mirror of https://github.com/llvm/torch-mlir
342 lines
14 KiB
C++
342 lines
14 KiB
C++
//===- ivalue_importer.cpp ------------------------------------------------===//
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//
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// This file is licensed under a pytorch-style license
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// See frontends/pytorch/LICENSE for license information.
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//
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//===----------------------------------------------------------------------===//
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#include "ivalue_importer.h"
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#include "graph_importer.h"
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#include <unordered_map>
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#include "mlir_utils.h"
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#include "mlir-c/BuiltinAttributes.h"
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#include "mlir-c/BuiltinTypes.h"
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#include "mlir-c/Diagnostics.h"
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#include "npcomp-c/Types.h"
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using namespace torch_mlir;
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// Hashing functionality for IValue's.
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//
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// What we want here is a strict object identity hash. This is different from
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// what Python usually treats as hashing, which is a deep equality hash. In
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// Python terms, what we want here is a hash of `id(x)` -- unfortunately, IValue
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// is not uniformly heap allocated the way a `PyObject*` is, so special handling
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// is needed. At the time of this writing, there seem to be two different
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// implementations, neither of which is exactly what we want.
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//
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// - c10::IValue::hash static method
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// - Problem: Doesn't handle certain data types, in particular objects (which
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// modules are a special case of) and lists/dicts. This makes sense when
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// reflecting the Python semantics.
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// - c10::WeakIValue::hash method
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// - Problem: it literally just returns the bits of the "union" as an int.
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// This seems to read uninitialized bits for the bool variant.
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//
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// We use the `c10::IValue::hash` static method with special cases for data
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// types that need their identity to be handled specially. `c10::IValue::hash`
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// seems to be implemented in a principled way following the Python semantics,
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// which is compatible with the semantics we want (for the subset it doesn't
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// throw an error on).
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namespace {
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struct IValueHasher {
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size_t operator()(const c10::IValue &ivalue) const {
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if (ivalue.isObject() || ivalue.isList()) {
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return std::hash<const void *>()(
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static_cast<const void *>(ivalue.internalToPointer()));
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}
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return c10::IValue::hash(ivalue);
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}
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};
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} // namespace
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// TODO: The implementation of isSameIdentity looks vulnerable to malloc reusing
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// the same memory block (if this hash function is used in an online setting,
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// such as when tracing). Can we do better?
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namespace {
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struct IValueEq {
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bool operator()(const c10::IValue &lhs, const c10::IValue &rhs) const {
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return lhs.isSameIdentity(rhs);
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}
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};
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} // namespace
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namespace {
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/// Helper class for holding state during recursive IValue import.
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///
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/// The intended usage pattern of this class is to construct it then call
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/// `importIValue`.
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///
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/// The `importIValue` method can be called more than once, and values are
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/// unified *by object identity*. For types isomorphic to Python builtin types
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/// the behavior is what you would expect from `id(x)`.
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///
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/// For tensors, object identity is a little tricky. As background, at::Tensor
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/// basically has 4 parts:
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/// - at::Tensor which is a smart pointer to at::TensorImpl
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/// - at::TensorImpl which holds sizes/strides/etc. and points to at::Storage
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/// - the address of the at::TensorImpl is the identity of the tensor.
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/// - at::Storage which is a smart pointer to at::StorageImpl
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/// - at::StorageImpl which is a low-level buffer
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/// - the address of the at::StorageImpl is the identity of the "storage".
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///
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/// Multiple different tensors can share the same underlying storage. We
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/// currently import tensors by identity and emit errors in the case of tensors
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/// with different identity but sharing the same storage. This is done because
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/// correctly modeling the many ways that tensors can overlap and alias when
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/// they share storage is difficult. Example hard cases are weird
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/// strides/offsets that overlap, and even cases where the data types mismatch
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/// (PyTorch allows this!).
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class IValueImporter {
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public:
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IValueImporter(MlirBlock importBlock, MlirContext context)
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: importBlock(importBlock), context(context), typeMapper(context) {}
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MlirValue importIValue(c10::IValue value);
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private:
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MlirValue rawImportIValue(c10::IValue value);
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MlirValue importModule(torch::jit::Module jitModule);
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void importMethod(torch::jit::Function *function, MlirBlock classTypeBody);
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void importClassType(c10::ClassType *classType);
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MlirBlock importBlock;
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MlirContext context;
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TypeMapper typeMapper;
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// Map tracking already-imported values.
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std::unordered_map<c10::IValue, MlirValue, IValueHasher, IValueEq> valueMap;
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// Used to detect potentially aliasing tensors.
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std::unordered_set<c10::StorageImpl *> seenStorageImpls;
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// The set of ClassType's that have already been imported.
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//
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// ClassType's are referenced via their `classType->name()->qualifiedName()`
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// string (as an MLIR symbol name) so we don't need to keep a map associating
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// them with the MlirOperation that they import into.
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std::unordered_set<c10::ClassType *> classTypes;
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// The stack of attribute names we have traversed to reach the current IValue.
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// Used for diagnostics.
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std::vector<std::string> attributeNameStack;
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// The root module encountered during recursive IValue traversal.
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// Used for diagnostics.
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// Note that the "top-level" object being imported can in theory be a list
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// of modules, so this is populated when our recursive traversal enters a
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// module not enclosed in any other module, and unset after our recursive
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// traversal exits the module.
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c10::optional<std::string> rootModuleName;
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};
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} // namespace
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MlirValue IValueImporter::importModule(torch::jit::Module currentModule) {
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// TODO: Can we do better?
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MlirLocation loc = mlirLocationUnknownGet(context);
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c10::optional<c10::QualifiedName> maybeName = currentModule.type()->name();
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if (!maybeName) {
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throw std::invalid_argument("cannot import unnamed module");
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}
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std::string moduleTypeName = maybeName->qualifiedName();
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// Ensure the class type has been imported.
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importClassType(currentModule.type().get());
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MlirOperation nnModule = createMlirOperation(
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"torch.nn_module", loc,
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npcompNnModuleTypeGet(context, toMlirStringRef(moduleTypeName)),
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mlirRegionCreate());
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MlirRegion nnModuleRegion = mlirOperationGetRegion(nnModule, 0);
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mlirRegionAppendOwnedBlock(nnModuleRegion, mlirBlockCreate(0, nullptr));
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MlirBlock nnModuleBody = mlirRegionGetFirstBlock(nnModuleRegion);
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if (!rootModuleName.has_value()) {
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rootModuleName = moduleTypeName;
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}
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const std::vector<c10::IValue> &slots = currentModule._ivalue()->slots();
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const std::vector<c10::ClassAttribute> &classAttributes =
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currentModule.type()->getAttributes();
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assert(slots.size() == classAttributes.size() &&
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"mismatch between object and type!");
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for (int i = 0, e = slots.size(); i < e; i++) {
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const c10::ClassAttribute &classAttribute = classAttributes[i];
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attributeNameStack.push_back(classAttribute.getName());
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MlirValue slotValue = importIValue(slots[i]);
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// TODO: Is it necessary to track whether an attribute is a "parameter"?
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createMlirOperationAtEnd(
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nnModuleBody, "torch.slot", loc, slotValue,
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toMlirNamedAttribute(
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"name", mlirStringAttrGet(
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context, toMlirStringRef(classAttribute.getName()))));
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attributeNameStack.pop_back();
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}
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if (rootModuleName.has_value()) {
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rootModuleName = c10::nullopt;
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}
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createMlirOperationAtEnd(nnModuleBody, "torch.nn_module_terminator", loc);
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mlirBlockInsertOwnedOperationBefore(
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importBlock, mlirBlockGetTerminator(importBlock), nnModule);
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return mlirOperationGetResult(nnModule, 0);
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}
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MlirValue IValueImporter::importIValue(c10::IValue ivalue) {
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auto it = valueMap.find(ivalue);
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if (it != valueMap.end()) {
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return it->second;
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}
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// Reject potentially aliased tensors.
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if (ivalue.isTensor()) {
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c10::StorageImpl *storageImpl =
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ivalue.toTensor().storage().unsafeGetStorageImpl();
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if (!seenStorageImpls.insert(storageImpl).second) {
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std::stringstream msg;
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msg << "Unhandled tensor that shares storage with another tensor.";
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if (rootModuleName) {
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msg << "\nFound at path '<root>."
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<< c10::QualifiedName(attributeNameStack).qualifiedName()
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<< "' from root object '" << *rootModuleName << "'";
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}
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throw std::invalid_argument(msg.str());
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}
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}
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MlirValue value = rawImportIValue(ivalue);
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valueMap[ivalue] = value;
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return value;
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}
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MlirValue IValueImporter::rawImportIValue(c10::IValue ivalue) {
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// TODO: Can we do better?
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MlirLocation loc = mlirLocationUnknownGet(context);
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if (ivalue.isBool()) {
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MlirType type = npcompBoolTypeGet(context);
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MlirOperation operation = createMlirOperationAtEnd(
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importBlock, "basicpy.bool_constant", loc, type,
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toMlirNamedAttribute("value",
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mlirBoolAttrGet(context, ivalue.toBool())));
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return mlirOperationGetResult(operation, 0);
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}
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if (ivalue.isDouble()) {
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MlirType type = mlirF64TypeGet(context);
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MlirOperation operation = createMlirOperationAtEnd(
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importBlock, "basicpy.numeric_constant", loc, type,
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toMlirNamedAttribute(
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"value", mlirFloatAttrDoubleGet(context, type, ivalue.toDouble())));
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return mlirOperationGetResult(operation, 0);
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}
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if (ivalue.isInt()) {
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MlirType type = mlirIntegerTypeGet(context, 64);
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MlirOperation operation = createMlirOperationAtEnd(
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importBlock, "basicpy.numeric_constant", loc, type,
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toMlirNamedAttribute("value",
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mlirIntegerAttrGet(type, ivalue.toInt())));
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return mlirOperationGetResult(operation, 0);
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}
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if (ivalue.isList()) {
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c10::List<c10::IValue> list = ivalue.toList();
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std::vector<MlirValue> elems;
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for (const c10::IValue &elem : list) {
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elems.push_back(importIValue(elem));
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}
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MlirOperation operation =
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createMlirOperationAtEnd(importBlock, "basicpy.build_list", loc,
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npcompListTypeGet(context), elems);
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return mlirOperationGetResult(operation, 0);
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}
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if (ivalue.isTensor()) {
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at::Tensor tensor = ivalue.toTensor().contiguous();
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MlirAttribute denseElements = converTensorToMlirElementsAttr(tensor, loc);
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MlirOperation constant = createMlirOperationAtEnd(
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importBlock, "std.constant", loc, mlirAttributeGetType(denseElements),
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toMlirNamedAttribute("value", denseElements));
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MlirOperation ndarray = createMlirOperationAtEnd(
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importBlock, "numpy.create_array_from_tensor", loc,
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npcompNdArrayTypeGetUnranked(npcompAnyDtypeTypeGet(context)),
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mlirOperationGetResult(constant, 0));
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return mlirOperationGetResult(ndarray, 0);
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}
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if (ivalue.isModule()) {
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return importModule(ivalue.toModule());
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}
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if (ivalue.isNone()) {
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MlirOperation operation = createMlirOperationAtEnd(
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importBlock, "basicpy.singleton", loc, npcompNoneTypeGet(context));
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return mlirOperationGetResult(operation, 0);
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}
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std::stringstream msg;
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msg << "Unsupported ivalue: " << ivalue;
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throw std::invalid_argument(msg.str());
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}
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void IValueImporter::importMethod(torch::jit::Function *function,
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MlirBlock classTypeBody) {
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// We make an effort for the func op's symbol name to be useful for debugging,
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// but still clearly non-load-bearing.
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std::string symName =
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"__npcomp_priv_fn." + function->qualname().qualifiedName();
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MlirOperation func =
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importGraphAsFuncOp(context, function->graph().get(), symName);
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mlirOperationSetAttributeByName(
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func, toMlirStringRef("sym_visibility"),
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mlirStringAttrGet(context, toMlirStringRef("private")));
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mlirBlockInsertOwnedOperationBefore(
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importBlock, mlirBlockGetTerminator(importBlock), func);
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createMlirOperationAtEnd(
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classTypeBody, "torch.method", mlirLocationUnknownGet(context),
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toMlirNamedAttribute(
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"name",
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mlirStringAttrGet(context, toMlirStringRef(function->name()))),
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toMlirNamedAttribute("function", mlirFlatSymbolRefAttrGet(
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context, toMlirStringRef(symName))));
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}
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void IValueImporter::importClassType(c10::ClassType *classType) {
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if (!classTypes.insert(classType).second) {
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return;
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}
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// TODO: Can we do better?
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MlirLocation loc = mlirLocationUnknownGet(context);
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MlirOperation op = createMlirOperationAtEnd(
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importBlock, "torch.class_type", loc, mlirRegionCreate(),
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toMlirNamedAttribute(
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"sym_name",
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mlirStringAttrGet(
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context, toMlirStringRef(classType->name()->qualifiedName()))));
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MlirRegion region = mlirOperationGetRegion(op, 0);
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mlirRegionAppendOwnedBlock(region, mlirBlockCreate(0, nullptr));
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MlirBlock classTypeBody = mlirRegionGetFirstBlock(region);
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for (const c10::ClassAttribute &classAttribute : classType->getAttributes()) {
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createMlirOperationAtEnd(
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classTypeBody, "torch.attr", loc,
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toMlirNamedAttribute(
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"name", mlirStringAttrGet(
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context, toMlirStringRef(classAttribute.getName()))),
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toMlirNamedAttribute("type",
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mlirTypeAttrGet(typeMapper.mapFromTorchType(
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loc, classAttribute.getType()))));
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}
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for (torch::jit::Function *function : classType->methods()) {
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importMethod(function, classTypeBody);
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}
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createMlirOperationAtEnd(classTypeBody, "torch.class_type_terminator", loc);
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}
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void torch_mlir::importIValue(c10::IValue ivalue, MlirBlock block,
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MlirContext context) {
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// When debugging module importing, it can be useful to dump as so:
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// if (ivalue.isModule())
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// ivalue.toModule().dump(true, false, false);
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IValueImporter importer(block, context);
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importer.importIValue(ivalue);
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}
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