diff --git a/mlir/lib/Dialect/SparseTensor/Transforms/SparseTensorConversion.cpp b/mlir/lib/Dialect/SparseTensor/Transforms/SparseTensorConversion.cpp --- a/mlir/lib/Dialect/SparseTensor/Transforms/SparseTensorConversion.cpp +++ b/mlir/lib/Dialect/SparseTensor/Transforms/SparseTensorConversion.cpp @@ -360,6 +360,32 @@ rewriter.create(loc, elemV, tensor, ivs); } +/// Determine if the runtime library supports direct conversion to the +/// given target `dimTypes`. +static bool canUseDirectConversion( + ArrayRef dimTypes) { + bool alreadyCompressed = false; + for (uint64_t rank = dimTypes.size(), r = 0; r < rank; r++) { + switch (dimTypes[r]) { + case SparseTensorEncodingAttr::DimLevelType::Compressed: + if (alreadyCompressed) + return false; // Multiple compressed dimensions not yet supported. + alreadyCompressed = true; + break; + case SparseTensorEncodingAttr::DimLevelType::Dense: + if (alreadyCompressed) + return false; // Dense after Compressed not yet supported. + break; + case SparseTensorEncodingAttr::DimLevelType::Singleton: + // Although Singleton isn't generally supported yet, the direct + // conversion method doesn't have any particular problems with + // singleton after compressed. + break; + } + } + return true; +} + //===----------------------------------------------------------------------===// // Conversion rules. //===----------------------------------------------------------------------===// @@ -497,21 +523,41 @@ SmallVector params; ShapedType stp = srcType.cast(); sizesFromPtr(rewriter, sizes, op, encSrc, stp, src); - // Set up encoding with right mix of src and dst so that the two - // method calls can share most parameters, while still providing - // the correct sparsity information to either of them. - auto enc = SparseTensorEncodingAttr::get( - op->getContext(), encDst.getDimLevelType(), encDst.getDimOrdering(), - encSrc.getPointerBitWidth(), encSrc.getIndexBitWidth()); - newParams(rewriter, params, op, stp, enc, Action::kToCOO, sizes, src); - Value coo = genNewCall(rewriter, op, params); - params[3] = constantPointerTypeEncoding(rewriter, loc, encDst); - params[4] = constantIndexTypeEncoding(rewriter, loc, encDst); - params[6] = constantAction(rewriter, loc, Action::kFromCOO); - params[7] = coo; - Value dst = genNewCall(rewriter, op, params); - genDelCOOCall(rewriter, op, stp.getElementType(), coo); - rewriter.replaceOp(op, dst); + bool useDirectConversion; + switch (options.sparseToSparseStrategy) { + case SparseToSparseConversionStrategy::kViaCOO: + useDirectConversion = false; + break; + case SparseToSparseConversionStrategy::kDirect: + useDirectConversion = true; + assert(canUseDirectConversion(encDst.getDimLevelType()) && + "Unsupported target for direct sparse-to-sparse conversion"); + break; + case SparseToSparseConversionStrategy::kAuto: + useDirectConversion = canUseDirectConversion(encDst.getDimLevelType()); + break; + } + if (useDirectConversion) { + newParams(rewriter, params, op, stp, encDst, Action::kSparseToSparse, + sizes, src); + rewriter.replaceOp(op, genNewCall(rewriter, op, params)); + } else { // use via-COO conversion. + // Set up encoding with right mix of src and dst so that the two + // method calls can share most parameters, while still providing + // the correct sparsity information to either of them. + auto enc = SparseTensorEncodingAttr::get( + op->getContext(), encDst.getDimLevelType(), encDst.getDimOrdering(), + encSrc.getPointerBitWidth(), encSrc.getIndexBitWidth()); + newParams(rewriter, params, op, stp, enc, Action::kToCOO, sizes, src); + Value coo = genNewCall(rewriter, op, params); + params[3] = constantPointerTypeEncoding(rewriter, loc, encDst); + params[4] = constantIndexTypeEncoding(rewriter, loc, encDst); + params[6] = constantAction(rewriter, loc, Action::kFromCOO); + params[7] = coo; + Value dst = genNewCall(rewriter, op, params); + genDelCOOCall(rewriter, op, stp.getElementType(), coo); + rewriter.replaceOp(op, dst); + } return success(); } if (!encDst && encSrc) { diff --git a/mlir/lib/ExecutionEngine/SparseTensorUtils.cpp b/mlir/lib/ExecutionEngine/SparseTensorUtils.cpp --- a/mlir/lib/ExecutionEngine/SparseTensorUtils.cpp +++ b/mlir/lib/ExecutionEngine/SparseTensorUtils.cpp @@ -80,6 +80,25 @@ return lhs * rhs; } +// TODO: adjust this so it can be used by `openSparseTensorCOO` too. +// That version doesn't have the permutation, and the `sizes` are +// a pointer/C-array rather than `std::vector`. +// +/// Asserts that the `sizes` (in target-order) under the `perm` (mapping +/// semantic-order to target-order) are a refinement of the desired `shape` +/// (in semantic-order). +/// +/// Precondition: `perm` and `shape` must be valid for `rank`. +static inline void +assertPermutedSizesMatchShape(const std::vector &sizes, uint64_t rank, + const uint64_t *perm, const uint64_t *shape) { + assert(perm && shape); + assert(rank == sizes.size() && "Rank mismatch"); + for (uint64_t r = 0; r < rank; r++) + assert((shape[r] == 0 || shape[r] == sizes[perm[r]]) && + "Dimension size mismatch"); +} + /// A sparse tensor element in coordinate scheme (value and indices). /// For example, a rank-1 vector element would look like /// ({i}, a[i]) @@ -423,6 +442,119 @@ std::vector cursor; // in target order. }; +/// Statistics regarding the number of nonzero subtensors in +/// a source tensor, for direct sparse=>sparse conversion a la +/// . +/// +/// N.B., this class stores references to the parameters passed to +/// the constructor; thus, objects of this class must not outlive +/// those parameters. +class SparseTensorNNZ { +public: + /// Allocate the statistics structure for the desired sizes and + /// sparsity (in the target tensor's storage-order). This constructor + /// does not actually populate the statistics, however; for that see + /// `initialize`. + /// + /// Precondition: `szs` must not contain zeros. + SparseTensorNNZ(const std::vector &szs, + const std::vector &sparsity) + : dimSizes(szs), dimTypes(sparsity), nnz(getRank()) { + assert(dimSizes.size() == dimTypes.size() && "Rank mismatch"); + bool uncompressed = true; + uint64_t sz = 1; // the product of all `dimSizes` strictly less than `r`. + for (uint64_t rank = getRank(), r = 0; r < rank; r++) { + switch (dimTypes[r]) { + case DimLevelType::kCompressed: + assert(uncompressed && + "Multiple compressed layers not currently supported"); + uncompressed = false; + nnz[r].resize(sz, 0); // Both allocate and zero-initialize. + break; + case DimLevelType::kDense: + assert(uncompressed && + "Dense after compressed not currently supported"); + break; + case DimLevelType::kSingleton: + // Singleton after Compressed causes no problems for allocating + // `nnz` nor for the yieldPos loop. This remains true even + // when adding support for multiple compressed dimensions or + // for dense-after-compressed. + break; + } + sz = checkedMul(sz, dimSizes[r]); + } + } + + SparseTensorNNZ(const SparseTensorNNZ &) = delete; + SparseTensorNNZ(SparseTensorNNZ &&) = delete; + SparseTensorNNZ &operator=(const SparseTensorNNZ &) = delete; + SparseTensorNNZ &operator=(SparseTensorNNZ &&) = delete; + + /// Returns the rank of the target tensor. + uint64_t getRank() const { return dimSizes.size(); } + + /// Enumerate the source tensor to fill in the statistics. The + /// enumerator should already incorporate the permutation (from + /// semantic-order to the target storage-order). + template + void initialize(SparseTensorEnumerator &enumerator) { + assert(enumerator.getRank() == getRank() && "Tensor rank mismatch"); + assert(enumerator.permutedSizes() == dimSizes && "Tensor size mismatch"); + enumerator.forallElements( + [this](const std::vector &ind, V) { add(ind); }); + } + + /// The type of callback functions which receive an nnz-statistic. + using NNZConsumer = const std::function &; + + /// Lexicographically enumerates all indicies for dimensions strictly + /// less than `stopDim`, and passes their nnz statistic to the callback. + /// Since our use-case only requires the statistic not the coordinates + /// themselves, we do not bother to construct those coordinates. + void forallIndices(uint64_t stopDim, NNZConsumer yield) const { + assert(stopDim < getRank() && "Stopping-dimension is out of bounds"); + assert(dimTypes[stopDim] == DimLevelType::kCompressed && + "Cannot look up non-compressed dimensions"); + forallIndices(yield, stopDim, 0, 0); + } + +private: + /// Adds a new element (i.e., increment its statistics). We use + /// a method rather than inlining into the lambda in `initialize`, + /// to avoid spurious templating over `V`. And this method is private + /// to avoid needing to re-assert validity of `ind` (which is guaranteed + /// by `forallElements`). + void add(const std::vector &ind) { + uint64_t parentPos = 0; + for (uint64_t rank = getRank(), r = 0; r < rank; r++) { + if (dimTypes[r] == DimLevelType::kCompressed) + nnz[r][parentPos]++; + parentPos = parentPos * dimSizes[r] + ind[r]; + } + } + + /// Recursive component of the public `forallIndices`. + void forallIndices(NNZConsumer yield, uint64_t stopDim, uint64_t parentPos, + uint64_t d) const { + assert(d <= stopDim); + if (d == stopDim) { + assert(parentPos < nnz[d].size() && "Cursor is out of range"); + yield(nnz[d][parentPos]); + } else { + const uint64_t sz = dimSizes[d]; + const uint64_t pstart = parentPos * sz; + for (uint64_t i = 0; i < sz; i++) + forallIndices(yield, stopDim, pstart + i, d + 1); + } + } + + // All of these are in the target storage-order. + const std::vector &dimSizes; + const std::vector &dimTypes; + std::vector> nnz; +}; + /// A memory-resident sparse tensor using a storage scheme based on /// per-dimension sparse/dense annotations. This data structure provides a /// bufferized form of a sparse tensor type. In contrast to generating setup @@ -433,17 +565,26 @@ class SparseTensorStorage : public EnumerableSparseTensorStorage { using Base = EnumerableSparseTensorStorage; -public: - /// Constructs a sparse tensor storage scheme with the given dimensions, - /// permutation, and per-dimension dense/sparse annotations, using - /// the coordinate scheme tensor for the initial contents if provided. + /// Private constructor to share code between the other constructors. + /// Beware that the object is not necessarily guaranteed to be in a + /// valid state after this constructor alone; e.g., `isCompressedDim(d)` + /// doesn't entail `!(pointers[d].empty())`. /// /// Precondition: `perm` and `sparsity` must be valid for `szs.size()`. SparseTensorStorage(const std::vector &szs, const uint64_t *perm, - const DimLevelType *sparsity, - SparseTensorCOO *coo = nullptr) + const DimLevelType *sparsity) : Base(szs, perm, sparsity), pointers(Base::getRank()), - indices(Base::getRank()), idx(Base::getRank()) { + indices(Base::getRank()), idx(Base::getRank()) {} + +public: + /// Constructs a sparse tensor storage scheme with the given dimensions, + /// permutation, and per-dimension dense/sparse annotations, using + /// the coordinate scheme tensor for the initial contents if provided. + /// + /// Precondition: `perm` and `sparsity` must be valid for `szs.size()`. + SparseTensorStorage(const std::vector &szs, const uint64_t *perm, + const DimLevelType *sparsity, SparseTensorCOO *coo) + : SparseTensorStorage(szs, perm, sparsity) { // Provide hints on capacity of pointers and indices. // TODO: needs much fine-tuning based on actual sparsity; currently // we reserve pointer/index space based on all previous dense @@ -479,6 +620,95 @@ } } + /// Constructs a sparse tensor storage scheme with the given dimensions, + /// permutation, and per-dimension dense/sparse annotations, using + /// the given sparse tensor for the initial contents. + /// + /// Precondition: `perm` and `sparsity` must be valid for `szs.size()`. + SparseTensorStorage(const std::vector &szs, const uint64_t *perm, + const DimLevelType *sparsity, + const EnumerableSparseTensorStorage &tensor) + : SparseTensorStorage(szs, perm, sparsity) { + SparseTensorEnumerator enumerator(tensor, Base::getRank(), perm); + { + // Initialize the statistics structure. + SparseTensorNNZ nnz(Base::getDimSizes(), Base::getDimTypes()); + nnz.initialize(enumerator); + // Initialize "pointers" overhead (and allocate "indices", "values"). + uint64_t parentSz = 1; // assembled-size (not dimension-size) of `r-1`. + for (uint64_t rank = Base::getRank(), r = 0; r < rank; r++) { + if (Base::isCompressedDim(r)) { + pointers[r].reserve(parentSz + 1); + pointers[r].push_back(0); + uint64_t currentPos = 0; + nnz.forallIndices(r, [this, ¤tPos, r](uint64_t n) { + currentPos += n; + appendPointer(r, currentPos); + }); + assert(pointers[r].size() == parentSz + 1 && + "Final pointers size doesn't match allocated size"); + // That assertion entails `assembledSize(parentSz, r)` + // is now in a valid state. That is, `pointers[r][parentSz]` + // equals the present value of `currentPos`, which is the + // correct assembled-size for `indices[r]`. + } + // Update assembled-size for the next iteration. + parentSz = assembledSize(parentSz, r); + // Ideally we need only `indices[r].reserve(parentSz)`, however + // the `std::vector` implementation forces us to initialize it too. + // That is, in the yieldPos loop we need random-access assignment + // to `indices[r]`; however, `std::vector`'s subscript-assignment + // only allows assigning to already-initialized positions. + if (Base::isCompressedDim(r)) + indices[r].resize(parentSz, 0); + } + values.resize(parentSz, 0); // Both allocate and zero-initialize. + } + // The yieldPos loop + enumerator.forallElements([this](const std::vector &ind, V val) { + uint64_t parentSz = 1, parentPos = 0; + for (uint64_t rank = Base::getRank(), r = 0; r < rank; r++) { + if (Base::isCompressedDim(r)) { + // If `parentPos == parentSz` then it's valid as an array-lookup; + // however, it's semantically invalid here since that entry + // does not represent a segment of `indices[r]`. Moreover, that + // entry must be immutable for `assembledSize` to remain valid. + assert(parentPos < parentSz && "Pointers position is out of bounds"); + const uint64_t currentPos = pointers[r][parentPos]; + // This increment won't overflow the `P` type, since it can't + // exceed the original value of `pointers[r][parentPos+1]` + // which was already verified to be within bounds for `P` + // when it was written to the array. + pointers[r][parentPos]++; + writeIndex(r, currentPos, ind[r]); + parentPos = currentPos; + } else { // Dense dimension. + parentPos = parentPos * Base::getDimSizes()[r] + ind[r]; + } + parentSz = assembledSize(parentSz, r); + } + assert(parentPos < values.size() && "Value position is out of bounds"); + values[parentPos] = val; + }); + // The finalizeYieldPos loop + for (uint64_t parentSz = 1, rank = Base::getRank(), r = 0; r < rank; r++) { + if (Base::isCompressedDim(r)) { + assert(parentSz == pointers[r].size() - 1 && + "Actual pointers size doesn't match the expected size"); + // Can't check all of them, but at least we can check the last one. + assert(pointers[r][parentSz - 1] == pointers[r][parentSz] && + "Pointers got corrupted"); + // TODO: optimize this by using `memmove` or similar. + for (uint64_t n = 0; n < parentSz; n++) { + const uint64_t parentPos = parentSz - n; + pointers[r][parentPos] = pointers[r][parentPos - 1]; + } + pointers[r][0] = 0; + } + parentSz = assembledSize(parentSz, r); + } + } + ~SparseTensorStorage() override = default; /// Partially specialize these getter methods based on template types. @@ -573,10 +803,8 @@ const DimLevelType *sparsity, SparseTensorCOO *coo) { SparseTensorStorage *n = nullptr; if (coo) { - assert(coo->getRank() == rank && "Tensor rank mismatch"); const auto &coosz = coo->getSizes(); - for (uint64_t r = 0; r < rank; r++) - assert(shape[r] == 0 || shape[r] == coosz[perm[r]]); + assertPermutedSizesMatchShape(coosz, rank, perm, shape); n = new SparseTensorStorage(coosz, perm, sparsity, coo); } else { std::vector permsz(rank); @@ -584,11 +812,28 @@ assert(shape[r] > 0 && "Dimension size zero has trivial storage"); permsz[perm[r]] = shape[r]; } - n = new SparseTensorStorage(permsz, perm, sparsity); + // We pass the null `coo` to ensure we select the intended constructor. + n = new SparseTensorStorage(permsz, perm, sparsity, coo); } return n; } + /// Factory method. Constructs a sparse tensor storage scheme with + /// the given dimensions, permutation, and per-dimension dense/sparse + /// annotations, using the sparse tensor for the initial contents. + /// + /// Precondition: `shape`, `perm`, and `sparsity` must be valid for `rank`. + static SparseTensorStorage * + newSparseTensor(uint64_t rank, const uint64_t *shape, const uint64_t *perm, + const DimLevelType *sparsity, + const EnumerableSparseTensorStorage *source) { + assert(source && "Got nullptr for source"); + SparseTensorEnumerator enumerator(*source, rank, perm); + const auto &permsz = enumerator.permutedSizes(); + assertPermutedSizesMatchShape(permsz, rank, perm, shape); + return new SparseTensorStorage(permsz, perm, sparsity, *source); + } + private: /// Appends an arbitrary new position to `pointers[d]`. This method /// checks that `pos` is representable in the `P` type; however, it @@ -626,6 +871,36 @@ } } + /// Writes the given coordinate to `indices[d][pos]`. This method + /// checks that `i` is representable in the `I` type; however, it + /// does not check that `i` is semantically valid (i.e., in bounds + /// for `sizes[d]` and not elsewhere occurring in the same segment). + void writeIndex(uint64_t d, uint64_t pos, uint64_t i) { + assert(Base::isCompressedDim(d)); + // Subscript assignment to `std::vector` requires that the `pos`-th + // entry has been initialized; thus we must be sure to check `size()` + // here, instead of `capacity()` as would be ideal. + assert(pos < indices[d].size() && "Index position is out of bounds"); + assert(i <= std::numeric_limits::max() && + "Index value is too large for the I-type"); + indices[d][pos] = static_cast(i); + } + + /// Computes the assembled-size associated with the `d`-th dimension, + /// given the assembled-size associated with the `(d-1)`-th dimension. + /// "Assembled-sizes" correspond to the (nominal) sizes of overhead + /// storage, as opposed to "dimension-sizes" which are the cardinality + /// of coordinates for that dimension. + /// + /// Precondition: the `pointers[d]` array must be fully initialized + /// before calling this method. + uint64_t assembledSize(uint64_t parentSz, uint64_t d) const { + if (Base::isCompressedDim(d)) + return pointers[d][parentSz]; + // else if dense: + return parentSz * Base::getDimSizes()[d]; + } + /// Initializes sparse tensor storage scheme from a memory-resident sparse /// tensor in coordinate scheme. This method prepares the pointers and /// indices arrays under the given per-dimension dense/sparse annotations. @@ -861,7 +1136,7 @@ "dimension size mismatch"); SparseTensorCOO *tensor = SparseTensorCOO::newSparseTensorCOO(rank, idata + 2, perm, nnz); - // Read all nonzero elements. + // Read all nonzero elements. std::vector indices(rank); for (uint64_t k = 0; k < nnz; k++) { if (!fgets(line, kColWidth, file)) { @@ -1033,6 +1308,11 @@ delete coo; \ return tensor; \ } \ + if (action == Action::kSparseToSparse) { \ + auto *tensor = static_cast *>(ptr); \ + return SparseTensorStorage::newSparseTensor(rank, shape, perm, \ + sparsity, tensor); \ + } \ if (action == Action::kEmptyCOO) \ return SparseTensorCOO::newSparseTensorCOO(rank, shape, perm); \ coo = static_cast *>(ptr)->toCOO(perm); \ diff --git a/mlir/test/Dialect/SparseTensor/conversion.mlir b/mlir/test/Dialect/SparseTensor/conversion.mlir --- a/mlir/test/Dialect/SparseTensor/conversion.mlir +++ b/mlir/test/Dialect/SparseTensor/conversion.mlir @@ -1,4 +1,10 @@ -// RUN: mlir-opt %s --sparse-tensor-conversion --canonicalize --cse | FileCheck %s +// First use with `kViaCOO` for sparse2sparse conversion (the old way). +// RUN: mlir-opt %s --sparse-tensor-conversion="s2s-strategy=1" \ +// RUN: --canonicalize --cse | FileCheck %s +// +// Now again with `kAuto` (the new default) +// RUN: mlir-opt %s --sparse-tensor-conversion="s2s-strategy=0" \ +// RUN: --canonicalize --cse | FileCheck %s -check-prefix=CHECKAUTO #SparseVector = #sparse_tensor.encoding<{ dimLevelType = ["compressed"] @@ -210,6 +216,17 @@ // CHECK: %[[T:.*]] = call @newSparseTensor(%[[X]], %[[Y]], %[[Z]], %{{.*}}, %{{.*}}, %{{.*}}, %[[FromCOO]], %[[C]]) // CHECK: call @delSparseTensorCOOF32(%[[C]]) // CHECK: return %[[T]] : !llvm.ptr +// CHECKAUTO-LABEL: func @sparse_convert_1d_ss( +// CHECKAUTO-SAME: %[[A:.*]]: !llvm.ptr) +// CHECKAUTO-DAG: %[[SparseToSparse:.*]] = arith.constant 3 : i32 +// CHECKAUTO-DAG: %[[P:.*]] = memref.alloca() : memref<1xi8> +// CHECKAUTO-DAG: %[[Q:.*]] = memref.alloca() : memref<1xindex> +// CHECKAUTO-DAG: %[[R:.*]] = memref.alloca() : memref<1xindex> +// CHECKAUTO-DAG: %[[X:.*]] = memref.cast %[[P]] : memref<1xi8> to memref +// CHECKAUTO-DAG: %[[Y:.*]] = memref.cast %[[Q]] : memref<1xindex> to memref +// CHECKAUTO-DAG: %[[Z:.*]] = memref.cast %[[R]] : memref<1xindex> to memref +// CHECKAUTO: %[[T:.*]] = call @newSparseTensor(%[[X]], %[[Y]], %[[Z]], %{{.*}}, %{{.*}}, %{{.*}}, %[[SparseToSparse]], %[[A]]) +// CHECKAUTO: return %[[T]] : !llvm.ptr func @sparse_convert_1d_ss(%arg0: tensor) -> tensor { %0 = sparse_tensor.convert %arg0 : tensor to tensor return %0 : tensor diff --git a/mlir/test/Integration/Dialect/SparseTensor/CPU/sparse_conversion_sparse2sparse.mlir b/mlir/test/Integration/Dialect/SparseTensor/CPU/sparse_conversion_sparse2sparse.mlir new file mode 100644 --- /dev/null +++ b/mlir/test/Integration/Dialect/SparseTensor/CPU/sparse_conversion_sparse2sparse.mlir @@ -0,0 +1,102 @@ +// Force this file to use the kDirect method for sparse2sparse +// RUN: mlir-opt %s --sparse-compiler="s2s-strategy=2" | \ +// RUN: mlir-cpu-runner -e entry -entry-point-result=void \ +// RUN: -shared-libs=%mlir_integration_test_dir/libmlir_c_runner_utils%shlibext | \ +// RUN: FileCheck %s + +#Tensor1 = #sparse_tensor.encoding<{ + dimLevelType = [ "dense", "dense", "compressed" ] +}> + +// NOTE: dense after compressed is not currently supported for the target +// of direct-sparse2sparse conversion. (It's fine for the source though.) +#Tensor2 = #sparse_tensor.encoding<{ + dimLevelType = [ "dense", "compressed", "dense" ] +}> + +#Tensor3 = #sparse_tensor.encoding<{ + dimLevelType = [ "dense", "dense", "compressed" ], + dimOrdering = affine_map<(i,j,k) -> (i,k,j)> +}> + +module { + // + // Utilities for output and releasing memory. + // + func @dump(%arg0: tensor<2x3x4xf64>) { + %c0 = arith.constant 0 : index + %d0 = arith.constant -1.0 : f64 + %0 = vector.transfer_read %arg0[%c0, %c0, %c0], %d0: tensor<2x3x4xf64>, vector<2x3x4xf64> + vector.print %0 : vector<2x3x4xf64> + return + } + func @dumpAndRelease_234(%arg0: tensor<2x3x4xf64>) { + call @dump(%arg0) : (tensor<2x3x4xf64>) -> () + %1 = bufferization.to_memref %arg0 : memref<2x3x4xf64> + memref.dealloc %1 : memref<2x3x4xf64> + return + } + + // + // Main driver. + // + func @entry() { + // + // Initialize a 3-dim dense tensor. + // + %src = arith.constant dense<[ + [ [ 1.0, 2.0, 3.0, 4.0 ], + [ 5.0, 6.0, 7.0, 8.0 ], + [ 9.0, 10.0, 11.0, 12.0 ] ], + [ [ 13.0, 14.0, 15.0, 16.0 ], + [ 17.0, 18.0, 19.0, 20.0 ], + [ 21.0, 22.0, 23.0, 24.0 ] ] + ]> : tensor<2x3x4xf64> + + // + // Convert dense tensor directly to various sparse tensors. + // + %s1 = sparse_tensor.convert %src : tensor<2x3x4xf64> to tensor<2x3x4xf64, #Tensor1> + %s2 = sparse_tensor.convert %src : tensor<2x3x4xf64> to tensor<2x3x4xf64, #Tensor2> + %s3 = sparse_tensor.convert %src : tensor<2x3x4xf64> to tensor<2x3x4xf64, #Tensor3> + + // + // Convert sparse tensor directly to another sparse format. + // + %t13 = sparse_tensor.convert %s1 : tensor<2x3x4xf64, #Tensor1> to tensor<2x3x4xf64, #Tensor3> + %t21 = sparse_tensor.convert %s2 : tensor<2x3x4xf64, #Tensor2> to tensor<2x3x4xf64, #Tensor1> + %t23 = sparse_tensor.convert %s2 : tensor<2x3x4xf64, #Tensor2> to tensor<2x3x4xf64, #Tensor3> + %t31 = sparse_tensor.convert %s3 : tensor<2x3x4xf64, #Tensor3> to tensor<2x3x4xf64, #Tensor1> + + // + // Convert sparse tensor back to dense. + // + %d13 = sparse_tensor.convert %t13 : tensor<2x3x4xf64, #Tensor3> to tensor<2x3x4xf64> + %d21 = sparse_tensor.convert %t21 : tensor<2x3x4xf64, #Tensor1> to tensor<2x3x4xf64> + %d23 = sparse_tensor.convert %t23 : tensor<2x3x4xf64, #Tensor3> to tensor<2x3x4xf64> + %d31 = sparse_tensor.convert %t31 : tensor<2x3x4xf64, #Tensor1> to tensor<2x3x4xf64> + + // + // Check round-trip equality. And release dense tensors. + // + // CHECK-COUNT-5: ( ( ( 1, 2, 3, 4 ), ( 5, 6, 7, 8 ), ( 9, 10, 11, 12 ) ), ( ( 13, 14, 15, 16 ), ( 17, 18, 19, 20 ), ( 21, 22, 23, 24 ) ) ) + call @dump(%src) : (tensor<2x3x4xf64>) -> () + call @dumpAndRelease_234(%d13) : (tensor<2x3x4xf64>) -> () + call @dumpAndRelease_234(%d21) : (tensor<2x3x4xf64>) -> () + call @dumpAndRelease_234(%d23) : (tensor<2x3x4xf64>) -> () + call @dumpAndRelease_234(%d31) : (tensor<2x3x4xf64>) -> () + + // + // Release sparse tensors. + // + sparse_tensor.release %t13 : tensor<2x3x4xf64, #Tensor3> + sparse_tensor.release %t21 : tensor<2x3x4xf64, #Tensor1> + sparse_tensor.release %t23 : tensor<2x3x4xf64, #Tensor3> + sparse_tensor.release %t31 : tensor<2x3x4xf64, #Tensor1> + sparse_tensor.release %s1 : tensor<2x3x4xf64, #Tensor1> + sparse_tensor.release %s2 : tensor<2x3x4xf64, #Tensor2> + sparse_tensor.release %s3 : tensor<2x3x4xf64, #Tensor3> + + return + } +} diff --git a/mlir/test/Integration/Dialect/SparseTensor/python/test_stress.py b/mlir/test/Integration/Dialect/SparseTensor/python/test_stress.py --- a/mlir/test/Integration/Dialect/SparseTensor/python/test_stress.py +++ b/mlir/test/Integration/Dialect/SparseTensor/python/test_stress.py @@ -189,11 +189,17 @@ vec = 0 vl = 1 e = False + # Disable direct sparse2sparse conversion, because it doubles the time! + # TODO: While direct s2s is far too slow for per-commit testing, + # we should have some framework ensure that we run this test with + # `s2s=0` on a regular basis, to ensure that it does continue to work. + s2s = 1 sparsification_options = ( f'parallelization-strategy={par} ' f'vectorization-strategy={vec} ' f'vl={vl} ' - f'enable-simd-index32={e}') + f'enable-simd-index32={e} ' + f's2s-strategy={s2s}') compiler = sparse_compiler.SparseCompiler(options=sparsification_options) f64 = ir.F64Type.get() # Be careful about increasing this because