Merge branch 'master' into matmul-shape

src/builder/frontend_dialect_transformer.cpp

@@ -226,7 +226,7 @@ private:
     std::string _name;
 
     mlir::NamedAttribute operator()(int64_t const &r) {
-      auto val = _builder.getI32IntegerAttr(r);
+      auto val = _builder.getI64IntegerAttr(r);
       return _builder.getNamedAttr(_name, val);
     }
 
@@ -288,21 +288,12 @@ private:
   }
 
   std::vector<mlir::NamedAttribute> ImportNodeAttributes(
-      const onnx::NodeProto &node,
-      std::initializer_list<std::pair<std::string, AttrValueType>>
-          defaultAttrList) {
+      const onnx::NodeProto &node) {
     std::vector<mlir::NamedAttribute> attributes;
-    std::set<std::string> definedAttributeSet;
     for (int i = 0; i < node.attribute_size(); ++i) {
       auto attr = node.attribute(i);
       auto nameValPair = convertAttributeProtoToNameValuePair(attr);
       attributes.push_back(convertNameValuePairToNamedAttribute(nameValPair));
-      definedAttributeSet.insert(attr.name());
-    }
-    for (const auto &defaultAttr : defaultAttrList) {
-      if (definedAttributeSet.find(defaultAttr.first) ==
-          definedAttributeSet.end())
-        attributes.push_back(convertNameValuePairToNamedAttribute(defaultAttr));
     }
     return attributes;
   }
@@ -340,9 +331,7 @@ private:
    */
   template <typename T>
   void
-  ImportNodeOneOut(const onnx::NodeProto &node, int nIn, int nOut,
-                   std::initializer_list<std::pair<std::string, AttrValueType>>
-                       defaultAttrList) {
+  ImportNodeOneOut(const onnx::NodeProto &node, int nIn, int nOut) {
     std::vector<mlir::Value> inputs;
     for (const auto &item : node.input()) {
       if (frontend_symbols_.ContainKey(legalize_name(item))) {
@@ -356,7 +345,7 @@ private:
           mlir::UnrankedTensorType::get(builder_.getF32Type()));
     }
 
-    auto attributes = ImportNodeAttributes(node, defaultAttrList);
+    auto attributes = ImportNodeAttributes(node);
 
     llvm::StringRef OpName = node.op_type();
 
@@ -372,9 +361,7 @@ private:
 
   template <typename T>
   void ImportNodeMultipleOuts(
-      const onnx::NodeProto &node, int nIn, int nOut,
-      std::initializer_list<std::pair<std::string, AttrValueType>>
-          defaultAttrList) {
+      const onnx::NodeProto &node, int nIn, int nOut) {
     std::vector<mlir::Value> inputs;
     for (const auto &item : node.input()) {
       if (frontend_symbols_.ContainKey(legalize_name(item))) {
@@ -388,7 +375,7 @@ private:
           mlir::UnrankedTensorType::get(builder_.getF32Type()));
     }
 
-    auto attributes = ImportNodeAttributes(node, defaultAttrList);
+    auto attributes = ImportNodeAttributes(node);
 
     llvm::StringRef OpName = node.op_type();
 
@@ -410,9 +397,7 @@ private:
    * a specialized function is used
    */
   void
-  ImportNodeConv(onnx::NodeProto node, int nIn, int nOut,
-                 std::initializer_list<std::pair<std::string, AttrValueType>>
-                     defaultAttrList) {
+  ImportNodeConv(onnx::NodeProto node, int nIn, int nOut) {
     // Conv has attribute dilations, kernel_shape, pads, the default value of
     // which  is determined by the shape of first argument. However, since the
     // shape is unknown now, these attributes can be not generated auto
@@ -427,25 +412,23 @@ private:
 
     if (nOps == 2)
       ImportNodeOneOut<mlir::ONNXConvNoBiasOp>(
-          node, nOps, nOut, defaultAttrList);
+          node, nOps, nOut);
     else
-      ImportNodeOneOut<mlir::ONNXConvOp>(node, nOps, nOut, defaultAttrList);
+      ImportNodeOneOut<mlir::ONNXConvOp>(node, nOps, nOut);
   }
 
   /*!
    * Special handle for MaxPool operations.
    */
   void ImportNodeMaxPool(
-      onnx::NodeProto node, int nIn, int nOut,
-      std::initializer_list<std::pair<std::string, AttrValueType>>
-          defaultAttrList) {
+      onnx::NodeProto node, int nIn, int nOut) {
     int nOuts = node.output().size();
     if (nOuts == 1) {
       ImportNodeOneOut<mlir::ONNXMaxPoolSingleOutOp>(
-          node, nIn, nOuts, defaultAttrList);
+          node, nIn, nOuts);
     } else {
       ImportNodeMultipleOuts<mlir::ONNXMaxPoolOp>(
-          node, nIn, nOuts, defaultAttrList);
+          node, nIn, nOuts);
     }
   }
 

src/builder/op_build_table.inc

@@ -1,592 +1,314 @@
     if (OpName == "DUMMY") {
     }else if (OpName == "Abs") {
-       ImportNodeOneOut<mlir::ONNXAbsOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXAbsOp>(node, 1, 1);
     }else if (OpName == "Acos") {
-       ImportNodeOneOut<mlir::ONNXAcosOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXAcosOp>(node, 1, 1);
     }else if (OpName == "Acosh") {
-       ImportNodeOneOut<mlir::ONNXAcoshOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXAcoshOp>(node, 1, 1);
     }else if (OpName == "Add") {
-       ImportNodeOneOut<mlir::ONNXAddOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXAddOp>(node, 2, 1);
     }else if (OpName == "And") {
-       ImportNodeOneOut<mlir::ONNXAndOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXAndOp>(node, 2, 1);
     }else if (OpName == "ArgMax") {
-       ImportNodeOneOut<mlir::ONNXArgMaxOp>(node, 1, 1, {
-         {"axis", 0}
-        ,{"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXArgMaxOp>(node, 1, 1);
     }else if (OpName == "ArgMin") {
-       ImportNodeOneOut<mlir::ONNXArgMinOp>(node, 1, 1, {
-         {"axis", 0}
-        ,{"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXArgMinOp>(node, 1, 1);
     }else if (OpName == "Asin") {
-       ImportNodeOneOut<mlir::ONNXAsinOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXAsinOp>(node, 1, 1);
     }else if (OpName == "Asinh") {
-       ImportNodeOneOut<mlir::ONNXAsinhOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXAsinhOp>(node, 1, 1);
     }else if (OpName == "Atan") {
-       ImportNodeOneOut<mlir::ONNXAtanOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXAtanOp>(node, 1, 1);
     }else if (OpName == "Atanh") {
-       ImportNodeOneOut<mlir::ONNXAtanhOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXAtanhOp>(node, 1, 1);
     }else if (OpName == "AveragePool") {
-       ImportNodeOneOut<mlir::ONNXAveragePoolOp>(node, 1, 1, {
-         {"auto_pad", "NOTSET"}
-        ,{"ceil_mode", 0}
-        ,{"count_include_pad", 0}
-        ,{"kernel_shape", std::vector<int64_t> {}}
-      });
+       ImportNodeOneOut<mlir::ONNXAveragePoolOp>(node, 1, 1);
     }else if (OpName == "BatchNormalization") {
-       ImportNodeMultipleOuts<mlir::ONNXBatchNormalizationOp>(node, 5, 5, {
-         {"epsilon", (float)1e-05}
-        ,{"momentum", (float)0.9}
-      });
+       ImportNodeMultipleOuts<mlir::ONNXBatchNormalizationOp>(node, 5, 5);
     }else if (OpName == "BitShift") {
-       ImportNodeOneOut<mlir::ONNXBitShiftOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXBitShiftOp>(node, 2, 1);
     }else if (OpName == "Cast") {
-       ImportNodeOneOut<mlir::ONNXCastOp>(node, 1, 1, {
-         {"to", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXCastOp>(node, 1, 1);
     }else if (OpName == "Ceil") {
-       ImportNodeOneOut<mlir::ONNXCeilOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXCeilOp>(node, 1, 1);
     }else if (OpName == "Clip") {
-       ImportNodeOneOut<mlir::ONNXClipOp>(node, 3, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXClipOp>(node, 3, 1);
     }else if (OpName == "Compress") {
-       ImportNodeOneOut<mlir::ONNXCompressOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXCompressOp>(node, 2, 1);
     }else if (OpName == "Concat") {
-       ImportNodeOneOut<mlir::ONNXConcatOp>(node, 1, 1, {
-         {"axis", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXConcatOp>(node, 1, 1);
     }else if (OpName == "ConcatFromSequence") {
-       ImportNodeOneOut<mlir::ONNXConcatFromSequenceOp>(node, 1, 1, {
-         {"new_axis", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXConcatFromSequenceOp>(node, 1, 1);
     }else if (OpName == "Constant") {
-       ImportNodeOneOut<mlir::ONNXConstantOp>(node, 0, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXConstantOp>(node, 0, 1);
     }else if (OpName == "ConstantOfShape") {
-       ImportNodeOneOut<mlir::ONNXConstantOfShapeOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXConstantOfShapeOp>(node, 1, 1);
     }else if (OpName == "Conv") {
-       ImportNodeConv(node, 3, 1, {
-         {"auto_pad", "NOTSET"}
-        ,{"group", 1}
-      });
+       ImportNodeConv(node, 3, 1);
     }else if (OpName == "ConvInteger") {
-       ImportNodeOneOut<mlir::ONNXConvIntegerOp>(node, 4, 1, {
-         {"auto_pad", "NOTSET"}
-        ,{"group", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXConvIntegerOp>(node, 4, 1);
     }else if (OpName == "ConvTranspose") {
-       ImportNodeOneOut<mlir::ONNXConvTransposeOp>(node, 3, 1, {
-         {"auto_pad", "NOTSET"}
-        ,{"group", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXConvTransposeOp>(node, 3, 1);
     }else if (OpName == "Cos") {
-       ImportNodeOneOut<mlir::ONNXCosOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXCosOp>(node, 1, 1);
     }else if (OpName == "Cosh") {
-       ImportNodeOneOut<mlir::ONNXCoshOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXCoshOp>(node, 1, 1);
     }else if (OpName == "CumSum") {
-       ImportNodeOneOut<mlir::ONNXCumSumOp>(node, 2, 1, {
-         {"exclusive", 0}
-        ,{"reverse", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXCumSumOp>(node, 2, 1);
     }else if (OpName == "DepthToSpace") {
-       ImportNodeOneOut<mlir::ONNXDepthToSpaceOp>(node, 1, 1, {
-         {"mode", "DCR"}
-      });
+       ImportNodeOneOut<mlir::ONNXDepthToSpaceOp>(node, 1, 1);
     }else if (OpName == "DequantizeLinear") {
-       ImportNodeOneOut<mlir::ONNXDequantizeLinearOp>(node, 3, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXDequantizeLinearOp>(node, 3, 1);
     }else if (OpName == "Det") {
-       ImportNodeOneOut<mlir::ONNXDetOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXDetOp>(node, 1, 1);
     }else if (OpName == "Div") {
-       ImportNodeOneOut<mlir::ONNXDivOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXDivOp>(node, 2, 1);
     }else if (OpName == "Dropout") {
-       ImportNodeMultipleOuts<mlir::ONNXDropoutOp>(node, 1, 2, {
-         {"ratio", (float)0.5}
-      });
+       ImportNodeMultipleOuts<mlir::ONNXDropoutOp>(node, 1, 2);
     }else if (OpName == "DynamicQuantizeLinear") {
-       ImportNodeMultipleOuts<mlir::ONNXDynamicQuantizeLinearOp>(node, 1, 3, {
-      });
+       ImportNodeMultipleOuts<mlir::ONNXDynamicQuantizeLinearOp>(node, 1, 3);
     }else if (OpName == "Elu") {
-       ImportNodeOneOut<mlir::ONNXEluOp>(node, 1, 1, {
-         {"alpha", (float)1.0}
-      });
+       ImportNodeOneOut<mlir::ONNXEluOp>(node, 1, 1);
     }else if (OpName == "Equal") {
-       ImportNodeOneOut<mlir::ONNXEqualOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXEqualOp>(node, 2, 1);
     }else if (OpName == "Erf") {
-       ImportNodeOneOut<mlir::ONNXErfOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXErfOp>(node, 1, 1);
     }else if (OpName == "Exp") {
-       ImportNodeOneOut<mlir::ONNXExpOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXExpOp>(node, 1, 1);
     }else if (OpName == "Expand") {
-       ImportNodeOneOut<mlir::ONNXExpandOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXExpandOp>(node, 2, 1);
     }else if (OpName == "EyeLike") {
-       ImportNodeOneOut<mlir::ONNXEyeLikeOp>(node, 1, 1, {
-         {"k", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXEyeLikeOp>(node, 1, 1);
     }else if (OpName == "Flatten") {
-       ImportNodeOneOut<mlir::ONNXFlattenOp>(node, 1, 1, {
-         {"axis", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXFlattenOp>(node, 1, 1);
     }else if (OpName == "Floor") {
-       ImportNodeOneOut<mlir::ONNXFloorOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXFloorOp>(node, 1, 1);
     }else if (OpName == "GRU") {
-       ImportNodeMultipleOuts<mlir::ONNXGRUOp>(node, 6, 2, {
-         {"direction", "forward"}
-        ,{"linear_before_reset", 0}
-      });
+       ImportNodeMultipleOuts<mlir::ONNXGRUOp>(node, 6, 2);
     }else if (OpName == "Gather") {
-       ImportNodeOneOut<mlir::ONNXGatherOp>(node, 2, 1, {
-         {"axis", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXGatherOp>(node, 2, 1);
     }else if (OpName == "GatherElements") {
-       ImportNodeOneOut<mlir::ONNXGatherElementsOp>(node, 2, 1, {
-         {"axis", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXGatherElementsOp>(node, 2, 1);
     }else if (OpName == "GatherND") {
-       ImportNodeOneOut<mlir::ONNXGatherNDOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXGatherNDOp>(node, 2, 1);
     }else if (OpName == "Gemm") {
-       ImportNodeOneOut<mlir::ONNXGemmOp>(node, 3, 1, {
-         {"alpha", (float)1.0}
-        ,{"beta", (float)1.0}
-        ,{"transA", 0}
-        ,{"transB", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXGemmOp>(node, 3, 1);
     }else if (OpName == "GlobalAveragePool") {
-       ImportNodeOneOut<mlir::ONNXGlobalAveragePoolOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXGlobalAveragePoolOp>(node, 1, 1);
     }else if (OpName == "GlobalLpPool") {
-       ImportNodeOneOut<mlir::ONNXGlobalLpPoolOp>(node, 1, 1, {
-         {"p", 2}
-      });
+       ImportNodeOneOut<mlir::ONNXGlobalLpPoolOp>(node, 1, 1);
     }else if (OpName == "GlobalMaxPool") {
-       ImportNodeOneOut<mlir::ONNXGlobalMaxPoolOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXGlobalMaxPoolOp>(node, 1, 1);
     }else if (OpName == "Greater") {
-       ImportNodeOneOut<mlir::ONNXGreaterOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXGreaterOp>(node, 2, 1);
     }else if (OpName == "HardSigmoid") {
-       ImportNodeOneOut<mlir::ONNXHardSigmoidOp>(node, 1, 1, {
-         {"alpha", (float)0.2}
-        ,{"beta", (float)0.5}
-      });
+       ImportNodeOneOut<mlir::ONNXHardSigmoidOp>(node, 1, 1);
     }else if (OpName == "Hardmax") {
-       ImportNodeOneOut<mlir::ONNXHardmaxOp>(node, 1, 1, {
-         {"axis", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXHardmaxOp>(node, 1, 1);
     }else if (OpName == "Identity") {
-       ImportNodeOneOut<mlir::ONNXIdentityOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXIdentityOp>(node, 1, 1);
     }else if (OpName == "If") {
-       ImportNodeOneOut<mlir::ONNXIfOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXIfOp>(node, 1, 1);
     }else if (OpName == "InstanceNormalization") {
-       ImportNodeOneOut<mlir::ONNXInstanceNormalizationOp>(node, 3, 1, {
-         {"epsilon", (float)1e-05}
-      });
+       ImportNodeOneOut<mlir::ONNXInstanceNormalizationOp>(node, 3, 1);
     }else if (OpName == "IsInf") {
-       ImportNodeOneOut<mlir::ONNXIsInfOp>(node, 1, 1, {
-         {"detect_negative", 1}
-        ,{"detect_positive", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXIsInfOp>(node, 1, 1);
     }else if (OpName == "IsNaN") {
-       ImportNodeOneOut<mlir::ONNXIsNaNOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXIsNaNOp>(node, 1, 1);
     }else if (OpName == "LRN") {
-       ImportNodeOneOut<mlir::ONNXLRNOp>(node, 1, 1, {
-         {"alpha", (float)0.0001}
-        ,{"beta", (float)0.75}
-        ,{"bias", (float)1.0}
-      });
+       ImportNodeOneOut<mlir::ONNXLRNOp>(node, 1, 1);
     }else if (OpName == "LSTM") {
-       ImportNodeMultipleOuts<mlir::ONNXLSTMOp>(node, 8, 3, {
-         {"direction", "forward"}
-        ,{"input_forget", 0}
-      });
+       ImportNodeMultipleOuts<mlir::ONNXLSTMOp>(node, 8, 3);
     }else if (OpName == "LeakyRelu") {
-       ImportNodeOneOut<mlir::ONNXLeakyReluOp>(node, 1, 1, {
-         {"alpha", (float)0.01}
-      });
+       ImportNodeOneOut<mlir::ONNXLeakyReluOp>(node, 1, 1);
     }else if (OpName == "Less") {
-       ImportNodeOneOut<mlir::ONNXLessOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXLessOp>(node, 2, 1);
     }else if (OpName == "Log") {
-       ImportNodeOneOut<mlir::ONNXLogOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXLogOp>(node, 1, 1);
     }else if (OpName == "LogSoftmax") {
-       ImportNodeOneOut<mlir::ONNXLogSoftmaxOp>(node, 1, 1, {
-         {"axis", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXLogSoftmaxOp>(node, 1, 1);
     }else if (OpName == "Loop") {
-       ImportNodeOneOut<mlir::ONNXLoopOp>(node, 3, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXLoopOp>(node, 3, 1);
     }else if (OpName == "LpNormalization") {
-       ImportNodeOneOut<mlir::ONNXLpNormalizationOp>(node, 1, 1, {
-         {"axis", -1}
-        ,{"p", 2}
-      });
+       ImportNodeOneOut<mlir::ONNXLpNormalizationOp>(node, 1, 1);
     }else if (OpName == "LpPool") {
-       ImportNodeOneOut<mlir::ONNXLpPoolOp>(node, 1, 1, {
-         {"auto_pad", "NOTSET"}
-        ,{"p", 2}
-      });
+       ImportNodeOneOut<mlir::ONNXLpPoolOp>(node, 1, 1);
     }else if (OpName == "MatMul") {
-       ImportNodeOneOut<mlir::ONNXMatMulOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXMatMulOp>(node, 2, 1);
     }else if (OpName == "MatMulInteger") {
-       ImportNodeOneOut<mlir::ONNXMatMulIntegerOp>(node, 4, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXMatMulIntegerOp>(node, 4, 1);
     }else if (OpName == "Max") {
-       ImportNodeOneOut<mlir::ONNXMaxOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXMaxOp>(node, 1, 1);
     }else if (OpName == "MaxPool") {
-       ImportNodeMaxPool(node, 1, 2, {
-         {"auto_pad", "NOTSET"}
-        ,{"ceil_mode", 0}
-        ,{"kernel_shape", std::vector<int64_t> {}}
-        ,{"storage_order", 0}
-      });
+       ImportNodeMaxPool(node, 1, 2);
     }else if (OpName == "MaxRoiPool") {
-       ImportNodeOneOut<mlir::ONNXMaxRoiPoolOp>(node, 2, 1, {
-         {"spatial_scale", (float)1.0}
-      });
+       ImportNodeOneOut<mlir::ONNXMaxRoiPoolOp>(node, 2, 1);
     }else if (OpName == "MaxUnpool") {
-       ImportNodeOneOut<mlir::ONNXMaxUnpoolOp>(node, 3, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXMaxUnpoolOp>(node, 3, 1);
     }else if (OpName == "Mean") {
-       ImportNodeOneOut<mlir::ONNXMeanOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXMeanOp>(node, 1, 1);
     }else if (OpName == "MeanVarianceNormalization") {
-       ImportNodeOneOut<mlir::ONNXMeanVarianceNormalizationOp>(node, 1, 1, {
-         {"axes", std::vector<int64_t>{0, 2, 3}}
-      });
+       ImportNodeOneOut<mlir::ONNXMeanVarianceNormalizationOp>(node, 1, 1);
     }else if (OpName == "Min") {
-       ImportNodeOneOut<mlir::ONNXMinOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXMinOp>(node, 1, 1);
     }else if (OpName == "Mod") {
-       ImportNodeOneOut<mlir::ONNXModOp>(node, 2, 1, {
-         {"fmod", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXModOp>(node, 2, 1);
     }else if (OpName == "Mul") {
-       ImportNodeOneOut<mlir::ONNXMulOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXMulOp>(node, 2, 1);
     }else if (OpName == "Multinomial") {
-       ImportNodeOneOut<mlir::ONNXMultinomialOp>(node, 1, 1, {
-         {"dtype", 6}
-        ,{"sample_size", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXMultinomialOp>(node, 1, 1);
     }else if (OpName == "Neg") {
-       ImportNodeOneOut<mlir::ONNXNegOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXNegOp>(node, 1, 1);
     }else if (OpName == "NonMaxSuppression") {
-       ImportNodeOneOut<mlir::ONNXNonMaxSuppressionOp>(node, 5, 1, {
-         {"center_point_box", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXNonMaxSuppressionOp>(node, 5, 1);
     }else if (OpName == "NonZero") {
-       ImportNodeOneOut<mlir::ONNXNonZeroOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXNonZeroOp>(node, 1, 1);
     }else if (OpName == "Not") {
-       ImportNodeOneOut<mlir::ONNXNotOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXNotOp>(node, 1, 1);
     }else if (OpName == "OneHot") {
-       ImportNodeOneOut<mlir::ONNXOneHotOp>(node, 3, 1, {
-         {"axis", -1}
-      });
+       ImportNodeOneOut<mlir::ONNXOneHotOp>(node, 3, 1);
     }else if (OpName == "Or") {
-       ImportNodeOneOut<mlir::ONNXOrOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXOrOp>(node, 2, 1);
     }else if (OpName == "PRelu") {
-       ImportNodeOneOut<mlir::ONNXPReluOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXPReluOp>(node, 2, 1);
     }else if (OpName == "Pad") {
-       ImportNodeOneOut<mlir::ONNXPadOp>(node, 3, 1, {
-         {"mode", "constant"}
-      });
+       ImportNodeOneOut<mlir::ONNXPadOp>(node, 3, 1);
     }else if (OpName == "Pow") {
-       ImportNodeOneOut<mlir::ONNXPowOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXPowOp>(node, 2, 1);
     }else if (OpName == "QLinearConv") {
-       ImportNodeOneOut<mlir::ONNXQLinearConvOp>(node, 9, 1, {
-         {"auto_pad", "NOTSET"}
-        ,{"group", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXQLinearConvOp>(node, 9, 1);
     }else if (OpName == "QLinearMatMul") {
-       ImportNodeOneOut<mlir::ONNXQLinearMatMulOp>(node, 8, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXQLinearMatMulOp>(node, 8, 1);
     }else if (OpName == "QuantizeLinear") {
-       ImportNodeOneOut<mlir::ONNXQuantizeLinearOp>(node, 3, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXQuantizeLinearOp>(node, 3, 1);
     }else if (OpName == "RNN") {
-       ImportNodeMultipleOuts<mlir::ONNXRNNOp>(node, 6, 2, {
-         {"activation_alpha", std::vector<float> {}}
-        ,{"activation_beta", std::vector<float> {}}
-        ,{"activations", std::vector<std::string>{"Tanh", "Tanh"}}
-        ,{"direction", "forward"}
-      });
+       ImportNodeMultipleOuts<mlir::ONNXRNNOp>(node, 6, 2);
     }else if (OpName == "RandomNormal") {
-       ImportNodeOneOut<mlir::ONNXRandomNormalOp>(node, 0, 1, {
-         {"dtype", 1}
-        ,{"mean", (float)0.0}
-        ,{"scale", (float)1.0}
-      });
+       ImportNodeOneOut<mlir::ONNXRandomNormalOp>(node, 0, 1);
     }else if (OpName == "RandomNormalLike") {
-       ImportNodeOneOut<mlir::ONNXRandomNormalLikeOp>(node, 1, 1, {
-         {"mean", (float)0.0}
-        ,{"scale", (float)1.0}
-      });
+       ImportNodeOneOut<mlir::ONNXRandomNormalLikeOp>(node, 1, 1);
     }else if (OpName == "RandomUniform") {
-       ImportNodeOneOut<mlir::ONNXRandomUniformOp>(node, 0, 1, {
-         {"dtype", 1}
-        ,{"high", (float)1.0}
-        ,{"low", (float)0.0}
-      });
+       ImportNodeOneOut<mlir::ONNXRandomUniformOp>(node, 0, 1);
     }else if (OpName == "RandomUniformLike") {
-       ImportNodeOneOut<mlir::ONNXRandomUniformLikeOp>(node, 1, 1, {
-         {"high", (float)1.0}
-        ,{"low", (float)0.0}
-      });
+       ImportNodeOneOut<mlir::ONNXRandomUniformLikeOp>(node, 1, 1);
     }else if (OpName == "Range") {
-       ImportNodeOneOut<mlir::ONNXRangeOp>(node, 3, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXRangeOp>(node, 3, 1);
     }else if (OpName == "Reciprocal") {
-       ImportNodeOneOut<mlir::ONNXReciprocalOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXReciprocalOp>(node, 1, 1);
     }else if (OpName == "ReduceL1") {
-       ImportNodeOneOut<mlir::ONNXReduceL1Op>(node, 1, 1, {
-         {"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXReduceL1Op>(node, 1, 1);
     }else if (OpName == "ReduceL2") {
-       ImportNodeOneOut<mlir::ONNXReduceL2Op>(node, 1, 1, {
-         {"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXReduceL2Op>(node, 1, 1);
     }else if (OpName == "ReduceLogSum") {
-       ImportNodeOneOut<mlir::ONNXReduceLogSumOp>(node, 1, 1, {
-         {"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXReduceLogSumOp>(node, 1, 1);
     }else if (OpName == "ReduceLogSumExp") {
-       ImportNodeOneOut<mlir::ONNXReduceLogSumExpOp>(node, 1, 1, {
-         {"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXReduceLogSumExpOp>(node, 1, 1);
     }else if (OpName == "ReduceMax") {
-       ImportNodeOneOut<mlir::ONNXReduceMaxOp>(node, 1, 1, {
-         {"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXReduceMaxOp>(node, 1, 1);
     }else if (OpName == "ReduceMean") {
-       ImportNodeOneOut<mlir::ONNXReduceMeanOp>(node, 1, 1, {
-         {"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXReduceMeanOp>(node, 1, 1);
     }else if (OpName == "ReduceMin") {
-       ImportNodeOneOut<mlir::ONNXReduceMinOp>(node, 1, 1, {
-         {"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXReduceMinOp>(node, 1, 1);
     }else if (OpName == "ReduceProd") {
-       ImportNodeOneOut<mlir::ONNXReduceProdOp>(node, 1, 1, {
-         {"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXReduceProdOp>(node, 1, 1);
     }else if (OpName == "ReduceSum") {
-       ImportNodeOneOut<mlir::ONNXReduceSumOp>(node, 1, 1, {
-         {"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXReduceSumOp>(node, 1, 1);
     }else if (OpName == "ReduceSumSquare") {
-       ImportNodeOneOut<mlir::ONNXReduceSumSquareOp>(node, 1, 1, {
-         {"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXReduceSumSquareOp>(node, 1, 1);
     }else if (OpName == "Relu") {
-       ImportNodeOneOut<mlir::ONNXReluOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXReluOp>(node, 1, 1);
     }else if (OpName == "Reshape") {
-       ImportNodeOneOut<mlir::ONNXReshapeOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXReshapeOp>(node, 2, 1);
     }else if (OpName == "Resize") {
-       ImportNodeOneOut<mlir::ONNXResizeOp>(node, 4, 1, {
-         {"coordinate_transformation_mode", "half_pixel"}
-        ,{"cubic_coeff_a", (float)-0.75}
-        ,{"exclude_outside", 0}
-        ,{"extrapolation_value", (float)0.0}
-        ,{"mode", "nearest"}
-        ,{"nearest_mode", "round_prefer_floor"}
-      });
+       ImportNodeOneOut<mlir::ONNXResizeOp>(node, 4, 1);
     }else if (OpName == "ReverseSequence") {
-       ImportNodeOneOut<mlir::ONNXReverseSequenceOp>(node, 2, 1, {
-         {"batch_axis", 1}
-        ,{"time_axis", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXReverseSequenceOp>(node, 2, 1);
     }else if (OpName == "RoiAlign") {
-       ImportNodeOneOut<mlir::ONNXRoiAlignOp>(node, 3, 1, {
-         {"mode", "avg"}
-        ,{"output_height", 1}
-        ,{"output_width", 1}
-        ,{"sampling_ratio", 0}
-        ,{"spatial_scale", (float)1.0}
-      });
+       ImportNodeOneOut<mlir::ONNXRoiAlignOp>(node, 3, 1);
     }else if (OpName == "Round") {
-       ImportNodeOneOut<mlir::ONNXRoundOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXRoundOp>(node, 1, 1);
     }else if (OpName == "Scan") {
-       ImportNodeOneOut<mlir::ONNXScanOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXScanOp>(node, 1, 1);
     }else if (OpName == "Scatter") {
-       ImportNodeOneOut<mlir::ONNXScatterOp>(node, 3, 1, {
-         {"axis", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXScatterOp>(node, 3, 1);
     }else if (OpName == "ScatterElements") {
-       ImportNodeOneOut<mlir::ONNXScatterElementsOp>(node, 3, 1, {
-         {"axis", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXScatterElementsOp>(node, 3, 1);
     }else if (OpName == "ScatterND") {
-       ImportNodeOneOut<mlir::ONNXScatterNDOp>(node, 3, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXScatterNDOp>(node, 3, 1);
     }else if (OpName == "Selu") {
-       ImportNodeOneOut<mlir::ONNXSeluOp>(node, 1, 1, {
-         {"alpha", (float)1.67326}
-        ,{"gamma", (float)1.0507}
-      });
+       ImportNodeOneOut<mlir::ONNXSeluOp>(node, 1, 1);
     }else if (OpName == "SequenceAt") {
-       ImportNodeOneOut<mlir::ONNXSequenceAtOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSequenceAtOp>(node, 2, 1);
     }else if (OpName == "SequenceConstruct") {
-       ImportNodeOneOut<mlir::ONNXSequenceConstructOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSequenceConstructOp>(node, 1, 1);
     }else if (OpName == "SequenceEmpty") {
-       ImportNodeOneOut<mlir::ONNXSequenceEmptyOp>(node, 0, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSequenceEmptyOp>(node, 0, 1);
     }else if (OpName == "SequenceErase") {
-       ImportNodeOneOut<mlir::ONNXSequenceEraseOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSequenceEraseOp>(node, 2, 1);
     }else if (OpName == "SequenceInsert") {
-       ImportNodeOneOut<mlir::ONNXSequenceInsertOp>(node, 3, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSequenceInsertOp>(node, 3, 1);
     }else if (OpName == "SequenceLength") {
-       ImportNodeOneOut<mlir::ONNXSequenceLengthOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSequenceLengthOp>(node, 1, 1);
     }else if (OpName == "Shape") {
-       ImportNodeOneOut<mlir::ONNXShapeOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXShapeOp>(node, 1, 1);
     }else if (OpName == "Shrink") {
-       ImportNodeOneOut<mlir::ONNXShrinkOp>(node, 1, 1, {
-         {"bias", (float)0.0}
-        ,{"lambd", (float)0.5}
-      });
+       ImportNodeOneOut<mlir::ONNXShrinkOp>(node, 1, 1);
     }else if (OpName == "Sigmoid") {
-       ImportNodeOneOut<mlir::ONNXSigmoidOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSigmoidOp>(node, 1, 1);
     }else if (OpName == "Sign") {
-       ImportNodeOneOut<mlir::ONNXSignOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSignOp>(node, 1, 1);
     }else if (OpName == "Sin") {
-       ImportNodeOneOut<mlir::ONNXSinOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSinOp>(node, 1, 1);
     }else if (OpName == "Sinh") {
-       ImportNodeOneOut<mlir::ONNXSinhOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSinhOp>(node, 1, 1);
     }else if (OpName == "Size") {
-       ImportNodeOneOut<mlir::ONNXSizeOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSizeOp>(node, 1, 1);
     }else if (OpName == "Slice") {
-       ImportNodeOneOut<mlir::ONNXSliceOp>(node, 5, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSliceOp>(node, 5, 1);
     }else if (OpName == "Softmax") {
-       ImportNodeOneOut<mlir::ONNXSoftmaxOp>(node, 1, 1, {
-         {"axis", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXSoftmaxOp>(node, 1, 1);
     }else if (OpName == "Softplus") {
-       ImportNodeOneOut<mlir::ONNXSoftplusOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSoftplusOp>(node, 1, 1);
     }else if (OpName == "Softsign") {
-       ImportNodeOneOut<mlir::ONNXSoftsignOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSoftsignOp>(node, 1, 1);
     }else if (OpName == "SpaceToDepth") {
-       ImportNodeOneOut<mlir::ONNXSpaceToDepthOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSpaceToDepthOp>(node, 1, 1);
     }else if (OpName == "Split") {
-       ImportNodeOneOut<mlir::ONNXSplitOp>(node, 1, 1, {
-         {"axis", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXSplitOp>(node, 1, 1);
     }else if (OpName == "SplitToSequence") {
-       ImportNodeOneOut<mlir::ONNXSplitToSequenceOp>(node, 2, 1, {
-         {"axis", 0}
-        ,{"keepdims", 1}
-      });
+       ImportNodeOneOut<mlir::ONNXSplitToSequenceOp>(node, 2, 1);
     }else if (OpName == "Sqrt") {
-       ImportNodeOneOut<mlir::ONNXSqrtOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSqrtOp>(node, 1, 1);
     }else if (OpName == "Squeeze") {
-       ImportNodeOneOut<mlir::ONNXSqueezeOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSqueezeOp>(node, 1, 1);
     }else if (OpName == "StringNormalizer") {
-       ImportNodeOneOut<mlir::ONNXStringNormalizerOp>(node, 1, 1, {
-         {"case_change_action", "NONE"}
-        ,{"is_case_sensitive", 0}
-      });
+       ImportNodeOneOut<mlir::ONNXStringNormalizerOp>(node, 1, 1);
     }else if (OpName == "Sub") {
-       ImportNodeOneOut<mlir::ONNXSubOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSubOp>(node, 2, 1);
     }else if (OpName == "Sum") {
-       ImportNodeOneOut<mlir::ONNXSumOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXSumOp>(node, 1, 1);
     }else if (OpName == "Tan") {
-       ImportNodeOneOut<mlir::ONNXTanOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXTanOp>(node, 1, 1);
     }else if (OpName == "Tanh") {
-       ImportNodeOneOut<mlir::ONNXTanhOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXTanhOp>(node, 1, 1);
     }else if (OpName == "TfIdfVectorizer") {
-       ImportNodeOneOut<mlir::ONNXTfIdfVectorizerOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXTfIdfVectorizerOp>(node, 1, 1);
     }else if (OpName == "ThresholdedRelu") {
-       ImportNodeOneOut<mlir::ONNXThresholdedReluOp>(node, 1, 1, {
-         {"alpha", (float)1.0}
-      });
+       ImportNodeOneOut<mlir::ONNXThresholdedReluOp>(node, 1, 1);
     }else if (OpName == "Tile") {
-       ImportNodeOneOut<mlir::ONNXTileOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXTileOp>(node, 2, 1);
     }else if (OpName == "TopK") {
-       ImportNodeMultipleOuts<mlir::ONNXTopKOp>(node, 2, 2, {
-         {"axis", -1}
-        ,{"largest", 1}
-        ,{"sorted", 1}
-      });
+       ImportNodeMultipleOuts<mlir::ONNXTopKOp>(node, 2, 2);
     }else if (OpName == "Transpose") {
-       ImportNodeOneOut<mlir::ONNXTransposeOp>(node, 1, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXTransposeOp>(node, 1, 1);
     }else if (OpName == "Unique") {
-       ImportNodeMultipleOuts<mlir::ONNXUniqueOp>(node, 1, 4, {
-         {"sorted", 1}
-      });
+       ImportNodeMultipleOuts<mlir::ONNXUniqueOp>(node, 1, 4);
     }else if (OpName == "Unsqueeze") {
-       ImportNodeOneOut<mlir::ONNXUnsqueezeOp>(node, 1, 1, {
-         {"axes", std::vector<int64_t> {}}
-      });
+       ImportNodeOneOut<mlir::ONNXUnsqueezeOp>(node, 1, 1);
     }else if (OpName == "Upsample") {
-       ImportNodeOneOut<mlir::ONNXUpsampleOp>(node, 2, 1, {
-         {"mode", "nearest"}
-      });
+       ImportNodeOneOut<mlir::ONNXUpsampleOp>(node, 2, 1);
     }else if (OpName == "Where") {
-       ImportNodeOneOut<mlir::ONNXWhereOp>(node, 3, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXWhereOp>(node, 3, 1);
     }else if (OpName == "Xor") {
-       ImportNodeOneOut<mlir::ONNXXorOp>(node, 2, 1, {
-      });
+       ImportNodeOneOut<mlir::ONNXXorOp>(node, 2, 1);
     }

src/dialect/onnx/gen_doc.py

@@ -270,6 +270,12 @@ def gen_schema(schema) :
                         'Identity', 'Cos', 'Log', 'Transpose', 'Softmax',
                         'Softplus', 'Softsign']
     CanonicalList=['Add', 'Identity']
+    manual_code = dict([
+      ('DummyExample', '  let extraClassDeclaration = [{ \n'+
+                    '    static StringRef getPermAttrName() { return "perm"; }\n'+
+                    '    }];\n')
+      ])
+    skip_attr_gen = []
     line_indent = '  '
 
     #s = 'def ONNX'+schema.name+str(schema.since_version)+'Op:ONNX_Op<"'+schema.name+'", \n'
@@ -303,21 +309,23 @@ def gen_schema(schema) :
 
     #input
     s+= '\n'+line_indent+'let arguments = (ins '
+    isfirst = True
     if schema.inputs:
+        isfirst = False
         for input in schema.inputs:
             if input != schema.inputs[0] :
-                s+= ', '
+                s+= ',\n           '
             etypes=collect_types(schema, input)
 
             if OpSchema.FormalParameterOption.Optional == input.option:
                 #TODO: handle optional
-                print("optional ", input.name)
+                print("warning: optional input for"+schema.name+' '+input.name)
             elif OpSchema.FormalParameterOption.Variadic == input.option:
                 if input.isHomogeneous:
                     s+= 'Variadic<'
                 else:
                     #TODO handle  (variadic, heterogeneous)"
-                    print('variadic, heterogeneous', input.name)
+                    print("warning: (variadic, heterogeneous) for"+schema.name+' '+input.name)
             if etypes == '':
                 s+= 'AnyTypeOf<[AnyMemRef, AnyTensor]>'
             else:
@@ -333,6 +341,8 @@ def gen_schema(schema) :
                     #TODO handle  (variadic, heterogeneous)"
                     t=''
             s+=':$'+input.name
+    if not schema.name in skip_attr_gen :
+        s += gen_attr_ins(schema, isfirst)
     s+= ');'
 
     #output
@@ -347,11 +357,15 @@ def gen_schema(schema) :
                 s+= 'AnyTypeOf<[AnyMemRef, AnyTensor]>'
             else:
                 s+= 'TensorOf<['+etypes+']>'
-    s+= ');'
+            s += ':$o_'+output.name
+    s+= ');\n'
 
     #s+= 'let hasCanonicalizer = 1;'
+    #add special code
+    if schema.name in manual_code :
+        s += manual_code[schema.name]
 
-    s += '\n}\n\n'
+    s += '}\n\n'
 
     return s
 
@@ -369,44 +383,91 @@ def gen_code(schema,fefile) :
         ("MaxPool", "ImportNodeMaxPool"),
         #("Transpose", "ImportNodeTranspose")
         ])
-    list_str = 'std::vector'
-    empty_ints = list_str+'<int> {}' 
-    empty_floats = list_str+'<float> {}' 
-    special_default = dict([
-        ("AveragePool "+"kernel_shape", empty_ints),
-        ("MaxPool "+"kernel_shape", empty_ints),
-        ("Cast "+"to", '0'),
-        ("Concat "+"axis", '0'),
-        ("Unsqueeze "+"axes", empty_ints),
-        ("RNN "+"activation_alpha", empty_floats),
-        ("RNN "+"activation_beta", empty_floats)
-        ])
+
     line_indent = '  '
     fefile.write('    '+'}else if (OpName == "'+schema.name+'") {\n')
     op_type_str='mlir::ONNX'+schema.name+'Op'
     if schema.name in special_handler :
         fefile.write('       '+special_handler[schema.name]+'(node, '
           +str(len(schema.inputs))
-          +', ' +str(len(schema.outputs))+', {\n')
+          +', ' +str(len(schema.outputs)))
     elif len(schema.outputs) > 1 :
         fefile.write('       '+'ImportNodeMultipleOuts<'+op_type_str+'>(node, '
           +str(len(schema.inputs))
-          +', ' +str(len(schema.outputs))+', {\n')
+          +', ' +str(len(schema.outputs)))
     else :
         fefile.write('       '+'ImportNodeOneOut<'+op_type_str+'>(node, '
           +str(len(schema.inputs))
-          +', ' +str(len(schema.outputs))+', {\n')
+          +', ' +str(len(schema.outputs)))
+    fefile.write(');\n')
 
+def gen_attr_ins(schema, isfirst) :
+    special_defaults = dict([
+        ("AveragePool "+"kernel_shape", ('ints', '{}')),
+        ("MaxPool "+"kernel_shape", ('ints', '{}')),
+        ("Cast "+"to", ('int', '0')),
+        ("Concat "+"axis", ('int', '0')),
+        ("Conv "+"group", ('int', '1')),
+        ("Unsqueeze "+"axes", ('ints', '{}')),
+        ("RNN "+"activation_alpha", ('floats', '{}')),
+        ("RNN "+"activation_beta", ('floats', '{}')),
+        ])
     
+    def get_attr_type_basic(attr_type) :
+        if attr_type == 'int' :
+            mytype = 'I64Attr'
+        elif attr_type == 'float' :
+            mytype = 'F32Attr'
+        elif attr_type == 'ints' :
+            mytype = 'I64ArrayAttr'
+        elif attr_type == 'floats' :
+            mytype = 'F32ArrayAttr'
+        elif attr_type == "string" :
+            mytype = 'StrAttr'
+        elif attr_type == "strings" :
+            mytype = 'StrArrayAttr'
+        else :
+            mytype ='AnyAttr'
+        #TODO: tensor and sparse tensor
+        return mytype
+
+    def get_attr_type_optional(attr_type) :
+        mytype = 'OptionalAttr<'
+        mytype += get_attr_type_basic(attr_type)
+        mytype += '>'
+        return mytype
+
+    def get_attr_type_with_default(attr_type, attr_default) :
+        mytype = 'DefaultValuedAttr<'
+        mytype += get_attr_type_basic(attr_type)
+        mytype += ', "'+attr_default+'">'
+        return mytype
+
+    attr_line = ''
     if schema.attributes:
-        first_attr = True
         for _, attr in sorted(schema.attributes.items()):
-            #only generate default attr list
-            if schema.name+' '+attr.name in special_default:
-                attr_value = special_default[schema.name+' '+attr.name]
-            elif attr.default_value.name:
-                default_value = helper.get_attribute_value(attr.default_value)
+            #attr_line = line_indent+line_indent+line_indent+line_indent
+            if not isfirst:
+                attr_line += ',\n           '
+            else :
+                isfirst = False
             
+            if schema.name+' '+attr.name in special_defaults:
+                (attr_type_str, attr_default_str) = special_defaults[schema.name+' '+attr.name]
+                attr_line += get_attr_type_with_default(attr_type_str, attr_default_str)
+                attr_line += ':$'+attr.name
+            elif attr.required:
+                s = Text(attr.type)
+                attr_type_str  = s[s.rfind('.') + 1:].lower()
+                attr_line += get_attr_type_basic(attr_type_str)
+                attr_line += ':$'+attr.name
+
+            # option holds either required or default value
+            elif attr.default_value.name:
+                s = Text(attr.type)
+                attr_type_str  = s[s.rfind('.') + 1:].lower()
+
+                default_value = helper.get_attribute_value(attr.default_value)
                 def format_value(value):  # type: (Any) -> Text
                     if isinstance(value, float):
                         formatted = str(np.round(value, 5))
@@ -419,66 +480,25 @@ def gen_code(schema,fefile) :
                     return str(value)
 
                 if isinstance(default_value, list):
-
-                    value = default_value[0]
                     default_value = [format_value(val) for val in default_value]
                     attr_option_str = '{}'.format(default_value)
                     attr_option_str = attr_option_str.replace('[', '{', 1)
                     attr_option_str = attr_option_str.replace(']', '}', 1)
-                    # TODO the list type is homogenous or htergeneous?
-                   
-                    if isinstance(value, float) : 
-                        attr_type_str = list_str+'<float>'
-                        attr_option_str = attr_option_str.replace("'", '')
-                    elif isinstance(value, int) :
-                        attr_type_str = list_str+'<int>'
-                        attr_option_str = attr_option_str.replace("'", '')
-                    elif isinstance(value, str) :
-                        attr_type_str = list_str+'<std::string>'
-                        attr_option_str = attr_option_str.replace("'", '"')
-                    elif isinstance(value, (bytes, bytearray)) :
-                        attr_type_str = list_str+'<std::string>'
-                        attr_option_str = attr_option_str.replace("'", '"')
+                    if attr_type_str == 'strings' :
+                        attr_option_str = attr_option_str.replace("'", '\\"')
                     else :
-                        attr_type_str = '"unknowns"'
+                        attr_option_str = attr_option_str.replace("'", '')
                 else:
-                    if isinstance(default_value, float) : 
-                        attr_type_str = '(float)'
-                        attr_option_str = default_value
-                    elif isinstance(default_value, int) :
-                        attr_option_str = default_value
-                        attr_type_str=''
-                    elif isinstance(default_value, str) :
-                        attr_type_str = '"str"'
-                    elif isinstance(default_value, (bytes, bytearray)) :
-                        attr_type_str = '"str"'
-                    else :
-                        attr_type_str = '"unknown"'
                     default_value = format_value(default_value)
-                    if attr_type_str == '"str"' :
-                        attr_option_str = '"'+default_value+'"'
-                        attr_type_str=''
-                    else :
                     attr_option_str = default_value
-                attr_value = attr_type_str+attr_option_str
+                attr_line += get_attr_type_with_default(attr_type_str, attr_option_str)
+                attr_line += ':$'+attr.name
             else:
-                #no default value
-                continue
-
-            attr_line = line_indent+line_indent+line_indent+line_indent
-            if not first_attr:
-                attr_line += ',{'
-            else :
-                attr_line += ' {'
-            first_attr = False
-
-            attr_line += '"'+attr.name+'", '
-            attr_line += attr_value
-            attr_line += '}\n'
-            fefile.write(attr_line)
-    fefile.write(line_indent+line_indent+line_indent+'});\n')
-          
-
+                s = Text(attr.type)
+                attr_type_str  = s[s.rfind('.') + 1:].lower()
+                attr_line += get_attr_type_optional(attr_type_str)
+                attr_line += ':$'+attr.name
+    return attr_line
 
 def main(args):  # type: (Type[Args]) -> None
     with io.open(args.changelog, 'w', newline='') as fout:
@@ -496,7 +516,6 @@ def main(args):  # type: (Type[Args]) -> None
         fout.write('\n')
 
         for domain, versionmap in sorted(dv_index.items()):
-            print("domain", domain)
             if not should_render_domain(domain):
                 continue
 
@@ -633,6 +652,6 @@ if __name__ == '__main__':
     class Args(object):
         output = os.path.join(docs_dir, 'Operators' + ext)
         changelog = os.path.join(docs_dir, 'Changelog' + ext)
-        tdfile = os.path.join(docs_dir, 'onnxop.inc')
+        tdfile = os.path.join(base_dir, 'onnxop.inc')
     print(Args)
     main(Args)

src/dialect/onnx/onnx.td

@@ -99,8 +99,14 @@ def ONNXGemmNoBiasOp: ONNX_Op<"GemmNoBias",
 
   }];
 
-  let arguments = (ins AnyTypeOf<[AnyMemRef, AnyTensor]>:$lhs_in, AnyTypeOf<[AnyMemRef, AnyTensor]>:$rhs_in);
-  let results = (outs AnyTypeOf<[AnyMemRef, AnyTensor]>);
+  let arguments = (ins AnyTypeOf<[AnyMemRef, AnyTensor]>:$A,
+           AnyTypeOf<[AnyMemRef, AnyTensor]>:$B,
+           DefaultValuedAttr<F32Attr, "1.0">:$alpha,
+           DefaultValuedAttr<F32Attr, "1.0">:$beta,
+           DefaultValuedAttr<I64Attr, "0">:$transA,
+           DefaultValuedAttr<I64Attr, "0">:$transB);
+
+  let results = (outs AnyTypeOf<[AnyMemRef, AnyTensor]>:$o_Y);
 }
 
 def ONNXConvNoBiasOp:ONNX_Op<"ConvNoBias",
@@ -110,10 +116,15 @@ def ONNXConvNoBiasOp:ONNX_Op<"ConvNoBias",
     "The convolution operator consumes an input tensor and a filter, and"
     "computes the output."
   }];
-  let arguments = (ins AnyTypeOf<[AnyMemRef, AnyTensor]>:$X, AnyTypeOf<[AnyMemRef, AnyTensor]>:$W);
-  let results = (outs AnyTypeOf<[AnyMemRef, AnyTensor]>);
-
-  let verifier = [{ return ::verify(*this); }];
+  let arguments = (ins AnyTypeOf<[AnyMemRef, AnyTensor]>:$X,
+           AnyTypeOf<[AnyMemRef, AnyTensor]>:$W,
+           DefaultValuedAttr<StrAttr, "NOTSET">:$auto_pad,
+           OptionalAttr<I64ArrayAttr>:$dilations,
+           DefaultValuedAttr<I64Attr, "1">:$group,
+           OptionalAttr<I64ArrayAttr>:$kernel_shape,
+           OptionalAttr<I64ArrayAttr>:$pads,
+           OptionalAttr<I64ArrayAttr>:$strides);
+  let results = (outs AnyTypeOf<[AnyMemRef, AnyTensor]>:$o_Y);
 }
 
 def ONNXMaxPoolSingleOutOp: ONNX_Op<"MaxPoolSingleOut",
@@ -123,8 +134,15 @@ def ONNXMaxPoolSingleOutOp: ONNX_Op<"MaxPoolSingleOut",
     "ONNX MaxPool operation with a single output."
     "See ONNXMaxPoolOp for a full description of the MaxPool semantics."
   }];
-  let arguments = (ins AnyTypeOf<[AnyMemRef, AnyTensor]>:$X);
-  let results = (outs AnyTypeOf<[AnyMemRef, AnyTensor]>);
+  let arguments = (ins AnyTypeOf<[AnyMemRef, AnyTensor]>:$X,
+           DefaultValuedAttr<StrAttr, "NOTSET">:$auto_pad,
+           DefaultValuedAttr<I64Attr, "0">:$ceil_mode,
+           OptionalAttr<I64ArrayAttr>:$dilations,
+           DefaultValuedAttr<I64ArrayAttr, "{}">:$kernel_shape,
+           OptionalAttr<I64ArrayAttr>:$pads,
+           DefaultValuedAttr<I64Attr, "0">:$storage_order,
+           OptionalAttr<I64ArrayAttr>:$strides);
+  let results = (outs AnyTypeOf<[AnyMemRef, AnyTensor]>:$o_Y);
 }
 
 #endif // ONNX_OPS

src/dialect/onnx/onnx_ops.cpp

@@ -512,8 +512,10 @@ void ONNXTransposeOp::inferShapes() {
   auto arrayTy = getOperand().getType().cast<RankedTensorType>();
   SmallVector<int64_t, 2> dims;
 
-  if (auto permutation = getAttrOfType<ArrayAttr>(
-          ONNXTransposeOp::getPermAttrName())) {
+  //if (auto permutation = getAttrOfType<ArrayAttr>(
+   //       ONNXTransposeOp::getPermAttrName())) {
+  auto permutation = ONNXTransposeOp::permAttr();
+  if (permutation) {
     // Perform transposition according to perm attribute.
     for (auto perm : permutation.getValue())
       dims.emplace_back(arrayTy.getShape()[perm.cast<IntegerAttr>().getInt()]);
@@ -526,20 +528,6 @@ void ONNXTransposeOp::inferShapes() {
   getResult().setType(RankedTensorType::get(dims, arrayTy.getElementType()));
 }
 
-LogicalResult verify(ONNXTransposeOp op) {
-  auto module = op.getParentOfType<ModuleOp>();
-  if (!module)
-    op.emitError("Expected to belong to a module.");
-
-  if (auto permutation = op.getAttrOfType<ArrayAttr>(
-          ONNXTransposeOp::getPermAttrName())) {
-    for (auto perm : permutation.getValue())
-      if (perm.cast<IntegerAttr>().getInt() < 0)
-        op.emitError("Cannot tranpose, permuation contains negative index.");
-  }
-
-  return success();
-}
 
 //===----------------------------------------------------------------------===//
 
@@ -568,11 +556,9 @@ void ONNXConvNoBiasOp::inferShapes() {
     emitError("Weight size not compatible with data size.");
 
   // Required attribute auto_pad defaults to NOTSET.
-  auto autoPad = getAttrOfType<StringAttr>(
-      ONNXConvOp::getAutoPadAttrName()).getValue();
+  auto autoPad = auto_pad();
   // Group is a required attribute and should have default value of 1.
-  int64_t group = getAttrOfType<IntegerAttr>(
-      ONNXConvOp::getGroupAttrName()).getInt();
+  int64_t group = ONNXConvNoBiasOp::group().getSExtValue(); //.getLimitedValue();
   // Check that the X.shape[1] == (W.shape[1] * group) == C condition holds.
   if (dataShape[1] != (weightShape[1] * group))
     emitError("Channel dimension mismatch.");
@@ -604,8 +590,7 @@ void ONNXConvNoBiasOp::inferShapes() {
   // Use kernel_shape attribute if present otherwise use size from weight
   // argument.
   SmallVector<int64_t, 2> kernelDims;
-  if (auto kernelShape = getAttrOfType<ArrayAttr>(
-          ONNXConvOp::getKernelShapeAttrName())) {
+  if (auto kernelShape = kernel_shapeAttr()) {
     if (kernelShape.getValue().size() != nDims)
       emitError("kernel_shape length incompatible with spatial dimensions.");
     for (int i = 0; i < nDims; ++i)
@@ -627,8 +612,7 @@ void ONNXConvNoBiasOp::inferShapes() {
   //
   // From a dimensionality perspective the kernel size becomes the dilated
   // kernel size.
-  if (auto dilations = getAttrOfType<ArrayAttr>(
-          ONNXConvOp::getDilationsAttrName())) {
+  if (auto dilations = dilationsAttr()) {
     if (dilations.getValue().size() != nDims)
       emitError("dilations length incompatible with spatial dimensions.");
     for (int i = 0; i < nDims; ++i)
@@ -644,8 +628,7 @@ void ONNXConvNoBiasOp::inferShapes() {
   if (autoPad == "NOTSET") {
     // Use pads to to determine the padding. If attribute is not
     // present then pads is considered to be all zeros (no padding).
-    if (auto pads = getAttrOfType<ArrayAttr>(
-            ONNXConvOp::getPadsAttrName())) {
+    if (auto pads = padsAttr()) {
       // pads consists of two entries for each spatial axis.
       if (pads.getValue().size() != 2 * nDims)
         emitError("pads size is not twice the spatial size.");
@@ -676,13 +659,12 @@ void ONNXConvNoBiasOp::inferShapes() {
   }
 
   // Strides
-  if (auto strides = getAttrOfType<ArrayAttr>(
-      ONNXConvOp::getStridesAttrName())) {
+  if (auto strides = ONNXConvNoBiasOp::stridesAttr()) {
     if (strides.getValue().size() != nDims)
       emitError("strides length incompatible with spatial dimensions.");
     for (int i = 0; i < nDims; ++i) {
       int64_t stride =
-          (strides.getValue()[i]).cast<IntegerAttr>().getInt();
+          strides.getValue()[i].cast<IntegerAttr>().getInt();
       outSpatialDims[i] = floor(outSpatialDims[i] / stride);
     }
   }
@@ -694,28 +676,6 @@ void ONNXConvNoBiasOp::inferShapes() {
   getResult().setType(RankedTensorType::get(dims, dataTy.getElementType()));
 }
 
-LogicalResult verify(ONNXConvNoBiasOp op) {
-  auto module = op.getParentOfType<ModuleOp>();
-  if (!module)
-    op.emitError("expected to belong to a module");
-
-  auto autoPadAttr = op.getAttrOfType<StringAttr>(
-      ONNXConvOp::getAutoPadAttrName());
-  if (!autoPadAttr)
-    op.emitError("auto_pad attribute not specified.");
-  if (autoPadAttr.getValue() != "NOTSET")
-    if (auto pads = op.getAttrOfType<ArrayAttr>(
-            ONNXConvOp::getPadsAttrName()))
-      op.emitError("auto_pad and pads are both set.");
-
-  auto groupAttr =
-      op.getAttrOfType<IntegerAttr>(ONNXConvOp::getGroupAttrName());
-  if (!groupAttr)
-    op.emitError("group attribute not specified.");
-
-  return success();
-}
-
 //===----------------------------------------------------------------------===//
 // TableGen'd op method definitions
 //===----------------------------------------------------------------------===//

src/pass/lower_frontend_to_krnl.cpp

@@ -420,14 +420,16 @@ Value mapToLowerScalarOp<ONNXHardSigmoidOp>(
   //                                  Constant 1)
   auto loc = op->getLoc();
   Value operand = operands[0];
-  auto alphaAttr = op->getAttrOfType<FloatAttr>("alpha");
-  auto betaAttr = op->getAttrOfType<FloatAttr>("beta");
+  auto alphaAttribute = FloatAttr::get(rewriter.getF32Type(),
+      llvm::dyn_cast<ONNXHardSigmoidOp>(op).alpha().convertToFloat());
+  auto betaAttribute = FloatAttr::get(rewriter.getF32Type(),
+      llvm::dyn_cast<ONNXHardSigmoidOp>(op).beta().convertToFloat());
   auto elementType = result_types[0];
 
   auto zero = rewriter.create<ConstantOp>(loc, FloatAttr::get(elementType, 0));
   auto one = rewriter.create<ConstantOp>(loc, FloatAttr::get(elementType, 1));
-  auto alpha = rewriter.create<ConstantOp>(loc, alphaAttr);
-  auto beta = rewriter.create<ConstantOp>(loc, betaAttr);
+  auto alpha = rewriter.create<ConstantOp>(loc, alphaAttribute);
+  auto beta = rewriter.create<ConstantOp>(loc, betaAttribute);
 
   auto add = rewriter.create<AddFOp>(
       loc, rewriter.create<MulFOp>(loc, alpha, operand), beta);
@@ -455,10 +457,11 @@ Value mapToLowerScalarOp<ONNXEluOp>(Operation *op, ArrayRef<Type> result_types,
   Value operand = operands[0];
   auto elementType = result_types[0];
 
-  auto alphaAttr = op->getAttrOfType<FloatAttr>("alpha");
+  auto alphaAttribute = FloatAttr::get(rewriter.getF32Type(),
+      llvm::dyn_cast<ONNXEluOp>(op).alpha().convertToFloat());
   auto zero = rewriter.create<ConstantOp>(loc, FloatAttr::get(elementType, 0));
   auto one = rewriter.create<ConstantOp>(loc, FloatAttr::get(elementType, 1));
-  auto alpha = rewriter.create<ConstantOp>(loc, alphaAttr);
+  auto alpha = rewriter.create<ConstantOp>(loc, alphaAttribute);
   auto exp = rewriter.create<ExpOp>(loc, operand);
   auto lessThanZero =
       rewriter.create<CmpFOp>(loc, CmpFPredicate::OLT, operand, zero);
@@ -508,9 +511,10 @@ Value mapToLowerScalarOp<ONNXLeakyReluOp>(Operation *op,
   Value operand = operands[0];
   auto elementType = result_types[0];
 
-  auto alphaAttr = op->getAttrOfType<FloatAttr>("alpha");
+  auto alphaAttribute = FloatAttr::get(rewriter.getF32Type(),
+      llvm::dyn_cast<ONNXLeakyReluOp>(op).alpha().convertToFloat());
   auto zero = rewriter.create<ConstantOp>(loc, FloatAttr::get(elementType, 0));
-  auto alpha = rewriter.create<ConstantOp>(loc, alphaAttr);
+  auto alpha = rewriter.create<ConstantOp>(loc, alphaAttribute);
   auto lessThanZero =
       rewriter.create<CmpFOp>(loc, CmpFPredicate::OLT, operand, zero);
   auto result = rewriter.create<SelectOp>(
@@ -533,13 +537,15 @@ Value mapToLowerScalarOp<ONNXSeluOp>(Operation *op, ArrayRef<Type> result_types,
   //                                         alpha)))
   auto loc = op->getLoc();
   Value operand = operands[0];
-  auto alphaAttr = op->getAttrOfType<FloatAttr>("alpha");
-  auto gammaAttr = op->getAttrOfType<FloatAttr>("gamma");
+  auto alphaAttribute = FloatAttr::get(rewriter.getF32Type(),
+      llvm::dyn_cast<ONNXSeluOp>(op).alpha().convertToFloat());
+  auto gammaAttribute = FloatAttr::get(rewriter.getF32Type(),
+      llvm::dyn_cast<ONNXSeluOp>(op).gamma().convertToFloat());
   auto elementType = result_types[0];
 
   auto zero = rewriter.create<ConstantOp>(loc, FloatAttr::get(elementType, 0));
-  auto alpha = rewriter.create<ConstantOp>(loc, alphaAttr);
-  auto gamma = rewriter.create<ConstantOp>(loc, gammaAttr);
+  auto alpha = rewriter.create<ConstantOp>(loc, alphaAttribute);
+  auto gamma = rewriter.create<ConstantOp>(loc, gammaAttribute);
   auto exp = rewriter.create<ExpOp>(loc, operand);
   auto greaterThanZero =
       rewriter.create<CmpFOp>(loc, CmpFPredicate::OGT, operand, zero);
@@ -876,7 +882,7 @@ struct ONNXSoftmaxOpLowering : public ConversionPattern {
     //                    exp_x / sum
     auto tensorType = (*op->result_type_begin()).cast<RankedTensorType>();
     int64_t rank = tensorType.getRank();
-    int64_t axis = op->getAttrOfType<IntegerAttr>("axis").getInt();
+    int64_t axis = llvm::dyn_cast<ONNXSoftmaxOp>(op).axis().getSExtValue();
     axis = axis >= 0 ? axis : rank + axis;
     assert(axis >= -rank && axis <= rank - 1);
 

src/pass/onnx_combine.td

@@ -30,9 +30,14 @@ def HasOneUse : Constraint<CPred<"$0.hasOneUse()">>;
 // Pattern-Match and Rewrite
 //===----------------------------------------------------------------------===//
 
+def GemmAlpha : NativeCodeCall<"$_builder.getF32FloatAttr(1.0)">;
+def GemmBeta : NativeCodeCall<"$_builder.getF32FloatAttr(1.0)">;
+def GemmTransA : NativeCodeCall<"$_builder.getI64IntegerAttr(0)">;
+def GemmTransB : NativeCodeCall<"$_builder.getI64IntegerAttr(0)">;
+
 // onnx.add(onnx.matmul(%X, %Y), %Z) = onnx.Gemm(%X, %Y, %Z)
 def MulAddToGemmOptPattern : Pat<(ONNXAddOp (ONNXMatMulOp:$res $m1, $m2), $m3),
-                                 (ONNXGemmOp $m1, $m2, $m3),
+                                 (ONNXGemmOp $m1, $m2, $m3, (GemmAlpha), (GemmBeta), (GemmTransA), (GemmTransB)),
 				 [(HasOneUse $res)]>;
 
 // ONNX_Op (onnx.Identity (%X)) = ONNX_Op (%X)

test/mlir/onnx/onnx_canonicalization.mlir

@@ -2,7 +2,7 @@
 
 func @test_matmul_add_simplification(%a0: tensor<10x10xf32>, %a1: tensor<10x10xf32>, %a2: tensor<10x10xf32>) -> tensor<10x10xf32> {
   // CHECK-LABEL: test_matmul_add_simplification
-  // CHECK: %{{[0-9]+}} = "onnx.Gemm"(%{{.*}}, %{{.*}}, %{{.*}}) : (tensor<10x10xf32>, tensor<10x10xf32>, tensor<10x10xf32>) -> tensor<10x10xf32>
+  // CHECK: %{{[0-9]+}} = "onnx.Gemm"(%{{.*}}, %{{.*}}, %{{.*}}) {alpha = 1.000000e+00 : f32, beta = 1.000000e+00 : f32, transA = 0 : i64, transB = 0 : i64} : (tensor<10x10xf32>, tensor<10x10xf32>, tensor<10x10xf32>) -> tensor<10x10xf32>
   %0 = "onnx.MatMul"(%a0, %a1) : (tensor<10x10xf32>, tensor<10x10xf32>) -> tensor<10x10xf32>
   %1 = "onnx.Add"(%0, %a2) : (tensor<10x10xf32>, tensor<10x10xf32>) -> tensor<10x10xf32>
   "std.return"(%1) : (tensor<10x10xf32>) -> ()

test/mlir/onnx/onnx_lowering.mlir

@@ -579,7 +579,7 @@ func @test_add_with_broadcasting(%arg0 : tensor<?xf32>, %arg1 : tensor<?x10xf32>
 }
 
 func @test_softmax(%arg0 : tensor<10x10xf32>) -> tensor<*xf32> {
-  %0 = "onnx.Softmax"(%arg0) {axis=1:i32} : (tensor<10x10xf32>) -> tensor<*xf32>
+  %0 = "onnx.Softmax"(%arg0) {axis=1:i64} : (tensor<10x10xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 
   // CHECK-LABEL: test_softmax

test/mlir/onnx/onnx_shape_inference.mlir

@@ -124,120 +124,120 @@ func @test_matmul_8(%arg0 : tensor<32x64xf32>, %arg1 : tensor<64x128xf32>) -> te
 /// Default and required attributes.
 
 func @test_conv_no_bias_1(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x7xf32>) -> tensor<*xf32> {
-  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i32} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
+  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 }
 
 // CHECK-LABEL: test_conv_no_bias_1
-// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i32} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x27x58xf32>
+// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x27x58xf32>
 // CHECK: return [[RES_ATTR]] : tensor<1x5x27x58xf32>
 
 /// kernel_shape attribute.
 
 func @test_conv_no_bias_2(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x7xf32>) -> tensor<*xf32> {
-  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i32, kernel_shape = [8, 9]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
+  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64, kernel_shape = [8, 9]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 }
 
 // CHECK-LABEL: test_conv_no_bias_2
-// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i32, kernel_shape = [8, 9]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x25x56xf32>
+// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64, kernel_shape = [8, 9]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x25x56xf32>
 // CHECK: return [[RES_ATTR]] : tensor<1x5x25x56xf32>
 
 /// pads attribute.
 /// Use pads to make output size equal to input size by adding K - 1 to the result.
 
 func @test_conv_no_bias_3(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x10xf32>) -> tensor<*xf32> {
-  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i32, pads = [2, 4, 3, 5]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<*xf32>
+  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64, pads = [2, 4, 3, 5]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 }
 
 // CHECK-LABEL: test_conv_no_bias_3
-// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i32, pads = [2, 4, 3, 5]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x32x64xf32>
+// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64, pads = [2, 4, 3, 5]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x32x64xf32>
 // CHECK: return [[RES_ATTR]] : tensor<1x5x32x64xf32>
 
 /// auto_pad set to SAME_UPPER and SAME_LOWER.
 
 func @test_conv_no_bias_4(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x10xf32>) -> tensor<*xf32> {
-  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i32} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<*xf32>
+  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 }
 
 // CHECK-LABEL: test_conv_no_bias_4
-// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i32} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x32x64xf32>
+// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x32x64xf32>
 // CHECK: return [[RES_ATTR]] : tensor<1x5x32x64xf32>
 
 func @test_conv_no_bias_5(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x10xf32>) -> tensor<*xf32> {
-  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_LOWER", group = 1 : i32} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<*xf32>
+  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_LOWER", group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 }
 
 // CHECK-LABEL: test_conv_no_bias_5
-// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_LOWER", group = 1 : i32} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x32x64xf32>
+// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_LOWER", group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x32x64xf32>
 // CHECK: return [[RES_ATTR]] : tensor<1x5x32x64xf32>
 
 /// auto_pad set to VALID.
 
 func @test_conv_no_bias_6(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x10xf32>) -> tensor<*xf32> {
-  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "VALID", group = 1 : i32} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<*xf32>
+  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "VALID", group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 }
 
 // CHECK-LABEL: test_conv_no_bias_6
-// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "VALID", group = 1 : i32} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x27x55xf32>
+// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "VALID", group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x10xf32>) -> tensor<1x5x27x55xf32>
 // CHECK: return [[RES_ATTR]] : tensor<1x5x27x55xf32>
 
 /// With strides attribute.
 
 func @test_conv_no_bias_7(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x7xf32>) -> tensor<*xf32> {
-  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i32, strides = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
+  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64, strides = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 }
 
 // CHECK-LABEL: test_conv_no_bias_7
-// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i32, strides = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x14x20xf32>
+// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64, strides = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x14x20xf32>
 // CHECK: return [[RES_ATTR]] : tensor<1x5x14x20xf32>
 
 /// auto_pad set to SAME_UPPER with strides attribute.
 /// The auto_pad will pas as if stride is equal to 1.
 
 func @test_conv_no_bias_8(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x7xf32>) -> tensor<*xf32> {
-  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i32, strides = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
+  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i64, strides = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 }
 
 // CHECK-LABEL: test_conv_no_bias_8
-// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i32, strides = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x16x22xf32>
+// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i64, strides = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x16x22xf32>
 // CHECK: return [[RES_ATTR]] : tensor<1x5x16x22xf32>
 
 /// dilations attribute.
 
 func @test_conv_no_bias_9(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x7xf32>) -> tensor<*xf32> {
-  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i32, dilations = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
+  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64, dilations = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 }
 
 // CHECK-LABEL: test_conv_no_bias_9
-// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", dilations = [2, 3], group = 1 : i32} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x20x42xf32>
+// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", dilations = [2, 3], group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x20x42xf32>
 // CHECK: return [[RES_ATTR]] : tensor<1x5x20x42xf32>
 
 /// dilations attribute with stride.
 
 func @test_conv_no_bias_10(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x7xf32>) -> tensor<*xf32> {
-  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i32, dilations = [2, 3], strides = [2, 2]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
+  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", group = 1 : i64, dilations = [2, 3], strides = [2, 2]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 }
 
 // CHECK-LABEL: test_conv_no_bias_10
-// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", dilations = [2, 3], group = 1 : i32, strides = [2, 2]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x10x21xf32>
+// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "NOTSET", dilations = [2, 3], group = 1 : i64, strides = [2, 2]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x10x21xf32>
 // CHECK: return [[RES_ATTR]] : tensor<1x5x10x21xf32>
 
 /// dilations attribute with auto_pad set to SAME_UPPER.
 
 func @test_conv_no_bias_11(%arg0 : tensor<1x2x32x64xf32>, %arg1 : tensor<5x2x6x7xf32>) -> tensor<*xf32> {
-  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i32, dilations = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
+  %0 = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", group = 1 : i64, dilations = [2, 3]} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<*xf32>
   "std.return"(%0) : (tensor<*xf32>) -> ()
 }
 
 // CHECK-LABEL: test_conv_no_bias_11
-// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", dilations = [2, 3], group = 1 : i32} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x32x64xf32>
+// CHECK: [[RES_ATTR:%.+]] = "onnx.ConvNoBias"(%arg0, %arg1) {auto_pad = "SAME_UPPER", dilations = [2, 3], group = 1 : i64} : (tensor<1x2x32x64xf32>, tensor<5x2x6x7xf32>) -> tensor<1x5x32x64xf32>
 // CHECK: return [[RES_ATTR]] : tensor<1x5x32x64xf32>