src/yang_access.cpp - CzechLight/netconf-cli - Gitiles

 #include <boost/algorithm/string/predicate.hpp>
 #include <experimental/iterator>
 #include <iostream>
 #include <libyang/Tree_Data.hpp>
 #include <libyang/libyang.h>
 #include "UniqueResource.hpp"
 #include "libyang_utils.hpp"
 #include "utils.hpp"
 #include "yang_access.hpp"
 #include "yang_schema.hpp"

 namespace {
 template <typename Type> using lyPtrDeleter_type = void (*)(Type*);
 template <typename Type> const lyPtrDeleter_type<Type> lyPtrDeleter;
 template <> const auto lyPtrDeleter<ly_set> = ly_set_free;
 template <> const auto lyPtrDeleter<ly_ctx> = static_cast<lyPtrDeleter_type<ly_ctx>>([] (auto* ptr) {ly_ctx_destroy(ptr, nullptr);});
 template <> const auto lyPtrDeleter<lyd_node> = lyd_free_withsiblings;

 template <typename Type>
 auto lyWrap(Type* ptr)
 {
     return std::unique_ptr<Type, lyPtrDeleter_type<Type>>{ptr, lyPtrDeleter<Type>};
 }

 // Convenient for functions that take m_datastore as an argument
 using DatastoreType = std::unique_ptr<lyd_node, lyPtrDeleter_type<lyd_node>>;
 }

 YangAccess::YangAccess()
     : m_ctx(lyWrap(ly_ctx_new(nullptr, LY_CTX_DISABLE_SEARCHDIR_CWD)))
     , m_datastore(lyWrap<lyd_node>(nullptr))
     , m_schema(std::make_shared<YangSchema>(libyang::create_new_Context(m_ctx.get())))
 {
 }

 YangAccess::~YangAccess()
 {
 }

 [[noreturn]] void YangAccess::getErrorsAndThrow() const
 {
     auto errors = libyang::get_ly_errors(libyang::create_new_Context(m_ctx.get()));
     std::vector<DatastoreError> errorsRes;
     for (const auto& error : errors) {
         using namespace std::string_view_literals;
         errorsRes.emplace_back(error->errmsg(), error->errpath() != ""sv ? std::optional{error->errpath()} : std::nullopt);
     }

     throw DatastoreException(errorsRes);
 }

 void YangAccess::impl_newPath(const std::string& path, const std::optional<std::string>& value)
 {
     auto newNode = lyd_new_path(m_datastore.get(), m_ctx.get(), path.c_str(), value ? (void*)value->c_str() : nullptr, LYD_ANYDATA_CONSTSTRING, LYD_PATH_OPT_UPDATE);
     if (!newNode) {
         getErrorsAndThrow();
     }
     if (!m_datastore) {
         m_datastore = lyWrap(newNode);
     }
 }

 namespace {
 void impl_unlink(DatastoreType& datastore, lyd_node* what)
 {
     // If the node to be unlinked is the one our datastore variable points to, we need to find a new one to point to (one of its siblings)
     if (datastore.get() == what) {
         auto oldDatastore = datastore.release();
         if (oldDatastore->prev != oldDatastore) {
             datastore = lyWrap(oldDatastore->prev);
         } else {
             datastore = lyWrap(oldDatastore->next);
         }
     }

     lyd_unlink(what);
 }
 }

 void YangAccess::impl_removeNode(const std::string& path)
 {
     auto set = lyWrap(lyd_find_path(m_datastore.get(), path.c_str()));
     if (!set || set->number == 0) {
         // Check if schema node exists - lyd_find_path first checks if the first argument is non-null before checking for path validity
         if (!ly_ctx_get_node(m_ctx.get(), nullptr, path.c_str(), 0)) {
             throw DatastoreException{{DatastoreError{"Schema node doesn't exist.", path}}};
         }
         // Check if libyang found another error
         if (ly_err_first(m_ctx.get())) {
             getErrorsAndThrow();
         }

         // Otherwise the datastore just doesn't contain the wanted node.
         throw DatastoreException{{DatastoreError{"Data node doesn't exist.", path}}};
     }

     auto toRemove = set->set.d[0];

     impl_unlink(m_datastore, toRemove);

     lyd_free(toRemove);
 }

 void YangAccess::validate()
 {
     auto datastore = m_datastore.release();
     lyd_validate(&datastore, LYD_OPT_DATA | LYD_OPT_DATA_NO_YANGLIB, m_ctx.get());
     m_datastore = lyWrap(datastore);
 }

 DatastoreAccess::Tree YangAccess::getItems(const std::string& path)
 {
     DatastoreAccess::Tree res;
     if (!m_datastore) {
         return res;
     }

     auto set = lyWrap(lyd_find_path(m_datastore.get(), path == "/" ? "/*" : path.c_str()));
     auto setWrapper = libyang::Set(set.get(), nullptr);

     lyNodesToTree(res, setWrapper.data());
     return res;
 }

 void YangAccess::setLeaf(const std::string& path, leaf_data_ value)
 {
     auto lyValue = value.type() == typeid(empty_) ? std::nullopt : std::optional(leafDataToString(value));
     impl_newPath(path, lyValue);
 }

 void YangAccess::createItem(const std::string& path)
 {
     impl_newPath(path);
 }

 void YangAccess::deleteItem(const std::string& path)
 {
     impl_removeNode(path);
 }

 namespace {
 struct impl_moveItem {
     DatastoreType& m_datastore;
     lyd_node* m_sourceNode;

     void operator()(yang::move::Absolute absolute) const
     {
         auto set = lyWrap(lyd_find_instance(m_sourceNode, m_sourceNode->schema));
         if (set->number == 1) { // m_sourceNode is the sole instance, do nothing
             return;
         }

         doUnlink();
         switch (absolute) {
         case yang::move::Absolute::Begin:
             if (set->set.d[0] == m_sourceNode) { // List is already at the beginning, do nothing
                 return;
             }
             lyd_insert_before(set->set.d[0], m_sourceNode);
             return;
         case yang::move::Absolute::End:
             if (set->set.d[set->number - 1] == m_sourceNode) { // List is already at the end, do nothing
                 return;
             }
             lyd_insert_after(set->set.d[set->number - 1], m_sourceNode);
             return;
         }
     }

     void operator()(const yang::move::Relative& relative) const
     {
         auto keySuffix = m_sourceNode->schema->nodetype == LYS_LIST ? instanceToString(relative.m_path)
                                                                     : leafDataToString(relative.m_path.at("."));
         lyd_node* destNode;
         lyd_find_sibling_val(m_sourceNode, m_sourceNode->schema, keySuffix.c_str(), &destNode);

         doUnlink();
         if (relative.m_position == yang::move::Relative::Position::After) {
             lyd_insert_after(destNode, m_sourceNode);
         } else {
             lyd_insert_before(destNode, m_sourceNode);
         }
     }

 private:
     void doUnlink() const
     {
         impl_unlink(m_datastore, m_sourceNode);
     }
 };
 }

 void YangAccess::moveItem(const std::string& source, std::variant<yang::move::Absolute, yang::move::Relative> move)
 {
     auto set = lyWrap(lyd_find_path(m_datastore.get(), source.c_str()));
     if (!set) { // Error, the node probably doesn't exist in the schema
         getErrorsAndThrow();
     }
     if (set->number == 0) {
         return;
     }
     auto sourceNode = set->set.d[0];
     std::visit(impl_moveItem{m_datastore, sourceNode}, move);
 }

 void YangAccess::commitChanges()
 {
     validate();
 }

 void YangAccess::discardChanges()
 {
 }

 DatastoreAccess::Tree YangAccess::executeRpc(const std::string& path, const Tree& input)
 {
     auto root = lyWrap(lyd_new_path(nullptr, m_ctx.get(), path.c_str(), nullptr, LYD_ANYDATA_CONSTSTRING, 0));
     if (!root) {
         getErrorsAndThrow();
     }
     for (const auto& [k, v] : input) {
         auto node = lyd_new_path(root.get(), m_ctx.get(), joinPaths(path, k).c_str(), (void*)leafDataToString(v).c_str(), LYD_ANYDATA_CONSTSTRING, 0);
         if (!node) {
             getErrorsAndThrow();
         }
     }
     throw std::logic_error("in-memory datastore doesn't support executing RPCs.");
 }

 void YangAccess::copyConfig(const Datastore source, const Datastore dest)
 {
     if (source == Datastore::Startup && dest == Datastore::Running) {
         m_datastore = nullptr;
     }
 }

 std::shared_ptr<Schema> YangAccess::schema()
 {
     return m_schema;
 }

 std::vector<ListInstance> YangAccess::listInstances(const std::string& path)
 {
     std::vector<ListInstance> res;
     if (!m_datastore) {
         return res;
     }

     auto instances = lyWrap(lyd_find_path(m_datastore.get(), path.c_str()));
     auto instancesWrapper = libyang::Set(instances.get(), nullptr);
     for (const auto& list : instancesWrapper.data()) {
         ListInstance instance;
         for (const auto& child : list->child()->tree_for()) {
             if (child->schema()->nodetype() == LYS_LEAF) {
                 libyang::Schema_Node_Leaf leafSchema(child->schema());
                 if (leafSchema.is_key()) {
                     libyang::Data_Node_Leaf_List leafData(child);
                     instance.insert({leafSchema.name(), leafValueFromValue(leafData.value(), leafSchema.type()->base())});
                 }
             }
         }
         res.push_back(instance);
     }
     return res;
 }

 std::string impl_dumpConfig(const lyd_node* datastore, LYD_FORMAT format)
 {
     char* output;
     lyd_print_mem(&output, datastore, format, LYP_WITHSIBLINGS);

     if (output) {
         std::string res = output;
         free(output);
         return res;
     }

     return "";
 }

 std::string YangAccess::dumpXML() const
 {
     return impl_dumpConfig(m_datastore.get(), LYD_XML);
 }

 std::string YangAccess::dumpJSON() const
 {
     return impl_dumpConfig(m_datastore.get(), LYD_JSON);
 }

 void YangAccess::addSchemaFile(const std::string& path)
 {
     m_schema->addSchemaFile(path.c_str());
 }

 void YangAccess::addSchemaDir(const std::string& path)
 {
     m_schema->addSchemaDirectory(path.c_str());
 }

 void YangAccess::enableFeature(const std::string& module, const std::string& feature)
 {
     m_schema->enableFeature(module, feature);
 }
	#include <boost/algorithm/string/predicate.hpp>
	#include <experimental/iterator>
	#include <iostream>
	#include <libyang/Tree_Data.hpp>
	#include <libyang/libyang.h>
	#include "UniqueResource.hpp"
	#include "libyang_utils.hpp"
	#include "utils.hpp"
	#include "yang_access.hpp"
	#include "yang_schema.hpp"

	namespace {
	template <typename Type> using lyPtrDeleter_type = void ()(Type);
	template <typename Type> const lyPtrDeleter_type<Type> lyPtrDeleter;
	template <> const auto lyPtrDeleter<ly_set> = ly_set_free;
	template <> const auto lyPtrDeleter<ly_ctx> = static_cast<lyPtrDeleter_type<ly_ctx>>([] (auto* ptr) {ly_ctx_destroy(ptr, nullptr);});
	template <> const auto lyPtrDeleter<lyd_node> = lyd_free_withsiblings;

	template <typename Type>
	auto lyWrap(Type* ptr)
	{
	return std::unique_ptr<Type, lyPtrDeleter_type<Type>>{ptr, lyPtrDeleter<Type>};
	}

	// Convenient for functions that take m_datastore as an argument
	using DatastoreType = std::unique_ptr<lyd_node, lyPtrDeleter_type<lyd_node>>;
	}

	YangAccess::YangAccess()
	: m_ctx(lyWrap(ly_ctx_new(nullptr, LY_CTX_DISABLE_SEARCHDIR_CWD)))
	, m_datastore(lyWrap<lyd_node>(nullptr))
	, m_schema(std::make_shared<YangSchema>(libyang::create_new_Context(m_ctx.get())))
	{
	}

	YangAccess::~YangAccess()
	{
	}

	[[noreturn]] void YangAccess::getErrorsAndThrow() const
	{
	auto errors = libyang::get_ly_errors(libyang::create_new_Context(m_ctx.get()));
	std::vector<DatastoreError> errorsRes;
	for (const auto& error : errors) {
	using namespace std::string_view_literals;
	errorsRes.emplace_back(error->errmsg(), error->errpath() != ""sv ? std::optional{error->errpath()} : std::nullopt);
	}

	throw DatastoreException(errorsRes);
	}

	void YangAccess::impl_newPath(const std::string& path, const std::optional<std::string>& value)
	{
	auto newNode = lyd_new_path(m_datastore.get(), m_ctx.get(), path.c_str(), value ? (void*)value->c_str() : nullptr, LYD_ANYDATA_CONSTSTRING, LYD_PATH_OPT_UPDATE);
	if (!newNode) {
	getErrorsAndThrow();
	}
	if (!m_datastore) {
	m_datastore = lyWrap(newNode);
	}
	}

	namespace {
	void impl_unlink(DatastoreType& datastore, lyd_node* what)
	{
	// If the node to be unlinked is the one our datastore variable points to, we need to find a new one to point to (one of its siblings)
	if (datastore.get() == what) {
	auto oldDatastore = datastore.release();
	if (oldDatastore->prev != oldDatastore) {
	datastore = lyWrap(oldDatastore->prev);
	} else {
	datastore = lyWrap(oldDatastore->next);
	}
	}

	lyd_unlink(what);
	}
	}

	void YangAccess::impl_removeNode(const std::string& path)
	{
	auto set = lyWrap(lyd_find_path(m_datastore.get(), path.c_str()));
	if (!set \|\| set->number == 0) {
	// Check if schema node exists - lyd_find_path first checks if the first argument is non-null before checking for path validity
	if (!ly_ctx_get_node(m_ctx.get(), nullptr, path.c_str(), 0)) {
	throw DatastoreException{{DatastoreError{"Schema node doesn't exist.", path}}};
	}
	// Check if libyang found another error
	if (ly_err_first(m_ctx.get())) {
	getErrorsAndThrow();
	}

	// Otherwise the datastore just doesn't contain the wanted node.
	throw DatastoreException{{DatastoreError{"Data node doesn't exist.", path}}};
	}

	auto toRemove = set->set.d[0];

	impl_unlink(m_datastore, toRemove);

	lyd_free(toRemove);
	}

	void YangAccess::validate()
	{
	auto datastore = m_datastore.release();
	lyd_validate(&datastore, LYD_OPT_DATA \| LYD_OPT_DATA_NO_YANGLIB, m_ctx.get());
	m_datastore = lyWrap(datastore);
	}

	DatastoreAccess::Tree YangAccess::getItems(const std::string& path)
	{
	DatastoreAccess::Tree res;
	if (!m_datastore) {
	return res;
	}

	auto set = lyWrap(lyd_find_path(m_datastore.get(), path == "/" ? "/*" : path.c_str()));
	auto setWrapper = libyang::Set(set.get(), nullptr);

	lyNodesToTree(res, setWrapper.data());
	return res;
	}

	void YangAccess::setLeaf(const std::string& path, leaf_data_ value)
	{
	auto lyValue = value.type() == typeid(empty_) ? std::nullopt : std::optional(leafDataToString(value));
	impl_newPath(path, lyValue);
	}

	void YangAccess::createItem(const std::string& path)
	{
	impl_newPath(path);
	}

	void YangAccess::deleteItem(const std::string& path)
	{
	impl_removeNode(path);
	}

	namespace {
	struct impl_moveItem {
	DatastoreType& m_datastore;
	lyd_node* m_sourceNode;

	void operator()(yang::move::Absolute absolute) const
	{
	auto set = lyWrap(lyd_find_instance(m_sourceNode, m_sourceNode->schema));
	if (set->number == 1) { // m_sourceNode is the sole instance, do nothing
	return;
	}

	doUnlink();
	switch (absolute) {
	case yang::move::Absolute::Begin:
	if (set->set.d[0] == m_sourceNode) { // List is already at the beginning, do nothing
	return;
	}
	lyd_insert_before(set->set.d[0], m_sourceNode);
	return;
	case yang::move::Absolute::End:
	if (set->set.d[set->number - 1] == m_sourceNode) { // List is already at the end, do nothing
	return;
	}
	lyd_insert_after(set->set.d[set->number - 1], m_sourceNode);
	return;
	}
	}

	void operator()(const yang::move::Relative& relative) const
	{
	auto keySuffix = m_sourceNode->schema->nodetype == LYS_LIST ? instanceToString(relative.m_path)
	: leafDataToString(relative.m_path.at("."));
	lyd_node* destNode;
	lyd_find_sibling_val(m_sourceNode, m_sourceNode->schema, keySuffix.c_str(), &destNode);

	doUnlink();
	if (relative.m_position == yang::move::Relative::Position::After) {
	lyd_insert_after(destNode, m_sourceNode);
	} else {
	lyd_insert_before(destNode, m_sourceNode);
	}
	}

	private:
	void doUnlink() const
	{
	impl_unlink(m_datastore, m_sourceNode);
	}
	};
	}

	void YangAccess::moveItem(const std::string& source, std::variant<yang::move::Absolute, yang::move::Relative> move)
	{
	auto set = lyWrap(lyd_find_path(m_datastore.get(), source.c_str()));
	if (!set) { // Error, the node probably doesn't exist in the schema
	getErrorsAndThrow();
	}
	if (set->number == 0) {
	return;
	}
	auto sourceNode = set->set.d[0];
	std::visit(impl_moveItem{m_datastore, sourceNode}, move);
	}

	void YangAccess::commitChanges()
	{
	validate();
	}

	void YangAccess::discardChanges()
	{
	}

	DatastoreAccess::Tree YangAccess::executeRpc(const std::string& path, const Tree& input)
	{
	auto root = lyWrap(lyd_new_path(nullptr, m_ctx.get(), path.c_str(), nullptr, LYD_ANYDATA_CONSTSTRING, 0));
	if (!root) {
	getErrorsAndThrow();
	}
	for (const auto& [k, v] : input) {
	auto node = lyd_new_path(root.get(), m_ctx.get(), joinPaths(path, k).c_str(), (void*)leafDataToString(v).c_str(), LYD_ANYDATA_CONSTSTRING, 0);
	if (!node) {
	getErrorsAndThrow();
	}
	}
	throw std::logic_error("in-memory datastore doesn't support executing RPCs.");
	}

	void YangAccess::copyConfig(const Datastore source, const Datastore dest)
	{
	if (source == Datastore::Startup && dest == Datastore::Running) {
	m_datastore = nullptr;
	}
	}

	std::shared_ptr<Schema> YangAccess::schema()
	{
	return m_schema;
	}

	std::vector<ListInstance> YangAccess::listInstances(const std::string& path)
	{
	std::vector<ListInstance> res;
	if (!m_datastore) {
	return res;
	}

	auto instances = lyWrap(lyd_find_path(m_datastore.get(), path.c_str()));
	auto instancesWrapper = libyang::Set(instances.get(), nullptr);
	for (const auto& list : instancesWrapper.data()) {
	ListInstance instance;
	for (const auto& child : list->child()->tree_for()) {
	if (child->schema()->nodetype() == LYS_LEAF) {
	libyang::Schema_Node_Leaf leafSchema(child->schema());
	if (leafSchema.is_key()) {
	libyang::Data_Node_Leaf_List leafData(child);
	instance.insert({leafSchema.name(), leafValueFromValue(leafData.value(), leafSchema.type()->base())});
	}
	}
	}
	res.push_back(instance);
	}
	return res;
	}

	std::string impl_dumpConfig(const lyd_node* datastore, LYD_FORMAT format)
	{
	char* output;
	lyd_print_mem(&output, datastore, format, LYP_WITHSIBLINGS);

	if (output) {
	std::string res = output;
	free(output);
	return res;
	}

	return "";
	}

	std::string YangAccess::dumpXML() const
	{
	return impl_dumpConfig(m_datastore.get(), LYD_XML);
	}

	std::string YangAccess::dumpJSON() const
	{
	return impl_dumpConfig(m_datastore.get(), LYD_JSON);
	}

	void YangAccess::addSchemaFile(const std::string& path)
	{
	m_schema->addSchemaFile(path.c_str());
	}

	void YangAccess::addSchemaDir(const std::string& path)
	{
	m_schema->addSchemaDirectory(path.c_str());
	}

	void YangAccess::enableFeature(const std::string& module, const std::string& feature)
	{
	m_schema->enableFeature(module, feature);
	}