//===- AsyncParallelFor.cpp - Implementation of Async Parallel For --------===// // // 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 scf.parallel to scf.for + async.execute conversion pass. // //===----------------------------------------------------------------------===// #include "PassDetail.h" #include "mlir/Dialect/Arithmetic/IR/Arithmetic.h" #include "mlir/Dialect/Async/IR/Async.h" #include "mlir/Dialect/Async/Passes.h" #include "mlir/Dialect/SCF/SCF.h" #include "mlir/Dialect/StandardOps/IR/Ops.h" #include "mlir/IR/BlockAndValueMapping.h" #include "mlir/IR/ImplicitLocOpBuilder.h" #include "mlir/IR/Matchers.h" #include "mlir/IR/PatternMatch.h" #include "mlir/Transforms/GreedyPatternRewriteDriver.h" #include "mlir/Transforms/RegionUtils.h" using namespace mlir; using namespace mlir::async; #define DEBUG_TYPE "async-parallel-for" namespace { // Rewrite scf.parallel operation into multiple concurrent async.execute // operations over non overlapping subranges of the original loop. // // Example: // // scf.parallel (%i, %j) = (%lbi, %lbj) to (%ubi, %ubj) step (%si, %sj) { // "do_some_compute"(%i, %j): () -> () // } // // Converted to: // // // Parallel compute function that executes the parallel body region for // // a subset of the parallel iteration space defined by the one-dimensional // // compute block index. // func parallel_compute_function(%block_index : index, %block_size : index, // , ...) { // // Compute multi-dimensional loop bounds for %block_index. // %block_lbi, %block_lbj = ... // %block_ubi, %block_ubj = ... // // // Clone parallel operation body into the scf.for loop nest. // scf.for %i = %blockLbi to %blockUbi { // scf.for %j = block_lbj to %block_ubj { // "do_some_compute"(%i, %j): () -> () // } // } // } // // And a dispatch function depending on the `asyncDispatch` option. // // When async dispatch is on: (pseudocode) // // %block_size = ... compute parallel compute block size // %block_count = ... compute the number of compute blocks // // func @async_dispatch(%block_start : index, %block_end : index, ...) { // // Keep splitting block range until we reached a range of size 1. // while (%block_end - %block_start > 1) { // %mid_index = block_start + (block_end - block_start) / 2; // async.execute { call @async_dispatch(%mid_index, %block_end); } // %block_end = %mid_index // } // // // Call parallel compute function for a single block. // call @parallel_compute_fn(%block_start, %block_size, ...); // } // // // Launch async dispatch for [0, block_count) range. // call @async_dispatch(%c0, %block_count); // // When async dispatch is off: // // %block_size = ... compute parallel compute block size // %block_count = ... compute the number of compute blocks // // scf.for %block_index = %c0 to %block_count { // call @parallel_compute_fn(%block_index, %block_size, ...) // } // struct AsyncParallelForPass : public AsyncParallelForBase { AsyncParallelForPass() = default; AsyncParallelForPass(bool asyncDispatch, int32_t numWorkerThreads, int32_t minTaskSize) { this->asyncDispatch = asyncDispatch; this->numWorkerThreads = numWorkerThreads; this->minTaskSize = minTaskSize; } void runOnOperation() override; }; struct AsyncParallelForRewrite : public OpRewritePattern { public: AsyncParallelForRewrite(MLIRContext *ctx, bool asyncDispatch, int32_t numWorkerThreads, int32_t minTaskSize) : OpRewritePattern(ctx), asyncDispatch(asyncDispatch), numWorkerThreads(numWorkerThreads), minTaskSize(minTaskSize) {} LogicalResult matchAndRewrite(scf::ParallelOp op, PatternRewriter &rewriter) const override; private: bool asyncDispatch; int32_t numWorkerThreads; int32_t minTaskSize; }; struct ParallelComputeFunctionType { FunctionType type; SmallVector captures; }; // Helper struct to parse parallel compute function argument list. struct ParallelComputeFunctionArgs { BlockArgument blockIndex(); BlockArgument blockSize(); ArrayRef tripCounts(); ArrayRef lowerBounds(); ArrayRef upperBounds(); ArrayRef steps(); ArrayRef captures(); unsigned numLoops; ArrayRef args; }; struct ParallelComputeFunctionBounds { SmallVector tripCounts; SmallVector lowerBounds; SmallVector upperBounds; SmallVector steps; }; struct ParallelComputeFunction { unsigned numLoops; FuncOp func; llvm::SmallVector captures; }; } // namespace BlockArgument ParallelComputeFunctionArgs::blockIndex() { return args[0]; } BlockArgument ParallelComputeFunctionArgs::blockSize() { return args[1]; } ArrayRef ParallelComputeFunctionArgs::tripCounts() { return args.drop_front(2).take_front(numLoops); } ArrayRef ParallelComputeFunctionArgs::lowerBounds() { return args.drop_front(2 + 1 * numLoops).take_front(numLoops); } ArrayRef ParallelComputeFunctionArgs::upperBounds() { return args.drop_front(2 + 2 * numLoops).take_front(numLoops); } ArrayRef ParallelComputeFunctionArgs::steps() { return args.drop_front(2 + 3 * numLoops).take_front(numLoops); } ArrayRef ParallelComputeFunctionArgs::captures() { return args.drop_front(2 + 4 * numLoops); } template static SmallVector integerConstants(ValueRange values) { SmallVector attrs(values.size()); for (unsigned i = 0; i < values.size(); ++i) matchPattern(values[i], m_Constant(&attrs[i])); return attrs; } // Converts one-dimensional iteration index in the [0, tripCount) interval // into multidimensional iteration coordinate. static SmallVector delinearize(ImplicitLocOpBuilder &b, Value index, ArrayRef tripCounts) { SmallVector coords(tripCounts.size()); assert(!tripCounts.empty() && "tripCounts must be not empty"); for (ssize_t i = tripCounts.size() - 1; i >= 0; --i) { coords[i] = b.create(index, tripCounts[i]); index = b.create(index, tripCounts[i]); } return coords; } // Returns a function type and implicit captures for a parallel compute // function. We'll need a list of implicit captures to setup block and value // mapping when we'll clone the body of the parallel operation. static ParallelComputeFunctionType getParallelComputeFunctionType(scf::ParallelOp op, PatternRewriter &rewriter) { // Values implicitly captured by the parallel operation. llvm::SetVector captures; getUsedValuesDefinedAbove(op.region(), op.region(), captures); SmallVector inputs; inputs.reserve(2 + 4 * op.getNumLoops() + captures.size()); Type indexTy = rewriter.getIndexType(); // One-dimensional iteration space defined by the block index and size. inputs.push_back(indexTy); // blockIndex inputs.push_back(indexTy); // blockSize // Multi-dimensional parallel iteration space defined by the loop trip counts. for (unsigned i = 0; i < op.getNumLoops(); ++i) inputs.push_back(indexTy); // loop tripCount // Parallel operation lower bound, upper bound and step. Lower bound, upper // bound and step passed as contiguous arguments: // call @compute(%lb0, %lb1, ..., %ub0, %ub1, ..., %step0, %step1, ...) for (unsigned i = 0; i < op.getNumLoops(); ++i) { inputs.push_back(indexTy); // lower bound inputs.push_back(indexTy); // upper bound inputs.push_back(indexTy); // step } // Types of the implicit captures. for (Value capture : captures) inputs.push_back(capture.getType()); // Convert captures to vector for later convenience. SmallVector capturesVector(captures.begin(), captures.end()); return {rewriter.getFunctionType(inputs, TypeRange()), capturesVector}; } // Create a parallel compute fuction from the parallel operation. static ParallelComputeFunction createParallelComputeFunction( scf::ParallelOp op, ParallelComputeFunctionBounds bounds, unsigned numBlockAlignedInnerLoops, PatternRewriter &rewriter) { OpBuilder::InsertionGuard guard(rewriter); ImplicitLocOpBuilder b(op.getLoc(), rewriter); ModuleOp module = op->getParentOfType(); ParallelComputeFunctionType computeFuncType = getParallelComputeFunctionType(op, rewriter); FunctionType type = computeFuncType.type; FuncOp func = FuncOp::create(op.getLoc(), "parallel_compute_fn", type); func.setPrivate(); // Insert function into the module symbol table and assign it unique name. SymbolTable symbolTable(module); symbolTable.insert(func); rewriter.getListener()->notifyOperationInserted(func); // Create function entry block. Block *block = b.createBlock(&func.getBody(), func.begin(), type.getInputs()); b.setInsertionPointToEnd(block); ParallelComputeFunctionArgs args = {op.getNumLoops(), func.getArguments()}; // Block iteration position defined by the block index and size. BlockArgument blockIndex = args.blockIndex(); BlockArgument blockSize = args.blockSize(); // Constants used below. Value c0 = b.create(0); Value c1 = b.create(1); // Materialize known constants as constant operation in the function body. auto values = [&](ArrayRef args, ArrayRef attrs) { return llvm::to_vector( llvm::map_range(llvm::zip(args, attrs), [&](auto tuple) -> Value { if (IntegerAttr attr = std::get<1>(tuple)) return b.create(attr); return std::get<0>(tuple); })); }; // Multi-dimensional parallel iteration space defined by the loop trip counts. auto tripCounts = values(args.tripCounts(), bounds.tripCounts); // Parallel operation lower bound and step. auto lowerBounds = values(args.lowerBounds(), bounds.lowerBounds); auto steps = values(args.steps(), bounds.steps); // Remaining arguments are implicit captures of the parallel operation. ArrayRef captures = args.captures(); // Compute a product of trip counts to get the size of the flattened // one-dimensional iteration space. Value tripCount = tripCounts[0]; for (unsigned i = 1; i < tripCounts.size(); ++i) tripCount = b.create(tripCount, tripCounts[i]); // Find one-dimensional iteration bounds: [blockFirstIndex, blockLastIndex]: // blockFirstIndex = blockIndex * blockSize Value blockFirstIndex = b.create(blockIndex, blockSize); // The last one-dimensional index in the block defined by the `blockIndex`: // blockLastIndex = min(blockFirstIndex + blockSize, tripCount) - 1 Value blockEnd0 = b.create(blockFirstIndex, blockSize); Value blockEnd1 = b.create(blockEnd0, tripCount); Value blockLastIndex = b.create(blockEnd1, c1); // Convert one-dimensional indices to multi-dimensional coordinates. auto blockFirstCoord = delinearize(b, blockFirstIndex, tripCounts); auto blockLastCoord = delinearize(b, blockLastIndex, tripCounts); // Compute loops upper bounds derived from the block last coordinates: // blockEndCoord[i] = blockLastCoord[i] + 1 // // Block first and last coordinates can be the same along the outer compute // dimension when inner compute dimension contains multiple blocks. SmallVector blockEndCoord(op.getNumLoops()); for (size_t i = 0; i < blockLastCoord.size(); ++i) blockEndCoord[i] = b.create(blockLastCoord[i], c1); // Construct a loop nest out of scf.for operations that will iterate over // all coordinates in [blockFirstCoord, blockLastCoord] range. using LoopBodyBuilder = std::function; using LoopNestBuilder = std::function; // Parallel region induction variables computed from the multi-dimensional // iteration coordinate using parallel operation bounds and step: // // computeBlockInductionVars[loopIdx] = // lowerBound[loopIdx] + blockCoord[loopIdx] * step[loopIdx] SmallVector computeBlockInductionVars(op.getNumLoops()); // We need to know if we are in the first or last iteration of the // multi-dimensional loop for each loop in the nest, so we can decide what // loop bounds should we use for the nested loops: bounds defined by compute // block interval, or bounds defined by the parallel operation. // // Example: 2d parallel operation // i j // loop sizes: [50, 50] // first coord: [25, 25] // last coord: [30, 30] // // If `i` is equal to 25 then iteration over `j` should start at 25, when `i` // is between 25 and 30 it should start at 0. The upper bound for `j` should // be 50, except when `i` is equal to 30, then it should also be 30. // // Value at ith position specifies if all loops in [0, i) range of the loop // nest are in the first/last iteration. SmallVector isBlockFirstCoord(op.getNumLoops()); SmallVector isBlockLastCoord(op.getNumLoops()); // Builds inner loop nest inside async.execute operation that does all the // work concurrently. LoopNestBuilder workLoopBuilder = [&](size_t loopIdx) -> LoopBodyBuilder { return [&, loopIdx](OpBuilder &nestedBuilder, Location loc, Value iv, ValueRange args) { ImplicitLocOpBuilder nb(loc, nestedBuilder); // Compute induction variable for `loopIdx`. computeBlockInductionVars[loopIdx] = nb.create( lowerBounds[loopIdx], nb.create(iv, steps[loopIdx])); // Check if we are inside first or last iteration of the loop. isBlockFirstCoord[loopIdx] = nb.create( arith::CmpIPredicate::eq, iv, blockFirstCoord[loopIdx]); isBlockLastCoord[loopIdx] = nb.create( arith::CmpIPredicate::eq, iv, blockLastCoord[loopIdx]); // Check if the previous loop is in its first or last iteration. if (loopIdx > 0) { isBlockFirstCoord[loopIdx] = nb.create( isBlockFirstCoord[loopIdx], isBlockFirstCoord[loopIdx - 1]); isBlockLastCoord[loopIdx] = nb.create( isBlockLastCoord[loopIdx], isBlockLastCoord[loopIdx - 1]); } // Keep building loop nest. if (loopIdx < op.getNumLoops() - 1) { if (loopIdx + 1 >= op.getNumLoops() - numBlockAlignedInnerLoops) { // For block aligned loops we always iterate starting from 0 up to // the loop trip counts. nb.create(c0, tripCounts[loopIdx + 1], c1, ValueRange(), workLoopBuilder(loopIdx + 1)); } else { // Select nested loop lower/upper bounds depending on our position in // the multi-dimensional iteration space. auto lb = nb.create(isBlockFirstCoord[loopIdx], blockFirstCoord[loopIdx + 1], c0); auto ub = nb.create(isBlockLastCoord[loopIdx], blockEndCoord[loopIdx + 1], tripCounts[loopIdx + 1]); nb.create(lb, ub, c1, ValueRange(), workLoopBuilder(loopIdx + 1)); } nb.create(loc); return; } // Copy the body of the parallel op into the inner-most loop. BlockAndValueMapping mapping; mapping.map(op.getInductionVars(), computeBlockInductionVars); mapping.map(computeFuncType.captures, captures); for (auto &bodyOp : op.getLoopBody().getOps()) nb.clone(bodyOp, mapping); }; }; b.create(blockFirstCoord[0], blockEndCoord[0], c1, ValueRange(), workLoopBuilder(0)); b.create(ValueRange()); return {op.getNumLoops(), func, std::move(computeFuncType.captures)}; } // Creates recursive async dispatch function for the given parallel compute // function. Dispatch function keeps splitting block range into halves until it // reaches a single block, and then excecutes it inline. // // Function pseudocode (mix of C++ and MLIR): // // func @async_dispatch(%block_start : index, %block_end : index, ...) { // // // Keep splitting block range until we reached a range of size 1. // while (%block_end - %block_start > 1) { // %mid_index = block_start + (block_end - block_start) / 2; // async.execute { call @async_dispatch(%mid_index, %block_end); } // %block_end = %mid_index // } // // // Call parallel compute function for a single block. // call @parallel_compute_fn(%block_start, %block_size, ...); // } // static FuncOp createAsyncDispatchFunction(ParallelComputeFunction &computeFunc, PatternRewriter &rewriter) { OpBuilder::InsertionGuard guard(rewriter); Location loc = computeFunc.func.getLoc(); ImplicitLocOpBuilder b(loc, rewriter); ModuleOp module = computeFunc.func->getParentOfType(); ArrayRef computeFuncInputTypes = computeFunc.func.type().cast().getInputs(); // Compared to the parallel compute function async dispatch function takes // additional !async.group argument. Also instead of a single `blockIndex` it // takes `blockStart` and `blockEnd` arguments to define the range of // dispatched blocks. SmallVector inputTypes; inputTypes.push_back(async::GroupType::get(rewriter.getContext())); inputTypes.push_back(rewriter.getIndexType()); // add blockStart argument inputTypes.append(computeFuncInputTypes.begin(), computeFuncInputTypes.end()); FunctionType type = rewriter.getFunctionType(inputTypes, TypeRange()); FuncOp func = FuncOp::create(loc, "async_dispatch_fn", type); func.setPrivate(); // Insert function into the module symbol table and assign it unique name. SymbolTable symbolTable(module); symbolTable.insert(func); rewriter.getListener()->notifyOperationInserted(func); // Create function entry block. Block *block = b.createBlock(&func.getBody(), func.begin(), type.getInputs()); b.setInsertionPointToEnd(block); Type indexTy = b.getIndexType(); Value c1 = b.create(1); Value c2 = b.create(2); // Get the async group that will track async dispatch completion. Value group = block->getArgument(0); // Get the block iteration range: [blockStart, blockEnd) Value blockStart = block->getArgument(1); Value blockEnd = block->getArgument(2); // Create a work splitting while loop for the [blockStart, blockEnd) range. SmallVector types = {indexTy, indexTy}; SmallVector operands = {blockStart, blockEnd}; // Create a recursive dispatch loop. scf::WhileOp whileOp = b.create(types, operands); Block *before = b.createBlock(&whileOp.before(), {}, types); Block *after = b.createBlock(&whileOp.after(), {}, types); // Setup dispatch loop condition block: decide if we need to go into the // `after` block and launch one more async dispatch. { b.setInsertionPointToEnd(before); Value start = before->getArgument(0); Value end = before->getArgument(1); Value distance = b.create(end, start); Value dispatch = b.create(arith::CmpIPredicate::sgt, distance, c1); b.create(dispatch, before->getArguments()); } // Setup the async dispatch loop body: recursively call dispatch function // for the seconds half of the original range and go to the next iteration. { b.setInsertionPointToEnd(after); Value start = after->getArgument(0); Value end = after->getArgument(1); Value distance = b.create(end, start); Value halfDistance = b.create(distance, c2); Value midIndex = b.create(start, halfDistance); // Call parallel compute function inside the async.execute region. auto executeBodyBuilder = [&](OpBuilder &executeBuilder, Location executeLoc, ValueRange executeArgs) { // Update the original `blockStart` and `blockEnd` with new range. SmallVector operands{block->getArguments().begin(), block->getArguments().end()}; operands[1] = midIndex; operands[2] = end; executeBuilder.create(executeLoc, func.sym_name(), func.getCallableResults(), operands); executeBuilder.create(executeLoc, ValueRange()); }; // Create async.execute operation to dispatch half of the block range. auto execute = b.create(TypeRange(), ValueRange(), ValueRange(), executeBodyBuilder); b.create(indexTy, execute.token(), group); b.create(ValueRange({start, midIndex})); } // After dispatching async operations to process the tail of the block range // call the parallel compute function for the first block of the range. b.setInsertionPointAfter(whileOp); // Drop async dispatch specific arguments: async group, block start and end. auto forwardedInputs = block->getArguments().drop_front(3); SmallVector computeFuncOperands = {blockStart}; computeFuncOperands.append(forwardedInputs.begin(), forwardedInputs.end()); b.create(computeFunc.func.sym_name(), computeFunc.func.getCallableResults(), computeFuncOperands); b.create(ValueRange()); return func; } // Launch async dispatch of the parallel compute function. static void doAsyncDispatch(ImplicitLocOpBuilder &b, PatternRewriter &rewriter, ParallelComputeFunction ¶llelComputeFunction, scf::ParallelOp op, Value blockSize, Value blockCount, const SmallVector &tripCounts) { MLIRContext *ctx = op->getContext(); // Add one more level of indirection to dispatch parallel compute functions // using async operations and recursive work splitting. FuncOp asyncDispatchFunction = createAsyncDispatchFunction(parallelComputeFunction, rewriter); Value c0 = b.create(0); Value c1 = b.create(1); // Appends operands shared by async dispatch and parallel compute functions to // the given operands vector. auto appendBlockComputeOperands = [&](SmallVector &operands) { operands.append(tripCounts); operands.append(op.lowerBound().begin(), op.lowerBound().end()); operands.append(op.upperBound().begin(), op.upperBound().end()); operands.append(op.step().begin(), op.step().end()); operands.append(parallelComputeFunction.captures); }; // Check if the block size is one, in this case we can skip the async dispatch // completely. If this will be known statically, then canonicalization will // erase async group operations. Value isSingleBlock = b.create(arith::CmpIPredicate::eq, blockCount, c1); auto syncDispatch = [&](OpBuilder &nestedBuilder, Location loc) { ImplicitLocOpBuilder nb(loc, nestedBuilder); // Call parallel compute function for the single block. SmallVector operands = {c0, blockSize}; appendBlockComputeOperands(operands); nb.create(parallelComputeFunction.func.sym_name(), parallelComputeFunction.func.getCallableResults(), operands); nb.create(); }; auto asyncDispatch = [&](OpBuilder &nestedBuilder, Location loc) { // Create an async.group to wait on all async tokens from the concurrent // execution of multiple parallel compute function. First block will be // executed synchronously in the caller thread. Value groupSize = b.create(blockCount, c1); Value group = b.create(GroupType::get(ctx), groupSize); ImplicitLocOpBuilder nb(loc, nestedBuilder); // Launch async dispatch function for [0, blockCount) range. SmallVector operands = {group, c0, blockCount, blockSize}; appendBlockComputeOperands(operands); nb.create(asyncDispatchFunction.sym_name(), asyncDispatchFunction.getCallableResults(), operands); // Wait for the completion of all parallel compute operations. b.create(group); nb.create(); }; // Dispatch either single block compute function, or launch async dispatch. b.create(TypeRange(), isSingleBlock, syncDispatch, asyncDispatch); } // Dispatch parallel compute functions by submitting all async compute tasks // from a simple for loop in the caller thread. static void doSequentialDispatch(ImplicitLocOpBuilder &b, PatternRewriter &rewriter, ParallelComputeFunction ¶llelComputeFunction, scf::ParallelOp op, Value blockSize, Value blockCount, const SmallVector &tripCounts) { MLIRContext *ctx = op->getContext(); FuncOp compute = parallelComputeFunction.func; Value c0 = b.create(0); Value c1 = b.create(1); // Create an async.group to wait on all async tokens from the concurrent // execution of multiple parallel compute function. First block will be // executed synchronously in the caller thread. Value groupSize = b.create(blockCount, c1); Value group = b.create(GroupType::get(ctx), groupSize); // Call parallel compute function for all blocks. using LoopBodyBuilder = std::function; // Returns parallel compute function operands to process the given block. auto computeFuncOperands = [&](Value blockIndex) -> SmallVector { SmallVector computeFuncOperands = {blockIndex, blockSize}; computeFuncOperands.append(tripCounts); computeFuncOperands.append(op.lowerBound().begin(), op.lowerBound().end()); computeFuncOperands.append(op.upperBound().begin(), op.upperBound().end()); computeFuncOperands.append(op.step().begin(), op.step().end()); computeFuncOperands.append(parallelComputeFunction.captures); return computeFuncOperands; }; // Induction variable is the index of the block: [0, blockCount). LoopBodyBuilder loopBuilder = [&](OpBuilder &loopBuilder, Location loc, Value iv, ValueRange args) { ImplicitLocOpBuilder nb(loc, loopBuilder); // Call parallel compute function inside the async.execute region. auto executeBodyBuilder = [&](OpBuilder &executeBuilder, Location executeLoc, ValueRange executeArgs) { executeBuilder.create(executeLoc, compute.sym_name(), compute.getCallableResults(), computeFuncOperands(iv)); executeBuilder.create(executeLoc, ValueRange()); }; // Create async.execute operation to launch parallel computate function. auto execute = nb.create(TypeRange(), ValueRange(), ValueRange(), executeBodyBuilder); nb.create(rewriter.getIndexType(), execute.token(), group); nb.create(); }; // Iterate over all compute blocks and launch parallel compute operations. b.create(c1, blockCount, c1, ValueRange(), loopBuilder); // Call parallel compute function for the first block in the caller thread. b.create(compute.sym_name(), compute.getCallableResults(), computeFuncOperands(c0)); // Wait for the completion of all async compute operations. b.create(group); } LogicalResult AsyncParallelForRewrite::matchAndRewrite(scf::ParallelOp op, PatternRewriter &rewriter) const { // We do not currently support rewrite for parallel op with reductions. if (op.getNumReductions() != 0) return failure(); ImplicitLocOpBuilder b(op.getLoc(), rewriter); // Make sure that all constants will be inside the parallel operation body to // reduce the number of parallel compute function arguments. cloneConstantsIntoTheRegion(op.getLoopBody(), rewriter); // Compute trip count for each loop induction variable: // tripCount = ceil_div(upperBound - lowerBound, step); SmallVector tripCounts(op.getNumLoops()); for (size_t i = 0; i < op.getNumLoops(); ++i) { auto lb = op.lowerBound()[i]; auto ub = op.upperBound()[i]; auto step = op.step()[i]; auto range = b.createOrFold(ub, lb); tripCounts[i] = b.createOrFold(range, step); } // Compute a product of trip counts to get the 1-dimensional iteration space // for the scf.parallel operation. Value tripCount = tripCounts[0]; for (size_t i = 1; i < tripCounts.size(); ++i) tripCount = b.create(tripCount, tripCounts[i]); // Short circuit no-op parallel loops (zero iterations) that can arise from // the memrefs with dynamic dimension(s) equal to zero. Value c0 = b.create(0); Value isZeroIterations = b.create(arith::CmpIPredicate::eq, tripCount, c0); // Do absolutely nothing if the trip count is zero. auto noOp = [&](OpBuilder &nestedBuilder, Location loc) { nestedBuilder.create(loc); }; // Compute the parallel block size and dispatch concurrent tasks computing // results for each block. auto dispatch = [&](OpBuilder &nestedBuilder, Location loc) { ImplicitLocOpBuilder nb(loc, nestedBuilder); // Collect statically known constants defining the loop nest in the parallel // compute function. LLVM can't always push constants across the non-trivial // async dispatch call graph, by providing these values explicitly we can // choose to build more efficient loop nest, and rely on a better constant // folding, loop unrolling and vectorization. ParallelComputeFunctionBounds staticBounds = { integerConstants(tripCounts), integerConstants(op.lowerBound()), integerConstants(op.upperBound()), integerConstants(op.step()), }; // Find how many inner iteration dimensions are statically known, and their // product is smaller than the `512`. We aling the parallel compute block // size by the product of statically known dimensions, so that we can // guarantee that the inner loops executes from 0 to the loop trip counts // and we can elide dynamic loop boundaries, and give LLVM an opportunity to // unroll the loops. The constant `512` is arbitrary, it should depend on // how many iterations LLVM will typically decide to unroll. static constexpr int64_t maxIterations = 512; // The number of inner loops with statically known number of iterations less // than the `maxIterations` value. int numUnrollableLoops = 0; auto getInt = [](IntegerAttr attr) { return attr ? attr.getInt() : 0; }; SmallVector numIterations(op.getNumLoops()); numIterations.back() = getInt(staticBounds.tripCounts.back()); for (int i = op.getNumLoops() - 2; i >= 0; --i) { int64_t tripCount = getInt(staticBounds.tripCounts[i]); int64_t innerIterations = numIterations[i + 1]; numIterations[i] = tripCount * innerIterations; // Update the number of inner loops that we can potentially unroll. if (innerIterations > 0 && innerIterations <= maxIterations) numUnrollableLoops++; } // With large number of threads the value of creating many compute blocks // is reduced because the problem typically becomes memory bound. For small // number of threads it helps with stragglers. float overshardingFactor = numWorkerThreads <= 4 ? 8.0 : numWorkerThreads <= 8 ? 4.0 : numWorkerThreads <= 16 ? 2.0 : numWorkerThreads <= 32 ? 1.0 : numWorkerThreads <= 64 ? 0.8 : 0.6; // Do not overload worker threads with too many compute blocks. Value maxComputeBlocks = b.create( std::max(1, static_cast(numWorkerThreads * overshardingFactor))); // Target block size from the pass parameters. Value minTaskSizeCst = b.create(minTaskSize); // Compute parallel block size from the parallel problem size: // blockSize = min(tripCount, // max(ceil_div(tripCount, maxComputeBlocks), // ceil_div(minTaskSize, bodySize))) Value bs0 = b.create(tripCount, maxComputeBlocks); Value bs1 = b.create(bs0, minTaskSizeCst); Value blockSize = b.create(tripCount, bs1); // Align the block size to be a multiple of the statically known number // of iterations in the inner loops. if (numUnrollableLoops > 0 && minTaskSize >= maxIterations) { Value numIters = b.create( numIterations[op.getNumLoops() - numUnrollableLoops]); Value bs2 = b.create( b.create(blockSize, numIters), numIters); blockSize = b.create(tripCount, bs2); } else { // Reset the number of unrollable loops if we didn't align the block size. numUnrollableLoops = 0; } // Compute the number of parallel compute blocks. Value blockCount = b.create(tripCount, blockSize); // Create a parallel compute function that takes a block id and computes // the parallel operation body for a subset of iteration space. ParallelComputeFunction parallelComputeFunction = createParallelComputeFunction(op, staticBounds, numUnrollableLoops, rewriter); // Dispatch parallel compute function using async recursive work splitting, // or by submitting compute task sequentially from a caller thread. if (asyncDispatch) { doAsyncDispatch(b, rewriter, parallelComputeFunction, op, blockSize, blockCount, tripCounts); } else { doSequentialDispatch(b, rewriter, parallelComputeFunction, op, blockSize, blockCount, tripCounts); } nb.create(); }; // Replace the `scf.parallel` operation with the parallel compute function. b.create(TypeRange(), isZeroIterations, noOp, dispatch); // Parallel operation was replaced with a block iteration loop. rewriter.eraseOp(op); return success(); } void AsyncParallelForPass::runOnOperation() { MLIRContext *ctx = &getContext(); RewritePatternSet patterns(ctx); patterns.add(ctx, asyncDispatch, numWorkerThreads, minTaskSize); if (failed(applyPatternsAndFoldGreedily(getOperation(), std::move(patterns)))) signalPassFailure(); } std::unique_ptr mlir::createAsyncParallelForPass() { return std::make_unique(); } std::unique_ptr mlir::createAsyncParallelForPass(bool asyncDispatch, int32_t numWorkerThreads, int32_t minTaskSize) { return std::make_unique(asyncDispatch, numWorkerThreads, minTaskSize); }