src/ast_handlers.hpp - CzechLight/netconf-cli - Gitiles

 /*
  * Copyright (C) 2018 CESNET, https://photonics.cesnet.cz/
  * Copyright (C) 2018 FIT CVUT, https://fit.cvut.cz/
  *
  * Written by Václav Kubernát <kubervac@fit.cvut.cz>
  *
 */

 #pragma once

 #include <boost/mpl/for_each.hpp>
 #include "ast_commands.hpp"
 #include "parser_context.hpp"
 #include "schema.hpp"
 #include "utils.hpp"
 namespace x3 = boost::spirit::x3;

 struct parser_context_tag;

 struct keyValue_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         const Schema& schema = parserContext.m_schema;

         if (parserContext.m_tmpListKeys.find(ast.first) != parserContext.m_tmpListKeys.end()) {
             _pass(context) = false;
             parserContext.m_errorMsg = "Key \"" + ast.first + "\" was entered more than once.";
         } else if (!schema.listHasKey(parserContext.m_curPath, {parserContext.m_curModule, parserContext.m_tmpListName}, ast.first)) {
             _pass(context) = false;
             parserContext.m_errorMsg = parserContext.m_tmpListName + " is not indexed by \"" + ast.first + "\".";
         } else {
             parserContext.m_tmpListKeys.insert(ast.first);
         }
     }

     template <typename Iterator, typename Exception, typename Context>
     x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         parserContext.m_errorMsg = "Error parsing key values here:";
         return x3::error_handler_result::rethrow;
     }
 };

 struct node_identifier_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);

         if (!parserContext.m_topLevelModulePresent) {
             if (parserContext.m_errorMsg.empty())
                 parserContext.m_errorMsg = "You have to specify a top level module.";
             _pass(context) = false;
         }
     }
 };

 struct key_identifier_class;

 struct module_identifier_class;

 struct listPrefix_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         const Schema& schema = parserContext.m_schema;

         if (schema.isList(parserContext.m_curPath, {parserContext.m_curModule, ast})) {
             parserContext.m_tmpListName = ast;
         } else {
             _pass(context) = false;
         }
     }
 };

 struct listSuffix_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         const Schema& schema = parserContext.m_schema;

         const auto& keysNeeded = schema.listKeys(parserContext.m_curPath, {parserContext.m_curModule, parserContext.m_tmpListName});
         std::set<std::string> keysSupplied;
         for (const auto& it : ast)
             keysSupplied.insert(it.first);

         if (keysNeeded != keysSupplied) {
             parserContext.m_errorMsg = "Not enough keys for " + parserContext.m_tmpListName + ". " +
                                        "These keys were not supplied:";
             std::set<std::string> missingKeys;
             std::set_difference(keysNeeded.begin(), keysNeeded.end(),
                                 keysSupplied.begin(), keysSupplied.end(),
                                 std::inserter(missingKeys, missingKeys.end()));

             for (const auto& it : missingKeys)
                 parserContext.m_errorMsg += " " + it;
             parserContext.m_errorMsg += ".";

             _pass(context) = false;
         }
     }

     template <typename Iterator, typename Exception, typename Context>
     x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         if (parserContext.m_errorMsg.empty())
             parserContext.m_errorMsg = "Expecting ']' here:";
         return x3::error_handler_result::rethrow;
     }
 };
 struct listElement_class {
     template <typename Iterator, typename Exception, typename Context>
     x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         if (parserContext.m_errorMsg.empty()) {
             return x3::error_handler_result::fail;
         } else {
             return x3::error_handler_result::rethrow;
         }
     }
 };
 struct list_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         const Schema& schema = parserContext.m_schema;

         if (!schema.isList(parserContext.m_curPath, {parserContext.m_curModule, ast.m_name})) {
             _pass(context) = false;
         }
     }
 };
 struct nodeup_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);

         if (parserContext.m_curPath.m_nodes.empty())
             _pass(context) = false;
     }
 };

 struct container_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         const auto& schema = parserContext.m_schema;

         if (!schema.isContainer(parserContext.m_curPath, {parserContext.m_curModule, ast.m_name}))
             _pass(context) = false;
     }
 };

 struct leaf_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         const auto& schema = parserContext.m_schema;

         if (!schema.isLeaf(parserContext.m_curPath, {parserContext.m_curModule, ast.m_name}))
             _pass(context) = false;
     }
 };

 struct module_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         const auto& schema = parserContext.m_schema;

         if (schema.isModule(parserContext.m_curPath, ast.m_name)) {
             parserContext.m_curModule = ast.m_name;
             parserContext.m_topLevelModulePresent = true;
         } else {
             parserContext.m_errorMsg = "Invalid module name.";
             _pass(context) = false;
         }
     }
 };

 struct schemaNode_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         if (ast.m_suffix.type() == typeid(nodeup_)) {
             parserContext.m_curPath.m_nodes.pop_back();
             if (parserContext.m_curPath.m_nodes.empty())
                 parserContext.m_topLevelModulePresent = false;
         } else {
             parserContext.m_curPath.m_nodes.push_back(ast);
             parserContext.m_curModule = boost::none;
         }
     }
 };

 struct dataNodeList_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         parserContext.m_curPath.m_nodes.push_back(dataNodeToSchemaNode(ast));
     }
 };

 struct dataNode_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         if (ast.m_suffix.type() == typeid(nodeup_)) {
             parserContext.m_curPath.m_nodes.pop_back();
             if (parserContext.m_curPath.m_nodes.empty())
                 parserContext.m_topLevelModulePresent = false;
         } else {
             parserContext.m_curPath.m_nodes.push_back(dataNodeToSchemaNode(ast));
             parserContext.m_curModule = boost::none;
         }
     }
 };

 struct absoluteStart_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         parserContext.m_curPath.m_nodes.clear();
     }
 };

 struct dataNodesListEnd_class;

 struct dataPathListEnd_class;

 struct dataPath_class {
     template <typename Iterator, typename Exception, typename Context>
     x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         if (parserContext.m_errorMsg.empty()) {
             parserContext.m_errorMsg = "Expected path.";
             return x3::error_handler_result::fail;
         } else {
             return x3::error_handler_result::rethrow;
         }
     }
 };

 struct schemaPath_class {
     template <typename Iterator, typename Exception, typename Context>
     x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         if (parserContext.m_errorMsg.empty()) {
             parserContext.m_errorMsg = "Expected path.";
             return x3::error_handler_result::fail;
         } else {
             return x3::error_handler_result::rethrow;
         }
     }
 };

 struct discard_class;

 struct ls_class;

 struct cd_class {
     template <typename Iterator, typename Exception, typename Context>
     x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const& x, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         if (parserContext.m_errorMsg.empty())
             parserContext.m_errorMsg = "Expected " + x.which() + " here:";
         return x3::error_handler_result::rethrow;
     }
 };

 struct presenceContainerPathHandler {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         const auto& schema = parserContext.m_schema;
         try {
             boost::optional<std::string> module;
             if (ast.m_path.m_nodes.back().m_prefix)
                 module = ast.m_path.m_nodes.back().m_prefix.value().m_name;
             container_ cont = boost::get<container_>(ast.m_path.m_nodes.back().m_suffix);
             schemaPath_ location = pathWithoutLastNode(parserContext.m_curPath);

             if (!schema.isPresenceContainer(location, {module, cont.m_name})) {
                 parserContext.m_errorMsg = "This container is not a presence container.";
                 _pass(context) = false;
             }
         } catch (boost::bad_get&) {
             parserContext.m_errorMsg = "This is not a container.";
             _pass(context) = false;
         }
     }

     template <typename Iterator, typename Exception, typename Context>
     x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         if (parserContext.m_errorMsg.empty())
             parserContext.m_errorMsg = "Couldn't parse create/delete command.";
         return x3::error_handler_result::rethrow;
     }
 };

 struct create_class : public presenceContainerPathHandler {
 };

 struct delete_class : public presenceContainerPathHandler {
 };

 struct leaf_path_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         try {
             auto leaf = boost::get<leaf_>(ast.m_nodes.back().m_suffix);
         } catch (boost::bad_get&) {
             parserContext.m_errorMsg = "This is not a path to leaf.";
             _pass(context) = false;
         }
     }
 };

 struct leaf_data_class {
     template <typename Iterator, typename Exception, typename Context>
     x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         auto& schema = parserContext.m_schema;
         if (parserContext.m_errorMsg.empty()) {
             leaf_ leaf = boost::get<leaf_>(parserContext.m_curPath.m_nodes.back().m_suffix);
             schemaPath_ location = pathWithoutLastNode(parserContext.m_curPath);
             if (location.m_nodes.empty()) {
                 parserContext.m_curModule = parserContext.m_curPath.m_nodes.back().m_prefix->m_name;
             }
             parserContext.m_errorMsg = "Expected " + leafDataTypeToString(schema.leafType(location, {parserContext.m_curModule, leaf.m_name})) + " here:";
             return x3::error_handler_result::fail;
         }
         return x3::error_handler_result::rethrow;
     }
 };

 struct leaf_data_base_class {
     yang::LeafDataTypes m_type;

     leaf_data_base_class(yang::LeafDataTypes type)
         : m_type(type)
     {
     }

     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         auto& schema = parserContext.m_schema;
         boost::optional<std::string> module;
         if (parserContext.m_curPath.m_nodes.back().m_prefix)
             module = parserContext.m_curPath.m_nodes.back().m_prefix.value().m_name;

         leaf_ leaf = boost::get<leaf_>(parserContext.m_curPath.m_nodes.back().m_suffix);
         schemaPath_ location = pathWithoutLastNode(parserContext.m_curPath);

         if (schema.leafType(location, {module, leaf.m_name}) != m_type) {
             _pass(context) = false;
         }
     }
 };

 struct leaf_data_enum_class : leaf_data_base_class {
     leaf_data_enum_class()
         : leaf_data_base_class(yang::LeafDataTypes::Enum)
     {
     }

     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const& start, Iterator const& end, T& ast, Context const& context)
     {
         leaf_data_base_class::on_success(start, end, ast, context);
         auto& parserContext = x3::get<parser_context_tag>(context);
         auto& schema = parserContext.m_schema;
         boost::optional<std::string> module;
         if (parserContext.m_curPath.m_nodes.back().m_prefix)
             module = parserContext.m_curPath.m_nodes.back().m_prefix.value().m_name;

         leaf_ leaf = boost::get<leaf_>(parserContext.m_curPath.m_nodes.back().m_suffix);
         schemaPath_ location = pathWithoutLastNode(parserContext.m_curPath);

         if (!schema.leafEnumHasValue(location, {module, leaf.m_name}, ast.m_value)) {
             _pass(context) = false;
         }
     }
 };

 struct leaf_data_decimal_class : leaf_data_base_class {
     leaf_data_decimal_class()
         : leaf_data_base_class(yang::LeafDataTypes::Decimal)
     {
     }
 };

 struct leaf_data_bool_class : leaf_data_base_class {
     leaf_data_bool_class()
         : leaf_data_base_class(yang::LeafDataTypes::Bool)
     {
     }
 };

 struct leaf_data_int_class : leaf_data_base_class {
     leaf_data_int_class()
         : leaf_data_base_class(yang::LeafDataTypes::Int)
     {
     }
 };

 struct leaf_data_uint_class : leaf_data_base_class {
     leaf_data_uint_class()
         : leaf_data_base_class(yang::LeafDataTypes::Uint)
     {
     }
 };

 struct leaf_data_string_class : leaf_data_base_class {
     leaf_data_string_class()
         : leaf_data_base_class(yang::LeafDataTypes::String)
     {
     }
 };

 struct set_class {
     template <typename Iterator, typename Exception, typename Context>
     x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const& x, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         if (parserContext.m_errorMsg.empty())
             parserContext.m_errorMsg = "Expected " + x.which() + " here:";
         return x3::error_handler_result::rethrow;
     }
 };

 struct commit_class;

 struct get_class;

 struct command_class {
     template <typename Iterator, typename Exception, typename Context>
     x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const& x, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         auto& error_handler = x3::get<x3::error_handler_tag>(context).get();
         if (parserContext.m_errorMsg.empty()) {
             parserContext.m_errorMsg = "Unknown command.";
         }
         error_handler(x.where(), parserContext.m_errorMsg);
         return x3::error_handler_result::fail;
     }
 };

 struct initializePath_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         parserContext.m_curPath = parserContext.m_curPathOrig;
         parserContext.m_tmpListKeys.clear();
         parserContext.m_tmpListName.clear();
         parserContext.m_suggestions.clear();
         if (!parserContext.m_curPath.m_nodes.empty() && parserContext.m_curPath.m_nodes.at(0).m_prefix)
             parserContext.m_topLevelModulePresent = true;
         else
             parserContext.m_topLevelModulePresent = false;
     }
 };

 struct trailingSlash_class;

 struct createPathSuggestions_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const& begin, Iterator const&, T&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         const auto& schema = parserContext.m_schema;

         parserContext.m_completionIterator = begin;
         parserContext.m_suggestions = schema.childNodes(parserContext.m_curPath, Recursion::NonRecursive);
     }
 };

 std::set<std::string> generateMissingKeyCompletionSet(std::set<std::string> keysNeeded, std::set<std::string> currentSet);

 struct createKeySuggestions_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const& begin, Iterator const&, T&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         const auto& schema = parserContext.m_schema;

         parserContext.m_completionIterator = begin;

         const auto& keysNeeded = schema.listKeys(parserContext.m_curPath, {parserContext.m_curModule, parserContext.m_tmpListName});
         parserContext.m_suggestions = generateMissingKeyCompletionSet(keysNeeded, parserContext.m_tmpListKeys);
     }
 };

 struct suggestKeysEnd_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const& begin, Iterator const&, T&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         const auto& schema = parserContext.m_schema;

         parserContext.m_completionIterator = begin;
         const auto& keysNeeded = schema.listKeys(parserContext.m_curPath, {parserContext.m_curModule, parserContext.m_tmpListName});
         if (generateMissingKeyCompletionSet(keysNeeded, parserContext.m_tmpListKeys).empty()) {
             parserContext.m_suggestions = {"]/"};
         } else {
             parserContext.m_suggestions = {"]"};
         }
     }
 };

 struct commandNamesVisitor {
     template <typename T>
     auto operator()(boost::type<T>)
     {
         return T::name;
     }
 };

 struct createCommandSuggestions_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const& begin, Iterator const&, T&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);
         parserContext.m_completionIterator = begin;

         parserContext.m_suggestions.clear();
         boost::mpl::for_each<CommandTypes, boost::type<boost::mpl::_>>([&parserContext](auto cmd) {
             parserContext.m_suggestions.emplace(commandNamesVisitor()(cmd));
         });
     }
 };

 struct completing_class {
     template <typename T, typename Iterator, typename Context>
     void on_success(Iterator const&, Iterator const&, T&, Context const& context)
     {
         auto& parserContext = x3::get<parser_context_tag>(context);

         if (!parserContext.m_completing)
             _pass(context) = false;
     }
 };
	/*
	* Copyright (C) 2018 CESNET, https://photonics.cesnet.cz/
	* Copyright (C) 2018 FIT CVUT, https://fit.cvut.cz/
	*
	* Written by Václav Kubernát <kubervac@fit.cvut.cz>
	*
	*/

	#pragma once

	#include <boost/mpl/for_each.hpp>
	#include "ast_commands.hpp"
	#include "parser_context.hpp"
	#include "schema.hpp"
	#include "utils.hpp"
	namespace x3 = boost::spirit::x3;

	struct parser_context_tag;

	struct keyValue_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	const Schema& schema = parserContext.m_schema;

	if (parserContext.m_tmpListKeys.find(ast.first) != parserContext.m_tmpListKeys.end()) {
	_pass(context) = false;
	parserContext.m_errorMsg = "Key \"" + ast.first + "\" was entered more than once.";
	} else if (!schema.listHasKey(parserContext.m_curPath, {parserContext.m_curModule, parserContext.m_tmpListName}, ast.first)) {
	_pass(context) = false;
	parserContext.m_errorMsg = parserContext.m_tmpListName + " is not indexed by \"" + ast.first + "\".";
	} else {
	parserContext.m_tmpListKeys.insert(ast.first);
	}
	}

	template <typename Iterator, typename Exception, typename Context>
	x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	parserContext.m_errorMsg = "Error parsing key values here:";
	return x3::error_handler_result::rethrow;
	}
	};

	struct node_identifier_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);

	if (!parserContext.m_topLevelModulePresent) {
	if (parserContext.m_errorMsg.empty())
	parserContext.m_errorMsg = "You have to specify a top level module.";
	_pass(context) = false;
	}
	}
	};

	struct key_identifier_class;

	struct module_identifier_class;

	struct listPrefix_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	const Schema& schema = parserContext.m_schema;

	if (schema.isList(parserContext.m_curPath, {parserContext.m_curModule, ast})) {
	parserContext.m_tmpListName = ast;
	} else {
	_pass(context) = false;
	}
	}
	};

	struct listSuffix_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	const Schema& schema = parserContext.m_schema;

	const auto& keysNeeded = schema.listKeys(parserContext.m_curPath, {parserContext.m_curModule, parserContext.m_tmpListName});
	std::set<std::string> keysSupplied;
	for (const auto& it : ast)
	keysSupplied.insert(it.first);

	if (keysNeeded != keysSupplied) {
	parserContext.m_errorMsg = "Not enough keys for " + parserContext.m_tmpListName + ". " +
	"These keys were not supplied:";
	std::set<std::string> missingKeys;
	std::set_difference(keysNeeded.begin(), keysNeeded.end(),
	keysSupplied.begin(), keysSupplied.end(),
	std::inserter(missingKeys, missingKeys.end()));

	for (const auto& it : missingKeys)
	parserContext.m_errorMsg += " " + it;
	parserContext.m_errorMsg += ".";

	_pass(context) = false;
	}
	}

	template <typename Iterator, typename Exception, typename Context>
	x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	if (parserContext.m_errorMsg.empty())
	parserContext.m_errorMsg = "Expecting ']' here:";
	return x3::error_handler_result::rethrow;
	}
	};
	struct listElement_class {
	template <typename Iterator, typename Exception, typename Context>
	x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	if (parserContext.m_errorMsg.empty()) {
	return x3::error_handler_result::fail;
	} else {
	return x3::error_handler_result::rethrow;
	}
	}
	};
	struct list_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	const Schema& schema = parserContext.m_schema;

	if (!schema.isList(parserContext.m_curPath, {parserContext.m_curModule, ast.m_name})) {
	_pass(context) = false;
	}
	}
	};
	struct nodeup_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);

	if (parserContext.m_curPath.m_nodes.empty())
	_pass(context) = false;
	}
	};

	struct container_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	const auto& schema = parserContext.m_schema;

	if (!schema.isContainer(parserContext.m_curPath, {parserContext.m_curModule, ast.m_name}))
	_pass(context) = false;
	}
	};

	struct leaf_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	const auto& schema = parserContext.m_schema;

	if (!schema.isLeaf(parserContext.m_curPath, {parserContext.m_curModule, ast.m_name}))
	_pass(context) = false;
	}
	};

	struct module_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	const auto& schema = parserContext.m_schema;

	if (schema.isModule(parserContext.m_curPath, ast.m_name)) {
	parserContext.m_curModule = ast.m_name;
	parserContext.m_topLevelModulePresent = true;
	} else {
	parserContext.m_errorMsg = "Invalid module name.";
	_pass(context) = false;
	}
	}
	};

	struct schemaNode_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	if (ast.m_suffix.type() == typeid(nodeup_)) {
	parserContext.m_curPath.m_nodes.pop_back();
	if (parserContext.m_curPath.m_nodes.empty())
	parserContext.m_topLevelModulePresent = false;
	} else {
	parserContext.m_curPath.m_nodes.push_back(ast);
	parserContext.m_curModule = boost::none;
	}
	}
	};

	struct dataNodeList_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	parserContext.m_curPath.m_nodes.push_back(dataNodeToSchemaNode(ast));
	}
	};

	struct dataNode_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	if (ast.m_suffix.type() == typeid(nodeup_)) {
	parserContext.m_curPath.m_nodes.pop_back();
	if (parserContext.m_curPath.m_nodes.empty())
	parserContext.m_topLevelModulePresent = false;
	} else {
	parserContext.m_curPath.m_nodes.push_back(dataNodeToSchemaNode(ast));
	parserContext.m_curModule = boost::none;
	}
	}
	};

	struct absoluteStart_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	parserContext.m_curPath.m_nodes.clear();
	}
	};

	struct dataNodesListEnd_class;

	struct dataPathListEnd_class;

	struct dataPath_class {
	template <typename Iterator, typename Exception, typename Context>
	x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	if (parserContext.m_errorMsg.empty()) {
	parserContext.m_errorMsg = "Expected path.";
	return x3::error_handler_result::fail;
	} else {
	return x3::error_handler_result::rethrow;
	}
	}
	};

	struct schemaPath_class {
	template <typename Iterator, typename Exception, typename Context>
	x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	if (parserContext.m_errorMsg.empty()) {
	parserContext.m_errorMsg = "Expected path.";
	return x3::error_handler_result::fail;
	} else {
	return x3::error_handler_result::rethrow;
	}
	}
	};

	struct discard_class;

	struct ls_class;

	struct cd_class {
	template <typename Iterator, typename Exception, typename Context>
	x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const& x, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	if (parserContext.m_errorMsg.empty())
	parserContext.m_errorMsg = "Expected " + x.which() + " here:";
	return x3::error_handler_result::rethrow;
	}
	};

	struct presenceContainerPathHandler {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	const auto& schema = parserContext.m_schema;
	try {
	boost::optional<std::string> module;
	if (ast.m_path.m_nodes.back().m_prefix)
	module = ast.m_path.m_nodes.back().m_prefix.value().m_name;
	container_ cont = boost::get<container_>(ast.m_path.m_nodes.back().m_suffix);
	schemaPath_ location = pathWithoutLastNode(parserContext.m_curPath);

	if (!schema.isPresenceContainer(location, {module, cont.m_name})) {
	parserContext.m_errorMsg = "This container is not a presence container.";
	_pass(context) = false;
	}
	} catch (boost::bad_get&) {
	parserContext.m_errorMsg = "This is not a container.";
	_pass(context) = false;
	}
	}

	template <typename Iterator, typename Exception, typename Context>
	x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	if (parserContext.m_errorMsg.empty())
	parserContext.m_errorMsg = "Couldn't parse create/delete command.";
	return x3::error_handler_result::rethrow;
	}
	};

	struct create_class : public presenceContainerPathHandler {
	};

	struct delete_class : public presenceContainerPathHandler {
	};

	struct leaf_path_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T& ast, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	try {
	auto leaf = boost::get<leaf_>(ast.m_nodes.back().m_suffix);
	} catch (boost::bad_get&) {
	parserContext.m_errorMsg = "This is not a path to leaf.";
	_pass(context) = false;
	}
	}
	};

	struct leaf_data_class {
	template <typename Iterator, typename Exception, typename Context>
	x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	auto& schema = parserContext.m_schema;
	if (parserContext.m_errorMsg.empty()) {
	leaf_ leaf = boost::get<leaf_>(parserContext.m_curPath.m_nodes.back().m_suffix);
	schemaPath_ location = pathWithoutLastNode(parserContext.m_curPath);
	if (location.m_nodes.empty()) {
	parserContext.m_curModule = parserContext.m_curPath.m_nodes.back().m_prefix->m_name;
	}
	parserContext.m_errorMsg = "Expected " + leafDataTypeToString(schema.leafType(location, {parserContext.m_curModule, leaf.m_name})) + " here:";
	return x3::error_handler_result::fail;
	}
	return x3::error_handler_result::rethrow;
	}
	};

	struct leaf_data_base_class {
	yang::LeafDataTypes m_type;

	leaf_data_base_class(yang::LeafDataTypes type)
	: m_type(type)
	{
	}

	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	auto& schema = parserContext.m_schema;
	boost::optional<std::string> module;
	if (parserContext.m_curPath.m_nodes.back().m_prefix)
	module = parserContext.m_curPath.m_nodes.back().m_prefix.value().m_name;

	leaf_ leaf = boost::get<leaf_>(parserContext.m_curPath.m_nodes.back().m_suffix);
	schemaPath_ location = pathWithoutLastNode(parserContext.m_curPath);

	if (schema.leafType(location, {module, leaf.m_name}) != m_type) {
	_pass(context) = false;
	}
	}
	};

	struct leaf_data_enum_class : leaf_data_base_class {
	leaf_data_enum_class()
	: leaf_data_base_class(yang::LeafDataTypes::Enum)
	{
	}

	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const& start, Iterator const& end, T& ast, Context const& context)
	{
	leaf_data_base_class::on_success(start, end, ast, context);
	auto& parserContext = x3::get<parser_context_tag>(context);
	auto& schema = parserContext.m_schema;
	boost::optional<std::string> module;
	if (parserContext.m_curPath.m_nodes.back().m_prefix)
	module = parserContext.m_curPath.m_nodes.back().m_prefix.value().m_name;

	leaf_ leaf = boost::get<leaf_>(parserContext.m_curPath.m_nodes.back().m_suffix);
	schemaPath_ location = pathWithoutLastNode(parserContext.m_curPath);

	if (!schema.leafEnumHasValue(location, {module, leaf.m_name}, ast.m_value)) {
	_pass(context) = false;
	}
	}
	};

	struct leaf_data_decimal_class : leaf_data_base_class {
	leaf_data_decimal_class()
	: leaf_data_base_class(yang::LeafDataTypes::Decimal)
	{
	}
	};

	struct leaf_data_bool_class : leaf_data_base_class {
	leaf_data_bool_class()
	: leaf_data_base_class(yang::LeafDataTypes::Bool)
	{
	}
	};

	struct leaf_data_int_class : leaf_data_base_class {
	leaf_data_int_class()
	: leaf_data_base_class(yang::LeafDataTypes::Int)
	{
	}
	};

	struct leaf_data_uint_class : leaf_data_base_class {
	leaf_data_uint_class()
	: leaf_data_base_class(yang::LeafDataTypes::Uint)
	{
	}
	};

	struct leaf_data_string_class : leaf_data_base_class {
	leaf_data_string_class()
	: leaf_data_base_class(yang::LeafDataTypes::String)
	{
	}
	};

	struct set_class {
	template <typename Iterator, typename Exception, typename Context>
	x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const& x, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	if (parserContext.m_errorMsg.empty())
	parserContext.m_errorMsg = "Expected " + x.which() + " here:";
	return x3::error_handler_result::rethrow;
	}
	};

	struct commit_class;

	struct get_class;

	struct command_class {
	template <typename Iterator, typename Exception, typename Context>
	x3::error_handler_result on_error(Iterator&, Iterator const&, Exception const& x, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	auto& error_handler = x3::get<x3::error_handler_tag>(context).get();
	if (parserContext.m_errorMsg.empty()) {
	parserContext.m_errorMsg = "Unknown command.";
	}
	error_handler(x.where(), parserContext.m_errorMsg);
	return x3::error_handler_result::fail;
	}
	};

	struct initializePath_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	parserContext.m_curPath = parserContext.m_curPathOrig;
	parserContext.m_tmpListKeys.clear();
	parserContext.m_tmpListName.clear();
	parserContext.m_suggestions.clear();
	if (!parserContext.m_curPath.m_nodes.empty() && parserContext.m_curPath.m_nodes.at(0).m_prefix)
	parserContext.m_topLevelModulePresent = true;
	else
	parserContext.m_topLevelModulePresent = false;
	}
	};

	struct trailingSlash_class;

	struct createPathSuggestions_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const& begin, Iterator const&, T&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	const auto& schema = parserContext.m_schema;

	parserContext.m_completionIterator = begin;
	parserContext.m_suggestions = schema.childNodes(parserContext.m_curPath, Recursion::NonRecursive);
	}
	};

	std::set<std::string> generateMissingKeyCompletionSet(std::set<std::string> keysNeeded, std::set<std::string> currentSet);

	struct createKeySuggestions_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const& begin, Iterator const&, T&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	const auto& schema = parserContext.m_schema;

	parserContext.m_completionIterator = begin;

	const auto& keysNeeded = schema.listKeys(parserContext.m_curPath, {parserContext.m_curModule, parserContext.m_tmpListName});
	parserContext.m_suggestions = generateMissingKeyCompletionSet(keysNeeded, parserContext.m_tmpListKeys);
	}
	};

	struct suggestKeysEnd_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const& begin, Iterator const&, T&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	const auto& schema = parserContext.m_schema;

	parserContext.m_completionIterator = begin;
	const auto& keysNeeded = schema.listKeys(parserContext.m_curPath, {parserContext.m_curModule, parserContext.m_tmpListName});
	if (generateMissingKeyCompletionSet(keysNeeded, parserContext.m_tmpListKeys).empty()) {
	parserContext.m_suggestions = {"]/"};
	} else {
	parserContext.m_suggestions = {"]"};
	}
	}
	};

	struct commandNamesVisitor {
	template <typename T>
	auto operator()(boost::type<T>)
	{
	return T::name;
	}
	};

	struct createCommandSuggestions_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const& begin, Iterator const&, T&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);
	parserContext.m_completionIterator = begin;

	parserContext.m_suggestions.clear();
	boost::mpl::for_each<CommandTypes, boost::type<boost::mpl::_>>([&parserContext](auto cmd) {
	parserContext.m_suggestions.emplace(commandNamesVisitor()(cmd));
	});
	}
	};

	struct completing_class {
	template <typename T, typename Iterator, typename Context>
	void on_success(Iterator const&, Iterator const&, T&, Context const& context)
	{
	auto& parserContext = x3::get<parser_context_tag>(context);

	if (!parserContext.m_completing)
	_pass(context) = false;
	}
	};