blob: 85833f1e9816f6f8c3b7ee2718c012f7028491a6 [file] [log] [blame]
/*
* 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>
*
*/
#include <boost/algorithm/string/predicate.hpp>
#include <boost/mpl/for_each.hpp>
#include <iostream>
#include <sstream>
#include "datastore_access.hpp"
#include "interpreter.hpp"
#include "utils.hpp"
struct pathToStringVisitor : boost::static_visitor<std::string> {
std::string operator()(const module_& path) const
{
using namespace std::string_literals;
return "/"s + boost::get<module_>(path).m_name + ":*";
}
std::string operator()(const schemaPath_& path) const
{
return pathToSchemaString(path, Prefixes::WhenNeeded);
}
std::string operator()(const dataPath_& path) const
{
return pathToDataString(path, Prefixes::WhenNeeded);
}
};
template <typename PathType>
std::string pathToString(const PathType& path)
{
return boost::apply_visitor(pathToStringVisitor(), path);
}
void Interpreter::operator()(const commit_&) const
{
m_datastore.commitChanges();
}
void Interpreter::operator()(const discard_&) const
{
m_datastore.discardChanges();
}
void Interpreter::operator()(const set_& set) const
{
auto data = set.m_data;
// If the user didn't supply a module prefix for identityref, we need to add it ourselves
if (data.type() == typeid(identityRef_)) {
auto identityRef = boost::get<identityRef_>(data);
if (!identityRef.m_prefix) {
identityRef.m_prefix = set.m_path.m_nodes.front().m_prefix.value();
data = identityRef;
}
}
m_datastore.setLeaf(pathToString(toCanonicalPath(set.m_path)), data);
}
void Interpreter::operator()(const get_& get) const
{
auto items = m_datastore.getItems(pathToString(toCanonicalPath(get.m_path)));
for (auto it = items.begin(); it != items.end(); it++) {
auto [path, value] = *it;
if (value.type() == typeid(special_) && boost::get<special_>(value).m_value == SpecialValue::LeafList) {
auto leafListPrefix = path;
std::cout << path << " = " << leafDataToString(value) << std::endl;
while (it + 1 != items.end() && boost::starts_with((it + 1) ->first, leafListPrefix)) {
++it;
std::cout << stripLeafListValueFromPath(it->first) << " = " << leafDataToString(it->second) << std::endl;
}
} else {
std::cout << path << " = " << leafDataToString(value) << std::endl;
}
}
}
void Interpreter::operator()(const cd_& cd) const
{
m_parser.changeNode(cd.m_path);
}
void Interpreter::operator()(const create_& create) const
{
m_datastore.createItem(pathToString(toCanonicalPath(create.m_path)));
}
void Interpreter::operator()(const delete_& delet) const
{
m_datastore.deleteItem(pathToString(toCanonicalPath(delet.m_path)));
}
void Interpreter::operator()(const ls_& ls) const
{
std::cout << "Possible nodes:" << std::endl;
auto recursion{Recursion::NonRecursive};
for (auto it : ls.m_options) {
if (it == LsOption::Recursive)
recursion = Recursion::Recursive;
}
auto toPrint = m_datastore.schema()->availableNodes(toCanonicalPath(ls.m_path), recursion);
for (const auto& it : toPrint) {
std::cout << (it.first ? *it.first + ":" : "" ) + it.second << std::endl;
}
}
void Interpreter::operator()(const copy_& copy) const
{
m_datastore.copyConfig(copy.m_source, copy.m_destination);
}
std::string Interpreter::buildTypeInfo(const std::string& path) const
{
std::ostringstream ss;
switch (m_datastore.schema()->nodeType(path)) {
case yang::NodeTypes::Container:
ss << "container";
break;
case yang::NodeTypes::PresenceContainer:
ss << "presence container";
break;
case yang::NodeTypes::Leaf:
{
auto leafType = m_datastore.schema()->leafType(path);
auto typedefName = m_datastore.schema()->leafTypeName(path);
std::string baseTypeStr;
if (std::holds_alternative<yang::LeafRef>(leafType.m_type)) {
ss << "-> ";
ss << m_datastore.schema()->leafrefPath(path) << " ";
baseTypeStr = leafDataTypeToString(std::get<yang::LeafRef>(leafType.m_type).m_targetType->m_type);
} else {
baseTypeStr = leafDataTypeToString(leafType.m_type);
}
if (typedefName) {
ss << *typedefName << " (" << baseTypeStr << ")";
} else {
ss << baseTypeStr;
}
if (leafType.m_units) {
ss << " [" + *leafType.m_units + "]";
}
if (m_datastore.schema()->leafIsKey(path)) {
ss << " (key)";
}
if (auto defaultValue = m_datastore.schema()->defaultValue(path)) {
ss << " default: " << leafDataToString(*defaultValue);
}
break;
}
case yang::NodeTypes::List:
ss << "list";
break;
case yang::NodeTypes::Action:
case yang::NodeTypes::AnyXml:
case yang::NodeTypes::LeafList:
case yang::NodeTypes::Notification:
case yang::NodeTypes::Rpc:
throw std::logic_error("describe got an rpc or an action: this should never happen, because their paths cannot be parsed");
}
if (!m_datastore.schema()->isConfig(path)) {
ss << " (ro)";
}
return ss.str();
}
void Interpreter::operator()(const describe_& describe) const
{
auto path = pathToString(toCanonicalPath(describe.m_path));
auto status = m_datastore.schema()->status(path);
auto statusStr = status == yang::Status::Deprecated ? " (deprecated)" :
status == yang::Status::Obsolete ? " (obsolete)" :
"";
std::cout << path << ": " << buildTypeInfo(path) << statusStr << std::endl;
if (auto description = m_datastore.schema()->description(path)) {
std::cout << std::endl << *description << std::endl;
}
}
void Interpreter::operator()(const move_& move) const
{
m_datastore.moveItem(pathToDataString(move.m_source, Prefixes::WhenNeeded), move.m_destination);
}
void Interpreter::operator()(const dump_& dump) const
{
std::cout << m_datastore.dump(dump.m_format) << "\n";
}
struct commandLongHelpVisitor : boost::static_visitor<const char*> {
template <typename T>
auto constexpr operator()(boost::type<T>) const
{
return T::longHelp;
}
};
struct commandShortHelpVisitor : boost::static_visitor<const char*> {
template <typename T>
auto constexpr operator()(boost::type<T>) const
{
return T::shortHelp;
}
};
void Interpreter::operator()(const help_& help) const
{
if (help.m_cmd)
std::cout << boost::apply_visitor(commandLongHelpVisitor(), help.m_cmd.get()) << std::endl;
else
boost::mpl::for_each<CommandTypes, boost::type<boost::mpl::_>>([](auto cmd) {
std::cout << commandShortHelpVisitor()(cmd) << std::endl;
});
}
template <typename PathType>
boost::variant<dataPath_, schemaPath_, module_> Interpreter::toCanonicalPath(const boost::optional<PathType>& optPath) const
{
if (!optPath) {
return m_parser.currentPath();
}
return toCanonicalPath(*optPath);
}
struct impl_toCanonicalPath {
const dataPath_& m_parserPath;
using ReturnType = boost::variant<dataPath_, schemaPath_, module_>;
impl_toCanonicalPath(const dataPath_& parserPath)
: m_parserPath(parserPath)
{
}
ReturnType operator()(const module_& path) const
{
return path;
}
ReturnType operator()(const schemaPath_& path) const
{
return impl(path);
}
ReturnType operator()(const dataPath_& path) const
{
return impl(path);
}
private:
template <typename PathType>
ReturnType impl(const PathType& suffix) const
{
PathType res = [this] {
if constexpr (std::is_same<PathType, schemaPath_>()) {
return dataPathToSchemaPath(m_parserPath);
} else {
return m_parserPath;
}
}();
if (suffix.m_scope == Scope::Absolute) {
res = {Scope::Absolute, {}};
}
for (const auto& fragment : suffix.m_nodes) {
res.pushFragment(fragment);
}
return res;
}
};
template <typename PathType>
boost::variant<dataPath_, schemaPath_, module_> Interpreter::toCanonicalPath(const PathType& path) const
{
if constexpr (std::is_same<PathType, dataPath_>()) {
return impl_toCanonicalPath(m_parser.currentPath())(path);
} else {
return boost::apply_visitor(impl_toCanonicalPath(m_parser.currentPath()), path);
}
}
Interpreter::Interpreter(Parser& parser, DatastoreAccess& datastore)
: m_parser(parser)
, m_datastore(datastore)
{
}