Spaces:

DanofficeIT
/

privatellm

Runtime error

privatellm / common /json-schema-to-grammar.cpp

lhhj

first

57e3690 about 1 year ago

43.5 kB

	#include "json-schema-to-grammar.h"
	#include <algorithm>
	#include <fstream>
	#include <map>
	#include <regex>
	#include <sstream>
	#include <string>
	#include <unordered_map>
	#include <unordered_set>
	#include <vector>

	using json = nlohmann::ordered_json;

	template <typename Iterator>
	static std::string join(Iterator begin, Iterator end, const std::string & separator);

	static std::string repeat(const std::string & str, size_t n);

	static std::string build_repetition(const std::string & item_rule, int min_items, int max_items, const std::string & separator_rule = "") {
	auto has_max = max_items != std::numeric_limits<int>::max();

	if (min_items == 0 && max_items == 1) {
	return item_rule + "?";
	}

	if (separator_rule.empty()) {
	if (min_items == 1 && !has_max) {
	return item_rule + "+";
	} else if (min_items == 0 && !has_max) {
	return item_rule + "*";
	} else {
	return item_rule + "{" + std::to_string(min_items) + "," + (has_max ? std::to_string(max_items) : "") + "}";
	}
	}

	auto result = item_rule + " " + build_repetition("(" + separator_rule + " " + item_rule + ")", min_items == 0 ? 0 : min_items - 1, has_max ? max_items - 1 : max_items);
	if (min_items == 0) {
	result = "(" + result + ")?";
	}
	return result;
	}

	/* Minimalistic replacement for std::string_view, which is only available from C++17 onwards */
	class string_view {
	const std::string & _str;
	const size_t _start;
	const size_t _end;
	public:
	string_view(const std::string & str, size_t start = 0, size_t end = std::string::npos) : _str(str), _start(start), _end(end == std::string::npos ? str.length() : end) {}

	size_t size() const {
	return _end - _start;
	}

	size_t length() const {
	return size();
	}

	operator std::string() const {
	return str();
	}

	std::string str() const {
	return _str.substr(_start, _end - _start);
	}

	string_view substr(size_t pos, size_t len = std::string::npos) const {
	return string_view(_str, _start + pos, len == std::string::npos ? _end : _start + pos + len);
	}

	char operator[](size_t pos) const {
	auto index = _start + pos;
	if (index >= _end) {
	throw std::out_of_range("string_view index out of range");
	}
	return _str[_start + pos];
	}

	bool operator==(const string_view & other) const {
	std::string this_str = *this;
	std::string other_str = other;
	return this_str == other_str;
	}
	};

	static void _build_min_max_int(int min_value, int max_value, std::stringstream & out, int decimals_left = 16, bool top_level = true) {
	auto has_min = min_value != std::numeric_limits<int>::min();
	auto has_max = max_value != std::numeric_limits<int>::max();

	auto digit_range = [&](char from, char to) {
	out << "[";
	if (from == to) {
	out << from;
	} else {
	out << from << "-" << to;
	}
	out << "]";
	};
	auto more_digits = [&](int min_digits, int max_digits) {
	out << "[0-9]";
	if (min_digits == max_digits && min_digits == 1) {
	return;
	}
	out << "{";
	out << min_digits;
	if (max_digits != min_digits) {
	out << ",";
	if (max_digits != std::numeric_limits<int>::max()) {
	out << max_digits;
	}
	}
	out << "}";
	};
	std::function<void(const string_view &, const string_view &)> uniform_range =
	[&](const string_view & from, const string_view & to) {
	size_t i = 0;
	while (i < from.length() && i < to.length() && from[i] == to[i]) {
	i++;
	}
	if (i > 0) {
	out << "\"" << from.substr(0, i).str() << "\"";
	}
	if (i < from.length() && i < to.length()) {
	if (i > 0) {
	out << " ";
	}
	auto sub_len = from.length() - i - 1;
	if (sub_len > 0) {
	auto from_sub = from.substr(i + 1);
	auto to_sub = to.substr(i + 1);
	auto sub_zeros = repeat("0", sub_len);
	auto sub_nines = repeat("9", sub_len);

	auto to_reached = false;
	out << "(";
	if (from_sub == sub_zeros) {
	digit_range(from[i], to[i] - 1);
	out << " ";
	more_digits(sub_len, sub_len);
	} else {
	out << "[" << from[i] << "] ";
	out << "(";
	uniform_range(from_sub, sub_nines);
	out << ")";
	if (from[i] < to[i] - 1) {
	out << " \| ";
	if (to_sub == sub_nines) {
	digit_range(from[i] + 1, to[i]);
	to_reached = true;
	} else {
	digit_range(from[i] + 1, to[i] - 1);
	}
	out << " ";
	more_digits(sub_len, sub_len);
	}
	}
	if (!to_reached) {
	out << " \| ";
	digit_range(to[i], to[i]);
	out << " ";
	uniform_range(sub_zeros, to_sub);
	}
	out << ")";
	} else {
	out << "[" << from[i] << "-" << to[i] << "]";
	}
	}
	};

	if (has_min && has_max) {
	if (min_value < 0 && max_value < 0) {
	out << "\"-\" (";
	_build_min_max_int(-max_value, -min_value, out, decimals_left, /* top_level= */ true);
	out << ")";
	return;
	}

	if (min_value < 0) {
	out << "\"-\" (";
	_build_min_max_int(0, -min_value, out, decimals_left, /* top_level= */ true);
	out << ") \| ";
	min_value = 0;
	}

	auto min_s = std::to_string(min_value);
	auto max_s = std::to_string(max_value);
	auto min_digits = min_s.length();
	auto max_digits = max_s.length();

	for (auto digits = min_digits; digits < max_digits; digits++) {
	uniform_range(min_s, repeat("9", digits));
	min_s = "1" + repeat("0", digits);
	out << " \| ";
	}
	uniform_range(min_s, max_s);
	return;
	}

	auto less_decimals = std::max(decimals_left - 1, 1);

	if (has_min) {
	if (min_value < 0) {
	out << "\"-\" (";
	_build_min_max_int(std::numeric_limits<int>::min(), -min_value, out, decimals_left, /* top_level= */ false);
	out << ") \| [0] \| [1-9] ";
	more_digits(0, decimals_left - 1);
	} else if (min_value == 0) {
	if (top_level) {
	out << "[0] \| [1-9] ";
	more_digits(0, less_decimals);
	} else {
	more_digits(1, decimals_left);
	}
	} else if (min_value <= 9) {
	char c = '0' + min_value;
	auto range_start = top_level ? '1' : '0';
	if (c > range_start) {
	digit_range(range_start, c - 1);
	out << " ";
	more_digits(1, less_decimals);
	out << " \| ";
	}
	digit_range(c, '9');
	out << " ";
	more_digits(0, less_decimals);
	} else {
	auto min_s = std::to_string(min_value);
	auto len = min_s.length();
	auto c = min_s[0];

	if (c > '1') {
	digit_range(top_level ? '1' : '0', c - 1);
	out << " ";
	more_digits(len, less_decimals);
	out << " \| ";
	}
	digit_range(c, c);
	out << " (";
	_build_min_max_int(std::stoi(min_s.substr(1)), std::numeric_limits<int>::max(), out, less_decimals, /* top_level= */ false);
	out << ")";
	if (c < '9') {
	out << " \| ";
	digit_range(c + 1, '9');
	out << " ";
	more_digits(len - 1, less_decimals);
	}
	}
	return;
	}

	if (has_max) {
	if (max_value >= 0) {
	if (top_level) {
	out << "\"-\" [1-9] ";
	more_digits(0, less_decimals);
	out << " \| ";
	}
	_build_min_max_int(0, max_value, out, decimals_left, /* top_level= */ true);
	} else {
	out << "\"-\" (";
	_build_min_max_int(-max_value, std::numeric_limits<int>::max(), out, decimals_left, /* top_level= */ false);
	out << ")";
	}
	return;
	}

	throw std::runtime_error("At least one of min_value or max_value must be set");
	}

	const std::string SPACE_RULE = "\| \" \" \| \"\\n\" [ \\t]{0,20}";

	struct BuiltinRule {
	std::string content;
	std::vector<std::string> deps;
	};

	std::unordered_map<std::string, BuiltinRule> PRIMITIVE_RULES = {
	{"boolean", {"(\"true\" \| \"false\") space", {}}},
	{"decimal-part", {"[0-9]{1,16}", {}}},
	{"integral-part", {"[0] \| [1-9] [0-9]{0,15}", {}}},
	{"number", {"(\"-\"? integral-part) (\".\" decimal-part)? ([eE] [-+]? integral-part)? space", {"integral-part", "decimal-part"}}},
	{"integer", {"(\"-\"? integral-part) space", {"integral-part"}}},
	{"value", {"object \| array \| string \| number \| boolean \| null", {"object", "array", "string", "number", "boolean", "null"}}},
	{"object", {"\"{\" space ( string \":\" space value (\",\" space string \":\" space value)* )? \"}\" space", {"string", "value"}}},
	{"array", {"\"[\" space ( value (\",\" space value)* )? \"]\" space", {"value"}}},
	{"uuid", {"\"\\\"\" [0-9a-fA-F]{8} \"-\" [0-9a-fA-F]{4} \"-\" [0-9a-fA-F]{4} \"-\" [0-9a-fA-F]{4} \"-\" [0-9a-fA-F]{12} \"\\\"\" space", {}}},
	{"char", {"[^\"\\\\\\x7F\\x00-\\x1F] \| [\\\\] ([\"\\\\bfnrt] \| \"u\" [0-9a-fA-F]{4})", {}}},
	{"string", {"\"\\\"\" char* \"\\\"\" space", {"char"}}},
	{"null", {"\"null\" space", {}}},
	};

	std::unordered_map<std::string, BuiltinRule> STRING_FORMAT_RULES = {
	{"date", {"[0-9]{4} \"-\" ( \"0\" [1-9] \| \"1\" [0-2] ) \"-\" ( \"0\" [1-9] \| [1-2] [0-9] \| \"3\" [0-1] )", {}}},
	{"time", {"([01] [0-9] \| \"2\" [0-3]) \":\" [0-5] [0-9] \":\" [0-5] [0-9] ( \".\" [0-9]{3} )? ( \"Z\" \| ( \"+\" \| \"-\" ) ( [01] [0-9] \| \"2\" [0-3] ) \":\" [0-5] [0-9] )", {}}},
	{"date-time", {"date \"T\" time", {"date", "time"}}},
	{"date-string", {"\"\\\"\" date \"\\\"\" space", {"date"}}},
	{"time-string", {"\"\\\"\" time \"\\\"\" space", {"time"}}},
	{"date-time-string", {"\"\\\"\" date-time \"\\\"\" space", {"date-time"}}}
	};

	static bool is_reserved_name(const std::string & name) {
	static std::unordered_set<std::string> RESERVED_NAMES;
	if (RESERVED_NAMES.empty()) {
	RESERVED_NAMES.insert("root");
	for (const auto &p : PRIMITIVE_RULES) RESERVED_NAMES.insert(p.first);
	for (const auto &p : STRING_FORMAT_RULES) RESERVED_NAMES.insert(p.first);
	}
	return RESERVED_NAMES.find(name) != RESERVED_NAMES.end();
	}

	std::regex INVALID_RULE_CHARS_RE("[^a-zA-Z0-9-]+");
	std::regex GRAMMAR_LITERAL_ESCAPE_RE("[\r\n\"]");
	std::regex GRAMMAR_RANGE_LITERAL_ESCAPE_RE("[\r\n\"\\]\\-\\\\]");
	std::unordered_map<char, std::string> GRAMMAR_LITERAL_ESCAPES = {
	{'\r', "\\r"}, {'\n', "\\n"}, {'"', "\\\""}, {'-', "\\-"}, {']', "\\]"}
	};

	std::unordered_set<char> NON_LITERAL_SET = {'\|', '.', '(', ')', '[', ']', '{', '}', '*', '+', '?'};
	std::unordered_set<char> ESCAPED_IN_REGEXPS_BUT_NOT_IN_LITERALS = {'^', '$', '.', '[', ']', '(', ')', '\|', '{', '}', '*', '+', '?'};

	template <typename Iterator>
	std::string join(Iterator begin, Iterator end, const std::string & separator) {
	std::ostringstream result;
	if (begin != end) {
	result << *begin;
	for (Iterator it = begin + 1; it != end; ++it) {
	result << separator << *it;
	}
	}
	return result.str();
	}

	static std::vector<std::string> split(const std::string & str, const std::string & delimiter) {
	std::vector<std::string> tokens;
	size_t start = 0;
	size_t end = str.find(delimiter);

	while (end != std::string::npos) {
	tokens.push_back(str.substr(start, end - start));
	start = end + delimiter.length();
	end = str.find(delimiter, start);
	}

	tokens.push_back(str.substr(start));

	return tokens;
	}

	static std::string repeat(const std::string & str, size_t n) {
	if (n == 0) {
	return "";
	}

	std::string result;
	result.reserve(str.length() * n);

	for (size_t i = 0; i < n; ++i) {
	result += str;
	}

	return result;
	}

	static std::string replacePattern(const std::string & input, const std::regex & regex, const std::function<std::string(const std::smatch &)> & replacement) {
	std::smatch match;
	std::string result;

	std::string::const_iterator searchStart(input.cbegin());
	std::string::const_iterator searchEnd(input.cend());

	while (std::regex_search(searchStart, searchEnd, match, regex)) {
	result.append(searchStart, searchStart + match.position());
	result.append(replacement(match));
	searchStart = match.suffix().first;
	}

	result.append(searchStart, searchEnd);

	return result;
	}

	static std::string format_literal(const std::string & literal) {
	std::string escaped = replacePattern(literal, GRAMMAR_LITERAL_ESCAPE_RE, [&](const std::smatch & match) {
	char c = match.str()[0];
	return GRAMMAR_LITERAL_ESCAPES.at(c);
	});
	return "\"" + escaped + "\"";
	}

	class SchemaConverter {
	private:
	std::function<json(const std::string &)> _fetch_json;
	bool _dotall;
	std::map<std::string, std::string> _rules;
	std::unordered_map<std::string, json> _refs;
	std::unordered_set<std::string> _refs_being_resolved;
	std::vector<std::string> _errors;
	std::vector<std::string> _warnings;

	std::string _add_rule(const std::string & name, const std::string & rule) {
	std::string esc_name = regex_replace(name, INVALID_RULE_CHARS_RE, "-");
	if (_rules.find(esc_name) == _rules.end() \|\| _rules[esc_name] == rule) {
	_rules[esc_name] = rule;
	return esc_name;
	} else {
	int i = 0;
	while (_rules.find(esc_name + std::to_string(i)) != _rules.end() && _rules[esc_name + std::to_string(i)] != rule) {
	i++;
	}
	std::string key = esc_name + std::to_string(i);
	_rules[key] = rule;
	return key;
	}
	}

	std::string _generate_union_rule(const std::string & name, const std::vector<json> & alt_schemas) {
	std::vector<std::string> rules;
	for (size_t i = 0; i < alt_schemas.size(); i++) {
	rules.push_back(visit(alt_schemas[i], name + (name.empty() ? "alternative-" : "-") + std::to_string(i)));
	}
	return join(rules.begin(), rules.end(), " \| ");
	}

	std::string _visit_pattern(const std::string & pattern, const std::string & name) {
	if (!(pattern.front() == '^' && pattern.back() == '$')) {
	_errors.push_back("Pattern must start with '^' and end with '$'");
	return "";
	}
	std::string sub_pattern = pattern.substr(1, pattern.length() - 2);
	std::unordered_map<std::string, std::string> sub_rule_ids;

	size_t i = 0;
	size_t length = sub_pattern.length();

	using literal_or_rule = std::pair<std::string, bool>;
	auto to_rule = [&](const literal_or_rule & ls) {
	auto is_literal = ls.second;
	auto s = ls.first;
	return is_literal ? "\"" + s + "\"" : s;
	};
	std::function<literal_or_rule()> transform = [&]() -> literal_or_rule {
	size_t start = i;
	std::vector<literal_or_rule> seq;

	auto get_dot = [&]() {
	std::string rule;
	if (_dotall) {
	rule = "[\\U00000000-\\U0010FFFF]";
	} else {
	rule = "[^\\x0A\\x0D]";
	}
	return _add_rule("dot", rule);
	};

	// Joins the sequence, merging consecutive literals together.
	auto join_seq = [&]() {
	std::vector<literal_or_rule> ret;

	std::string literal;
	auto flush_literal = [&]() {
	if (literal.empty()) {
	return false;
	}
	ret.emplace_back(literal, true);
	literal.clear();
	return true;
	};

	for (const auto & item : seq) {
	auto is_literal = item.second;
	if (is_literal) {
	literal += item.first;
	} else {
	flush_literal();
	ret.push_back(item);
	}
	}
	flush_literal();

	std::vector<std::string> results;
	for (const auto & item : ret) {
	results.push_back(to_rule(item));
	}
	return std::make_pair(join(results.begin(), results.end(), " "), false);
	};

	while (i < length) {
	char c = sub_pattern[i];
	if (c == '.') {
	seq.emplace_back(get_dot(), false);
	i++;
	} else if (c == '(') {
	i++;
	if (i < length) {
	if (sub_pattern[i] == '?') {
	_warnings.push_back("Unsupported pattern syntax");
	}
	}
	seq.emplace_back("(" + to_rule(transform()) + ")", false);
	} else if (c == ')') {
	i++;
	if (start > 0 && sub_pattern[start - 1] != '(') {
	_errors.push_back("Unbalanced parentheses");
	}
	return join_seq();
	} else if (c == '[') {
	std::string square_brackets = std::string(1, c);
	i++;
	while (i < length && sub_pattern[i] != ']') {
	if (sub_pattern[i] == '\\') {
	square_brackets += sub_pattern.substr(i, 2);
	i += 2;
	} else {
	square_brackets += sub_pattern[i];
	i++;
	}
	}
	if (i >= length) {
	_errors.push_back("Unbalanced square brackets");
	}
	square_brackets += ']';
	i++;
	seq.emplace_back(square_brackets, false);
	} else if (c == '\|') {
	seq.emplace_back("\|", false);
	i++;
	} else if (c == '*' \|\| c == '+' \|\| c == '?') {
	seq.back() = std::make_pair(to_rule(seq.back()) + c, false);
	i++;
	} else if (c == '{') {
	std::string curly_brackets = std::string(1, c);
	i++;
	while (i < length && sub_pattern[i] != '}') {
	curly_brackets += sub_pattern[i];
	i++;
	}
	if (i >= length) {
	_errors.push_back("Unbalanced curly brackets");
	}
	curly_brackets += '}';
	i++;
	auto nums = split(curly_brackets.substr(1, curly_brackets.length() - 2), ",");
	int min_times = 0;
	int max_times = std::numeric_limits<int>::max();
	try {
	if (nums.size() == 1) {
	min_times = max_times = std::stoi(nums[0]);
	} else if (nums.size() != 2) {
	_errors.push_back("Wrong number of values in curly brackets");
	} else {
	if (!nums[0].empty()) {
	min_times = std::stoi(nums[0]);
	}
	if (!nums[1].empty()) {
	max_times = std::stoi(nums[1]);
	}
	}
	} catch (const std::invalid_argument & e) {
	_errors.push_back("Invalid number in curly brackets");
	return std::make_pair("", false);
	}
	auto &last = seq.back();
	auto &sub = last.first;
	auto sub_is_literal = last.second;

	if (!sub_is_literal) {
	std::string & sub_id = sub_rule_ids[sub];
	if (sub_id.empty()) {
	sub_id = _add_rule(name + "-" + std::to_string(sub_rule_ids.size()), sub);
	}
	sub = sub_id;
	}
	seq.back().first = build_repetition(
	sub_is_literal ? "\"" + sub + "\"" : sub,
	min_times,
	max_times,
	""
	);
	seq.back().second = false;
	} else {
	std::string literal;
	auto is_non_literal = [&](char c) {
	return NON_LITERAL_SET.find(c) != NON_LITERAL_SET.end();
	};
	while (i < length) {
	if (sub_pattern[i] == '\\' && i < length - 1) {
	char next = sub_pattern[i + 1];
	if (ESCAPED_IN_REGEXPS_BUT_NOT_IN_LITERALS.find(next) != ESCAPED_IN_REGEXPS_BUT_NOT_IN_LITERALS.end()) {
	i++;
	literal += sub_pattern[i];
	i++;
	} else {
	literal += sub_pattern.substr(i, 2);
	i += 2;
	}
	} else if (sub_pattern[i] == '"') {
	literal += "\\\"";
	i++;
	} else if (!is_non_literal(sub_pattern[i]) &&
	(i == length - 1 \|\| literal.empty() \|\| sub_pattern[i + 1] == '.' \|\| !is_non_literal(sub_pattern[i + 1]))) {
	literal += sub_pattern[i];
	i++;
	} else {
	break;
	}
	}
	if (!literal.empty()) {
	seq.emplace_back(literal, true);
	}
	}
	}
	return join_seq();
	};
	return _add_rule(name, "\"\\\"\" (" + to_rule(transform()) + ") \"\\\"\" space");
	}

	/*
	Returns a rule that matches a JSON string that is none of the provided strings

	not_strings({"a"})
	-> ["] ( [a] char+ \| [^"a] char* )? ["] space
	not_strings({"and", "also"})
	-> ["] ( [a] ([l] ([s] ([o] char+ \| [^"o] char) \| [^"s] char) \| [n] ([d] char+ \| [^"d] char) \| [^"ln] char) \| [^"a] char* )? ["] space
	*/
	std::string _not_strings(const std::vector<std::string> & strings) {

	struct TrieNode {
	std::map<char, TrieNode> children;
	bool is_end_of_string;

	TrieNode() : is_end_of_string(false) {}

	void insert(const std::string & string) {
	auto node = this;
	for (char c : string) {
	node = &node->children[c];
	}
	node->is_end_of_string = true;
	}
	};

	TrieNode trie;
	for (const auto & s : strings) {
	trie.insert(s);
	}

	std::string char_rule = _add_primitive("char", PRIMITIVE_RULES.at("char"));
	std::ostringstream out;
	out << "[\"] ( ";
	std::function<void(const TrieNode &)> visit = [&](const TrieNode & node) {
	std::ostringstream rejects;
	auto first = true;
	for (const auto & kv : node.children) {
	rejects << kv.first;
	if (first) {
	first = false;
	} else {
	out << " \| ";
	}
	out << "[" << kv.first << "]";
	if (!kv.second.children.empty()) {
	out << " (";
	visit(kv.second);
	out << ")";
	} else if (kv.second.is_end_of_string) {
	out << " " << char_rule << "+";
	}
	}
	if (!node.children.empty()) {
	if (!first) {
	out << " \| ";
	}
	out << "[^\"" << rejects.str() << "] " << char_rule << "*";
	}
	};
	visit(trie);

	out << " )";
	if (!trie.is_end_of_string) {
	out << "?";
	}
	out << " [\"] space";
	return out.str();
	}

	std::string _resolve_ref(const std::string & ref) {
	std::string ref_name = ref.substr(ref.find_last_of('/') + 1);
	if (_rules.find(ref_name) == _rules.end() && _refs_being_resolved.find(ref) == _refs_being_resolved.end()) {
	_refs_being_resolved.insert(ref);
	json resolved = _refs[ref];
	ref_name = visit(resolved, ref_name);
	_refs_being_resolved.erase(ref);
	}
	return ref_name;
	}

	std::string _build_object_rule(
	const std::vector<std::pair<std::string, json>> & properties,
	const std::unordered_set<std::string> & required,
	const std::string & name,
	const json & additional_properties)
	{
	std::vector<std::string> required_props;
	std::vector<std::string> optional_props;
	std::unordered_map<std::string, std::string> prop_kv_rule_names;
	std::vector<std::string> prop_names;
	for (const auto & kv : properties) {
	const auto &prop_name = kv.first;
	const auto &prop_schema = kv.second;

	std::string prop_rule_name = visit(prop_schema, name + (name.empty() ? "" : "-") + prop_name);
	prop_kv_rule_names[prop_name] = _add_rule(
	name + (name.empty() ? "" : "-") + prop_name + "-kv",
	format_literal(json(prop_name).dump()) + " space \":\" space " + prop_rule_name
	);
	if (required.find(prop_name) != required.end()) {
	required_props.push_back(prop_name);
	} else {
	optional_props.push_back(prop_name);
	}
	prop_names.push_back(prop_name);
	}
	if ((additional_properties.is_boolean() && additional_properties.get<bool>()) \|\| additional_properties.is_object()) {
	std::string sub_name = name + (name.empty() ? "" : "-") + "additional";
	std::string value_rule =
	additional_properties.is_object() ? visit(additional_properties, sub_name + "-value")
	: _add_primitive("value", PRIMITIVE_RULES.at("value"));

	auto key_rule =
	prop_names.empty() ? _add_primitive("string", PRIMITIVE_RULES.at("string"))
	: _add_rule(sub_name + "-k", _not_strings(prop_names));
	std::string kv_rule = _add_rule(sub_name + "-kv", key_rule + " \":\" space " + value_rule);
	prop_kv_rule_names["*"] = kv_rule;
	optional_props.push_back("*");
	}

	std::string rule = "\"{\" space ";
	for (size_t i = 0; i < required_props.size(); i++) {
	if (i > 0) {
	rule += " \",\" space ";
	}
	rule += prop_kv_rule_names[required_props[i]];
	}

	if (!optional_props.empty()) {
	rule += " (";
	if (!required_props.empty()) {
	rule += " \",\" space ( ";
	}

	std::function<std::string(const std::vector<std::string> &, bool)> get_recursive_refs = [&](const std::vector<std::string> & ks, bool first_is_optional) {
	std::string res;
	if (ks.empty()) {
	return res;
	}
	std::string k = ks[0];
	std::string kv_rule_name = prop_kv_rule_names[k];
	std::string comma_ref = "( \",\" space " + kv_rule_name + " )";
	if (first_is_optional) {
	res = comma_ref + (k == "" ? "" : "?");
	} else {
	res = kv_rule_name + (k == "" ? " " + comma_ref + "" : "");
	}
	if (ks.size() > 1) {
	res += " " + _add_rule(
	name + (name.empty() ? "" : "-") + k + "-rest",
	get_recursive_refs(std::vector<std::string>(ks.begin() + 1, ks.end()), true)
	);
	}
	return res;
	};

	for (size_t i = 0; i < optional_props.size(); i++) {
	if (i > 0) {
	rule += " \| ";
	}
	rule += get_recursive_refs(std::vector<std::string>(optional_props.begin() + i, optional_props.end()), false);
	}
	if (!required_props.empty()) {
	rule += " )";
	}
	rule += " )?";
	}

	rule += " \"}\" space";

	return rule;
	}

	std::string _add_primitive(const std::string & name, const BuiltinRule & rule) {
	auto n = _add_rule(name, rule.content);
	for (const auto & dep : rule.deps) {
	BuiltinRule dep_rule;
	auto it = PRIMITIVE_RULES.find(dep);
	if (it == PRIMITIVE_RULES.end()) {
	it = STRING_FORMAT_RULES.find(dep);
	if (it == STRING_FORMAT_RULES.end()) {
	_errors.push_back("Rule " + dep + " not known");
	continue;
	}
	}
	if (_rules.find(dep) == _rules.end()) {
	_add_primitive(dep, it->second);
	}
	}
	return n;
	}

	public:
	SchemaConverter(
	const std::function<json(const std::string &)> & fetch_json,
	bool dotall)
	: _fetch_json(fetch_json), _dotall(dotall)
	{
	_rules["space"] = SPACE_RULE;
	}

	void resolve_refs(json & schema, const std::string & url) {
	/*
	* Resolves all $ref fields in the given schema, fetching any remote schemas,
	* replacing each $ref with absolute reference URL and populates _refs with the
	* respective referenced (sub)schema dictionaries.
	*/
	std::function<void(json &)> visit_refs = [&](json & n) {
	if (n.is_array()) {
	for (auto & x : n) {
	visit_refs(x);
	}
	} else if (n.is_object()) {
	if (n.contains("$ref")) {
	std::string ref = n["$ref"];
	if (_refs.find(ref) == _refs.end()) {
	json target;
	if (ref.find("https://") == 0) {
	std::string base_url = ref.substr(0, ref.find('#'));
	auto it = _refs.find(base_url);
	if (it != _refs.end()) {
	target = it->second;
	} else {
	// Fetch the referenced schema and resolve its refs
	auto referenced = _fetch_json(ref);
	resolve_refs(referenced, base_url);
	_refs[base_url] = referenced;
	}
	if (ref.find('#') == std::string::npos \|\| ref.substr(ref.find('#') + 1).empty()) {
	return;
	}
	} else if (ref.find("#/") == 0) {
	target = schema;
	n["$ref"] = url + ref;
	ref = url + ref;
	} else {
	_errors.push_back("Unsupported ref: " + ref);
	return;
	}
	std::string pointer = ref.substr(ref.find('#') + 1);
	std::vector<std::string> tokens = split(pointer, "/");
	for (size_t i = 1; i < tokens.size(); ++i) {
	std::string sel = tokens[i];
	if (target.is_null() \|\| !target.contains(sel)) {
	_errors.push_back("Error resolving ref " + ref + ": " + sel + " not in " + target.dump());
	return;
	}
	target = target[sel];
	}
	_refs[ref] = target;
	}
	} else {
	for (auto & kv : n.items()) {
	visit_refs(kv.value());
	}
	}
	}
	};

	visit_refs(schema);
	}

	std::string _generate_constant_rule(const json & value) {
	return format_literal(value.dump());
	}

	std::string visit(const json & schema, const std::string & name) {
	json schema_type = schema.contains("type") ? schema["type"] : json();
	std::string schema_format = schema.contains("format") ? schema["format"].get<std::string>() : "";
	std::string rule_name = is_reserved_name(name) ? name + "-" : name.empty() ? "root" : name;

	if (schema.contains("$ref")) {
	return _add_rule(rule_name, _resolve_ref(schema["$ref"]));
	} else if (schema.contains("oneOf") \|\| schema.contains("anyOf")) {
	std::vector<json> alt_schemas = schema.contains("oneOf") ? schema["oneOf"].get<std::vector<json>>() : schema["anyOf"].get<std::vector<json>>();
	return _add_rule(rule_name, _generate_union_rule(name, alt_schemas));
	} else if (schema_type.is_array()) {
	std::vector<json> schema_types;
	for (const auto & t : schema_type) {
	json schema_copy(schema);
	schema_copy["type"] = t;
	schema_types.push_back(schema_copy);
	}
	return _add_rule(rule_name, _generate_union_rule(name, schema_types));
	} else if (schema.contains("const")) {
	return _add_rule(rule_name, _generate_constant_rule(schema["const"]) + " space");
	} else if (schema.contains("enum")) {
	std::vector<std::string> enum_values;
	for (const auto & v : schema["enum"]) {
	enum_values.push_back(_generate_constant_rule(v));
	}
	return _add_rule(rule_name, "(" + join(enum_values.begin(), enum_values.end(), " \| ") + ") space");
	} else if ((schema_type.is_null() \|\| schema_type == "object")
	&& (schema.contains("properties") \|\|
	(schema.contains("additionalProperties") && schema["additionalProperties"] != true))) {
	std::unordered_set<std::string> required;
	if (schema.contains("required") && schema["required"].is_array()) {
	for (const auto & item : schema["required"]) {
	if (item.is_string()) {
	required.insert(item.get<std::string>());
	}
	}
	}
	std::vector<std::pair<std::string, json>> properties;
	if (schema.contains("properties")) {
	for (const auto & prop : schema["properties"].items()) {
	properties.emplace_back(prop.key(), prop.value());
	}
	}
	return _add_rule(rule_name,
	_build_object_rule(
	properties, required, name,
	schema.contains("additionalProperties") ? schema["additionalProperties"] : json()));
	} else if ((schema_type.is_null() \|\| schema_type == "object") && schema.contains("allOf")) {
	std::unordered_set<std::string> required;
	std::vector<std::pair<std::string, json>> properties;
	std::string hybrid_name = name;
	std::function<void(const json &, bool)> add_component = [&](const json & comp_schema, bool is_required) {
	if (comp_schema.contains("$ref")) {
	add_component(_refs[comp_schema["$ref"]], is_required);
	} else if (comp_schema.contains("properties")) {
	for (const auto & prop : comp_schema["properties"].items()) {
	properties.emplace_back(prop.key(), prop.value());
	if (is_required) {
	required.insert(prop.key());
	}
	}
	} else {
	// todo warning
	}
	};
	for (auto & t : schema["allOf"]) {
	if (t.contains("anyOf")) {
	for (auto & tt : t["anyOf"]) {
	add_component(tt, false);
	}
	} else {
	add_component(t, true);
	}
	}
	return _add_rule(rule_name, _build_object_rule(properties, required, hybrid_name, json()));
	} else if ((schema_type.is_null() \|\| schema_type == "array") && (schema.contains("items") \|\| schema.contains("prefixItems"))) {
	json items = schema.contains("items") ? schema["items"] : schema["prefixItems"];
	if (items.is_array()) {
	std::string rule = "\"[\" space ";
	for (size_t i = 0; i < items.size(); i++) {
	if (i > 0) {
	rule += " \",\" space ";
	}
	rule += visit(items[i], name + (name.empty() ? "" : "-") + "tuple-" + std::to_string(i));
	}
	rule += " \"]\" space";
	return _add_rule(rule_name, rule);
	} else {
	std::string item_rule_name = visit(items, name + (name.empty() ? "" : "-") + "item");
	int min_items = schema.contains("minItems") ? schema["minItems"].get<int>() : 0;
	json max_items_json = schema.contains("maxItems") ? schema["maxItems"] : json();
	int max_items = max_items_json.is_number_integer() ? max_items_json.get<int>() : std::numeric_limits<int>::max();

	return _add_rule(rule_name, "\"[\" space " + build_repetition(item_rule_name, min_items, max_items, "\",\" space") + " \"]\" space");
	}
	} else if ((schema_type.is_null() \|\| schema_type == "string") && schema.contains("pattern")) {
	return _visit_pattern(schema["pattern"], rule_name);
	} else if ((schema_type.is_null() \|\| schema_type == "string") && std::regex_match(schema_format, std::regex("^uuid[1-5]?$"))) {
	return _add_primitive(rule_name == "root" ? "root" : schema_format, PRIMITIVE_RULES.at("uuid"));
	} else if ((schema_type.is_null() \|\| schema_type == "string") && STRING_FORMAT_RULES.find(schema_format + "-string") != STRING_FORMAT_RULES.end()) {
	auto prim_name = schema_format + "-string";
	return _add_rule(rule_name, _add_primitive(prim_name, STRING_FORMAT_RULES.at(prim_name)));
	} else if (schema_type == "string" && (schema.contains("minLength") \|\| schema.contains("maxLength"))) {
	std::string char_rule = _add_primitive("char", PRIMITIVE_RULES.at("char"));
	int min_len = schema.contains("minLength") ? schema["minLength"].get<int>() : 0;
	int max_len = schema.contains("maxLength") ? schema["maxLength"].get<int>() : std::numeric_limits<int>::max();
	return _add_rule(rule_name, "\"\\\"\" " + build_repetition(char_rule, min_len, max_len) + " \"\\\"\" space");
	} else if (schema_type == "integer" && (schema.contains("minimum") \|\| schema.contains("exclusiveMinimum") \|\| schema.contains("maximum") \|\| schema.contains("exclusiveMaximum"))) {
	int min_value = std::numeric_limits<int>::min();
	int max_value = std::numeric_limits<int>::max();
	if (schema.contains("minimum")) {
	min_value = schema["minimum"].get<int>();
	} else if (schema.contains("exclusiveMinimum")) {
	min_value = schema["exclusiveMinimum"].get<int>() + 1;
	}
	if (schema.contains("maximum")) {
	max_value = schema["maximum"].get<int>();
	} else if (schema.contains("exclusiveMaximum")) {
	max_value = schema["exclusiveMaximum"].get<int>() - 1;
	}
	std::stringstream out;
	out << "(";
	_build_min_max_int(min_value, max_value, out);
	out << ") space";
	return _add_rule(rule_name, out.str());
	} else if (schema.empty() \|\| schema_type == "object") {
	return _add_rule(rule_name, _add_primitive("object", PRIMITIVE_RULES.at("object")));
	} else {
	if (!schema_type.is_string() \|\| PRIMITIVE_RULES.find(schema_type.get<std::string>()) == PRIMITIVE_RULES.end()) {
	_errors.push_back("Unrecognized schema: " + schema.dump());
	return "";
	}
	// TODO: support minimum, maximum, exclusiveMinimum, exclusiveMaximum at least for zero
	return _add_primitive(rule_name == "root" ? "root" : schema_type.get<std::string>(), PRIMITIVE_RULES.at(schema_type.get<std::string>()));
	}
	}

	void check_errors() {
	if (!_errors.empty()) {
	throw std::runtime_error("JSON schema conversion failed:\n" + join(_errors.begin(), _errors.end(), "\n"));
	}
	if (!_warnings.empty()) {
	fprintf(stderr, "WARNING: JSON schema conversion was incomplete: %s\n", join(_warnings.begin(), _warnings.end(), "; ").c_str());
	}
	}

	std::string format_grammar() {
	std::stringstream ss;
	for (const auto & kv : _rules) {
	ss << kv.first << " ::= " << kv.second << std::endl;
	}
	return ss.str();
	}
	};

	std::string json_schema_to_grammar(const json & schema) {
	SchemaConverter converter([](const std::string &) { return json::object(); }, /* dotall= */ false);
	auto copy = schema;
	converter.resolve_refs(copy, "input");
	converter.visit(copy, "");
	converter.check_errors();
	return converter.format_grammar();
	}