.. Licensed to the Apache Software Foundation (ASF) under one or more contributor license agreements. See the NOTICE file distributed with this work for additional information regarding copyright ownership. The ASF licenses this file to you under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at .. http://www.apache.org/licenses/LICENSE-2.0 .. Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. Your first kernel ================= A complete write → compile → run → inspect loop. This kernel scales a vector by 2 with one block of 256 threads. .. code-block:: python import numpy as np import tvm from tvm.script import tirx as T @T.prim_func def scale(A_ptr: T.handle, B_ptr: T.handle): A = T.match_buffer(A_ptr, (256,), "float32") B = T.match_buffer(B_ptr, (256,), "float32") T.device_entry() # everything below runs on the device bx = T.cta_id([1]) # 1 block (blockIdx) tx = T.thread_id([256]) # 256 threads per block (threadIdx) B[tx] = A[tx] * T.float32(2.0) # compile for CUDA through the TIRx pipeline -> an Executable exe = tvm.compile(tvm.IRModule({"main": scale}), target=tvm.target.Target("cuda"), tir_pipeline="tirx") dev = tvm.cuda(0) a = tvm.runtime.tensor(np.random.rand(256).astype("float32"), device=dev) b = tvm.runtime.tensor(np.zeros(256, "float32"), device=dev) exe(a, b) # run print(exe.mod.imports[0].inspect_source()) # the generated CUDA C What the surrounding calls do: - ``tvm.IRModule({"main": scale})`` wraps the ``PrimFunc`` into an *IRModule* — a named collection of functions; ``"main"`` is the entry point the compiler builds and the symbol you call. - ``tvm.compile(mod, target=..., tir_pipeline="tirx")`` returns an **Executable**: the compiled host launcher plus device code, bundled together. You call it like a function (``exe(a, b)``); arguments are positional and match the kernel's parameter order. - ``tvm.cuda(0)`` is a handle to CUDA device 0; ``tvm.runtime.tensor(arr, device=dev)`` places data on that device as a TVM tensor (an ``NDArray``). - ``exe.mod`` is the underlying runtime ``Module``; ``exe.mod.imports[0]`` is the imported device (CUDA) module, and its ``.inspect_source()`` returns the generated CUDA C. For this kernel, that last ``print`` produces (boilerplate elided): .. code-block:: c++ extern "C" __global__ void __launch_bounds__(256) scale_kernel(float* __restrict__ A_ptr, float* __restrict__ B_ptr) { int tx = ((int)threadIdx.x); B_ptr[tx] = A_ptr[tx] * 2.0f; } Every thread writes one element — a direct map from ``B[tx] = A[tx] * 2.0`` to the generated indexing. .. note:: The compiled ``Executable`` also accepts CUDA ``torch`` tensors **directly** (zero-copy, via DLPack) — no conversion step needed: .. code-block:: python import torch a = torch.rand(256, device="cuda") b = torch.empty(256, device="cuda") exe(a, b) torch.testing.assert_close(b, a * 2) The following chapters expand each piece: :doc:`functions`, :doc:`buffers`, :doc:`control_flow`, :doc:`threads_sync`, and :doc:`compiling`.