License-Identifier: BSD-3-Clause ``` Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. 2. Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. 3. Neither the name of the copyright holder nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ```