Emit the dynamic memory pool (#290)
* Reorganize main function. * Follow review comments. * Emit constants are globals in Krnl and LLVM dialects. * Add support for bundling dynamic memory pools. * Add dynamic bundling. * Clean-up code. * Clean-up file. * Add test for bundling dynamic memory pool. * Fixes. Simplify data structure. Add mixed test. * Remove unused import.
This commit is contained in:
parent
930e20f682
commit
9f69b2f317
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@ -15,6 +15,7 @@
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#include "mlir/Dialect/StandardOps/IR/Ops.h"
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#include "mlir/Pass/Pass.h"
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#include "mlir/Transforms/DialectConversion.h"
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#include "llvm/ADT/SetVector.h"
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#include "src/Conversion/ONNXToKrnl/ONNXToKrnlCommon.hpp"
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#include "src/Dialect/Krnl/KrnlOps.hpp"
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@ -24,6 +25,102 @@ using namespace mlir;
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namespace {
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//===----------------------------------------------------------------------===//
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// Insertion point for initialization instructions and the blocks used for
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// inserting the initialization and main code. These blocks will disappear
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// when the first canonicalization is performed because the init block
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// unconditionally branches into the second block. These blocks exist only for
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// the purpose of this optimization.
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// The information is recorded on a per function basis.
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//===----------------------------------------------------------------------===//
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typedef struct ONNXOperandsInitState {
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Block *initBlock;
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Block *mainBlock;
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BranchOp branchInit;
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AllocOp dynamicMemoryPool;
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} ONNXOperandsInitState;
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// Helper data structure for the bundling of dynamic AllocOps.
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std::map<FuncOp, std::unique_ptr<ONNXOperandsInitState>> initMap;
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//===----------------------------------------------------------------------===//
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// Helper functions.
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//===----------------------------------------------------------------------===//
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/// Retrieve function which contains the current operation.
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FuncOp getContainingFunction(AllocOp op) {
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Operation *parentFuncOp = op.getParentOp();
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// While parent is not a FuncOp and its cast to a FuncOp is null.
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while (!llvm::dyn_cast_or_null<FuncOp>(parentFuncOp))
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parentFuncOp = parentFuncOp->getParentOp();
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return cast<FuncOp>(parentFuncOp);
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}
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bool hasInitBlock(FuncOp function) {
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std::unique_ptr<ONNXOperandsInitState> &initState = initMap.at(function);
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return initState->initBlock != nullptr;
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}
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bool addInitBlock(PatternRewriter &rewriter, Location loc, AllocOp allocOp) {
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// If this is the first time we encounter an operation in this
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// function, we create an entry inside the initMap and split the
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// function body into an init block and a main block.
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//
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// function func_name() {
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// ... init block ...
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// br ^bb1
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// ^bb1: // pred: ^bb0
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// ... main block ...
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// return
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// }
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//
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// Note: the block ^bb0 being the first block has its label omitted.
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//
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FuncOp function = getContainingFunction(allocOp);
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// If the function does not contain an init block, create one.
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if (!hasInitBlock(function)) {
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std::unique_ptr<ONNXOperandsInitState> &initState = initMap.at(function);
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initState = std::make_unique<ONNXOperandsInitState>();
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// All input arguments are considered as part of the initialization block
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// so add them to the operandsInInitBlock set.
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Block *functionBlock = &function.front();
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PatternRewriter::InsertionGuard insertGuard(rewriter);
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rewriter.setInsertionPointToStart(functionBlock);
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initState->initBlock = rewriter.getInsertionBlock();
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auto currentPoint = rewriter.getInsertionPoint();
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initState->mainBlock =
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rewriter.splitBlock(initState->initBlock, currentPoint);
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rewriter.setInsertionPointToEnd(initState->initBlock);
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// Insert a branch operation from initBlock to mainBlock. This
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// ensures the final code contains legal blocks.
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initState->branchInit =
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rewriter.create<BranchOp>(loc, initState->mainBlock);
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rewriter.setInsertionPointToStart(initState->mainBlock);
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// Save a reference to the current dynamic memory pool value.
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initState->dynamicMemoryPool = allocOp;
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return true;
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}
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return false;
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}
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bool isBlockArgument(Block *block, Value operand) {
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for (auto arg : block->getArguments())
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if (operand == arg)
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return true;
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return false;
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}
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KrnlGetRefOp getUnbundledGetRef(AllocOp *memPool) {
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auto parentBlock = memPool->getOperation()->getBlock();
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@ -37,6 +134,23 @@ KrnlGetRefOp getUnbundledGetRef(AllocOp *memPool) {
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return unbundledGetRef;
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}
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KrnlGetRefOp getCurrentAllocGetRef(AllocOp *allocOp) {
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auto parentBlock = allocOp->getOperation()->getBlock();
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KrnlGetRefOp currentAllocGetRef = nullptr;
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parentBlock->walk([¤tAllocGetRef, allocOp](KrnlGetRefOp op) {
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auto result = allocOp->getResult();
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if (op.getOperands()[0] == result)
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currentAllocGetRef = op;
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});
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return currentAllocGetRef;
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}
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//===----------------------------------------------------------------------===//
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// Rewrite patterns.
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//===----------------------------------------------------------------------===//
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/*!
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* RewritePattern that replaces:
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* %mem1 = alloc() : memref<<dims1>x<type>>
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@ -73,7 +187,7 @@ public:
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if (!checkOpResultIsUsedByGetRef(&allocOp))
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return failure();
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// TODO: remove once we support the bundling of dynamic memory pools.
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// Only handle constant AllocOps.
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if (!hasAllConstantDimensions(memRefType))
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return failure();
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if (memRefShape.size() != 1)
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return failure();
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// TODO: Change this when dyanmic shapes are supported.
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// TODO: Add support for dynamic shapes.
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int64_t currentMemPoolSize = memRefShape[0];
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// Get a KrnlGetRefOp which does not use the current alloc.
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if (KrnlGetRefOp unbundledGetRef = getUnbundledGetRef(&allocOp)) {
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// Make sure that this get ref uses a static alloc.
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auto unbundledGetRefType =
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convertToMemRefType(unbundledGetRef.getResult().getType());
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if (!hasAllConstantDimensions(unbundledGetRefType))
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return failure();
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// Current memory pool size is the offset for the newly bundled
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// internal MemRef. Emit the offset as a constant.
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auto offset = rewriter.create<ConstantOp>(
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}
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};
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/*!
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* RewritePattern that merges a new dynamic AllocOp with the existing dynamic
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* memory pool.
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* %dyn_mempool = alloc(%a) : memref<?xi8>
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* %new_alloc = alloc(%b) : memref<?xi8>
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* %new_ref = krnl.getref %new_alloc 0 : memref<?xi8>
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* =>
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* %c = addi %a, %b
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* %dyn_mempool = alloc(%c) : memref<?xi8>
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* %new_ref = krnl.getref %dyn_mempool %a : memref<?xi8>
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*/
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class KrnlBundleDynamicMemoryPools : public OpRewritePattern<AllocOp> {
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public:
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using OpRewritePattern<AllocOp>::OpRewritePattern;
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LogicalResult matchAndRewrite(
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AllocOp allocOp, PatternRewriter &rewriter) const override {
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auto loc = allocOp.getLoc();
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auto memRefType = convertToMemRefType(allocOp.getResult().getType());
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auto memRefShape = memRefType.getShape();
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// If alloca result is not used by getref then it cannot be part of
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// the memory pool.
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if (!checkOpResultIsUsedByGetRef(&allocOp))
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return failure();
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// Only handle dynamic allocs here.
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if (hasAllConstantDimensions(memRefType))
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return failure();
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// Alloc memory type must be byte.
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if (getMemRefEltSizeInBytes(memRefType) != 1)
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return failure();
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// Rank of the allocated MemRef must be 1.
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if (memRefShape.size() != 1)
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return failure();
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// Visit dependendent operations in the current parent block and assemble
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// a trace of operations which participate in the computation of the size
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// of the AllocOp.
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auto parentBlock = allocOp.getOperation()->getBlock();
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// Get function.
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FuncOp function = getContainingFunction(allocOp);
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Block *firstBlock = &function.getBody().front();
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// If this is the alloc representing the memory pool and the function
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// already has an init block, pattern matching must fail to avoid
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// processing the dynamic memory pool a second time.
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if (hasInitBlock(function)) {
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std::unique_ptr<ONNXOperandsInitState> &initState = initMap.at(function);
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if (allocOp == initState->dynamicMemoryPool)
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return failure();
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}
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// Initialize work queue data structure.
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Operation *op = allocOp.getOperation();
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std::vector<Value> operandList;
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for (const auto &operand : allocOp.getOperands()) {
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operandList.emplace_back(operand);
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}
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// Check if list of operations depends on dynamic local AllocOp.
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bool dependsOnLocalDynamicAlloc = false;
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// Construct the list of Values on which the current AllocOp depends on.
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llvm::SetVector<Operation *> dependentOps;
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while (operandList.size() > 0) {
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Value currentElement = operandList[0];
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Operation *definingOperation = currentElement.getDefiningOp();
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// If this value has not been seen before, process it.
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if (dependentOps.count(definingOperation) == 0) {
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// Add value to dependent values list.
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dependentOps.insert(definingOperation);
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// Add operands to work queue.
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// printf("Processing the args of the following op:\n");
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for (const auto &operand : definingOperation->getOperands()) {
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// Check operand is not a block argument. If it is skip it, we
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// consider block arguments to be leafs.
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if (!isBlockArgument(firstBlock, operand)) {
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operandList.emplace_back(operand);
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// Check if the current operation is a dim or a load and the
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// argument list involves a local AllocOp with dynamic sizes.
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// If that's the case then it means that the whole set of
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// instructions cannot be moved.
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// Check if the current operation is a DimOp or a LoadOp.
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if (llvm::dyn_cast<DimOp>(definingOperation) ||
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llvm::dyn_cast<LoadOp>(definingOperation)) {
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Operation *operandOp = operand.getDefiningOp();
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if (operandOp) {
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auto localAlloc = llvm::dyn_cast<AllocOp>(operandOp);
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if (localAlloc) {
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auto memRefType =
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convertToMemRefType(localAlloc.getResult().getType());
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if (!hasAllConstantDimensions(memRefType))
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dependsOnLocalDynamicAlloc = true;
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}
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// If operand is a getref then this alloc cannot be bundled.
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auto memPool = llvm::dyn_cast<KrnlGetRefOp>(operandOp);
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if (memPool)
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dependsOnLocalDynamicAlloc = true;
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}
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}
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}
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}
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}
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// Erase first element from work queue.
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operandList.erase(operandList.begin());
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}
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if (dependsOnLocalDynamicAlloc)
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return failure();
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// Order the dependent values in the same order they appear in the code.
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// One cannot iterate over and make changes to the order of the operations
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// of a block. A temporary ordered list of dependent instructions is
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// necessary.
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llvm::SmallVector<Operation *, 32> orderedDependentOps;
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for (auto &op :
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llvm::make_range(parentBlock->begin(), std::prev(parentBlock->end())))
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if (dependentOps.count(&op) > 0)
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orderedDependentOps.emplace_back(&op);
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// If no dynamic alloc is in the trace of the dependent operations,
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// emit the size calculation in the init block, if one exists already,
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// if not, create the init block.
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bool addedInitBlock = addInitBlock(rewriter, loc, allocOp);
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// Move the ordered dependent size calculation to the init block.
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std::unique_ptr<ONNXOperandsInitState> &initState = initMap.at(function);
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for (auto &op : orderedDependentOps)
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op->moveBefore(initState->branchInit);
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// Bundle MemRef type: <?xi8>
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SmallVector<int64_t, 1> memPoolShape;
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memPoolShape.emplace_back(-1);
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auto bundledMemPoolMemRefType =
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MemRefType::get(memPoolShape, rewriter.getIntegerType(8));
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// Get the getref of the current allocOp. There is exactly one such getref.
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KrnlGetRefOp currentAllocGetRef = getCurrentAllocGetRef(&allocOp);
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if (!currentAllocGetRef)
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return failure();
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// Add the current alloc size to the current MemPool size.
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Value dynamicMemoryPoolSize = initState->dynamicMemoryPool.getOperand(0);
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if (addedInitBlock) {
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Value zero = emitConstantOp(rewriter, loc, rewriter.getIndexType(), 0);
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zero.getDefiningOp()->moveBefore(initState->branchInit);
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dynamicMemoryPoolSize = zero;
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}
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AddIOp bundledAllocOperand = rewriter.create<AddIOp>(
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loc, dynamicMemoryPoolSize, allocOp.getOperand(0));
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bundledAllocOperand.getOperation()->moveBefore(initState->branchInit);
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// The newly bundled MemRef expressed as a KrnlGetRefOp.
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// Current memory pool size is the offset for the newly bundled
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// internal MemRef.
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Value integerDynamicMemoryPoolSize = rewriter.create<IndexCastOp>(
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loc, dynamicMemoryPoolSize, rewriter.getIntegerType(64));
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integerDynamicMemoryPoolSize.getDefiningOp()->moveBefore(
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initState->branchInit);
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// We need to emit a new alloc which contains the additional MemRef.
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AllocOp bundledAlloc = rewriter.create<AllocOp>(
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loc, bundledMemPoolMemRefType, bundledAllocOperand.getResult());
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bundledAlloc.getOperation()->moveBefore(&initState->mainBlock->front());
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KrnlGetRefOp bundledMemRef = rewriter.create<KrnlGetRefOp>(loc,
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currentAllocGetRef.getResult().getType(), bundledAlloc,
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integerDynamicMemoryPoolSize);
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bundledMemRef.getOperation()->moveAfter(bundledAlloc);
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// Replace old memory pool with new one.
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rewriter.replaceOp(initState->dynamicMemoryPool, bundledAlloc.getResult());
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// Replace old getref with new getref from new memory pool.
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rewriter.replaceOp(currentAllocGetRef, bundledMemRef.getResult());
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// Update MemPool size.
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initState->dynamicMemoryPool = bundledAlloc;
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return success();
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}
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};
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/*!
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* Function pass that enables memory pooling for MemRefs.
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*/
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void runOnFunction() override {
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auto function = getFunction();
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// ModuleOp module = cast<ModuleOp>(function.getParentOp());
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initMap.insert(std::pair<FuncOp, std::unique_ptr<ONNXOperandsInitState>>(
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function, std::make_unique<ONNXOperandsInitState>()));
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// Initialize state for this function.
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std::unique_ptr<ONNXOperandsInitState> &initState = initMap.at(function);
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initState->initBlock = nullptr;
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ConversionTarget target(getContext());
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OwningRewritePatternList patterns;
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patterns.insert<KrnlBundleMemoryPools>(&getContext());
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patterns.insert<KrnlBundleMemoryPools, KrnlBundleDynamicMemoryPools>(
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&getContext());
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applyPatternsAndFoldGreedily(function, patterns);
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initMap.erase(function);
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}
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};
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} // namespace
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@ -51,3 +51,135 @@ func @test_pool_bundling(%arg0: memref<10x10xf32>, %arg1: memref<10x20xf32>) ->
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// CHECK: dealloc [[MEMPOOL]] : memref<3200xi8>
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// CHECK: return [[RES]] : memref<10x20xf32>
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}
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func @test_dynamic_pool_bundling(%arg0: memref<?x?xf32>) -> memref<?x10xf32> {
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%c1 = constant 1 : index
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%c0 = constant 0 : index
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%cst = constant 0.000000e+00 : f32
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%ind = constant 0 : index
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%c4 = constant 4 : index
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%c10 = constant 10 : index
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%c0_i64 = constant 0 : i64
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%0 = dim %arg0, %c0 : memref<?x?xf32>
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%1 = muli %0, %c4 : index
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%2 = muli %1, %c10 : index
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%3 = alloc(%2) : memref<?xi8>
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%4 = "krnl.getref"(%3, %c0_i64) : (memref<?xi8>, i64) -> memref<?x10xf32>
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%6 = cmpi "sgt", %0, %0 : index
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%7 = select %6, %0, %0 : index
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%8 = muli %7, %c4 : index
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%9 = muli %8, %c10 : index
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%10 = alloc(%9) : memref<?xi8>
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%11 = "krnl.getref"(%10, %c0_i64) : (memref<?xi8>, i64) -> memref<?x10xf32>
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%12 = cmpi "eq", %0, %c1 : index
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%13 = cmpi "eq", %0, %c1 : index
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%15 = alloc(%0) : memref<?x10xf32>
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affine.store %cst, %4[%ind, %ind] : memref<?x10xf32>
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affine.store %cst, %11[%ind, %ind] : memref<?x10xf32>
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affine.store %cst, %15[%ind, %ind] : memref<?x10xf32>
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dealloc %10 : memref<?xi8>
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dealloc %3 : memref<?xi8>
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return %15 : memref<?x10xf32>
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// CHECK-LABEL: test_dynamic_pool_bundling
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// CHECK: [[CST:%.+]] = constant 0.000000e+00 : f32
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// CHECK: [[C0:%.+]] = constant 0 : index
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// CHECK: [[C4:%.+]] = constant 4 : index
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// CHECK: [[C10:%.+]] = constant 10 : index
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// CHECK: [[C0_I64:%.+]] = constant 0 : i64
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// CHECK: [[DIM:%.+]] = dim %arg0, [[C0]] : memref<?x?xf32>
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// CHECK: [[SGT:%.+]] = cmpi "sgt", [[DIM]], [[DIM]] : index
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// CHECK: [[SELECT:%.+]] = select [[SGT]], [[DIM]], [[DIM]] : index
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// CHECK: [[MUL1:%.+]] = muli [[SELECT]], [[C4]] : index
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// CHECK: [[OFFSET1:%.+]] = muli [[MUL1]], [[C10]] : index
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// CHECK: [[MUL2:%.+]] = muli [[DIM]], [[C4]] : index
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// CHECK: [[OFFSET2:%.+]] = muli [[MUL2]], [[C10]] : index
|
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// CHECK: [[MEMPOOL_SIZE:%.+]] = addi [[OFFSET1]], [[OFFSET2]] : index
|
||||
// CHECK: [[OFFSET1_I64:%.+]] = index_cast [[OFFSET1]] : index to i64
|
||||
// CHECK: [[DYN_MEMPOOL:%.+]] = alloc([[MEMPOOL_SIZE]]) : memref<?xi8>
|
||||
// CHECK: [[DATA1:%.+]] = "krnl.getref"([[DYN_MEMPOOL]], [[OFFSET1_I64]]) : (memref<?xi8>, i64) -> memref<?x10xf32>
|
||||
// CHECK: [[DATA2:%.+]] = "krnl.getref"([[DYN_MEMPOOL]], [[C0_I64]]) : (memref<?xi8>, i64) -> memref<?x10xf32>
|
||||
// CHECK: [[RES:%.+]] = alloc([[DIM]]) : memref<?x10xf32>
|
||||
// CHECK: affine.store [[CST]], [[DATA1]][0, 0] : memref<?x10xf32>
|
||||
// CHECK: affine.store [[CST]], [[DATA2]][0, 0] : memref<?x10xf32>
|
||||
// CHECK: affine.store [[CST]], [[RES]][0, 0] : memref<?x10xf32>
|
||||
// CHECK: dealloc [[DYN_MEMPOOL]] : memref<?xi8>
|
||||
// CHECK: return [[RES]] : memref<?x10xf32>
|
||||
}
|
||||
|
||||
func @test_dynamic_and_static_pool_bundling(%arg0: memref<?x?xf32>, %arg1: memref<10x10xf32>) -> memref<?x10xf32> {
|
||||
%c1 = constant 1 : index
|
||||
%c0 = constant 0 : index
|
||||
%cst = constant 0.000000e+00 : f32
|
||||
%ind = constant 0 : index
|
||||
%c4 = constant 4 : index
|
||||
%c10 = constant 10 : index
|
||||
%c0_i64 = constant 0 : i64
|
||||
%0 = dim %arg0, %c0 : memref<?x?xf32>
|
||||
%1 = muli %0, %c4 : index
|
||||
%2 = muli %1, %c10 : index
|
||||
%3 = alloc(%2) : memref<?xi8>
|
||||
%4 = "krnl.getref"(%3, %c0_i64) : (memref<?xi8>, i64) -> memref<?x10xf32>
|
||||
%const_alloc1 = alloc() : memref<800xi8>
|
||||
%const_ref1 = "krnl.getref"(%const_alloc1, %c0_i64) : (memref<800xi8>, i64) -> memref<10x20xf32>
|
||||
%const_alloc2 = alloc() : memref<400xi8>
|
||||
%const_ref2 = "krnl.getref"(%const_alloc2, %c0_i64) : (memref<400xi8>, i64) -> memref<10x10xf32>
|
||||
%6 = cmpi "sgt", %0, %0 : index
|
||||
%7 = select %6, %0, %0 : index
|
||||
%8 = muli %7, %c4 : index
|
||||
%9 = muli %8, %c10 : index
|
||||
%10 = alloc(%9) : memref<?xi8>
|
||||
%11 = "krnl.getref"(%10, %c0_i64) : (memref<?xi8>, i64) -> memref<?x10xf32>
|
||||
%12 = cmpi "eq", %0, %c1 : index
|
||||
%13 = cmpi "eq", %0, %c1 : index
|
||||
%15 = alloc(%0) : memref<?x10xf32>
|
||||
%const_alloc3 = alloc() : memref<1600xi8>
|
||||
%const_ref3 = "krnl.getref"(%const_alloc3, %c0_i64) : (memref<1600xi8>, i64) -> memref<10x40xf32>
|
||||
affine.store %cst, %4[%ind, %ind] : memref<?x10xf32>
|
||||
affine.store %cst, %11[%ind, %ind] : memref<?x10xf32>
|
||||
affine.store %cst, %15[%ind, %ind] : memref<?x10xf32>
|
||||
affine.store %cst, %const_ref2[%ind, %ind] : memref<10x10xf32>
|
||||
affine.store %cst, %const_ref1[%ind, %ind] : memref<10x20xf32>
|
||||
affine.store %cst, %const_ref3[%ind, %ind] : memref<10x40xf32>
|
||||
dealloc %10 : memref<?xi8>
|
||||
dealloc %3 : memref<?xi8>
|
||||
dealloc %const_alloc1 : memref<800xi8>
|
||||
dealloc %const_alloc2 : memref<400xi8>
|
||||
dealloc %const_alloc3 : memref<1600xi8>
|
||||
return %15 : memref<?x10xf32>
|
||||
|
||||
// CHECK-LABEL: test_dynamic_and_static_pool_bundling
|
||||
// CHECK: [[CST:%.+]] = constant 0.000000e+00 : f32
|
||||
// CHECK: [[C0:%.+]] = constant 0 : index
|
||||
// CHECK: [[C4:%.+]] = constant 4 : index
|
||||
// CHECK: [[C10:%.+]] = constant 10 : index
|
||||
// CHECK: [[C400_I64:%.+]] = constant 400 : i64
|
||||
// CHECK: [[C2000_I64:%.+]] = constant 2000 : i64
|
||||
// CHECK: [[C0_I64:%.+]] = constant 0 : i64
|
||||
// CHECK: [[DIM:%.+]] = dim %arg0, [[C0]] : memref<?x?xf32>
|
||||
// CHECK: [[SGT:%.+]] = cmpi "sgt", [[DIM]], [[DIM]] : index
|
||||
// CHECK: [[SELECT:%.+]] = select [[SGT]], [[DIM]], [[DIM]] : index
|
||||
// CHECK: [[MUL1:%.+]] = muli [[SELECT]], [[C4]] : index
|
||||
// CHECK: [[OFFSET1:%.+]] = muli [[MUL1]], [[C10]] : index
|
||||
// CHECK: [[MUL2:%.+]] = muli [[DIM]], [[C4]] : index
|
||||
// CHECK: [[OFFSET2:%.+]] = muli [[MUL2]], [[C10]] : index
|
||||
// CHECK: [[MEMPOOL_SIZE:%.+]] = addi [[OFFSET1]], [[OFFSET2]] : index
|
||||
// CHECK: [[OFFSET1_I64:%.+]] = index_cast [[OFFSET1]] : index to i64
|
||||
// CHECK: [[DYN_MEMPOOL:%.+]] = alloc([[MEMPOOL_SIZE]]) : memref<?xi8>
|
||||
// CHECK: [[DATA1:%.+]] = "krnl.getref"([[DYN_MEMPOOL]], [[OFFSET1_I64]]) : (memref<?xi8>, i64) -> memref<?x10xf32>
|
||||
// CHECK: [[DATA2:%.+]] = "krnl.getref"([[DYN_MEMPOOL]], [[C0_I64]]) : (memref<?xi8>, i64) -> memref<?x10xf32>
|
||||
// CHECK: [[STATIC_MEMPOOL:%.+]] = alloc() : memref<2800xi8>
|
||||
// CHECK: [[DATA3:%.+]] = "krnl.getref"([[STATIC_MEMPOOL]], [[C2000_I64]]) : (memref<2800xi8>, i64) -> memref<10x20xf32>
|
||||
// CHECK: [[DATA4:%.+]] = "krnl.getref"([[STATIC_MEMPOOL]], [[C400_I64]]) : (memref<2800xi8>, i64) -> memref<10x40xf32>
|
||||
// CHECK: [[DATA5:%.+]] = "krnl.getref"([[STATIC_MEMPOOL]], [[C0_I64]]) : (memref<2800xi8>, i64) -> memref<10x10xf32>
|
||||
// CHECK: [[RES:%.+]] = alloc([[DIM]]) : memref<?x10xf32>
|
||||
// CHECK: affine.store [[CST]], [[DATA1]][0, 0] : memref<?x10xf32>
|
||||
// CHECK: affine.store [[CST]], [[DATA2]][0, 0] : memref<?x10xf32>
|
||||
// CHECK: affine.store [[CST]], [[RES]][0, 0] : memref<?x10xf32>
|
||||
// CHECK: affine.store [[CST]], [[DATA5]][0, 0] : memref<10x10xf32>
|
||||
// CHECK: affine.store [[CST]], [[DATA3]][0, 0] : memref<10x20xf32>
|
||||
// CHECK: affine.store [[CST]], [[DATA4]][0, 0] : memref<10x40xf32>
|
||||
// CHECK: dealloc [[DYN_MEMPOOL]] : memref<?xi8>
|
||||
// CHECK: dealloc [[STATIC_MEMPOOL]] : memref<2800xi8>
|
||||
// CHECK: return [[RES]] : memref<?x10xf32>
|
||||
}
|
||||
|
|
Loading…
Reference in New Issue