// Copyright 2012 Google Inc. // All rights reserved. // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in the // documentation and/or other materials provided with the distribution. // * Neither the name of Google Inc. nor the names of its contributors // may be used to endorse or promote products derived from this software // without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. #include "utils/config/tree.ipp" #include "utils/config/exceptions.hpp" #include "utils/config/keys.hpp" #include "utils/config/nodes.ipp" #include "utils/format/macros.hpp" namespace config = utils::config; /// Constructor. config::tree::tree(void) : _root(new detail::static_inner_node()) { } /// Constructor with a non-empty root. /// /// \param root The root to the tree to be owned by this instance. config::tree::tree(detail::static_inner_node* root) : _root(root) { } /// Destructor. config::tree::~tree(void) { } /// Generates a deep copy of the input tree. /// /// \return A new tree that is an exact copy of this tree. config::tree config::tree::deep_copy(void) const { detail::static_inner_node* new_root = dynamic_cast< detail::static_inner_node* >(_root->deep_copy()); return config::tree(new_root); } /// Registers a node as being dynamic. /// /// This operation creates the given key as an inner node. Further set /// operations that trespass this node will automatically create any missing /// keys. /// /// This method does not raise errors on invalid/unknown keys or other /// tree-related issues. The reasons is that define() is a method that does not /// depend on user input: it is intended to pre-populate the tree with a /// specific structure, and that happens once at coding time. /// /// \param dotted_key The key to be registered in dotted representation. void config::tree::define_dynamic(const std::string& dotted_key) { try { const detail::tree_key key = detail::parse_key(dotted_key); _root->define(key, 0, detail::new_node< detail::dynamic_inner_node >); } catch (const error& e) { UNREACHABLE_MSG("define() failing due to key errors is a programming " "mistake: " + std::string(e.what())); } } /// Checks if a given node is set. /// /// \param dotted_key The key to be checked. /// /// \return True if the key is set to a specific value (not just defined). /// False if the key is not set or if the key does not exist. /// /// \throw invalid_key_error If the provided key has an invalid format. bool config::tree::is_set(const std::string& dotted_key) const { const detail::tree_key key = detail::parse_key(dotted_key); try { const detail::base_node* raw_node = _root->lookup_ro(key, 0); try { const leaf_node& child = dynamic_cast< const leaf_node& >( *raw_node); return child.is_set(); } catch (const std::bad_cast& unused_error) { return false; } } catch (const unknown_key_error& unused_error) { return false; } } /// Pushes a leaf node's value onto the Lua stack. /// /// \param dotted_key The key to be pushed. /// \param state The Lua state into which to push the key's value. /// /// \throw invalid_key_error If the provided key has an invalid format. /// \throw unknown_key_error If the provided key is unknown. void config::tree::push_lua(const std::string& dotted_key, lutok::state& state) const { const detail::tree_key key = detail::parse_key(dotted_key); const detail::base_node* raw_node = _root->lookup_ro(key, 0); try { const leaf_node& child = dynamic_cast< const leaf_node& >(*raw_node); child.push_lua(state); } catch (const std::bad_cast& unused_error) { throw unknown_key_error(key); } } /// Sets a leaf node's value from a value in the Lua stack. /// /// \param dotted_key The key to be set. /// \param state The Lua state from which to retrieve the value. /// \param value_index The position in the Lua stack holding the value. /// /// \throw invalid_key_error If the provided key has an invalid format. /// \throw unknown_key_error If the provided key is unknown. /// \throw value_error If the value mismatches the node type. void config::tree::set_lua(const std::string& dotted_key, lutok::state& state, const int value_index) { const detail::tree_key key = detail::parse_key(dotted_key); detail::base_node* raw_node = _root->lookup_rw( key, 0, detail::new_node< string_node >); try { leaf_node& child = dynamic_cast< leaf_node& >(*raw_node); child.set_lua(state, value_index); } catch (const std::bad_cast& unused_error) { throw value_error(F("Invalid value for key '%s'") % detail::flatten_key(key)); } } /// Gets the value of a node as a plain string. /// /// \param dotted_key The key to be looked up. /// /// \return The value of the located node as a string. /// /// \throw invalid_key_error If the provided key has an invalid format. /// \throw unknown_key_error If the provided key is unknown. std::string config::tree::lookup_string(const std::string& dotted_key) const { const detail::tree_key key = detail::parse_key(dotted_key); const detail::base_node* raw_node = _root->lookup_ro(key, 0); try { const leaf_node& child = dynamic_cast< const leaf_node& >(*raw_node); return child.to_string(); } catch (const std::bad_cast& unused_error) { throw unknown_key_error(key); } } /// Sets the value of a leaf addressed by its key from a string value. /// /// This respects the native types of all the nodes that have been predefined. /// For new nodes under a dynamic subtree, this has no mechanism of determining /// what type they need to have, so they are created as plain string nodes. /// /// \param dotted_key The key to be registered in dotted representation. /// \param raw_value The string representation of the value to set the node to. /// /// \throw invalid_key_error If the provided key has an invalid format. /// \throw unknown_key_error If the provided key is unknown. /// \throw value_error If the value mismatches the node type. void config::tree::set_string(const std::string& dotted_key, const std::string& raw_value) { const detail::tree_key key = detail::parse_key(dotted_key); detail::base_node* raw_node = _root->lookup_rw( key, 0, detail::new_node< string_node >); try { leaf_node& child = dynamic_cast< leaf_node& >(*raw_node); child.set_string(raw_value); } catch (const std::bad_cast& unused_error) { throw value_error(F("Invalid value for key '%s'") % detail::flatten_key(key)); } } /// Converts the tree to a collection of key/value string pairs. /// /// \param dotted_key Subtree from which to start the export. /// \param strip_key If true, remove the dotted_key prefix from the resulting /// properties. /// /// \return A map of keys to values in their textual representation. /// /// \throw invalid_key_error If the provided key has an invalid format. /// \throw unknown_key_error If the provided key is unknown. /// \throw value_error If the provided key points to a leaf. config::properties_map config::tree::all_properties(const std::string& dotted_key, const bool strip_key) const { PRE(!strip_key || !dotted_key.empty()); properties_map properties; detail::tree_key key; const detail::base_node* raw_node; if (dotted_key.empty()) { raw_node = _root.get(); } else { key = detail::parse_key(dotted_key); raw_node = _root->lookup_ro(key, 0); } try { const detail::inner_node& child = dynamic_cast< const detail::inner_node& >(*raw_node); child.all_properties(properties, key); } catch (const std::bad_cast& unused_error) { INV(!dotted_key.empty()); throw value_error(F("Cannot export properties from a leaf node; " "'%s' given") % dotted_key); } if (strip_key) { properties_map stripped; for (properties_map::const_iterator iter = properties.begin(); iter != properties.end(); ++iter) { stripped[(*iter).first.substr(dotted_key.length() + 1)] = (*iter).second; } properties = stripped; } return properties; } /// Equality comparator. /// /// \param other The other object to compare this one to. /// /// \return True if this object and other are equal; false otherwise. bool config::tree::operator==(const tree& other) const { // TODO(jmmv): Would be nicer to perform the comparison directly on the // nodes, instead of exporting the values to strings first. return _root == other._root || all_properties() == other.all_properties(); } /// Inequality comparator. /// /// \param other The other object to compare this one to. /// /// \return True if this object and other are different; false otherwise. bool config::tree::operator!=(const tree& other) const { return !(*this == other); }