#include "yaml-cpp/node.h"
#include "yaml-cpp/aliasmanager.h"
#include "yaml-cpp/emitfromevents.h"
#include "yaml-cpp/emitter.h"
#include "yaml-cpp/eventhandler.h"
#include "iterpriv.h"
#include "nodebuilder.h"
#include "nodeownership.h"
#include "scanner.h"
#include "tag.h"
#include "token.h"
#include <cassert>
#include <stdexcept>
namespace YAML
{
bool ltnode::operator()(const Node *pNode1, const Node *pNode2) const {
return *pNode1 < *pNode2;
}
Node::Node(): m_pOwnership(new NodeOwnership), m_type(NodeType::Null)
{
}
Node::Node(NodeOwnership& owner): m_pOwnership(new NodeOwnership(&owner)), m_type(NodeType::Null)
{
}
Node::~Node()
{
Clear();
}
void Node::Clear()
{
m_pOwnership.reset(new NodeOwnership);
m_type = NodeType::Null;
m_tag.clear();
m_scalarData.clear();
m_seqData.clear();
m_mapData.clear();
}
bool Node::IsAliased() const
{
return m_pOwnership->IsAliased(*this);
}
Node& Node::CreateNode()
{
return m_pOwnership->Create();
}
std::auto_ptr<Node> Node::Clone() const
{
std::auto_ptr<Node> pNode(new Node);
NodeBuilder nodeBuilder(*pNode);
EmitEvents(nodeBuilder);
return pNode;
}
void Node::EmitEvents(EventHandler& eventHandler) const
{
eventHandler.OnDocumentStart(m_mark);
AliasManager am;
EmitEvents(am, eventHandler);
eventHandler.OnDocumentEnd();
}
void Node::EmitEvents(AliasManager& am, EventHandler& eventHandler) const
{
anchor_t anchor = NullAnchor;
if(IsAliased()) {
anchor = am.LookupAnchor(*this);
if(anchor) {
eventHandler.OnAlias(m_mark, anchor);
return;
}
am.RegisterReference(*this);
anchor = am.LookupAnchor(*this);
}
switch(m_type) {
case NodeType::Null:
eventHandler.OnNull(m_mark, anchor);
break;
case NodeType::Scalar:
eventHandler.OnScalar(m_mark, m_tag, anchor, m_scalarData);
break;
case NodeType::Sequence:
eventHandler.OnSequenceStart(m_mark, m_tag, anchor);
for(std::size_t i=0;i<m_seqData.size();i++)
m_seqData[i]->EmitEvents(am, eventHandler);
eventHandler.OnSequenceEnd();
break;
case NodeType::Map:
eventHandler.OnMapStart(m_mark, m_tag, anchor);
for(node_map::const_iterator it=m_mapData.begin();it!=m_mapData.end();++it) {
it->first->EmitEvents(am, eventHandler);
it->second->EmitEvents(am, eventHandler);
}
eventHandler.OnMapEnd();
break;
}
}
void Node::Init(NodeType::value type, const Mark& mark, const std::string& tag)
{
Clear();
m_mark = mark;
m_type = type;
m_tag = tag;
}
void Node::MarkAsAliased()
{
m_pOwnership->MarkAsAliased(*this);
}
void Node::SetScalarData(const std::string& data)
{
assert(m_type == NodeType::Scalar); // TODO: throw?
m_scalarData = data;
}
void Node::Append(Node& node)
{
assert(m_type == NodeType::Sequence); // TODO: throw?
m_seqData.push_back(&node);
}
void Node::Insert(Node& key, Node& value)
{
assert(m_type == NodeType::Map); // TODO: throw?
m_mapData[&key] = &value;
}
// begin
// Returns an iterator to the beginning of this (sequence or map).
Iterator Node::begin() const
{
switch(m_type) {
case NodeType::Null:
case NodeType::Scalar:
return Iterator();
case NodeType::Sequence:
return Iterator(std::auto_ptr<IterPriv>(new IterPriv(m_seqData.begin())));
case NodeType::Map:
return Iterator(std::auto_ptr<IterPriv>(new IterPriv(m_mapData.begin())));
}
assert(false);
return Iterator();
}
// end
// . Returns an iterator to the end of this (sequence or map).
Iterator Node::end() const
{
switch(m_type) {
case NodeType::Null:
case NodeType::Scalar:
return Iterator();
case NodeType::Sequence:
return Iterator(std::auto_ptr<IterPriv>(new IterPriv(m_seqData.end())));
case NodeType::Map:
return Iterator(std::auto_ptr<IterPriv>(new IterPriv(m_mapData.end())));
}
assert(false);
return Iterator();
}
// size
// . Returns the size of a sequence or map node
// . Otherwise, returns zero.
std::size_t Node::size() const
{
switch(m_type) {
case NodeType::Null:
case NodeType::Scalar:
return 0;
case NodeType::Sequence:
return m_seqData.size();
case NodeType::Map:
return m_mapData.size();
}
assert(false);
return 0;
}
const Node *Node::FindAtIndex(std::size_t i) const
{
if(m_type == NodeType::Sequence)
return m_seqData[i];
return 0;
}
bool Node::GetScalar(std::string& s) const
{
switch(m_type) {
case NodeType::Null:
s = "~";
return true;
case NodeType::Scalar:
s = m_scalarData;
return true;
case NodeType::Sequence:
case NodeType::Map:
return false;
}
assert(false);
return false;
}
Emitter& operator << (Emitter& out, const Node& node)
{
EmitFromEvents emitFromEvents(out);
node.EmitEvents(emitFromEvents);
return out;
}
int Node::Compare(const Node& rhs) const
{
if(m_type != rhs.m_type)
return rhs.m_type - m_type;
switch(m_type) {
case NodeType::Null:
return 0;
case NodeType::Scalar:
return m_scalarData.compare(rhs.m_scalarData);
case NodeType::Sequence:
if(m_seqData.size() < rhs.m_seqData.size())
return 1;
else if(m_seqData.size() > rhs.m_seqData.size())
return -1;
for(std::size_t i=0;i<m_seqData.size();i++)
if(int cmp = m_seqData[i]->Compare(*rhs.m_seqData[i]))
return cmp;
return 0;
case NodeType::Map:
if(m_mapData.size() < rhs.m_mapData.size())
return 1;
else if(m_mapData.size() > rhs.m_mapData.size())
return -1;
node_map::const_iterator it = m_mapData.begin();
node_map::const_iterator jt = rhs.m_mapData.begin();
for(;it!=m_mapData.end() && jt!=rhs.m_mapData.end();it++, jt++) {
if(int cmp = it->first->Compare(*jt->first))
return cmp;
if(int cmp = it->second->Compare(*jt->second))
return cmp;
}
return 0;
}
assert(false);
return 0;
}
bool operator < (const Node& n1, const Node& n2)
{
return n1.Compare(n2) < 0;
}
}