//===- ConvertStandardToSPIRV.cpp - Standard to SPIR-V dialect conversion--===// // // 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 // //===----------------------------------------------------------------------===// // // This file implements patterns to convert standard ops to SPIR-V ops. // //===----------------------------------------------------------------------===// #include "mlir/Dialect/SPIRV/LayoutUtils.h" #include "mlir/Dialect/SPIRV/SPIRVDialect.h" #include "mlir/Dialect/SPIRV/SPIRVLowering.h" #include "mlir/Dialect/SPIRV/SPIRVOps.h" #include "mlir/Dialect/StandardOps/IR/Ops.h" #include "mlir/IR/AffineMap.h" #include "mlir/Support/LogicalResult.h" #include "llvm/ADT/SetVector.h" #include "llvm/Support/Debug.h" #define DEBUG_TYPE "std-to-spirv-pattern" using namespace mlir; //===----------------------------------------------------------------------===// // Utility functions //===----------------------------------------------------------------------===// /// Returns true if the given `type` is a boolean scalar or vector type. static bool isBoolScalarOrVector(Type type) { if (type.isInteger(1)) return true; if (auto vecType = type.dyn_cast()) return vecType.getElementType().isInteger(1); return false; } /// Converts the given `srcAttr` into a boolean attribute if it holds an /// integral value. Returns null attribute if conversion fails. static BoolAttr convertBoolAttr(Attribute srcAttr, Builder builder) { if (auto boolAttr = srcAttr.dyn_cast()) return boolAttr; if (auto intAttr = srcAttr.dyn_cast()) return builder.getBoolAttr(intAttr.getValue().getBoolValue()); return BoolAttr(); } /// Converts the given `srcAttr` to a new attribute of the given `dstType`. /// Returns null attribute if conversion fails. static IntegerAttr convertIntegerAttr(IntegerAttr srcAttr, IntegerType dstType, Builder builder) { // If the source number uses less active bits than the target bitwidth, then // it should be safe to convert. if (srcAttr.getValue().isIntN(dstType.getWidth())) return builder.getIntegerAttr(dstType, srcAttr.getInt()); // XXX: Try again by interpreting the source number as a signed value. // Although integers in the standard dialect are signless, they can represent // a signed number. It's the operation decides how to interpret. This is // dangerous, but it seems there is no good way of handling this if we still // want to change the bitwidth. Emit a message at least. if (srcAttr.getValue().isSignedIntN(dstType.getWidth())) { auto dstAttr = builder.getIntegerAttr(dstType, srcAttr.getInt()); LLVM_DEBUG(llvm::dbgs() << "attribute '" << srcAttr << "' converted to '" << dstAttr << "' for type '" << dstType << "'\n"); return dstAttr; } LLVM_DEBUG(llvm::dbgs() << "attribute '" << srcAttr << "' illegal: cannot fit into target type '" << dstType << "'\n"); return IntegerAttr(); } /// Converts the given `srcAttr` to a new attribute of the given `dstType`. /// Returns null attribute if `dstType` is not 32-bit or conversion fails. static FloatAttr convertFloatAttr(FloatAttr srcAttr, FloatType dstType, Builder builder) { // Only support converting to float for now. if (!dstType.isF32()) return FloatAttr(); // Try to convert the source floating-point number to single precision. APFloat dstVal = srcAttr.getValue(); bool losesInfo = false; APFloat::opStatus status = dstVal.convert(APFloat::IEEEsingle(), APFloat::rmTowardZero, &losesInfo); if (status != APFloat::opOK || losesInfo) { LLVM_DEBUG(llvm::dbgs() << srcAttr << " illegal: cannot fit into converted type '" << dstType << "'\n"); return FloatAttr(); } return builder.getF32FloatAttr(dstVal.convertToFloat()); } /// Returns the offset of the value in `targetBits` representation. `srcIdx` is /// an index into a 1-D array with each element having `sourceBits`. When /// accessing an element in the array treating as having elements of /// `targetBits`, multiple values are loaded in the same time. The method /// returns the offset where the `srcIdx` locates in the value. For example, if /// `sourceBits` equals to 8 and `targetBits` equals to 32, the x-th element is /// located at (x % 4) * 8. Because there are four elements in one i32, and one /// element has 8 bits. static Value getOffsetForBitwidth(Location loc, Value srcIdx, int sourceBits, int targetBits, OpBuilder &builder) { assert(targetBits % sourceBits == 0); IntegerType targetType = builder.getIntegerType(targetBits); IntegerAttr idxAttr = builder.getIntegerAttr(targetType, targetBits / sourceBits); auto idx = builder.create(loc, targetType, idxAttr); IntegerAttr srcBitsAttr = builder.getIntegerAttr(targetType, sourceBits); auto srcBitsValue = builder.create(loc, targetType, srcBitsAttr); auto m = builder.create(loc, srcIdx, idx); return builder.create(loc, targetType, m, srcBitsValue); } /// Returns an adjusted spirv::AccessChainOp. Based on the /// extension/capabilities, certain integer bitwidths `sourceBits` might not be /// supported. During conversion if a memref of an unsupported type is used, /// load/stores to this memref need to be modified to use a supported higher /// bitwidth `targetBits` and extracting the required bits. For an accessing a /// 1D array (spv.array or spv.rt_array), the last index is modified to load the /// bits needed. The extraction of the actual bits needed are handled /// separately. Note that this only works for a 1-D tensor. static Value adjustAccessChainForBitwidth(SPIRVTypeConverter &typeConverter, spirv::AccessChainOp op, int sourceBits, int targetBits, OpBuilder &builder) { assert(targetBits % sourceBits == 0); const auto loc = op.getLoc(); IntegerType targetType = builder.getIntegerType(targetBits); IntegerAttr attr = builder.getIntegerAttr(targetType, targetBits / sourceBits); auto idx = builder.create(loc, targetType, attr); auto lastDim = op.getOperation()->getOperand(op.getNumOperands() - 1); auto indices = llvm::to_vector<4>(op.indices()); // There are two elements if this is a 1-D tensor. assert(indices.size() == 2); indices.back() = builder.create(loc, lastDim, idx); Type t = typeConverter.convertType(op.component_ptr().getType()); return builder.create(loc, t, op.base_ptr(), indices); } //===----------------------------------------------------------------------===// // Operation conversion //===----------------------------------------------------------------------===// // Note that DRR cannot be used for the patterns in this file: we may need to // convert type along the way, which requires ConversionPattern. DRR generates // normal RewritePattern. namespace { /// Converts unary and binary standard operations to SPIR-V operations. template class UnaryAndBinaryOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(StdOp operation, ArrayRef operands, ConversionPatternRewriter &rewriter) const override { assert(operands.size() <= 2); auto dstType = this->typeConverter.convertType(operation.getType()); if (!dstType) return failure(); rewriter.template replaceOpWithNewOp(operation, dstType, operands, ArrayRef()); return success(); } }; /// Converts bitwise standard operations to SPIR-V operations. This is a special /// pattern other than the BinaryOpPatternPattern because if the operands are /// boolean values, SPIR-V uses different operations (`SPIRVLogicalOp`). For /// non-boolean operands, SPIR-V should use `SPIRVBitwiseOp`. template class BitwiseOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(StdOp operation, ArrayRef operands, ConversionPatternRewriter &rewriter) const override { assert(operands.size() == 2); auto dstType = this->typeConverter.convertType(operation.getResult().getType()); if (!dstType) return failure(); if (isBoolScalarOrVector(operands.front().getType())) { rewriter.template replaceOpWithNewOp( operation, dstType, operands, ArrayRef()); } else { rewriter.template replaceOpWithNewOp( operation, dstType, operands, ArrayRef()); } return success(); } }; /// Converts composite std.constant operation to spv.constant. class ConstantCompositeOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(ConstantOp constOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const override; }; /// Converts scalar std.constant operation to spv.constant. class ConstantScalarOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(ConstantOp constOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const override; }; /// Converts floating-point comparison operations to SPIR-V ops. class CmpFOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(CmpFOp cmpFOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const override; }; /// Converts integer compare operation on i1 type opearnds to SPIR-V ops. class BoolCmpIOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(CmpIOp cmpIOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const override; }; /// Converts integer compare operation to SPIR-V ops. class CmpIOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(CmpIOp cmpIOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const override; }; /// Converts std.load to spv.Load. class IntLoadOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(LoadOp loadOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const override; }; /// Converts std.load to spv.Load. class LoadOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(LoadOp loadOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const override; }; /// Converts std.return to spv.Return. class ReturnOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(ReturnOp returnOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const override; }; /// Converts std.select to spv.Select. class SelectOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(SelectOp op, ArrayRef operands, ConversionPatternRewriter &rewriter) const override; }; /// Converts std.store to spv.Store. class StoreOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(StoreOp storeOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const override; }; /// Converts type-casting standard operations to SPIR-V operations. template class TypeCastingOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(StdOp operation, ArrayRef operands, ConversionPatternRewriter &rewriter) const override { assert(operands.size() == 1); auto dstType = this->typeConverter.convertType(operation.getResult().getType()); if (dstType == operands.front().getType()) { // Due to type conversion, we are seeing the same source and target type. // Then we can just erase this operation by forwarding its operand. rewriter.replaceOp(operation, operands.front()); } else { rewriter.template replaceOpWithNewOp( operation, dstType, operands, ArrayRef()); } return success(); } }; /// Converts std.xor to SPIR-V operations. class XOrOpPattern final : public SPIRVOpLowering { public: using SPIRVOpLowering::SPIRVOpLowering; LogicalResult matchAndRewrite(XOrOp xorOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const override; }; } // namespace //===----------------------------------------------------------------------===// // ConstantOp with composite type. //===----------------------------------------------------------------------===// LogicalResult ConstantCompositeOpPattern::matchAndRewrite( ConstantOp constOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const { auto srcType = constOp.getType().dyn_cast(); if (!srcType) return failure(); // std.constant should only have vector or tenor types. assert(srcType.isa() || srcType.isa()); auto dstType = typeConverter.convertType(srcType); if (!dstType) return failure(); auto dstElementsAttr = constOp.value().dyn_cast(); ShapedType dstAttrType = dstElementsAttr.getType(); if (!dstElementsAttr) return failure(); // If the composite type has more than one dimensions, perform linearization. if (srcType.getRank() > 1) { if (srcType.isa()) { dstAttrType = RankedTensorType::get(srcType.getNumElements(), srcType.getElementType()); dstElementsAttr = dstElementsAttr.reshape(dstAttrType); } else { // TODO(antiagainst): add support for large vectors. return failure(); } } Type srcElemType = srcType.getElementType(); Type dstElemType; // Tensor types are converted to SPIR-V array types; vector types are // converted to SPIR-V vector/array types. if (auto arrayType = dstType.dyn_cast()) dstElemType = arrayType.getElementType(); else dstElemType = dstType.cast().getElementType(); // If the source and destination element types are different, perform // attribute conversion. if (srcElemType != dstElemType) { SmallVector elements; if (srcElemType.isa()) { for (Attribute srcAttr : dstElementsAttr.getAttributeValues()) { FloatAttr dstAttr = convertFloatAttr( srcAttr.cast(), dstElemType.cast(), rewriter); if (!dstAttr) return failure(); elements.push_back(dstAttr); } } else if (srcElemType.isInteger(1)) { return failure(); } else { for (Attribute srcAttr : dstElementsAttr.getAttributeValues()) { IntegerAttr dstAttr = convertIntegerAttr(srcAttr.cast(), dstElemType.cast(), rewriter); if (!dstAttr) return failure(); elements.push_back(dstAttr); } } // Unfortunately, we cannot use dialect-specific types for element // attributes; element attributes only works with standard types. So we need // to prepare another converted standard types for the destination elements // attribute. if (dstAttrType.isa()) dstAttrType = RankedTensorType::get(dstAttrType.getShape(), dstElemType); else dstAttrType = VectorType::get(dstAttrType.getShape(), dstElemType); dstElementsAttr = DenseElementsAttr::get(dstAttrType, elements); } rewriter.replaceOpWithNewOp(constOp, dstType, dstElementsAttr); return success(); } //===----------------------------------------------------------------------===// // ConstantOp with scalar type. //===----------------------------------------------------------------------===// LogicalResult ConstantScalarOpPattern::matchAndRewrite( ConstantOp constOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const { Type srcType = constOp.getType(); if (!srcType.isIntOrIndexOrFloat()) return failure(); Type dstType = typeConverter.convertType(srcType); if (!dstType) return failure(); // Floating-point types. if (srcType.isa()) { auto srcAttr = constOp.value().cast(); auto dstAttr = srcAttr; // Floating-point types not supported in the target environment are all // converted to float type. if (srcType != dstType) { dstAttr = convertFloatAttr(srcAttr, dstType.cast(), rewriter); if (!dstAttr) return failure(); } rewriter.replaceOpWithNewOp(constOp, dstType, dstAttr); return success(); } // Bool type. if (srcType.isInteger(1)) { // std.constant can use 0/1 instead of true/false for i1 values. We need to // handle that here. auto dstAttr = convertBoolAttr(constOp.value(), rewriter); if (!dstAttr) return failure(); rewriter.replaceOpWithNewOp(constOp, dstType, dstAttr); return success(); } // IndexType or IntegerType. Index values are converted to 32-bit integer // values when converting to SPIR-V. auto srcAttr = constOp.value().cast(); auto dstAttr = convertIntegerAttr(srcAttr, dstType.cast(), rewriter); if (!dstAttr) return failure(); rewriter.replaceOpWithNewOp(constOp, dstType, dstAttr); return success(); } //===----------------------------------------------------------------------===// // CmpFOp //===----------------------------------------------------------------------===// LogicalResult CmpFOpPattern::matchAndRewrite(CmpFOp cmpFOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const { CmpFOpOperandAdaptor cmpFOpOperands(operands); switch (cmpFOp.getPredicate()) { #define DISPATCH(cmpPredicate, spirvOp) \ case cmpPredicate: \ rewriter.replaceOpWithNewOp(cmpFOp, cmpFOp.getResult().getType(), \ cmpFOpOperands.lhs(), \ cmpFOpOperands.rhs()); \ return success(); // Ordered. DISPATCH(CmpFPredicate::OEQ, spirv::FOrdEqualOp); DISPATCH(CmpFPredicate::OGT, spirv::FOrdGreaterThanOp); DISPATCH(CmpFPredicate::OGE, spirv::FOrdGreaterThanEqualOp); DISPATCH(CmpFPredicate::OLT, spirv::FOrdLessThanOp); DISPATCH(CmpFPredicate::OLE, spirv::FOrdLessThanEqualOp); DISPATCH(CmpFPredicate::ONE, spirv::FOrdNotEqualOp); // Unordered. DISPATCH(CmpFPredicate::UEQ, spirv::FUnordEqualOp); DISPATCH(CmpFPredicate::UGT, spirv::FUnordGreaterThanOp); DISPATCH(CmpFPredicate::UGE, spirv::FUnordGreaterThanEqualOp); DISPATCH(CmpFPredicate::ULT, spirv::FUnordLessThanOp); DISPATCH(CmpFPredicate::ULE, spirv::FUnordLessThanEqualOp); DISPATCH(CmpFPredicate::UNE, spirv::FUnordNotEqualOp); #undef DISPATCH default: break; } return failure(); } //===----------------------------------------------------------------------===// // CmpIOp //===----------------------------------------------------------------------===// LogicalResult BoolCmpIOpPattern::matchAndRewrite(CmpIOp cmpIOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const { CmpIOpOperandAdaptor cmpIOpOperands(operands); Type operandType = cmpIOp.lhs().getType(); if (!operandType.isa() || operandType.cast().getWidth() != 1) return failure(); switch (cmpIOp.getPredicate()) { #define DISPATCH(cmpPredicate, spirvOp) \ case cmpPredicate: \ rewriter.replaceOpWithNewOp(cmpIOp, cmpIOp.getResult().getType(), \ cmpIOpOperands.lhs(), \ cmpIOpOperands.rhs()); \ return success(); DISPATCH(CmpIPredicate::eq, spirv::LogicalEqualOp); DISPATCH(CmpIPredicate::ne, spirv::LogicalNotEqualOp); #undef DISPATCH default:; } return failure(); } LogicalResult CmpIOpPattern::matchAndRewrite(CmpIOp cmpIOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const { CmpIOpOperandAdaptor cmpIOpOperands(operands); Type operandType = cmpIOp.lhs().getType(); if (operandType.isa() && operandType.cast().getWidth() == 1) return failure(); switch (cmpIOp.getPredicate()) { #define DISPATCH(cmpPredicate, spirvOp) \ case cmpPredicate: \ rewriter.replaceOpWithNewOp(cmpIOp, cmpIOp.getResult().getType(), \ cmpIOpOperands.lhs(), \ cmpIOpOperands.rhs()); \ return success(); DISPATCH(CmpIPredicate::eq, spirv::IEqualOp); DISPATCH(CmpIPredicate::ne, spirv::INotEqualOp); DISPATCH(CmpIPredicate::slt, spirv::SLessThanOp); DISPATCH(CmpIPredicate::sle, spirv::SLessThanEqualOp); DISPATCH(CmpIPredicate::sgt, spirv::SGreaterThanOp); DISPATCH(CmpIPredicate::sge, spirv::SGreaterThanEqualOp); DISPATCH(CmpIPredicate::ult, spirv::ULessThanOp); DISPATCH(CmpIPredicate::ule, spirv::ULessThanEqualOp); DISPATCH(CmpIPredicate::ugt, spirv::UGreaterThanOp); DISPATCH(CmpIPredicate::uge, spirv::UGreaterThanEqualOp); #undef DISPATCH } return failure(); } //===----------------------------------------------------------------------===// // LoadOp //===----------------------------------------------------------------------===// LogicalResult IntLoadOpPattern::matchAndRewrite(LoadOp loadOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const { LoadOpOperandAdaptor loadOperands(operands); auto loc = loadOp.getLoc(); auto memrefType = loadOp.memref().getType().cast(); if (!memrefType.getElementType().isSignlessInteger()) return failure(); spirv::AccessChainOp accessChainOp = spirv::getElementPtr(typeConverter, memrefType, loadOperands.memref(), loadOperands.indices(), loc, rewriter); int srcBits = memrefType.getElementType().getIntOrFloatBitWidth(); auto dstType = typeConverter.convertType(memrefType) .cast() .getPointeeType() .cast() .getElementType(0) .cast() .getElementType(); int dstBits = dstType.getIntOrFloatBitWidth(); assert(dstBits % srcBits == 0); // If the rewrited load op has the same bit width, use the loading value // directly. if (srcBits == dstBits) { rewriter.replaceOpWithNewOp(loadOp, accessChainOp.getResult()); return success(); } // Assume that getElementPtr() works linearizely. If it's a scalar, the method // still returns a linearized accessing. If the accessing is not linearized, // there will be offset issues. assert(accessChainOp.indices().size() == 2); Value adjustedPtr = adjustAccessChainForBitwidth(typeConverter, accessChainOp, srcBits, dstBits, rewriter); Value spvLoadOp = rewriter.create( loc, dstType, adjustedPtr, loadOp.getAttrOfType( spirv::attributeName()), loadOp.getAttrOfType("alignment")); // Shift the bits to the rightmost. // ____XXXX________ -> ____________XXXX Value lastDim = accessChainOp.getOperation()->getOperand( accessChainOp.getNumOperands() - 1); Value offset = getOffsetForBitwidth(loc, lastDim, srcBits, dstBits, rewriter); Value result = rewriter.create( loc, spvLoadOp.getType(), spvLoadOp, offset); // Apply the mask to extract corresponding bits. Value mask = rewriter.create( loc, dstType, rewriter.getIntegerAttr(dstType, (1 << srcBits) - 1)); result = rewriter.create(loc, dstType, result, mask); rewriter.replaceOp(loadOp, result); assert(accessChainOp.use_empty()); rewriter.eraseOp(accessChainOp); return success(); } LogicalResult LoadOpPattern::matchAndRewrite(LoadOp loadOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const { LoadOpOperandAdaptor loadOperands(operands); auto memrefType = loadOp.memref().getType().cast(); if (memrefType.getElementType().isSignlessInteger()) return failure(); auto loadPtr = spirv::getElementPtr(typeConverter, memrefType, loadOperands.memref(), loadOperands.indices(), loadOp.getLoc(), rewriter); rewriter.replaceOpWithNewOp(loadOp, loadPtr); return success(); } //===----------------------------------------------------------------------===// // ReturnOp //===----------------------------------------------------------------------===// LogicalResult ReturnOpPattern::matchAndRewrite(ReturnOp returnOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const { if (returnOp.getNumOperands()) { return failure(); } rewriter.replaceOpWithNewOp(returnOp); return success(); } //===----------------------------------------------------------------------===// // SelectOp //===----------------------------------------------------------------------===// LogicalResult SelectOpPattern::matchAndRewrite(SelectOp op, ArrayRef operands, ConversionPatternRewriter &rewriter) const { SelectOpOperandAdaptor selectOperands(operands); rewriter.replaceOpWithNewOp(op, selectOperands.condition(), selectOperands.true_value(), selectOperands.false_value()); return success(); } //===----------------------------------------------------------------------===// // StoreOp //===----------------------------------------------------------------------===// LogicalResult StoreOpPattern::matchAndRewrite(StoreOp storeOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const { StoreOpOperandAdaptor storeOperands(operands); auto storePtr = spirv::getElementPtr( typeConverter, storeOp.memref().getType().cast(), storeOperands.memref(), storeOperands.indices(), storeOp.getLoc(), rewriter); rewriter.replaceOpWithNewOp(storeOp, storePtr, storeOperands.value()); return success(); } //===----------------------------------------------------------------------===// // XorOp //===----------------------------------------------------------------------===// LogicalResult XOrOpPattern::matchAndRewrite(XOrOp xorOp, ArrayRef operands, ConversionPatternRewriter &rewriter) const { assert(operands.size() == 2); if (isBoolScalarOrVector(operands.front().getType())) return failure(); auto dstType = typeConverter.convertType(xorOp.getType()); if (!dstType) return failure(); rewriter.replaceOpWithNewOp(xorOp, dstType, operands, ArrayRef()); return success(); } //===----------------------------------------------------------------------===// // Pattern population //===----------------------------------------------------------------------===// namespace mlir { void populateStandardToSPIRVPatterns(MLIRContext *context, SPIRVTypeConverter &typeConverter, OwningRewritePatternList &patterns) { patterns.insert< UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, UnaryAndBinaryOpPattern, BitwiseOpPattern, BitwiseOpPattern, BoolCmpIOpPattern, ConstantCompositeOpPattern, ConstantScalarOpPattern, CmpFOpPattern, CmpIOpPattern, IntLoadOpPattern, LoadOpPattern, ReturnOpPattern, SelectOpPattern, StoreOpPattern, TypeCastingOpPattern, TypeCastingOpPattern, TypeCastingOpPattern, TypeCastingOpPattern, TypeCastingOpPattern, XOrOpPattern>( context, typeConverter); } } // namespace mlir