//===- IRInterfaces.cpp - MLIR IR interfaces pybind -----------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "IRModule.h" #include "mlir-c/BuiltinAttributes.h" #include "mlir-c/Interfaces.h" namespace py = pybind11; namespace mlir { namespace python { constexpr static const char *constructorDoc = R"(Creates an interface from a given operation/opview object or from a subclass of OpView. Raises ValueError if the operation does not implement the interface.)"; constexpr static const char *operationDoc = R"(Returns an Operation for which the interface was constructed.)"; constexpr static const char *opviewDoc = R"(Returns an OpView subclass _instance_ for which the interface was constructed)"; constexpr static const char *inferReturnTypesDoc = R"(Given the arguments required to build an operation, attempts to infer its return types. Raises ValueError on failure.)"; /// CRTP base class for Python classes representing MLIR Op interfaces. /// Interface hierarchies are flat so no base class is expected here. The /// derived class is expected to define the following static fields: /// - `const char *pyClassName` - the name of the Python class to create; /// - `GetTypeIDFunctionTy getInterfaceID` - the function producing the TypeID /// of the interface. /// Derived classes may redefine the `bindDerived(ClassTy &)` method to bind /// interface-specific methods. /// /// An interface class may be constructed from either an Operation/OpView object /// or from a subclass of OpView. In the latter case, only the static interface /// methods are available, similarly to calling ConcereteOp::staticMethod on the /// C++ side. Implementations of concrete interfaces can use the `isStatic` /// method to check whether the interface object was constructed from a class or /// an operation/opview instance. The `getOpName` always succeeds and returns a /// canonical name of the operation suitable for lookups. template class PyConcreteOpInterface { protected: using ClassTy = py::class_; using GetTypeIDFunctionTy = MlirTypeID (*)(); public: /// Constructs an interface instance from an object that is either an /// operation or a subclass of OpView. In the latter case, only the static /// methods of the interface are accessible to the caller. PyConcreteOpInterface(py::object object, DefaultingPyMlirContext context) : obj(object) { try { operation = &py::cast(obj); } catch (py::cast_error &err) { // Do nothing. } try { operation = &py::cast(obj).getOperation(); } catch (py::cast_error &err) { // Do nothing. } if (operation != nullptr) { if (!mlirOperationImplementsInterface(*operation, ConcreteIface::getInterfaceID())) { std::string msg = "the operation does not implement "; throw py::value_error(msg + ConcreteIface::pyClassName); } MlirIdentifier identifier = mlirOperationGetName(*operation); MlirStringRef stringRef = mlirIdentifierStr(identifier); opName = std::string(stringRef.data, stringRef.length); } else { try { opName = obj.attr("OPERATION_NAME").template cast(); } catch (py::cast_error &err) { throw py::type_error( "Op interface does not refer to an operation or OpView class"); } if (!mlirOperationImplementsInterfaceStatic( mlirStringRefCreate(opName.data(), opName.length()), context.resolve().get(), ConcreteIface::getInterfaceID())) { std::string msg = "the operation does not implement "; throw py::value_error(msg + ConcreteIface::pyClassName); } } } /// Creates the Python bindings for this class in the given module. static void bind(py::module &m) { py::class_ cls(m, "InferTypeOpInterface", py::module_local()); cls.def(py::init(), py::arg("object"), py::arg("context") = py::none(), constructorDoc) .def_property_readonly("operation", &PyConcreteOpInterface::getOperationObject, operationDoc) .def_property_readonly("opview", &PyConcreteOpInterface::getOpView, opviewDoc); ConcreteIface::bindDerived(cls); } /// Hook for derived classes to add class-specific bindings. static void bindDerived(ClassTy &cls) {} /// Returns `true` if this object was constructed from a subclass of OpView /// rather than from an operation instance. bool isStatic() { return operation == nullptr; } /// Returns the operation instance from which this object was constructed. /// Throws a type error if this object was constructed from a subclass of /// OpView. py::object getOperationObject() { if (operation == nullptr) { throw py::type_error("Cannot get an operation from a static interface"); } return operation->getRef().releaseObject(); } /// Returns the opview of the operation instance from which this object was /// constructed. Throws a type error if this object was constructed form a /// subclass of OpView. py::object getOpView() { if (operation == nullptr) { throw py::type_error("Cannot get an opview from a static interface"); } return operation->createOpView(); } /// Returns the canonical name of the operation this interface is constructed /// from. const std::string &getOpName() { return opName; } private: PyOperation *operation = nullptr; std::string opName; py::object obj; }; /// Python wrapper for InterTypeOpInterface. This interface has only static /// methods. class PyInferTypeOpInterface : public PyConcreteOpInterface { public: using PyConcreteOpInterface::PyConcreteOpInterface; constexpr static const char *pyClassName = "InferTypeOpInterface"; constexpr static GetTypeIDFunctionTy getInterfaceID = &mlirInferTypeOpInterfaceTypeID; /// C-style user-data structure for type appending callback. struct AppendResultsCallbackData { std::vector &inferredTypes; PyMlirContext &pyMlirContext; }; /// Appends the types provided as the two first arguments to the user-data /// structure (expects AppendResultsCallbackData). static void appendResultsCallback(intptr_t nTypes, MlirType *types, void *userData) { auto *data = static_cast(userData); data->inferredTypes.reserve(data->inferredTypes.size() + nTypes); for (intptr_t i = 0; i < nTypes; ++i) { data->inferredTypes.push_back( PyType(data->pyMlirContext.getRef(), types[i])); } } /// Given the arguments required to build an operation, attempts to infer its /// return types. Throws value_error on faliure. std::vector inferReturnTypes(llvm::Optional> operands, llvm::Optional attributes, llvm::Optional> regions, DefaultingPyMlirContext context, DefaultingPyLocation location) { llvm::SmallVector mlirOperands; llvm::SmallVector mlirRegions; if (operands) { mlirOperands.reserve(operands->size()); for (PyValue &value : *operands) { mlirOperands.push_back(value); } } if (regions) { mlirRegions.reserve(regions->size()); for (PyRegion ®ion : *regions) { mlirRegions.push_back(region); } } std::vector inferredTypes; PyMlirContext &pyContext = context.resolve(); AppendResultsCallbackData data{inferredTypes, pyContext}; MlirStringRef opNameRef = mlirStringRefCreate(getOpName().data(), getOpName().length()); MlirAttribute attributeDict = attributes ? attributes->get() : mlirAttributeGetNull(); MlirLogicalResult result = mlirInferTypeOpInterfaceInferReturnTypes( opNameRef, pyContext.get(), location.resolve(), mlirOperands.size(), mlirOperands.data(), attributeDict, mlirRegions.size(), mlirRegions.data(), &appendResultsCallback, &data); if (mlirLogicalResultIsFailure(result)) { throw py::value_error("Failed to infer result types"); } return inferredTypes; } static void bindDerived(ClassTy &cls) { cls.def("inferReturnTypes", &PyInferTypeOpInterface::inferReturnTypes, py::arg("operands") = py::none(), py::arg("attributes") = py::none(), py::arg("regions") = py::none(), py::arg("context") = py::none(), py::arg("loc") = py::none(), inferReturnTypesDoc); } }; void populateIRInterfaces(py::module &m) { PyInferTypeOpInterface::bind(m); } } // namespace python } // namespace mlir