.. 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. elementwise → smem ================== The ``smem`` variant lowers an elementwise op (``sqrt``, ``exp``, ``add``, ``fma``, …) when **all operands are in shared memory**. Like the copy :doc:`../copy/gmem_smem` variant it *synthesizes* a ``[outer, threads, vec]`` partition from the execution scope, then applies the op to each (vectorized) element. Source: ``python/tvm/backend/cuda/operator/tile_primitive/elementwise/smem.py``. What it accepts --------------- ``is_smem_ewise(spec)`` builds the predicate: .. code-block:: python def check(op_call, sctx): if not sctx.is_target("cuda"): return False, "non-cuda target" if sctx.scope_kind not in ("thread", "warp", "warpgroup", "cta"): ... ok, reason = _all_threads_active(sctx) # full scope plan, msg = spec.parse(op_call) # parse the op's operands for br in buffer_regions(plan): if not br.buffer.scope().startswith("shared"): # every operand shared* return False, f"operand scope {br.buffer.scope()} != shared*" if br.buffer.layout is None: ... # + spec.check_extras (dtype rules) and anchor-layout validation .. list-table:: :header-rows: 1 :widths: 22 78 * - Property - Requirement * - target / scope / priority - ``cuda``; ``thread`` / ``warp`` / ``warpgroup`` / ``cta`` (all active); priority ``10`` * - operands - **every** operand (inputs and output) in ``shared*`` * - op - any op in the registry (unary ``sqrt``/``exp``/``zero``…, binary ``add``/``mul``…, ``fma``); ``spec.check_extras`` validates the dtype combo * - layout - operands have layouts; the layout sets the **vector width** (the partition itself is synthesized from the scope's thread count, not the layout) Demonstration program ---------------------- A CTA takes the elementwise ``sqrt`` of a ``32×32`` ``float32`` shared tile (adapted from ``test_unary.py`` — here a 256-thread CTA, so the partition is one round): .. code-block:: python s_layout = TileLayout(S[(32, 32)]); full = (slice(0, 32), slice(0, 32)) @T.prim_func def unary_op(A_ptr: T.handle): A = T.match_buffer(A_ptr, (32, 32), "float32", layout=s_layout) T.device_entry(); T.cta_id([1]); T.warp_id([8]); T.lane_id([32]); T.thread_id([256]) A_smem = T.alloc_buffer((32, 32), "float32", scope="shared", layout=s_layout) Tx.cta.copy(A_smem[full], A[full]) Tx.cta.sqrt(A_smem[full], A_smem[full]) # elementwise smem dispatch Tx.cta.copy(A[full], A_smem[full]) Algorithm --------- **1. Parse the op and check operands.** ``spec.parse`` turns the call into a plan (inputs, output, the op); the predicate confirms every operand is shared. **2. Synthesize the partition** from the scope's **thread count** (as :doc:`../copy/gmem_smem` does): split the region into ``[outer, threads, vec]``, with the vector width taken from the layout's innermost contiguous run. For ``32×32 = 1024`` ``float32`` over 256 threads, ``vec = 4`` ⇒ ``outer = 1``. **3. Apply the op per element.** Instead of a copy, each (thread, round) reads its ``vec`` elements, applies the op, and writes back — vectorized: Generated TIRx IR ----------------- .. code-block:: python for f in range(1): # outer = 1 A_smem[tid * 4 + vec] = T.sqrt(A_smem[tid * 4 + vec]) Generated CUDA -------------- The ``vec = 4`` element bundle becomes a ``float4`` and the op is applied per component: .. code-block:: c++ float4 v_ = *(float4*)(&A_smem_ptr[tid * 4]); __1.x = sqrtf(v_.x); __1.y = sqrtf(v_.y); __1.z = sqrtf(v_.z); __1.w = sqrtf(v_.w); (Verified on ``sm_100a`` — the tile equals ``sqrt(A)``.) How inputs change the algorithm ------------------------------- .. list-table:: :header-rows: 1 :widths: 28 72 * - input - effect * - op - unary → ``sqrtf`` / ``expf`` / … per component; binary → the two inputs combined (``a + b``); ``fma`` → ``a * b + c`` * - dtype - sets the vector width (``vec = widest aligned`` ⇒ the round count), as in :doc:`../copy/gmem_smem` * - scope - sets the thread axis and count, hence the synthesized partition