//===-- mlir-c/AffineExpr.h - C API for MLIR Affine Expressions ---*- C -*-===// // // 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 // //===----------------------------------------------------------------------===// #ifndef MLIR_C_AFFINEEXPR_H #define MLIR_C_AFFINEEXPR_H #include "mlir-c/AffineMap.h" #include "mlir-c/IR.h" #ifdef __cplusplus extern "C" { #endif //===----------------------------------------------------------------------===// /** Opaque type declarations. * * Types are exposed to C bindings as structs containing opaque pointers. They * are not supposed to be inspected from C. This allows the underlying * representation to change without affecting the API users. The use of structs * instead of typedefs enables some type safety as structs are not implicitly * convertible to each other. * * Instances of these types may or may not own the underlying object. The * ownership semantics is defined by how an instance of the type was obtained. */ //===----------------------------------------------------------------------===// #define DEFINE_C_API_STRUCT(name, storage) \ struct name { \ storage *ptr; \ }; \ typedef struct name name DEFINE_C_API_STRUCT(MlirAffineExpr, const void); #undef DEFINE_C_API_STRUCT /// Gets the context that owns the affine expression. MLIR_CAPI_EXPORTED MlirContext mlirAffineExprGetContext(MlirAffineExpr affineExpr); /** Prints an affine expression by sending chunks of the string representation * and forwarding `userData to `callback`. Note that the callback may be called * several times with consecutive chunks of the string. */ MLIR_CAPI_EXPORTED void mlirAffineExprPrint(MlirAffineExpr affineExpr, MlirStringCallback callback, void *userData); /// Prints the affine expression to the standard error stream. MLIR_CAPI_EXPORTED void mlirAffineExprDump(MlirAffineExpr affineExpr); /** Checks whether the given affine expression is made out of only symbols and * constants. */ MLIR_CAPI_EXPORTED bool mlirAffineExprIsSymbolicOrConstant(MlirAffineExpr affineExpr); /** Checks whether the given affine expression is a pure affine expression, i.e. * mul, floordiv, ceildic, and mod is only allowed w.r.t constants. */ MLIR_CAPI_EXPORTED bool mlirAffineExprIsPureAffine(MlirAffineExpr affineExpr); /** Returns the greatest known integral divisor of this affine expression. The * result is always positive. */ MLIR_CAPI_EXPORTED int64_t mlirAffineExprGetLargestKnownDivisor(MlirAffineExpr affineExpr); /// Checks whether the given affine expression is a multiple of 'factor'. MLIR_CAPI_EXPORTED bool mlirAffineExprIsMultipleOf(MlirAffineExpr affineExpr, int64_t factor); /** Checks whether the given affine expression involves AffineDimExpr * 'position'. */ MLIR_CAPI_EXPORTED bool mlirAffineExprIsFunctionOfDim(MlirAffineExpr affineExpr, intptr_t position); //===----------------------------------------------------------------------===// // Affine Dimension Expression. //===----------------------------------------------------------------------===// /// Creates an affine dimension expression with 'position' in the context. MLIR_CAPI_EXPORTED MlirAffineExpr mlirAffineDimExprGet(MlirContext ctx, intptr_t position); /// Returns the position of the given affine dimension expression. MLIR_CAPI_EXPORTED intptr_t mlirAffineDimExprGetPosition(MlirAffineExpr affineExpr); //===----------------------------------------------------------------------===// // Affine Symbol Expression. //===----------------------------------------------------------------------===// /// Creates an affine symbol expression with 'position' in the context. MLIR_CAPI_EXPORTED MlirAffineExpr mlirAffineSymbolExprGet(MlirContext ctx, intptr_t position); /// Returns the position of the given affine symbol expression. MLIR_CAPI_EXPORTED intptr_t mlirAffineSymbolExprGetPosition(MlirAffineExpr affineExpr); //===----------------------------------------------------------------------===// // Affine Constant Expression. //===----------------------------------------------------------------------===// /// Creates an affine constant expression with 'constant' in the context. MLIR_CAPI_EXPORTED MlirAffineExpr mlirAffineConstantExprGet(MlirContext ctx, int64_t constant); /// Returns the value of the given affine constant expression. MLIR_CAPI_EXPORTED int64_t mlirAffineConstantExprGetValue(MlirAffineExpr affineExpr); //===----------------------------------------------------------------------===// // Affine Add Expression. //===----------------------------------------------------------------------===// /// Checks whether the given affine expression is an add expression. MLIR_CAPI_EXPORTED bool mlirAffineExprIsAAdd(MlirAffineExpr affineExpr); /// Creates an affine add expression with 'lhs' and 'rhs'. MLIR_CAPI_EXPORTED MlirAffineExpr mlirAffineAddExprGet(MlirAffineExpr lhs, MlirAffineExpr rhs); //===----------------------------------------------------------------------===// // Affine Mul Expression. //===----------------------------------------------------------------------===// /// Checks whether the given affine expression is an mul expression. MLIR_CAPI_EXPORTED bool mlirAffineExprIsAMul(MlirAffineExpr affineExpr); /// Creates an affine mul expression with 'lhs' and 'rhs'. MLIR_CAPI_EXPORTED MlirAffineExpr mlirAffineMulExprGet(MlirAffineExpr lhs, MlirAffineExpr rhs); //===----------------------------------------------------------------------===// // Affine Mod Expression. //===----------------------------------------------------------------------===// /// Checks whether the given affine expression is an mod expression. MLIR_CAPI_EXPORTED bool mlirAffineExprIsAMod(MlirAffineExpr affineExpr); /// Creates an affine mod expression with 'lhs' and 'rhs'. MLIR_CAPI_EXPORTED MlirAffineExpr mlirAffineModExprGet(MlirAffineExpr lhs, MlirAffineExpr rhs); //===----------------------------------------------------------------------===// // Affine FloorDiv Expression. //===----------------------------------------------------------------------===// /// Checks whether the given affine expression is an floordiv expression. MLIR_CAPI_EXPORTED bool mlirAffineExprIsAFloorDiv(MlirAffineExpr affineExpr); /// Creates an affine floordiv expression with 'lhs' and 'rhs'. MLIR_CAPI_EXPORTED MlirAffineExpr mlirAffineFloorDivExprGet(MlirAffineExpr lhs, MlirAffineExpr rhs); //===----------------------------------------------------------------------===// // Affine CeilDiv Expression. //===----------------------------------------------------------------------===// /// Checks whether the given affine expression is an ceildiv expression. MLIR_CAPI_EXPORTED bool mlirAffineExprIsACeilDiv(MlirAffineExpr affineExpr); /// Creates an affine ceildiv expression with 'lhs' and 'rhs'. MLIR_CAPI_EXPORTED MlirAffineExpr mlirAffineCeilDivExprGet(MlirAffineExpr lhs, MlirAffineExpr rhs); //===----------------------------------------------------------------------===// // Affine Binary Operation Expression. //===----------------------------------------------------------------------===// /** Returns the left hand side affine expression of the given affine binary * operation expression. */ MLIR_CAPI_EXPORTED MlirAffineExpr mlirAffineBinaryOpExprGetLHS(MlirAffineExpr affineExpr); /** Returns the right hand side affine expression of the given affine binary * operation expression. */ MLIR_CAPI_EXPORTED MlirAffineExpr mlirAffineBinaryOpExprGetRHS(MlirAffineExpr affineExpr); #ifdef __cplusplus } #endif #endif // MLIR_C_AFFINEEXPR_H