#pragma once //BML v1.0 parser //revision 0.04 namespace nall { namespace BML { //metadata is used to store nesting level struct ManagedNode; using SharedNode = shared_pointer; struct ManagedNode : Markup::ManagedNode { protected: //test to verify if a valid character for a node name auto valid(char p) const -> bool { //A-Z, a-z, 0-9, -. return p - 'A' < 26u || p - 'a' < 26u || p - '0' < 10u || p - '-' < 2u; } //determine indentation level, without incrementing pointer auto readDepth(const char* p) -> uint { uint depth = 0; while(p[depth] == '\t' || p[depth] == ' ') depth++; return depth; } //determine indentation level auto parseDepth(const char*& p) -> uint { uint depth = readDepth(p); p += depth; return depth; } //read name auto parseName(const char*& p) -> void { uint length = 0; while(valid(p[length])) length++; if(length == 0) throw "Invalid node name"; _name = slice(p, 0, length); p += length; } auto parseData(const char*& p) -> void { if(*p == '=' && *(p + 1) == '\"') { uint length = 2; while(p[length] && p[length] != '\n' && p[length] != '\"') length++; if(p[length] != '\"') throw "Unescaped value"; _value = {slice(p, 2, length - 2), "\n"}; p += length + 1; } else if(*p == '=') { uint length = 1; while(p[length] && p[length] != '\n' && p[length] != '\"' && p[length] != ' ') length++; if(p[length] == '\"') throw "Illegal character in value"; _value = {slice(p, 1, length - 1), "\n"}; p += length; } else if(*p == ':') { uint length = 1; while(p[length] && p[length] != '\n') length++; _value = {slice(p, 1, length - 1), "\n"}; p += length; } } //read all attributes for a node auto parseAttributes(const char*& p) -> void { while(*p && *p != '\n') { if(*p != ' ') throw "Invalid node name"; while(*p == ' ') p++; //skip excess spaces if(*(p + 0) == '/' && *(p + 1) == '/') break; //skip comments SharedNode node(new ManagedNode); uint length = 0; while(valid(p[length])) length++; if(length == 0) throw "Invalid attribute name"; node->_name = slice(p, 0, length); node->parseData(p += length); node->_value.trimRight("\n", 1L); _children.append(node); } } //read a node and all of its child nodes auto parseNode(const string_vector& text, uint& y) -> void { const char* p = text[y++]; _metadata = parseDepth(p); parseName(p); parseData(p); parseAttributes(p); while(y < text.size()) { uint depth = readDepth(text[y]); if(depth <= _metadata) break; if(text[y][depth] == ':') { _value.append(slice(text[y++], depth + 1), "\n"); continue; } SharedNode node(new ManagedNode); node->parseNode(text, y); _children.append(node); } _value.trimRight("\n", 1L); } //read top-level nodes auto parse(string document) -> void { //in order to simplify the parsing logic; we do an initial pass to normalize the data //the below code will turn '\r\n' into '\n'; skip empty lines; and skip comment lines char* p = document.get(), *output = p; while(*p) { char* origin = p; bool empty = true; while(*p) { //scan for first non-whitespace character. if it's a line feed or comment; skip the line if(p[0] == ' ' || p[0] == '\t') { p++; continue; } empty = p[0] == '\r' || p[0] == '\n' || (p[0] == '/' && p[1] == '/'); break; } while(*p) { if(p[0] == '\r') p[0] = '\n'; //turns '\r\n' into '\n\n' (second '\n' will be skipped) if(*p++ == '\n') break; //include '\n' in the output to be copied } if(empty) continue; memory::move(output, origin, p - origin); output += p - origin; } document.resize(document.size() - (p - output)).trimRight("\n"); if(document.size() == 0) return; //empty document auto text = document.split("\n"); uint y = 0; while(y < text.size()) { SharedNode node(new ManagedNode); node->parseNode(text, y); if(node->_metadata > 0) throw "Root nodes cannot be indented"; _children.append(node); } } friend auto unserialize(const string&) -> Markup::Node; }; inline auto unserialize(const string& markup) -> Markup::Node { SharedNode node(new ManagedNode); try { node->parse(markup); } catch(const char* error) { node.reset(); } return (Markup::SharedNode&)node; } inline auto serialize(const Markup::Node& node, uint depth = 0) -> string { if(!node.name()) { string result; for(auto leaf : node) { result.append(serialize(leaf, depth)); } return result; } string padding; padding.resize(depth * 2); for(auto& byte : padding) byte = ' '; string_vector lines; if(auto value = node.value()) lines = value.split("\n"); string result; result.append(padding); result.append(node.name()); if(lines.size() == 1) result.append(":", lines[0]); result.append("\n"); if(lines.size() > 1) { padding.append(" "); for(auto& line : lines) { result.append(padding, ":", line, "\n"); } } for(auto leaf : node) { result.append(serialize(leaf, depth + 1)); } return result; } }}