/** * Computes a join or meet type for the given pair of types. The join flag allows to determine * whether the join or meet type is computed. */ TypePtr getJoinMeetType(const TypePtr& typeA, const TypePtr& typeB, bool join) { static const TypePtr fail = 0; // add a structure based algorithm for computing the Join-Type // shortcut for equal types if (*typeA == *typeB) { return typeA; } // the rest depends on the node types NodeType nodeTypeA = typeA->getNodeType(); NodeType nodeTypeB = typeB->getNodeType(); // handle generic types if (nodeTypeA == NT_GenericType && nodeTypeB == NT_GenericType) { // let the join computation handle the case const GenericTypePtr& genTypeA = static_pointer_cast<const GenericType>(typeA); const GenericTypePtr& genTypeB = static_pointer_cast<const GenericType>(typeB); return (join) ? getJoinType(genTypeA, genTypeB) : getMeetType(genTypeA, genTypeB); } // handle vector types (only if array super type of A is a super type of B) // make sure typeA is the vector if (nodeTypeA != NT_VectorType && nodeTypeB == NT_VectorType) { // switch sides return getJoinMeetType(typeB, typeA, join); } // handle vector-array conversion (only works for joins) if (join && nodeTypeA == NT_VectorType) { VectorTypePtr vector = static_pointer_cast<const VectorType>(typeA); // the only potential super type is an array of the same element type IRBuilder builder(vector->getNodeManager()); ArrayTypePtr array = builder.arrayType(vector->getElementType()); if (isSubTypeOf(typeB, array)) { return array; } // no common super type! return fail; } // the rest can only work if it is of the same kind if (nodeTypeA != nodeTypeB) { // => no common super type return fail; } // check for functions if (nodeTypeA == NT_FunctionType) { FunctionTypePtr funTypeA = static_pointer_cast<const FunctionType>(typeA); FunctionTypePtr funTypeB = static_pointer_cast<const FunctionType>(typeB); // check number of arguments auto paramsA = funTypeA->getParameterTypes(); auto paramsB = funTypeB->getParameterTypes(); if (paramsA.size() != paramsB.size()) { // not matching return fail; } // check function kind FunctionKind resKind = funTypeA->getKind(); if (funTypeA->getKind() != funTypeB->getKind()) { // differences are only allowed when going from plain to closure type if ((funTypeA->isPlain() && funTypeB->isClosure()) || (funTypeA->isClosure() && funTypeB->isPlain())) { resKind = FK_CLOSURE; } else { return fail; } } // compute join type // JOIN/MEET result and argument types - if possible TypePtr cur = getJoinMeetType(funTypeA->getReturnType(), funTypeB->getReturnType(), join); TypePtr resType = cur; // continue with parameters TypeList params; for (std::size_t i=0; i<paramsA.size(); i++) { // ATTENTION: this goes in the reverse direction cur = getJoinMeetType(paramsA[i], paramsB[i], !join); // if a pair can not be matched => fail if (!cur) return fail; params.push_back(cur); } // construct resulting type IRBuilder builder(funTypeA->getNodeManager()); return builder.functionType(params, resType, resKind); } // everything else does not have a common join/meet type return fail; }
GenericTypePtr toSIMDVector(const VectorTypePtr& type) { assert(type.isa<core::VectorTypePtr>() && "no SIMD type can be made out of a vector type"); insieme::core::IRBuilder builder(type.getNodeManager()); return builder.genericType("simd", {type}, IntParamList()); }
bool isSubTypeOf(const TypePtr& subType, const TypePtr& superType) { // quick check - reflexivity if (*subType == *superType) { return true; } // check for recursive types if (subType->getNodeType() == NT_RecType || superType->getNodeType() == NT_RecType) { // since they are not equivalent we have to compare the unrolled version of the sub with the super type if (subType->getNodeType() == NT_RecType) { return isSubTypeOf(subType.as<RecTypePtr>()->unroll(), superType); } if (superType->getNodeType() == NT_RecType) { assert(subType->getNodeType() != NT_RecType); return isSubTypeOf(subType, superType.as<RecTypePtr>()->unroll()); } assert(false && "How could you get here?"); } // check whether the sub-type is generic if (subType->getNodeType() == NT_GenericType || subType->getNodeType() == NT_StructType) { // use the delta algorithm for computing all the super-types of the given sub-type return isSubTypeOfInternal(subType, superType); } // check for vector types if (subType.isa<VectorTypePtr>() ) { VectorTypePtr vector = static_pointer_cast<const VectorType>(subType); // potential super type is an array of the same element type IRBuilder builder(vector->getNodeManager()); return *superType == *builder.arrayType(vector->getElementType()); } // for all other relations, the node type has to be the same if (subType->getNodeType() != superType->getNodeType()) { return false; } // check function types if (subType->getNodeType() == NT_FunctionType) { FunctionTypePtr funTypeA = static_pointer_cast<const FunctionType>(subType); FunctionTypePtr funTypeB = static_pointer_cast<const FunctionType>(superType); // check kind of functions if (funTypeA->getKind() != funTypeB->getKind()) { // only closure to plain conversion is allowed if (!(funTypeB->isClosure() && funTypeA->isPlain())) { return false; } } bool res = true; res = res && funTypeA->getParameterTypes().size() == funTypeB->getParameterTypes().size(); res = res && isSubTypeOf(funTypeA->getReturnType(), funTypeB->getReturnType()); for(std::size_t i = 0; res && i<funTypeB->getParameterTypes().size(); i++) { res = res && isSubTypeOf(funTypeB->getParameterTypes()[i], funTypeA->getParameterTypes()[i]); } return res; } // check reference types if (subType->getNodeType() == NT_RefType) { const auto& basic = subType->getNodeManager().getLangBasic(); // check source / sink auto srcRef = subType.as<RefTypePtr>(); auto trgRef = superType.as<RefTypePtr>(); // check read/write privileges if (trgRef.isRead() && !srcRef.isRead()) return false; if (trgRef.isWrite() && !srcRef.isWrite()) return false; // check element type auto srcElement = subType.as<RefTypePtr>()->getElementType(); auto trgElement = superType.as<RefTypePtr>()->getElementType(); // if element types are identical => it is fine //if (srcElement == trgElement) return true; if(core::analysis::compareTypes(srcElement, trgElement)) return true; // if sub-type is ref<any> it is ok if (basic.isAny(trgElement)) { return true; } // support nested references if (srcElement.isa<RefTypePtr>() && trgElement.isa<RefTypePtr>()) { return isSubTypeOf(srcElement, trgElement); } // a ref<vector<X,Y>> is a sub-type of a ref<array<X,1>> if (trgElement.isa<ArrayTypePtr>() && srcElement.isa<VectorTypePtr>()) { IRBuilder builder(srcElement.getNodeManager()); auto one = builder.concreteIntTypeParam(1); // array needs to be 1-dimensional and both have to have the same element type return trgElement.as<ArrayTypePtr>()->getDimension() == one && trgElement.as<ArrayTypePtr>()->getElementType() == srcElement.as<VectorTypePtr>()->getElementType(); } // also support references of derived classes being passed to base-type pointer if (core::analysis::isObjectType(srcElement) && core::analysis::isObjectType(trgElement)) { if (isSubTypeOf(srcElement, trgElement)) { return true; } } } // no other relations are supported return false; }