//===- AsyncRegionRewriter.cpp - Implementation of GPU async rewriters ----===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file implements the GPU dialect pattern rewriters that make GPU op // within a region execute asynchronously. // //===----------------------------------------------------------------------===// #include "PassDetail.h" #include "mlir/Dialect/Async/IR/Async.h" #include "mlir/Dialect/GPU/GPUDialect.h" #include "mlir/Dialect/GPU/Passes.h" #include "mlir/Dialect/GPU/Utils.h" #include "mlir/IR/BlockAndValueMapping.h" #include "mlir/IR/Builders.h" #include "mlir/IR/PatternMatch.h" #include "mlir/IR/SymbolTable.h" #include "mlir/Support/LLVM.h" #include "mlir/Transforms/RegionUtils.h" #include "llvm/ADT/TypeSwitch.h" using namespace mlir; namespace { class GpuAsyncRegionPass : public GpuAsyncRegionPassBase { struct ThreadTokenCallback; struct DeferWaitCallback; struct SingleTokenUseCallback; void runOnOperation() override; }; } // namespace static bool isTerminator(Operation *op) { return op->mightHaveTrait(); } static bool hasSideEffects(Operation *op) { return !MemoryEffectOpInterface::hasNoEffect(op); } // Region walk callback which makes GPU ops implementing the AsyncOpInterface // execute asynchronously. struct GpuAsyncRegionPass::ThreadTokenCallback { ThreadTokenCallback(MLIRContext &context) : builder(&context) {} WalkResult operator()(Block *block) { for (Operation &op : make_early_inc_range(*block)) { if (failed(visit(&op))) return WalkResult::interrupt(); } return WalkResult::advance(); } private: // If `op` implements the AsyncOpInterface, insert a `gpu.wait async` to // create a current token (unless it already exists), and 'thread' that token // through the `op` so that it executes asynchronously. // // If `op` is a terminator or an op with side-effects, insert a `gpu.wait` to // host-synchronize execution. A `!gpu.async.token` will therefore only be // used inside of its block and GPU execution will always synchronize with // the host at block boundaries. LogicalResult visit(Operation *op) { if (isa(op)) return op->emitOpError("replace with gpu.launch_func first"); if (auto waitOp = llvm::dyn_cast(op)) { if (currentToken) waitOp.addAsyncDependency(currentToken); currentToken = waitOp.asyncToken(); return success(); } builder.setInsertionPoint(op); if (auto asyncOp = dyn_cast(op)) return rewriteAsyncOp(asyncOp); // Replace GPU op with async version. if (!currentToken) return success(); // Insert host synchronization before terminator or op with side effects. if (isTerminator(op) || hasSideEffects(op)) currentToken = createWaitOp(op->getLoc(), Type(), {currentToken}); return success(); } // Replaces asyncOp with a clone that returns a token. LogicalResult rewriteAsyncOp(gpu::AsyncOpInterface asyncOp) { auto *op = asyncOp.getOperation(); auto tokenType = builder.getType(); // If there is no current token, insert a `gpu.wait async` without // dependencies to create one. if (!currentToken) currentToken = createWaitOp(op->getLoc(), tokenType, {}); asyncOp.addAsyncDependency(currentToken); // Return early if op returns a token already. currentToken = asyncOp.getAsyncToken(); if (currentToken) return success(); // Clone the op to return a token in addition to the other results. SmallVector resultTypes; resultTypes.reserve(1 + op->getNumResults()); copy(op->getResultTypes(), std::back_inserter(resultTypes)); resultTypes.push_back(tokenType); auto *newOp = Operation::create(op->getLoc(), op->getName(), resultTypes, op->getOperands(), op->getAttrDictionary(), op->getSuccessors(), op->getNumRegions()); // Clone regions into new op. BlockAndValueMapping mapping; for (auto pair : llvm::zip_first(op->getRegions(), newOp->getRegions())) std::get<0>(pair).cloneInto(&std::get<1>(pair), mapping); // Replace the op with the async clone. auto results = newOp->getResults(); currentToken = results.back(); builder.insert(newOp); op->replaceAllUsesWith(results.drop_back()); op->erase(); return success(); } Value createWaitOp(Location loc, Type resultType, ValueRange operands) { return builder.create(loc, resultType, operands).asyncToken(); } OpBuilder builder; // The token that represents the current asynchronous dependency. It's valid // range starts with a `gpu.wait async` op, and ends with a `gpu.wait` op. // In between, each gpu::AsyncOpInterface depends on the current token and // produces the new one. Value currentToken = {}; }; /// Erases `executeOp` and returns a clone with additional `results`. async::ExecuteOp addExecuteResults(async::ExecuteOp executeOp, ValueRange results) { // Add values to async.yield op. Operation *yieldOp = executeOp.getBody()->getTerminator(); yieldOp->insertOperands(yieldOp->getNumOperands(), results); // Construct new result type list with additional types. SmallVector resultTypes; resultTypes.reserve(executeOp.getNumResults() + results.size()); transform(executeOp.getResultTypes(), std::back_inserter(resultTypes), [](Type type) { // Extract value type from !async.value. if (auto valueType = type.dyn_cast()) return valueType.getValueType(); assert(type.isa() && "expected token type"); return type; }); transform(results, std::back_inserter(resultTypes), [](Value value) { return value.getType(); }); // Clone executeOp with the extra results. OpBuilder builder(executeOp); auto newOp = builder.create( executeOp.getLoc(), TypeRange{resultTypes}.drop_front() /*drop token*/, executeOp.dependencies(), executeOp.operands()); BlockAndValueMapping mapper; newOp.getRegion().getBlocks().clear(); executeOp.getRegion().cloneInto(&newOp.getRegion(), mapper); // Replace executeOp with cloned one. executeOp.getOperation()->replaceAllUsesWith( newOp.getResults().drop_back(results.size())); executeOp.erase(); return newOp; } // Callback for `async.execute` ops which tries to push the contained // synchronous `gpu.wait` op to the dependencies of the `async.execute`. struct GpuAsyncRegionPass::DeferWaitCallback { // If the `executeOp`s token is used only in `async.execute` or `async.await` // ops, add the region's last `gpu.wait` op to the worklist if it is // synchronous and is the last op with side effects. void operator()(async::ExecuteOp executeOp) { if (!areAllUsersExecuteOrAwait(executeOp.token())) return; // async.execute's region is currently restricted to one block. for (auto &op : llvm::reverse(executeOp.getBody()->without_terminator())) { if (auto waitOp = dyn_cast(op)) { if (!waitOp.asyncToken()) worklist.push_back(waitOp); return; } if (hasSideEffects(&op)) return; } } // The destructor performs the actual rewrite work. ~DeferWaitCallback() { for (size_t i = 0; i < worklist.size(); ++i) { auto waitOp = worklist[i]; auto executeOp = waitOp->getParentOfType(); // Erase `gpu.wait` and return async dependencies from execute op instead. SmallVector dependencies = waitOp.asyncDependencies(); waitOp.erase(); executeOp = addExecuteResults(executeOp, dependencies); // Add the async dependency to each user of the `async.execute` token. auto asyncTokens = executeOp.getResults().take_back(dependencies.size()); for (Operation *user : executeOp.token().getUsers()) addAsyncDependencyAfter(asyncTokens, user); } } private: // Returns whether all token users are either 'async.execute' or 'async.await' // ops. This is used as a requirement for pushing 'gpu.wait' ops from a // 'async.execute' body to it's users. Specifically, we do not allow // terminator users, because it could mean that the `async.execute` is inside // control flow code. static bool areAllUsersExecuteOrAwait(Value token) { return !token.use_empty() && llvm::all_of(token.getUsers(), [](Operation *user) { return isa(user); }); } // Add the `asyncToken` as dependency as needed after `op`. void addAsyncDependencyAfter(ValueRange asyncTokens, Operation *op) { OpBuilder builder(op->getContext()); auto loc = op->getLoc(); Block::iterator it; SmallVector tokens; tokens.reserve(asyncTokens.size()); TypeSwitch(op) .Case([&](auto awaitOp) { // Add async.await ops to wait for the !gpu.async.tokens. builder.setInsertionPointAfter(op); for (auto asyncToken : asyncTokens) tokens.push_back( builder.create(loc, asyncToken).result()); // Set `it` after the inserted async.await ops. it = builder.getInsertionPoint(); }) .Case([&](auto executeOp) { // Set `it` to the beginning of the region and add asyncTokens to the // async.execute operands. it = executeOp.getBody()->begin(); executeOp.operandsMutable().append(asyncTokens); SmallVector tokenTypes( asyncTokens.size(), builder.getType()); SmallVector tokenLocs(asyncTokens.size(), executeOp.getLoc()); copy(executeOp.getBody()->addArguments(tokenTypes, tokenLocs), std::back_inserter(tokens)); }); // Advance `it` to terminator or op with side-effects. it = std::find_if(it, Block::iterator(), [](Operation &op) { return isTerminator(&op) || hasSideEffects(&op); }); // If `op` implements the AsyncOpInterface, add `token` to the list of async // dependencies. if (auto asyncOp = dyn_cast(*it)) { for (auto token : tokens) asyncOp.addAsyncDependency(token); return; } // Otherwise, insert a gpu.wait before 'it'. builder.setInsertionPoint(it->getBlock(), it); auto waitOp = builder.create(loc, Type{}, tokens); // If the new waitOp is at the end of an async.execute region, add it to the // worklist. 'operator()(executeOp)' would do the same, but this is faster. auto executeOp = dyn_cast(it->getParentOp()); if (executeOp && areAllUsersExecuteOrAwait(executeOp.token()) && !it->getNextNode()) worklist.push_back(waitOp); } SmallVector worklist; }; // Callback for `async.execute` ops which repeats !gpu.async.token results // so that each of them is only used once. struct GpuAsyncRegionPass::SingleTokenUseCallback { void operator()(async::ExecuteOp executeOp) { // Extract !gpu.async.token results which have multiple uses. auto multiUseResults = llvm::make_filter_range(executeOp.results(), [](OpResult result) { if (result.use_empty() || result.hasOneUse()) return false; auto valueType = result.getType().dyn_cast(); return valueType && valueType.getValueType().isa(); }); if (multiUseResults.empty()) return; // Indices within !async.execute results (i.e. without the async.token). SmallVector indices; transform(multiUseResults, std::back_inserter(indices), [](OpResult result) { return result.getResultNumber() - 1; // Index without token. }); for (auto index : indices) { assert(!executeOp.results()[index].getUses().empty()); // Repeat async.yield token result, one for each use after the first one. auto uses = llvm::drop_begin(executeOp.results()[index].getUses()); auto count = std::distance(uses.begin(), uses.end()); auto yieldOp = cast(executeOp.getBody()->getTerminator()); SmallVector operands(count, yieldOp.getOperand(index)); executeOp = addExecuteResults(executeOp, operands); // Update 'uses' to refer to the new executeOp. uses = llvm::drop_begin(executeOp.results()[index].getUses()); auto results = executeOp.results().take_back(count); for (auto pair : llvm::zip(uses, results)) std::get<0>(pair).set(std::get<1>(pair)); } } }; // Replaces synchronous GPU ops in the op's region with asynchronous ones and // inserts the necessary synchronization (as gpu.wait ops). Assumes sequential // execution semantics and that no GPU ops are asynchronous yet. void GpuAsyncRegionPass::runOnOperation() { if (getOperation()->walk(ThreadTokenCallback(getContext())).wasInterrupted()) return signalPassFailure(); // Collect gpu.wait ops that we can move out of async.execute regions. getOperation().getRegion().walk(DeferWaitCallback()); // Makes each !gpu.async.token returned from async.execute op have single use. getOperation().getRegion().walk(SingleTokenUseCallback()); } std::unique_ptr> mlir::createGpuAsyncRegionPass() { return std::make_unique(); }