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CUTLASS Python Interface Example

Using Docker

You can run the PyCUTLASS on NGC PyTorch container.

docker run --gpus all -it --rm nvcr.io/nvidia/pytorch:22.09-py3

PyCUTLASS requires additional dependency Boost C++ library, which can be installed with

apt-get update
apt-get -y install libboost-all-dev

Install the Python Interface

The source code for python interface is allocated at tools/library/script/pycutlass. It requires two environment variables:

  • CUTLASS_PATH: the root directory of CUTLASS
  • CUDA_INSTALL_PATH: the directory where cuda toolkit is installed

After setting these two environment variables, PyCUTLASS can be installed with

cd $CUTLASS_PATH/tools/library/scripts/pycutlass && bash build.sh

Troubleshooting

Issue 1: permission denied

Building PyCUTLASS requires installing dependencies to python. So conda could an option if you don't have permission.

Issue 2: rmm: module not found

PyCUTLASS manages the device memory with RMM. Our build.sh automatically pull the rmm branch-22.08 from github and build it from source. The rmm is allocated at $CUTLASS_PATH/tools/library/scripts/pycutlass/rmm. It requires cmake > 3.20.1. If the build fails, it can be manually fixed with the following steps:

cd $CUTLASS_PATH/tools/library/scripts/pycutlass/rmm && ./build.sh librmm rmm

cd $CUTLASS_PATH/tools/library/scripts/pycutlass/rmm/python
python setup.py build_ext --inplace
python setup.py install

To test whether rmm is successfully installed, try import rmm. For other issues related to rmm, please check https://github.com/rapidsai/rmm/issues.

For all the tests, add --print_cuda to print the underlying CUDA kernel. Use -h or --help to display the help message.

GEMM Examples

The GEMM examples use numpy to create input tensors and verify the results.

GEMM F64 Example

Example 1: SM80_Device_Gemm_f64t_f64n_f64n_tensor_op_f64_32x32x16_16x16x16

python gemm.py -i 8 8 4 -ta float64 -tb float64 -tc float64 -tacc float64 -m multiply_add -op TensorOp -b 32 32 16 -s 4 -w 2 2 1 -cc 80 -la ColumnMajor -aa 1 -lb RowMajor -ab 1 -lc RowMajor -ac 1 -te float64 -ep LinearCombination -sw IdentitySwizzle1 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 1

Example 2: SM80_Device_Gemm_f64n_f64t_f64n_tensor_op_f64_64x64x16_32x32x16, split_k(2)_serial

python gemm.py -i 8 8 4 -ta float64 -tb float64 -tc float64 -tacc float64 -m multiply_add -op TensorOp -b 64 64 16 -s 4 -w 2 2 1 -cc 80 -la RowMajor -aa 1 -lb ColumnMajor -ab 1 -lc RowMajor -ac 1 -te float64 -ep LinearCombination -sw IdentitySwizzle1 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 2

GEMM F32 Example

Example 1: SM80_Device_Gemm_f32n_f32t_f32n_tensor_op_bf16_f32_128x128x32_64x64x32

python gemm.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add_fast_bf16 -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la RowMajor -aa 4 -lb ColumnMajor -ab 4 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -sw IdentitySwizzle1 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 1

Example 2: SM80_Device_Gemm_f32t_f32t_f32n_tensor_op_f32_128x128x32_64x64x32, split_k(2)_parallel

python gemm.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 4 -lb ColumnMajor -ab 4 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -sw IdentitySwizzle1 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm GemmSplitKParallel -k 2

Example 3: SM80_Device_Gemm_f32t_f32t_f32n_tensor_op_fast_accurate_f32_64x64x32_32x32x32, split_k(4)_serial

python gemm.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add_fast_f32 -op TensorOp -b 64 64 32 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 4 -lb ColumnMajor -ab 4 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -sw IdentitySwizzle1 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 4

GEMM F16 Example

Example 1: SM80_Device_Gemm_f32t_f32n_f32t_tensor_op_bf16_f32_128x128x32_64x64x32

python gemm.py -i 16 8 16 -ta float16 -tb float16 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 8 -lb RowMajor -ab 8 -lc ColumnMajor -ac 4 -te float32 -ep LinearCombination -sw IdentitySwizzle4 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 1

Example 2: SM80_Device_Gemm_f16t_f16t_f16n_tensor_op_f32_128x128x64_64x64x64, split_k(2)_serial

python gemm.py -i 16 8 16 -ta float16 -tb float16 -tc float16 -tacc float32 -m multiply_add -op TensorOp -b 128 128 64 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 8 -lb ColumnMajor -ab 8 -lc RowMajor -ac 8 -te float32 -ep LinearCombination -sw IdentitySwizzle2 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 2

Example 3: SM80_Device_Gemm_f16t_f16t_f32n_tensor_op_f32_256x128x64_64x64x64, split_k(3)_serial

python gemm.py -i 16 8 16 -ta float16 -tb float16 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 256 128 64 -s 3 -w 4 2 1 -cc 80 -la ColumnMajor -aa 8 -lb ColumnMajor -ab 8 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -sw IdentitySwizzle1 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm GemmSplitKParallel -k 3

GEMM BF16 Example

Example 1: Device_Gemm_bf16t_bf16t_f32n_tensor_op_f32_64x128x64_32x64x64, split_k(5)_parallel

python gemm.py -i 16 8 16 -ta bfloat16 -tb bfloat16 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 64 128 64 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 8 -lb ColumnMajor -ab 8 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -sw IdentitySwizzle2 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm GemmSplitKParallel -k 5

GEMM Int8 Example

Example 1: SM80_Device_Gemm_s8n_s8t_s8n_tensor_op_s32_256x128x128_64x64x128

python gemm.py -i 16 8 32 -ta int8 -tb int8 -tc int8 -tacc int32 -m multiply_add -op TensorOp -b 128 128 128 -s 3 -w 2 2 1 -cc 80 -la RowMajor -aa 16 -lb ColumnMajor -ab 16 -lc RowMajor -ac 16 -te float32 -ep FastLinearCombinationClamp -sw IdentitySwizzle2 -p 512 512 512 -alpha 1.0 -beta 0.0 -gm Gemm -k 1

Batched & Array GEMM

Example 1: Batched GEMM

python gemm.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add_fast_bf16 -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la RowMajor -aa 4 -lb ColumnMajor -ab 4 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -sw BatchedIdentitySwizzle -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Batched -k 1 -batch 3

Example 2: Array GEMM

python gemm.py -i 16 8 16 -ta float16 -tb float16 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 8 -lb RowMajor -ab 8 -lc ColumnMajor -ac 4 -te float32 -ep LinearCombination -sw IdentitySwizzle4 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Array -k 1 -batch 2

GEMM Grouped Examples

The GEMM Grouped examples use numpy to create input tensors and verify the results.

Example 1: SM80_Device_GemmGrouped_f16t_f16t_f32t_tensor_op_f32_128x128x32_64x64x32, device schedule

python gemm_grouped.py -i 16 8 16 -ta float16 -tb float16 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 8 -lb ColumnMajor -ab 8 -lc ColumnMajor -ac 4 -te float32 -ep LinearCombination -p ./grouped_gemm_problem_size.csv -alpha 1.0 -beta 0.0 -pm Device

Example 2: SM80_Device_GemmGrouped_f64n_f64n_f64t_tensor_op_f64_64x64x16_32x32x16, host schedule

python gemm_grouped.py -i 8 8 4 -ta float64 -tb float64 -tc float64 -tacc float64 -m multiply_add -op TensorOp -b 64 64 16 -s 4 -w 2 2 1 -cc 80 -la RowMajor -aa 1 -lb RowMajor -ab 1 -lc ColumnMajor -ac 1 -te float64 -ep LinearCombination -p ./grouped_gemm_problem_size.csv -alpha 1.0 -beta 1.0 -pm Host

Example 3: SM80_Device_GemmGrouped_f32n_f32n_f32n_simt_f32_128x64x8_64x32x1, device schedule

python gemm_grouped.py -i 1 1 1 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add -op Simt -b 128 64 8 -s 4 -w 2 2 1 -cc 80 -la RowMajor -aa 1 -lb RowMajor -ab 1 -lc RowMajor -ac 1 -te float32 -ep LinearCombination -p ./grouped_gemm_problem_size.csv -alpha 2.0 -beta 1.0 -pm Device

Example 4: SM80_Device_GemmGrouped_f16t_f16t_f32t_tensor_op_f32_128x128x32_64x64x32, device schedule

python gemm_grouped.py -i 16 8 16 -ta float16 -tb float16 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 8 -lb ColumnMajor -ab 8 -lc ColumnMajor -ac 4 -te float32 -ep LinearCombination -p ./grouped_gemm_problem_size.csv -alpha 2.0 -beta 1.0 -pm Device

Conv2d Example

The Conv2d examples use pytorch to create input tensors and verify the results. Pytorch can be installed following the official website.

Conv2d F32 Fprop

Example 1: SM80_Device_Conv2d_Fprop_Analytic_ImplicitGemm_tf32nhwc_tf32nhwc_f32nhwc_tensor_op_f32

python conv2d.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 16 -s 3 -w 2 2 1 -cc 80 -la TensorNHWC -aa 4 -lb TensorNHWC -ab 4 -lc TensorNHWC -ac 4 -te float32 -ep LinearCombination -sw IdentitySwizzle1 -co fprop -st Strided -ia optimized -sm Serial -k 1 -nhwc 1 13 17 8 -krsc 24 3 3 8 -pad 0 0 0 0 -stride 2 2 -dilation 1 1 -alpha 1.0 -beta 0.0

Example 2: SM80_Device_Conv2d_Fprop_Optimized_ImplicitGemm_tf32nhwc_tf32nhwc_f32nhwc_tensor_op_f32_align2

python conv2d.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 16 -s 3 -w 2 2 1 -cc 80 -la TensorNHWC -aa 2 -lb TensorNHWC -ab 2 -lc TensorNHWC -ac 2 -te float32 -ep LinearCombination -sw IdentitySwizzle2 -co fprop -st Strided -ia optimized -sm Serial -k 2 -nhwc 1 4 4 12 -krsc 8 3 3 12 -pad 0 0 0 0 -stride 3 3 -dilation 1 1 -alpha 1.0 -beta 1.0

Example 3: SM80_Device_Conv2d_Fprop_Analytic_ImplicitGemm_f32nhwc_f32nhwc_f32nhwc_simt_f32

python conv2d.py -i 1 1 1 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add -op Simt -b 128 128 8 -s 4 -w 4 2 1 -cc 80 -la TensorNHWC -aa 4 -lb TensorNHWC -ab 4 -lc TensorNHWC -ac 1 -te float32 -ep LinearCombination -sw IdentitySwizzle4 -co fprop -st Strided -ia analytic -sm Parallel -k 3 -nhwc 1 71 80 32 -krsc 64 5 5 32 -pad 2 2 2 2 -stride 2 2 -dilation 1 1 -alpha 1.0 -beta 1.0

Conv2d F32 Wgrad

Example 1: Device_Conv2d_Wgrad_Optimized_ImplicitGemm_tf32nhwc_tf32nhwc_f32nhwc_tensor_op_f32_align1

python conv2d.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la TensorNHWC -aa 1 -lb TensorNHWC -ab 1 -lc TensorNHWC -ac 4 -te float32 -ep LinearCombination -sw IdentitySwizzle1 -co wgrad -st Strided -ia optimized -sm Serial -k 1 -nhwc 1 8 8 1 -krsc 1 3 3 1 -pad 1 1 1 1 -stride 1 1 -dilation 1 1 -alpha 1.0 -beta 0.0

Example 2: Device_Conv2d_Wgrad_Analytic_ImplicitGemm_f32nhwc_f32nhwc_f32nhwc_simt_f32

python conv2d.py -i 1 1 1 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add -op Simt -b 128 128 8 -s 4 -w 2 4 1 -cc 80 -la TensorNHWC -aa 4 -lb TensorNHWC -ab 4 -lc TensorNHWC -ac 1 -te float32 -ep LinearCombination -sw IdentitySwizzle1 -co wgrad -st Strided -ia optimized -sm Serial -k 2 -nhwc 1 27 27 256 -krsc 512 3 3 256 -pad 1 1 1 1 -stride 2 1 -dilation 1 1 -alpha 1.0 -beta 0.0

Conv2d F32 Dgrad

Example 1: Device_Conv2d_Dgrad_Analytic_ImplicitGemm_tf32nhwc_tf32nhwc_f32nhwc_tensor_op_f32

python conv2d.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 16 -s 3 -w 2 2 1 -cc 80 -la TensorNHWC -aa 4 -lb TensorNHWC -ab 4 -lc TensorNHWC -ac 4 -te float32 -ep LinearCombination -sw StridedDgradIdentitySwizzle1 -co dgrad -st Strided -ia optimized -sm Serial -k 2 -nhwc 1 27 27 256 -krsc 512 3 3 256 -pad 1 1 1 1 -stride 2 1 -dilation 1 1 -alpha 1.0 -beta 0.0

Conv2d F16 Fprop

Example 1: SM80_Device_Conv2d_Fprop_Analytic_ImplicitGemm_f16nhwc_f16nhwc_f16nhwc_tensor_op_f32

python conv2d.py -i 16 8 16 -ta float16 -tb float16 -tc float16 -tacc float32 -m multiply_add -op TensorOp -b 128 128 64 -s 3 -w 2 2 1 -cc 80 -la TensorNHWC -aa 8 -lb TensorNHWC -ab 8 -lc TensorNHWC -ac 8 -te float32 -ep LinearCombination -sw IdentitySwizzle1 -co fprop -st Strided -ia optimized -sm Serial -k 1 -nhwc 1 27 27 256 -krsc 512 3 3 256 -pad 1 1 1 1 -stride 2 1 -dilation 1 1 -alpha 1.0 -beta 0.0

Example 2: SM80_Device_Conv2d_Fprop_Few_Channels_ImplicitGemm_f16nhwc_f16nhwc_f16nhwc_tensor_op_f32_channels_2

python conv2d.py -i 16 8 16 -ta float16 -tb float16 -tc float16 -tacc float32 -m multiply_add -op TensorOp -b 128 128 64 -s 3 -w 2 2 1 -cc 80 -la TensorNHWC -aa 2 -lb TensorNHWC -ab 2 -lc TensorNHWC -ac 8 -te float32 -ep LinearCombination -sw IdentitySwizzle1 -co fprop -st Strided -ia few_channels -sm Serial -k 1 -nhwc 1 16 16 2 -krsc 16 3 3 2 -pad 1 1 1 1 -stride 2 2 -dilation 1 1 -alpha 1.0 -beta 0.0

Example 3: SM80_Device_Conv2d_Fprop_Fixed_Channels_ImplicitGemm_f16nhwc_f16nhwc_f16nhwc_tensor_op_f32_channels_8

python conv2d.py -i 16 8 16 -ta float16 -tb float16 -tc float16 -tacc float32 -m multiply_add -op TensorOp -b 128 128 64 -s 3 -w 2 2 1 -cc 80 -la TensorNHWC -aa 8 -lb TensorNHWC -ab 8 -lc TensorNHWC -ac 8 -te float32 -ep LinearCombination -sw IdentitySwizzle2 -co fprop -st Strided -ia fixed_channels -sm Serial -k 1 -nhwc 1 8 8 8 -krsc 16 3 3 8 -pad 1 1 1 1 -stride 2 2 -dilation 1 1 -alpha 1.0 -beta 0.0

Example 4: SM80_Device_Conv2d_Strided_Dgrad_Optimized_ImplicitGemm_f16nhwc_f16nhwc_f32nhwc_tensor_op_f32_128x128_32x3_64x64x32_align4

python conv2d.py -i 16 8 16 -ta float16 -tb float16 -tc float16 -tacc float32 -m multiply_add -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la TensorNHWC -aa 4 -lb TensorNHWC -ab 4 -lc TensorNHWC -ac 4 -te float32 -ep LinearCombination -sw StridedDgradIdentitySwizzle1 -co dgrad -st Strided -ia optimized -sm Serial -k 1 -nhwc 1 56 56 12 -krsc 8 1 1 12 -pad 0 0 0 0 -stride 2 2 -dilation 1 1 -alpha 1.0 -beta 0.0

Epilogue

Bias

To replace C with a bias vector, add -bias flag.

Activation function

Example 1: ReLU

python gemm.py -i 8 8 4 -ta float64 -tb float64 -tc float64 -tacc float64 -m multiply_add -op TensorOp -b 32 32 16 -s 4 -w 2 2 1 -cc 80 -la ColumnMajor -aa 1 -lb RowMajor -ab 1 -lc RowMajor -ac 1 -te float64 -ep LinearCombination -sw IdentitySwizzle1 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 1 -bias -activ relu

Example 2: leaky ReLU

python gemm.py -i 8 8 4 -ta float64 -tb float64 -tc float64 -tacc float64 -m multiply_add -op TensorOp -b 64 64 16 -s 4 -w 2 2 1 -cc 80 -la RowMajor -aa 1 -lb ColumnMajor -ab 1 -lc RowMajor -ac 1 -te float64 -ep LinearCombination -sw IdentitySwizzle1 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 2 -bias -activ leaky_relu -activ_arg 0.2

Example 3: tanh (alpha=0 to avoid saturation)

python gemm.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 4 -lb ColumnMajor -ab 4 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -sw IdentitySwizzle1 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm GemmSplitKParallel -k 2 -bias -activ tanh

Example 4: sigmoid

python gemm_grouped.py -i 8 8 4 -ta float64 -tb float64 -tc float64 -tacc float64 -m multiply_add -op TensorOp -b 64 64 16 -s 4 -w 2 2 1 -cc 80 -la RowMajor -aa 1 -lb RowMajor -ab 1 -lc ColumnMajor -ac 1 -te float64 -ep LinearCombination -p ./grouped_gemm_problem_size.csv -alpha 0.0 -beta 0.5 -pm Host -bias -activ sigmoid -bias -activ sigmoid

Example 5: SiLU

python conv2d.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 16 -s 3 -w 2 2 1 -cc 80 -la TensorNHWC -aa 2 -lb TensorNHWC -ab 2 -lc TensorNHWC -ac 2 -te float32 -ep LinearCombination -sw IdentitySwizzle2 -co fprop -st Strided -ia optimized -sm Serial -k 2 -nhwc 1 4 4 12 -krsc 8 3 3 12 -pad 0 0 0 0 -stride 3 3 -dilation 1 1 -alpha 0.0 -beta 0.5 -bias -activ silu

Example 6: HardSwish

python conv2d.py -i 16 8 16 -ta float16 -tb float16 -tc float16 -tacc float32 -m multiply_add -op TensorOp -b 128 128 64 -s 3 -w 2 2 1 -cc 80 -la TensorNHWC -aa 2 -lb TensorNHWC -ab 2 -lc TensorNHWC -ac 8 -te float32 -ep LinearCombination -sw IdentitySwizzle1 -co fprop -st Strided -ia few_channels -sm Serial -k 1 -nhwc 1 16 16 2 -krsc 16 3 3 2 -pad 1 1 1 1 -stride 2 2 -dilation 1 1 -alpha 0.0 -beta 0.5 -bias -activ hardswish

Example 7: GELU

python gemm.py -i 16 8 16 -ta bfloat16 -tb bfloat16 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 64 128 64 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 8 -lb ColumnMajor -ab 8 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -sw IdentitySwizzle2 -p 512 256 128 -alpha 0.0 -beta 0.5 -gm GemmSplitKParallel -k 5 -bias -activ gelu

Epilogue Visitor Tree

Example 1:

python gemm.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add_fast_bf16 -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la RowMajor -aa 4 -lb ColumnMajor -ab 4 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -epv RowBroadcast -sw IdentitySwizzle1 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 1

Example 2:

python gemm.py -i 8 8 4 -ta float64 -tb float64 -tc float64 -tacc float64 -m multiply_add -op TensorOp -b 32 32 16 -s 4 -w 2 2 1 -cc 80 -la ColumnMajor -aa 1 -lb RowMajor -ab 1 -lc RowMajor -ac 1 -te float64 -ep LinearCombination -epv ColumnBroadcast -sw IdentitySwizzle1 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 1

Example 3:

python gemm.py -i 16 8 16 -ta float16 -tb float16 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 8 -lb RowMajor -ab 8 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -epv RowReduction -sw IdentitySwizzle4 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 1

Example 4:

python gemm.py -i 16 8 16 -ta bfloat16 -tb bfloat16 -tc float32 -tacc float32 -m multiply_add -op TensorOp -b 64 128 64 -s 3 -w 2 2 1 -cc 80 -la ColumnMajor -aa 8 -lb ColumnMajor -ab 8 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -epv ColumnReduction -sw IdentitySwizzle2 -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Gemm -k 1

Example 5:

python gemm.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add_fast_bf16 -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la RowMajor -aa 4 -lb ColumnMajor -ab 4 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -epv RowReduction -sw BatchedIdentitySwizzle -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Batched -k 1 -batch 3

Example 6:

python gemm.py -i 16 8 8 -ta float32 -tb float32 -tc float32 -tacc float32 -m multiply_add_fast_bf16 -op TensorOp -b 128 128 32 -s 3 -w 2 2 1 -cc 80 -la RowMajor -aa 4 -lb ColumnMajor -ab 4 -lc RowMajor -ac 4 -te float32 -ep LinearCombination -epv ColumnBroadcast -sw BatchedIdentitySwizzle -p 512 256 128 -alpha 1.0 -beta 0.5 -gm Array -k 1 -batch 3