mlir/lib/Bindings/Python/IRTypes.cpp - llvm-project - Git at Google

 //===- IRTypes.cpp - Exports builtin and standard types -------------------===//
 //
 // 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 "PybindUtils.h"

 #include "mlir-c/BuiltinAttributes.h"
 #include "mlir-c/BuiltinTypes.h"

 namespace py = pybind11;
 using namespace mlir;
 using namespace mlir::python;

 using llvm::SmallVector;
 using llvm::Twine;

 namespace {

 /// Checks whether the given type is an integer or float type.
 static int mlirTypeIsAIntegerOrFloat(MlirType type) {
   return mlirTypeIsAInteger(type) || mlirTypeIsABF16(type) ||
          mlirTypeIsAF16(type) || mlirTypeIsAF32(type) || mlirTypeIsAF64(type);
 }

 class PyIntegerType : public PyConcreteType<PyIntegerType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAInteger;
   static constexpr const char *pyClassName = "IntegerType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get_signless",
         [](unsigned width, DefaultingPyMlirContext context) {
           MlirType t = mlirIntegerTypeGet(context->get(), width);
           return PyIntegerType(context->getRef(), t);
         },
         py::arg("width"), py::arg("context") = py::none(),
         "Create a signless integer type");
     c.def_static(
         "get_signed",
         [](unsigned width, DefaultingPyMlirContext context) {
           MlirType t = mlirIntegerTypeSignedGet(context->get(), width);
           return PyIntegerType(context->getRef(), t);
         },
         py::arg("width"), py::arg("context") = py::none(),
         "Create a signed integer type");
     c.def_static(
         "get_unsigned",
         [](unsigned width, DefaultingPyMlirContext context) {
           MlirType t = mlirIntegerTypeUnsignedGet(context->get(), width);
           return PyIntegerType(context->getRef(), t);
         },
         py::arg("width"), py::arg("context") = py::none(),
         "Create an unsigned integer type");
     c.def_property_readonly(
         "width",
         [](PyIntegerType &self) { return mlirIntegerTypeGetWidth(self); },
         "Returns the width of the integer type");
     c.def_property_readonly(
         "is_signless",
         [](PyIntegerType &self) -> bool {
           return mlirIntegerTypeIsSignless(self);
         },
         "Returns whether this is a signless integer");
     c.def_property_readonly(
         "is_signed",
         [](PyIntegerType &self) -> bool {
           return mlirIntegerTypeIsSigned(self);
         },
         "Returns whether this is a signed integer");
     c.def_property_readonly(
         "is_unsigned",
         [](PyIntegerType &self) -> bool {
           return mlirIntegerTypeIsUnsigned(self);
         },
         "Returns whether this is an unsigned integer");
   }
 };

 /// Index Type subclass - IndexType.
 class PyIndexType : public PyConcreteType<PyIndexType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAIndex;
   static constexpr const char *pyClassName = "IndexType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get",
         [](DefaultingPyMlirContext context) {
           MlirType t = mlirIndexTypeGet(context->get());
           return PyIndexType(context->getRef(), t);
         },
         py::arg("context") = py::none(), "Create a index type.");
   }
 };

 /// Floating Point Type subclass - BF16Type.
 class PyBF16Type : public PyConcreteType<PyBF16Type> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsABF16;
   static constexpr const char *pyClassName = "BF16Type";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get",
         [](DefaultingPyMlirContext context) {
           MlirType t = mlirBF16TypeGet(context->get());
           return PyBF16Type(context->getRef(), t);
         },
         py::arg("context") = py::none(), "Create a bf16 type.");
   }
 };

 /// Floating Point Type subclass - F16Type.
 class PyF16Type : public PyConcreteType<PyF16Type> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAF16;
   static constexpr const char *pyClassName = "F16Type";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get",
         [](DefaultingPyMlirContext context) {
           MlirType t = mlirF16TypeGet(context->get());
           return PyF16Type(context->getRef(), t);
         },
         py::arg("context") = py::none(), "Create a f16 type.");
   }
 };

 /// Floating Point Type subclass - F32Type.
 class PyF32Type : public PyConcreteType<PyF32Type> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAF32;
   static constexpr const char *pyClassName = "F32Type";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get",
         [](DefaultingPyMlirContext context) {
           MlirType t = mlirF32TypeGet(context->get());
           return PyF32Type(context->getRef(), t);
         },
         py::arg("context") = py::none(), "Create a f32 type.");
   }
 };

 /// Floating Point Type subclass - F64Type.
 class PyF64Type : public PyConcreteType<PyF64Type> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAF64;
   static constexpr const char *pyClassName = "F64Type";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get",
         [](DefaultingPyMlirContext context) {
           MlirType t = mlirF64TypeGet(context->get());
           return PyF64Type(context->getRef(), t);
         },
         py::arg("context") = py::none(), "Create a f64 type.");
   }
 };

 /// None Type subclass - NoneType.
 class PyNoneType : public PyConcreteType<PyNoneType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsANone;
   static constexpr const char *pyClassName = "NoneType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get",
         [](DefaultingPyMlirContext context) {
           MlirType t = mlirNoneTypeGet(context->get());
           return PyNoneType(context->getRef(), t);
         },
         py::arg("context") = py::none(), "Create a none type.");
   }
 };

 /// Complex Type subclass - ComplexType.
 class PyComplexType : public PyConcreteType<PyComplexType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAComplex;
   static constexpr const char *pyClassName = "ComplexType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get",
         [](PyType &elementType) {
           // The element must be a floating point or integer scalar type.
           if (mlirTypeIsAIntegerOrFloat(elementType)) {
             MlirType t = mlirComplexTypeGet(elementType);
             return PyComplexType(elementType.getContext(), t);
           }
           throw SetPyError(
               PyExc_ValueError,
               Twine("invalid '") +
                   py::repr(py::cast(elementType)).cast<std::string>() +
                   "' and expected floating point or integer type.");
         },
         "Create a complex type");
     c.def_property_readonly(
         "element_type",
         [](PyComplexType &self) -> PyType {
           MlirType t = mlirComplexTypeGetElementType(self);
           return PyType(self.getContext(), t);
         },
         "Returns element type.");
   }
 };

 class PyShapedType : public PyConcreteType<PyShapedType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAShaped;
   static constexpr const char *pyClassName = "ShapedType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_property_readonly(
         "element_type",
         [](PyShapedType &self) {
           MlirType t = mlirShapedTypeGetElementType(self);
           return PyType(self.getContext(), t);
         },
         "Returns the element type of the shaped type.");
     c.def_property_readonly(
         "has_rank",
         [](PyShapedType &self) -> bool { return mlirShapedTypeHasRank(self); },
         "Returns whether the given shaped type is ranked.");
     c.def_property_readonly(
         "rank",
         [](PyShapedType &self) {
           self.requireHasRank();
           return mlirShapedTypeGetRank(self);
         },
         "Returns the rank of the given ranked shaped type.");
     c.def_property_readonly(
         "has_static_shape",
         [](PyShapedType &self) -> bool {
           return mlirShapedTypeHasStaticShape(self);
         },
         "Returns whether the given shaped type has a static shape.");
     c.def(
         "is_dynamic_dim",
         [](PyShapedType &self, intptr_t dim) -> bool {
           self.requireHasRank();
           return mlirShapedTypeIsDynamicDim(self, dim);
         },
         py::arg("dim"),
         "Returns whether the dim-th dimension of the given shaped type is "
         "dynamic.");
     c.def(
         "get_dim_size",
         [](PyShapedType &self, intptr_t dim) {
           self.requireHasRank();
           return mlirShapedTypeGetDimSize(self, dim);
         },
         py::arg("dim"),
         "Returns the dim-th dimension of the given ranked shaped type.");
     c.def_static(
         "is_dynamic_size",
         [](int64_t size) -> bool { return mlirShapedTypeIsDynamicSize(size); },
         py::arg("dim_size"),
         "Returns whether the given dimension size indicates a dynamic "
         "dimension.");
     c.def(
         "is_dynamic_stride_or_offset",
         [](PyShapedType &self, int64_t val) -> bool {
           self.requireHasRank();
           return mlirShapedTypeIsDynamicStrideOrOffset(val);
         },
         py::arg("dim_size"),
         "Returns whether the given value is used as a placeholder for dynamic "
         "strides and offsets in shaped types.");
     c.def_property_readonly(
         "shape",
         [](PyShapedType &self) {
           self.requireHasRank();

           std::vector<int64_t> shape;
           int64_t rank = mlirShapedTypeGetRank(self);
           shape.reserve(rank);
           for (int64_t i = 0; i < rank; ++i)
             shape.push_back(mlirShapedTypeGetDimSize(self, i));
           return shape;
         },
         "Returns the shape of the ranked shaped type as a list of integers.");
   }

 private:
   void requireHasRank() {
     if (!mlirShapedTypeHasRank(*this)) {
       throw SetPyError(
           PyExc_ValueError,
           "calling this method requires that the type has a rank.");
     }
   }
 };

 /// Vector Type subclass - VectorType.
 class PyVectorType : public PyConcreteType<PyVectorType, PyShapedType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAVector;
   static constexpr const char *pyClassName = "VectorType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get",
         [](std::vector<int64_t> shape, PyType &elementType,
            DefaultingPyLocation loc) {
           MlirType t = mlirVectorTypeGetChecked(loc, shape.size(), shape.data(),
                                                 elementType);
           // TODO: Rework error reporting once diagnostic engine is exposed
           // in C API.
           if (mlirTypeIsNull(t)) {
             throw SetPyError(
                 PyExc_ValueError,
                 Twine("invalid '") +
                     py::repr(py::cast(elementType)).cast<std::string>() +
                     "' and expected floating point or integer type.");
           }
           return PyVectorType(elementType.getContext(), t);
         },
         py::arg("shape"), py::arg("elementType"), py::arg("loc") = py::none(),
         "Create a vector type");
   }
 };

 /// Ranked Tensor Type subclass - RankedTensorType.
 class PyRankedTensorType
     : public PyConcreteType<PyRankedTensorType, PyShapedType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsARankedTensor;
   static constexpr const char *pyClassName = "RankedTensorType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get",
         [](std::vector<int64_t> shape, PyType &elementType,
            llvm::Optional<PyAttribute> &encodingAttr,
            DefaultingPyLocation loc) {
           MlirType t = mlirRankedTensorTypeGetChecked(
               loc, shape.size(), shape.data(), elementType,
               encodingAttr ? encodingAttr->get() : mlirAttributeGetNull());
           // TODO: Rework error reporting once diagnostic engine is exposed
           // in C API.
           if (mlirTypeIsNull(t)) {
             throw SetPyError(
                 PyExc_ValueError,
                 Twine("invalid '") +
                     py::repr(py::cast(elementType)).cast<std::string>() +
                     "' and expected floating point, integer, vector or "
                     "complex "
                     "type.");
           }
           return PyRankedTensorType(elementType.getContext(), t);
         },
         py::arg("shape"), py::arg("element_type"),
         py::arg("encoding") = py::none(), py::arg("loc") = py::none(),
         "Create a ranked tensor type");
     c.def_property_readonly(
         "encoding",
         [](PyRankedTensorType &self) -> llvm::Optional<PyAttribute> {
           MlirAttribute encoding = mlirRankedTensorTypeGetEncoding(self.get());
           if (mlirAttributeIsNull(encoding))
             return llvm::None;
           return PyAttribute(self.getContext(), encoding);
         });
   }
 };

 /// Unranked Tensor Type subclass - UnrankedTensorType.
 class PyUnrankedTensorType
     : public PyConcreteType<PyUnrankedTensorType, PyShapedType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAUnrankedTensor;
   static constexpr const char *pyClassName = "UnrankedTensorType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get",
         [](PyType &elementType, DefaultingPyLocation loc) {
           MlirType t = mlirUnrankedTensorTypeGetChecked(loc, elementType);
           // TODO: Rework error reporting once diagnostic engine is exposed
           // in C API.
           if (mlirTypeIsNull(t)) {
             throw SetPyError(
                 PyExc_ValueError,
                 Twine("invalid '") +
                     py::repr(py::cast(elementType)).cast<std::string>() +
                     "' and expected floating point, integer, vector or "
                     "complex "
                     "type.");
           }
           return PyUnrankedTensorType(elementType.getContext(), t);
         },
         py::arg("element_type"), py::arg("loc") = py::none(),
         "Create a unranked tensor type");
   }
 };

 /// Ranked MemRef Type subclass - MemRefType.
 class PyMemRefType : public PyConcreteType<PyMemRefType, PyShapedType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAMemRef;
   static constexpr const char *pyClassName = "MemRefType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
          "get",
          [](std::vector<int64_t> shape, PyType &elementType,
             PyAttribute *layout, PyAttribute *memorySpace,
             DefaultingPyLocation loc) {
            MlirAttribute layoutAttr = layout ? *layout : mlirAttributeGetNull();
            MlirAttribute memSpaceAttr =
                memorySpace ? *memorySpace : mlirAttributeGetNull();
            MlirType t =
                mlirMemRefTypeGetChecked(loc, elementType, shape.size(),
                                         shape.data(), layoutAttr, memSpaceAttr);
            // TODO: Rework error reporting once diagnostic engine is exposed
            // in C API.
            if (mlirTypeIsNull(t)) {
              throw SetPyError(
                  PyExc_ValueError,
                  Twine("invalid '") +
                      py::repr(py::cast(elementType)).cast<std::string>() +
                      "' and expected floating point, integer, vector or "
                      "complex "
                      "type.");
            }
            return PyMemRefType(elementType.getContext(), t);
          },
          py::arg("shape"), py::arg("element_type"),
          py::arg("layout") = py::none(), py::arg("memory_space") = py::none(),
          py::arg("loc") = py::none(), "Create a memref type")
         .def_property_readonly(
             "layout",
             [](PyMemRefType &self) -> PyAttribute {
               MlirAttribute layout = mlirMemRefTypeGetLayout(self);
               return PyAttribute(self.getContext(), layout);
             },
             "The layout of the MemRef type.")
         .def_property_readonly(
             "affine_map",
             [](PyMemRefType &self) -> PyAffineMap {
               MlirAffineMap map = mlirMemRefTypeGetAffineMap(self);
               return PyAffineMap(self.getContext(), map);
             },
             "The layout of the MemRef type as an affine map.")
         .def_property_readonly(
             "memory_space",
             [](PyMemRefType &self) -> PyAttribute {
               MlirAttribute a = mlirMemRefTypeGetMemorySpace(self);
               return PyAttribute(self.getContext(), a);
             },
             "Returns the memory space of the given MemRef type.");
   }
 };

 /// Unranked MemRef Type subclass - UnrankedMemRefType.
 class PyUnrankedMemRefType
     : public PyConcreteType<PyUnrankedMemRefType, PyShapedType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAUnrankedMemRef;
   static constexpr const char *pyClassName = "UnrankedMemRefType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
          "get",
          [](PyType &elementType, PyAttribute *memorySpace,
             DefaultingPyLocation loc) {
            MlirAttribute memSpaceAttr = {};
            if (memorySpace)
              memSpaceAttr = *memorySpace;

            MlirType t =
                mlirUnrankedMemRefTypeGetChecked(loc, elementType, memSpaceAttr);
            // TODO: Rework error reporting once diagnostic engine is exposed
            // in C API.
            if (mlirTypeIsNull(t)) {
              throw SetPyError(
                  PyExc_ValueError,
                  Twine("invalid '") +
                      py::repr(py::cast(elementType)).cast<std::string>() +
                      "' and expected floating point, integer, vector or "
                      "complex "
                      "type.");
            }
            return PyUnrankedMemRefType(elementType.getContext(), t);
          },
          py::arg("element_type"), py::arg("memory_space"),
          py::arg("loc") = py::none(), "Create a unranked memref type")
         .def_property_readonly(
             "memory_space",
             [](PyUnrankedMemRefType &self) -> PyAttribute {
               MlirAttribute a = mlirMemRefTypeGetMemorySpace(self);
               return PyAttribute(self.getContext(), a);
             },
             "Returns the memory space of the given Unranked MemRef type.");
   }
 };

 /// Tuple Type subclass - TupleType.
 class PyTupleType : public PyConcreteType<PyTupleType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsATuple;
   static constexpr const char *pyClassName = "TupleType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get_tuple",
         [](py::list elementList, DefaultingPyMlirContext context) {
           intptr_t num = py::len(elementList);
           // Mapping py::list to SmallVector.
           SmallVector<MlirType, 4> elements;
           for (auto element : elementList)
             elements.push_back(element.cast<PyType>());
           MlirType t = mlirTupleTypeGet(context->get(), num, elements.data());
           return PyTupleType(context->getRef(), t);
         },
         py::arg("elements"), py::arg("context") = py::none(),
         "Create a tuple type");
     c.def(
         "get_type",
         [](PyTupleType &self, intptr_t pos) -> PyType {
           MlirType t = mlirTupleTypeGetType(self, pos);
           return PyType(self.getContext(), t);
         },
         py::arg("pos"), "Returns the pos-th type in the tuple type.");
     c.def_property_readonly(
         "num_types",
         [](PyTupleType &self) -> intptr_t {
           return mlirTupleTypeGetNumTypes(self);
         },
         "Returns the number of types contained in a tuple.");
   }
 };

 /// Function type.
 class PyFunctionType : public PyConcreteType<PyFunctionType> {
 public:
   static constexpr IsAFunctionTy isaFunction = mlirTypeIsAFunction;
   static constexpr const char *pyClassName = "FunctionType";
   using PyConcreteType::PyConcreteType;

   static void bindDerived(ClassTy &c) {
     c.def_static(
         "get",
         [](std::vector<PyType> inputs, std::vector<PyType> results,
            DefaultingPyMlirContext context) {
           SmallVector<MlirType, 4> inputsRaw(inputs.begin(), inputs.end());
           SmallVector<MlirType, 4> resultsRaw(results.begin(), results.end());
           MlirType t = mlirFunctionTypeGet(context->get(), inputsRaw.size(),
                                            inputsRaw.data(), resultsRaw.size(),
                                            resultsRaw.data());
           return PyFunctionType(context->getRef(), t);
         },
         py::arg("inputs"), py::arg("results"), py::arg("context") = py::none(),
         "Gets a FunctionType from a list of input and result types");
     c.def_property_readonly(
         "inputs",
         [](PyFunctionType &self) {
           MlirType t = self;
           auto contextRef = self.getContext();
           py::list types;
           for (intptr_t i = 0, e = mlirFunctionTypeGetNumInputs(self); i < e;
                ++i) {
             types.append(PyType(contextRef, mlirFunctionTypeGetInput(t, i)));
           }
           return types;
         },
         "Returns the list of input types in the FunctionType.");
     c.def_property_readonly(
         "results",
         [](PyFunctionType &self) {
           auto contextRef = self.getContext();
           py::list types;
           for (intptr_t i = 0, e = mlirFunctionTypeGetNumResults(self); i < e;
                ++i) {
             types.append(
                 PyType(contextRef, mlirFunctionTypeGetResult(self, i)));
           }
           return types;
         },
         "Returns the list of result types in the FunctionType.");
   }
 };

 } // namespace

 void mlir::python::populateIRTypes(py::module &m) {
   PyIntegerType::bind(m);
   PyIndexType::bind(m);
   PyBF16Type::bind(m);
   PyF16Type::bind(m);
   PyF32Type::bind(m);
   PyF64Type::bind(m);
   PyNoneType::bind(m);
   PyComplexType::bind(m);
   PyShapedType::bind(m);
   PyVectorType::bind(m);
   PyRankedTensorType::bind(m);
   PyUnrankedTensorType::bind(m);
   PyMemRefType::bind(m);
   PyUnrankedMemRefType::bind(m);
   PyTupleType::bind(m);
   PyFunctionType::bind(m);
 }
	//===- IRTypes.cpp - Exports builtin and standard types -------------------===//
	//
	// 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 "PybindUtils.h"

	#include "mlir-c/BuiltinAttributes.h"
	#include "mlir-c/BuiltinTypes.h"

	namespace py = pybind11;
	using namespace mlir;
	using namespace mlir::python;

	using llvm::SmallVector;
	using llvm::Twine;

	namespace {

	/// Checks whether the given type is an integer or float type.
	static int mlirTypeIsAIntegerOrFloat(MlirType type) {
	return mlirTypeIsAInteger(type) \|\| mlirTypeIsABF16(type) \|\|
	mlirTypeIsAF16(type) \|\| mlirTypeIsAF32(type) \|\| mlirTypeIsAF64(type);
	}

	class PyIntegerType : public PyConcreteType<PyIntegerType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAInteger;
	static constexpr const char *pyClassName = "IntegerType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get_signless",
	[](unsigned width, DefaultingPyMlirContext context) {
	MlirType t = mlirIntegerTypeGet(context->get(), width);
	return PyIntegerType(context->getRef(), t);
	},
	py::arg("width"), py::arg("context") = py::none(),
	"Create a signless integer type");
	c.def_static(
	"get_signed",
	[](unsigned width, DefaultingPyMlirContext context) {
	MlirType t = mlirIntegerTypeSignedGet(context->get(), width);
	return PyIntegerType(context->getRef(), t);
	},
	py::arg("width"), py::arg("context") = py::none(),
	"Create a signed integer type");
	c.def_static(
	"get_unsigned",
	[](unsigned width, DefaultingPyMlirContext context) {
	MlirType t = mlirIntegerTypeUnsignedGet(context->get(), width);
	return PyIntegerType(context->getRef(), t);
	},
	py::arg("width"), py::arg("context") = py::none(),
	"Create an unsigned integer type");
	c.def_property_readonly(
	"width",
	[](PyIntegerType &self) { return mlirIntegerTypeGetWidth(self); },
	"Returns the width of the integer type");
	c.def_property_readonly(
	"is_signless",
	[](PyIntegerType &self) -> bool {
	return mlirIntegerTypeIsSignless(self);
	},
	"Returns whether this is a signless integer");
	c.def_property_readonly(
	"is_signed",
	[](PyIntegerType &self) -> bool {
	return mlirIntegerTypeIsSigned(self);
	},
	"Returns whether this is a signed integer");
	c.def_property_readonly(
	"is_unsigned",
	[](PyIntegerType &self) -> bool {
	return mlirIntegerTypeIsUnsigned(self);
	},
	"Returns whether this is an unsigned integer");
	}
	};

	/// Index Type subclass - IndexType.
	class PyIndexType : public PyConcreteType<PyIndexType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAIndex;
	static constexpr const char *pyClassName = "IndexType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](DefaultingPyMlirContext context) {
	MlirType t = mlirIndexTypeGet(context->get());
	return PyIndexType(context->getRef(), t);
	},
	py::arg("context") = py::none(), "Create a index type.");
	}
	};

	/// Floating Point Type subclass - BF16Type.
	class PyBF16Type : public PyConcreteType<PyBF16Type> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsABF16;
	static constexpr const char *pyClassName = "BF16Type";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](DefaultingPyMlirContext context) {
	MlirType t = mlirBF16TypeGet(context->get());
	return PyBF16Type(context->getRef(), t);
	},
	py::arg("context") = py::none(), "Create a bf16 type.");
	}
	};

	/// Floating Point Type subclass - F16Type.
	class PyF16Type : public PyConcreteType<PyF16Type> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAF16;
	static constexpr const char *pyClassName = "F16Type";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](DefaultingPyMlirContext context) {
	MlirType t = mlirF16TypeGet(context->get());
	return PyF16Type(context->getRef(), t);
	},
	py::arg("context") = py::none(), "Create a f16 type.");
	}
	};

	/// Floating Point Type subclass - F32Type.
	class PyF32Type : public PyConcreteType<PyF32Type> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAF32;
	static constexpr const char *pyClassName = "F32Type";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](DefaultingPyMlirContext context) {
	MlirType t = mlirF32TypeGet(context->get());
	return PyF32Type(context->getRef(), t);
	},
	py::arg("context") = py::none(), "Create a f32 type.");
	}
	};

	/// Floating Point Type subclass - F64Type.
	class PyF64Type : public PyConcreteType<PyF64Type> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAF64;
	static constexpr const char *pyClassName = "F64Type";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](DefaultingPyMlirContext context) {
	MlirType t = mlirF64TypeGet(context->get());
	return PyF64Type(context->getRef(), t);
	},
	py::arg("context") = py::none(), "Create a f64 type.");
	}
	};

	/// None Type subclass - NoneType.
	class PyNoneType : public PyConcreteType<PyNoneType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsANone;
	static constexpr const char *pyClassName = "NoneType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](DefaultingPyMlirContext context) {
	MlirType t = mlirNoneTypeGet(context->get());
	return PyNoneType(context->getRef(), t);
	},
	py::arg("context") = py::none(), "Create a none type.");
	}
	};

	/// Complex Type subclass - ComplexType.
	class PyComplexType : public PyConcreteType<PyComplexType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAComplex;
	static constexpr const char *pyClassName = "ComplexType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](PyType &elementType) {
	// The element must be a floating point or integer scalar type.
	if (mlirTypeIsAIntegerOrFloat(elementType)) {
	MlirType t = mlirComplexTypeGet(elementType);
	return PyComplexType(elementType.getContext(), t);
	}
	throw SetPyError(
	PyExc_ValueError,
	Twine("invalid '") +
	py::repr(py::cast(elementType)).cast<std::string>() +
	"' and expected floating point or integer type.");
	},
	"Create a complex type");
	c.def_property_readonly(
	"element_type",
	[](PyComplexType &self) -> PyType {
	MlirType t = mlirComplexTypeGetElementType(self);
	return PyType(self.getContext(), t);
	},
	"Returns element type.");
	}
	};

	class PyShapedType : public PyConcreteType<PyShapedType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAShaped;
	static constexpr const char *pyClassName = "ShapedType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_property_readonly(
	"element_type",
	[](PyShapedType &self) {
	MlirType t = mlirShapedTypeGetElementType(self);
	return PyType(self.getContext(), t);
	},
	"Returns the element type of the shaped type.");
	c.def_property_readonly(
	"has_rank",
	[](PyShapedType &self) -> bool { return mlirShapedTypeHasRank(self); },
	"Returns whether the given shaped type is ranked.");
	c.def_property_readonly(
	"rank",
	[](PyShapedType &self) {
	self.requireHasRank();
	return mlirShapedTypeGetRank(self);
	},
	"Returns the rank of the given ranked shaped type.");
	c.def_property_readonly(
	"has_static_shape",
	[](PyShapedType &self) -> bool {
	return mlirShapedTypeHasStaticShape(self);
	},
	"Returns whether the given shaped type has a static shape.");
	c.def(
	"is_dynamic_dim",
	[](PyShapedType &self, intptr_t dim) -> bool {
	self.requireHasRank();
	return mlirShapedTypeIsDynamicDim(self, dim);
	},
	py::arg("dim"),
	"Returns whether the dim-th dimension of the given shaped type is "
	"dynamic.");
	c.def(
	"get_dim_size",
	[](PyShapedType &self, intptr_t dim) {
	self.requireHasRank();
	return mlirShapedTypeGetDimSize(self, dim);
	},
	py::arg("dim"),
	"Returns the dim-th dimension of the given ranked shaped type.");
	c.def_static(
	"is_dynamic_size",
	[](int64_t size) -> bool { return mlirShapedTypeIsDynamicSize(size); },
	py::arg("dim_size"),
	"Returns whether the given dimension size indicates a dynamic "
	"dimension.");
	c.def(
	"is_dynamic_stride_or_offset",
	[](PyShapedType &self, int64_t val) -> bool {
	self.requireHasRank();
	return mlirShapedTypeIsDynamicStrideOrOffset(val);
	},
	py::arg("dim_size"),
	"Returns whether the given value is used as a placeholder for dynamic "
	"strides and offsets in shaped types.");
	c.def_property_readonly(
	"shape",
	[](PyShapedType &self) {
	self.requireHasRank();

	std::vector<int64_t> shape;
	int64_t rank = mlirShapedTypeGetRank(self);
	shape.reserve(rank);
	for (int64_t i = 0; i < rank; ++i)
	shape.push_back(mlirShapedTypeGetDimSize(self, i));
	return shape;
	},
	"Returns the shape of the ranked shaped type as a list of integers.");
	}

	private:
	void requireHasRank() {
	if (!mlirShapedTypeHasRank(*this)) {
	throw SetPyError(
	PyExc_ValueError,
	"calling this method requires that the type has a rank.");
	}
	}
	};

	/// Vector Type subclass - VectorType.
	class PyVectorType : public PyConcreteType<PyVectorType, PyShapedType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAVector;
	static constexpr const char *pyClassName = "VectorType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](std::vector<int64_t> shape, PyType &elementType,
	DefaultingPyLocation loc) {
	MlirType t = mlirVectorTypeGetChecked(loc, shape.size(), shape.data(),
	elementType);
	// TODO: Rework error reporting once diagnostic engine is exposed
	// in C API.
	if (mlirTypeIsNull(t)) {
	throw SetPyError(
	PyExc_ValueError,
	Twine("invalid '") +
	py::repr(py::cast(elementType)).cast<std::string>() +
	"' and expected floating point or integer type.");
	}
	return PyVectorType(elementType.getContext(), t);
	},
	py::arg("shape"), py::arg("elementType"), py::arg("loc") = py::none(),
	"Create a vector type");
	}
	};

	/// Ranked Tensor Type subclass - RankedTensorType.
	class PyRankedTensorType
	: public PyConcreteType<PyRankedTensorType, PyShapedType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsARankedTensor;
	static constexpr const char *pyClassName = "RankedTensorType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](std::vector<int64_t> shape, PyType &elementType,
	llvm::Optional<PyAttribute> &encodingAttr,
	DefaultingPyLocation loc) {
	MlirType t = mlirRankedTensorTypeGetChecked(
	loc, shape.size(), shape.data(), elementType,
	encodingAttr ? encodingAttr->get() : mlirAttributeGetNull());
	// TODO: Rework error reporting once diagnostic engine is exposed
	// in C API.
	if (mlirTypeIsNull(t)) {
	throw SetPyError(
	PyExc_ValueError,
	Twine("invalid '") +
	py::repr(py::cast(elementType)).cast<std::string>() +
	"' and expected floating point, integer, vector or "
	"complex "
	"type.");
	}
	return PyRankedTensorType(elementType.getContext(), t);
	},
	py::arg("shape"), py::arg("element_type"),
	py::arg("encoding") = py::none(), py::arg("loc") = py::none(),
	"Create a ranked tensor type");
	c.def_property_readonly(
	"encoding",
	[](PyRankedTensorType &self) -> llvm::Optional<PyAttribute> {
	MlirAttribute encoding = mlirRankedTensorTypeGetEncoding(self.get());
	if (mlirAttributeIsNull(encoding))
	return llvm::None;
	return PyAttribute(self.getContext(), encoding);
	});
	}
	};

	/// Unranked Tensor Type subclass - UnrankedTensorType.
	class PyUnrankedTensorType
	: public PyConcreteType<PyUnrankedTensorType, PyShapedType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAUnrankedTensor;
	static constexpr const char *pyClassName = "UnrankedTensorType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](PyType &elementType, DefaultingPyLocation loc) {
	MlirType t = mlirUnrankedTensorTypeGetChecked(loc, elementType);
	// TODO: Rework error reporting once diagnostic engine is exposed
	// in C API.
	if (mlirTypeIsNull(t)) {
	throw SetPyError(
	PyExc_ValueError,
	Twine("invalid '") +
	py::repr(py::cast(elementType)).cast<std::string>() +
	"' and expected floating point, integer, vector or "
	"complex "
	"type.");
	}
	return PyUnrankedTensorType(elementType.getContext(), t);
	},
	py::arg("element_type"), py::arg("loc") = py::none(),
	"Create a unranked tensor type");
	}
	};

	/// Ranked MemRef Type subclass - MemRefType.
	class PyMemRefType : public PyConcreteType<PyMemRefType, PyShapedType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAMemRef;
	static constexpr const char *pyClassName = "MemRefType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](std::vector<int64_t> shape, PyType &elementType,
	PyAttribute layout, PyAttribute memorySpace,
	DefaultingPyLocation loc) {
	MlirAttribute layoutAttr = layout ? *layout : mlirAttributeGetNull();
	MlirAttribute memSpaceAttr =
	memorySpace ? *memorySpace : mlirAttributeGetNull();
	MlirType t =
	mlirMemRefTypeGetChecked(loc, elementType, shape.size(),
	shape.data(), layoutAttr, memSpaceAttr);
	// TODO: Rework error reporting once diagnostic engine is exposed
	// in C API.
	if (mlirTypeIsNull(t)) {
	throw SetPyError(
	PyExc_ValueError,
	Twine("invalid '") +
	py::repr(py::cast(elementType)).cast<std::string>() +
	"' and expected floating point, integer, vector or "
	"complex "
	"type.");
	}
	return PyMemRefType(elementType.getContext(), t);
	},
	py::arg("shape"), py::arg("element_type"),
	py::arg("layout") = py::none(), py::arg("memory_space") = py::none(),
	py::arg("loc") = py::none(), "Create a memref type")
	.def_property_readonly(
	"layout",
	[](PyMemRefType &self) -> PyAttribute {
	MlirAttribute layout = mlirMemRefTypeGetLayout(self);
	return PyAttribute(self.getContext(), layout);
	},
	"The layout of the MemRef type.")
	.def_property_readonly(
	"affine_map",
	[](PyMemRefType &self) -> PyAffineMap {
	MlirAffineMap map = mlirMemRefTypeGetAffineMap(self);
	return PyAffineMap(self.getContext(), map);
	},
	"The layout of the MemRef type as an affine map.")
	.def_property_readonly(
	"memory_space",
	[](PyMemRefType &self) -> PyAttribute {
	MlirAttribute a = mlirMemRefTypeGetMemorySpace(self);
	return PyAttribute(self.getContext(), a);
	},
	"Returns the memory space of the given MemRef type.");
	}
	};

	/// Unranked MemRef Type subclass - UnrankedMemRefType.
	class PyUnrankedMemRefType
	: public PyConcreteType<PyUnrankedMemRefType, PyShapedType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAUnrankedMemRef;
	static constexpr const char *pyClassName = "UnrankedMemRefType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](PyType &elementType, PyAttribute *memorySpace,
	DefaultingPyLocation loc) {
	MlirAttribute memSpaceAttr = {};
	if (memorySpace)
	memSpaceAttr = *memorySpace;

	MlirType t =
	mlirUnrankedMemRefTypeGetChecked(loc, elementType, memSpaceAttr);
	// TODO: Rework error reporting once diagnostic engine is exposed
	// in C API.
	if (mlirTypeIsNull(t)) {
	throw SetPyError(
	PyExc_ValueError,
	Twine("invalid '") +
	py::repr(py::cast(elementType)).cast<std::string>() +
	"' and expected floating point, integer, vector or "
	"complex "
	"type.");
	}
	return PyUnrankedMemRefType(elementType.getContext(), t);
	},
	py::arg("element_type"), py::arg("memory_space"),
	py::arg("loc") = py::none(), "Create a unranked memref type")
	.def_property_readonly(
	"memory_space",
	[](PyUnrankedMemRefType &self) -> PyAttribute {
	MlirAttribute a = mlirMemRefTypeGetMemorySpace(self);
	return PyAttribute(self.getContext(), a);
	},
	"Returns the memory space of the given Unranked MemRef type.");
	}
	};

	/// Tuple Type subclass - TupleType.
	class PyTupleType : public PyConcreteType<PyTupleType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsATuple;
	static constexpr const char *pyClassName = "TupleType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get_tuple",
	[](py::list elementList, DefaultingPyMlirContext context) {
	intptr_t num = py::len(elementList);
	// Mapping py::list to SmallVector.
	SmallVector<MlirType, 4> elements;
	for (auto element : elementList)
	elements.push_back(element.cast<PyType>());
	MlirType t = mlirTupleTypeGet(context->get(), num, elements.data());
	return PyTupleType(context->getRef(), t);
	},
	py::arg("elements"), py::arg("context") = py::none(),
	"Create a tuple type");
	c.def(
	"get_type",
	[](PyTupleType &self, intptr_t pos) -> PyType {
	MlirType t = mlirTupleTypeGetType(self, pos);
	return PyType(self.getContext(), t);
	},
	py::arg("pos"), "Returns the pos-th type in the tuple type.");
	c.def_property_readonly(
	"num_types",
	[](PyTupleType &self) -> intptr_t {
	return mlirTupleTypeGetNumTypes(self);
	},
	"Returns the number of types contained in a tuple.");
	}
	};

	/// Function type.
	class PyFunctionType : public PyConcreteType<PyFunctionType> {
	public:
	static constexpr IsAFunctionTy isaFunction = mlirTypeIsAFunction;
	static constexpr const char *pyClassName = "FunctionType";
	using PyConcreteType::PyConcreteType;

	static void bindDerived(ClassTy &c) {
	c.def_static(
	"get",
	[](std::vector<PyType> inputs, std::vector<PyType> results,
	DefaultingPyMlirContext context) {
	SmallVector<MlirType, 4> inputsRaw(inputs.begin(), inputs.end());
	SmallVector<MlirType, 4> resultsRaw(results.begin(), results.end());
	MlirType t = mlirFunctionTypeGet(context->get(), inputsRaw.size(),
	inputsRaw.data(), resultsRaw.size(),
	resultsRaw.data());
	return PyFunctionType(context->getRef(), t);
	},
	py::arg("inputs"), py::arg("results"), py::arg("context") = py::none(),
	"Gets a FunctionType from a list of input and result types");
	c.def_property_readonly(
	"inputs",
	[](PyFunctionType &self) {
	MlirType t = self;
	auto contextRef = self.getContext();
	py::list types;
	for (intptr_t i = 0, e = mlirFunctionTypeGetNumInputs(self); i < e;
	++i) {
	types.append(PyType(contextRef, mlirFunctionTypeGetInput(t, i)));
	}
	return types;
	},
	"Returns the list of input types in the FunctionType.");
	c.def_property_readonly(
	"results",
	[](PyFunctionType &self) {
	auto contextRef = self.getContext();
	py::list types;
	for (intptr_t i = 0, e = mlirFunctionTypeGetNumResults(self); i < e;
	++i) {
	types.append(
	PyType(contextRef, mlirFunctionTypeGetResult(self, i)));
	}
	return types;
	},
	"Returns the list of result types in the FunctionType.");
	}
	};

	} // namespace

	void mlir::python::populateIRTypes(py::module &m) {
	PyIntegerType::bind(m);
	PyIndexType::bind(m);
	PyBF16Type::bind(m);
	PyF16Type::bind(m);
	PyF32Type::bind(m);
	PyF64Type::bind(m);
	PyNoneType::bind(m);
	PyComplexType::bind(m);
	PyShapedType::bind(m);
	PyVectorType::bind(m);
	PyRankedTensorType::bind(m);
	PyUnrankedTensorType::bind(m);
	PyMemRefType::bind(m);
	PyUnrankedMemRefType::bind(m);
	PyTupleType::bind(m);
	PyFunctionType::bind(m);
	}