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	/*
	Copyright 2024 Google LLC

	Use of this source code is governed by an MIT-style
	license that can be found in the LICENSE file or at
	https://opensource.org/licenses/MIT.
	*/
	// SPDX-License-Identifier: MIT
	#pragma once

	#include <iostream>
	#include <string>
	#include <vector>
	#include <regex>
	#include <memory>
	#include <stdexcept>
	#include <sstream>
	#include <unordered_set>
	#include <json.hpp>

	using json = nlohmann::ordered_json;

	namespace minja {

	class Context;

	struct Options {
	bool trim_blocks; // removes the first newline after a block
	bool lstrip_blocks; // removes leading whitespace on the line of the block
	bool keep_trailing_newline; // don't remove last newline
	};

	struct ArgumentsValue;

	inline std::string normalize_newlines(const std::string & s) {
	#ifdef _WIN32
	static const std::regex nl_regex("\r\n");
	return std::regex_replace(s, nl_regex, "\n");
	#else
	return s;
	#endif
	}

	/* Values that behave roughly like in Python. */
	class Value : public std::enable_shared_from_this<Value> {
	public:
	using CallableType = std::function<Value(const std::shared_ptr<Context> &, ArgumentsValue &)>;
	using FilterType = std::function<Value(const std::shared_ptr<Context> &, ArgumentsValue &)>;

	private:
	using ObjectType = nlohmann::ordered_map<json, Value>; // Only contains primitive keys
	using ArrayType = std::vector<Value>;

	std::shared_ptr<ArrayType> array_;
	std::shared_ptr<ObjectType> object_;
	std::shared_ptr<CallableType> callable_;
	json primitive_;

	Value(const std::shared_ptr<ArrayType> & array) : array_(array) {}
	Value(const std::shared_ptr<ObjectType> & object) : object_(object) {}
	Value(const std::shared_ptr<CallableType> & callable) : object_(std::make_shared<ObjectType>()), callable_(callable) {}

	/* Python-style string repr */
	static void dump_string(const json & primitive, std::ostringstream & out, char string_quote = '\'') {
	if (!primitive.is_string()) throw std::runtime_error("Value is not a string: " + primitive.dump());
	auto s = primitive.dump();
	if (string_quote == '"' \|\| s.find('\'') != std::string::npos) {
	out << s;
	return;
	}
	// Reuse json dump, just changing string quotes
	out << string_quote;
	for (size_t i = 1, n = s.size() - 1; i < n; ++i) {
	if (s[i] == '\\' && s[i + 1] == '"') {
	out << '"';
	i++;
	} else if (s[i] == string_quote) {
	out << '\\' << string_quote;
	} else {
	out << s[i];
	}
	}
	out << string_quote;
	}
	void dump(std::ostringstream & out, int indent = -1, int level = 0, bool to_json = false) const {
	auto print_indent = [&](int level) {
	if (indent > 0) {
	out << "\n";
	for (int i = 0, n = level * indent; i < n; ++i) out << ' ';
	}
	};
	auto print_sub_sep = [&]() {
	out << ',';
	if (indent < 0) out << ' ';
	else print_indent(level + 1);
	};

	auto string_quote = to_json ? '"' : '\'';

	if (is_null()) out << "null";
	else if (array_) {
	out << "[";
	print_indent(level + 1);
	for (size_t i = 0; i < array_->size(); ++i) {
	if (i) print_sub_sep();
	(*array_)[i].dump(out, indent, level + 1, to_json);
	}
	print_indent(level);
	out << "]";
	} else if (object_) {
	out << "{";
	print_indent(level + 1);
	for (auto begin = object_->begin(), it = begin; it != object_->end(); ++it) {
	if (it != begin) print_sub_sep();
	if (it->first.is_string()) {
	dump_string(it->first, out, string_quote);
	} else {
	out << string_quote << it->first.dump() << string_quote;
	}
	out << ": ";
	it->second.dump(out, indent, level + 1, to_json);
	}
	print_indent(level);
	out << "}";
	} else if (callable_) {
	throw std::runtime_error("Cannot dump callable to JSON");
	} else if (is_boolean() && !to_json) {
	out << (this->to_bool() ? "True" : "False");
	} else if (is_string() && !to_json) {
	dump_string(primitive_, out, string_quote);
	} else {
	out << primitive_.dump();
	}
	}

	public:
	Value() {}
	Value(const bool& v) : primitive_(v) {}
	Value(const int64_t & v) : primitive_(v) {}
	Value(const double& v) : primitive_(v) {}
	Value(const std::nullptr_t &) {}
	Value(const std::string & v) : primitive_(v) {}
	Value(const char * v) : primitive_(std::string(v)) {}

	Value(const json & v) {
	if (v.is_object()) {
	auto object = std::make_shared<ObjectType>();
	for (auto it = v.begin(); it != v.end(); ++it) {
	(*object)[it.key()] = it.value();
	}
	object_ = std::move(object);
	} else if (v.is_array()) {
	auto array = std::make_shared<ArrayType>();
	for (const auto& item : v) {
	array->push_back(Value(item));
	}
	array_ = array;
	} else {
	primitive_ = v;
	}
	}

	std::vector<Value> keys() {
	if (!object_) throw std::runtime_error("Value is not an object: " + dump());
	std::vector<Value> res;
	for (const auto& item : *object_) {
	res.push_back(item.first);
	}
	return res;
	}

	size_t size() const {
	if (is_object()) return object_->size();
	if (is_array()) return array_->size();
	if (is_string()) return primitive_.get<std::string>().length();
	throw std::runtime_error("Value is not an array or object: " + dump());
	}

	static Value array(const std::vector<Value> values = {}) {
	auto array = std::make_shared<ArrayType>();
	for (const auto& item : values) {
	array->push_back(item);
	}
	return Value(array);
	}
	static Value object(const std::shared_ptr<ObjectType> object = std::make_shared<ObjectType>()) {
	return Value(object);
	}
	static Value callable(const CallableType & callable) {
	return Value(std::make_shared<CallableType>(callable));
	}

	void insert(size_t index, const Value& v) {
	if (!array_)
	throw std::runtime_error("Value is not an array: " + dump());
	array_->insert(array_->begin() + index, v);
	}
	void push_back(const Value& v) {
	if (!array_)
	throw std::runtime_error("Value is not an array: " + dump());
	array_->push_back(v);
	}
	Value pop(const Value& index) {
	if (is_array()) {
	if (array_->empty())
	throw std::runtime_error("pop from empty list");
	if (index.is_null()) {
	auto ret = array_->back();
	array_->pop_back();
	return ret;
	} else if (!index.is_number_integer()) {
	throw std::runtime_error("pop index must be an integer: " + index.dump());
	} else {
	auto i = index.get<int>();
	if (i < 0 \|\| i >= static_cast<int>(array_->size()))
	throw std::runtime_error("pop index out of range: " + index.dump());
	auto it = array_->begin() + (i < 0 ? array_->size() + i : i);
	auto ret = *it;
	array_->erase(it);
	return ret;
	}
	} else if (is_object()) {
	if (!index.is_hashable())
	throw std::runtime_error("Unashable type: " + index.dump());
	auto it = object_->find(index.primitive_);
	if (it == object_->end())
	throw std::runtime_error("Key not found: " + index.dump());
	auto ret = it->second;
	object_->erase(it);
	return ret;
	} else {
	throw std::runtime_error("Value is not an array or object: " + dump());
	}
	}
	Value get(const Value& key) {
	if (array_) {
	if (!key.is_number_integer()) {
	return Value();
	}
	auto index = key.get<int>();
	return array_->at(index < 0 ? array_->size() + index : index);
	} else if (object_) {
	if (!key.is_hashable()) throw std::runtime_error("Unashable type: " + dump());
	auto it = object_->find(key.primitive_);
	if (it == object_->end()) return Value();
	return it->second;
	}
	return Value();
	}
	void set(const Value& key, const Value& value) {
	if (!object_) throw std::runtime_error("Value is not an object: " + dump());
	if (!key.is_hashable()) throw std::runtime_error("Unashable type: " + dump());
	(*object_)[key.primitive_] = value;
	}
	Value call(const std::shared_ptr<Context> & context, ArgumentsValue & args) const {
	if (!callable_) throw std::runtime_error("Value is not callable: " + dump());
	return (*callable_)(context, args);
	}

	bool is_object() const { return !!object_; }
	bool is_array() const { return !!array_; }
	bool is_callable() const { return !!callable_; }
	bool is_null() const { return !object_ && !array_ && primitive_.is_null() && !callable_; }
	bool is_boolean() const { return primitive_.is_boolean(); }
	bool is_number_integer() const { return primitive_.is_number_integer(); }
	bool is_number_float() const { return primitive_.is_number_float(); }
	bool is_number() const { return primitive_.is_number(); }
	bool is_string() const { return primitive_.is_string(); }
	bool is_iterable() const { return is_array() \|\| is_object() \|\| is_string(); }

	bool is_primitive() const { return !array_ && !object_ && !callable_; }
	bool is_hashable() const { return is_primitive(); }

	bool empty() const {
	if (is_null())
	throw std::runtime_error("Undefined value or reference");
	if (is_string()) return primitive_.empty();
	if (is_array()) return array_->empty();
	if (is_object()) return object_->empty();
	return false;
	}

	void for_each(const std::function<void(Value &)> & callback) const {
	if (is_null())
	throw std::runtime_error("Undefined value or reference");
	if (array_) {
	for (auto& item : *array_) {
	callback(item);
	}
	} else if (object_) {
	for (auto & item : *object_) {
	Value key(item.first);
	callback(key);
	}
	} else if (is_string()) {
	for (char c : primitive_.get<std::string>()) {
	auto val = Value(std::string(1, c));
	callback(val);
	}
	} else {
	throw std::runtime_error("Value is not iterable: " + dump());
	}
	}

	bool to_bool() const {
	if (is_null()) return false;
	if (is_boolean()) return get<bool>();
	if (is_number()) return get<double>() != 0;
	if (is_string()) return !get<std::string>().empty();
	if (is_array()) return !empty();
	return true;
	}

	int64_t to_int() const {
	if (is_null()) return 0;
	if (is_boolean()) return get<bool>() ? 1 : 0;
	if (is_number()) return static_cast<int64_t>(get<double>());
	if (is_string()) {
	try {
	return std::stol(get<std::string>());
	} catch (const std::exception &) {
	return 0;
	}
	}
	return 0;
	}

	bool operator<(const Value & other) const {
	if (is_null())
	throw std::runtime_error("Undefined value or reference");
	if (is_number() && other.is_number()) return get<double>() < other.get<double>();
	if (is_string() && other.is_string()) return get<std::string>() < other.get<std::string>();
	throw std::runtime_error("Cannot compare values: " + dump() + " < " + other.dump());
	}
	bool operator>=(const Value & other) const { return !(*this < other); }

	bool operator>(const Value & other) const {
	if (is_null())
	throw std::runtime_error("Undefined value or reference");
	if (is_number() && other.is_number()) return get<double>() > other.get<double>();
	if (is_string() && other.is_string()) return get<std::string>() > other.get<std::string>();
	throw std::runtime_error("Cannot compare values: " + dump() + " > " + other.dump());
	}
	bool operator<=(const Value & other) const { return !(*this > other); }

	bool operator==(const Value & other) const {
	if (callable_ \|\| other.callable_) {
	if (callable_.get() != other.callable_.get()) return false;
	}
	if (array_) {
	if (!other.array_) return false;
	if (array_->size() != other.array_->size()) return false;
	for (size_t i = 0; i < array_->size(); ++i) {
	if (!(array_)[i].to_bool() \|\| !(other.array_)[i].to_bool() \|\| (array_)[i] != (other.array_)[i]) return false;
	}
	return true;
	} else if (object_) {
	if (!other.object_) return false;
	if (object_->size() != other.object_->size()) return false;
	for (const auto& item : *object_) {
	if (!item.second.to_bool() \|\| !other.object_->count(item.first) \|\| item.second != other.object_->at(item.first)) return false;
	}
	return true;
	} else {
	return primitive_ == other.primitive_;
	}
	}
	bool operator!=(const Value & other) const { return !(*this == other); }

	bool contains(const char * key) const { return contains(std::string(key)); }
	bool contains(const std::string & key) const {
	if (array_) {
	return false;
	} else if (object_) {
	return object_->find(key) != object_->end();
	} else {
	throw std::runtime_error("contains can only be called on arrays and objects: " + dump());
	}
	}
	bool contains(const Value & value) const {
	if (is_null())
	throw std::runtime_error("Undefined value or reference");
	if (array_) {
	for (const auto& item : *array_) {
	if (item.to_bool() && item == value) return true;
	}
	return false;
	} else if (object_) {
	if (!value.is_hashable()) throw std::runtime_error("Unashable type: " + value.dump());
	return object_->find(value.primitive_) != object_->end();
	} else {
	throw std::runtime_error("contains can only be called on arrays and objects: " + dump());
	}
	}
	void erase(size_t index) {
	if (!array_) throw std::runtime_error("Value is not an array: " + dump());
	array_->erase(array_->begin() + index);
	}
	void erase(const std::string & key) {
	if (!object_) throw std::runtime_error("Value is not an object: " + dump());
	object_->erase(key);
	}
	const Value& at(const Value & index) const {
	return const_cast<Value*>(this)->at(index);
	}
	Value& at(const Value & index) {
	if (!index.is_hashable()) throw std::runtime_error("Unashable type: " + dump());
	if (is_array()) return array_->at(index.get<int>());
	if (is_object()) return object_->at(index.primitive_);
	throw std::runtime_error("Value is not an array or object: " + dump());
	}
	const Value& at(size_t index) const {
	return const_cast<Value*>(this)->at(index);
	}
	Value& at(size_t index) {
	if (is_null())
	throw std::runtime_error("Undefined value or reference");
	if (is_array()) return array_->at(index);
	if (is_object()) return object_->at(index);
	throw std::runtime_error("Value is not an array or object: " + dump());
	}

	template <typename T>
	T get(const std::string & key, T default_value) const {
	if (!contains(key)) return default_value;
	return at(key).get<T>();
	}

	template <typename T>
	T get() const {
	if (is_primitive()) return primitive_.get<T>();
	throw std::runtime_error("get<T> not defined for this value type: " + dump());
	}

	std::string dump(int indent=-1, bool to_json=false) const {
	std::ostringstream out;
	dump(out, indent, 0, to_json);
	return out.str();
	}

	Value operator-() const {
	if (is_number_integer())
	return -get<int64_t>();
	else
	return -get<double>();
	}
	std::string to_str() const {
	if (is_string()) return get<std::string>();
	if (is_number_integer()) return std::to_string(get<int64_t>());
	if (is_number_float()) return std::to_string(get<double>());
	if (is_boolean()) return get<bool>() ? "True" : "False";
	if (is_null()) return "None";
	return dump();
	}
	Value operator+(const Value& rhs) const {
	if (is_string() \|\| rhs.is_string()) {
	return to_str() + rhs.to_str();
	} else if (is_number_integer() && rhs.is_number_integer()) {
	return get<int64_t>() + rhs.get<int64_t>();
	} else if (is_array() && rhs.is_array()) {
	auto res = Value::array();
	for (const auto& item : *array_) res.push_back(item);
	for (const auto& item : *rhs.array_) res.push_back(item);
	return res;
	} else {
	return get<double>() + rhs.get<double>();
	}
	}
	Value operator-(const Value& rhs) const {
	if (is_number_integer() && rhs.is_number_integer())
	return get<int64_t>() - rhs.get<int64_t>();
	else
	return get<double>() - rhs.get<double>();
	}
	Value operator*(const Value& rhs) const {
	if (is_string() && rhs.is_number_integer()) {
	std::ostringstream out;
	for (int64_t i = 0, n = rhs.get<int64_t>(); i < n; ++i) {
	out << to_str();
	}
	return out.str();
	}
	else if (is_number_integer() && rhs.is_number_integer())
	return get<int64_t>() * rhs.get<int64_t>();
	else
	return get<double>() * rhs.get<double>();
	}
	Value operator/(const Value& rhs) const {
	if (is_number_integer() && rhs.is_number_integer())
	return get<int64_t>() / rhs.get<int64_t>();
	else
	return get<double>() / rhs.get<double>();
	}
	Value operator%(const Value& rhs) const {
	return get<int64_t>() % rhs.get<int64_t>();
	}
	};

	struct ArgumentsValue {
	std::vector<Value> args;
	std::vector<std::pair<std::string, Value>> kwargs;

	bool has_named(const std::string & name) {
	for (const auto & p : kwargs) {
	if (p.first == name) return true;
	}
	return false;
	}

	Value get_named(const std::string & name) {
	for (const auto & [key, value] : kwargs) {
	if (key == name) return value;
	}
	return Value();
	}

	bool empty() {
	return args.empty() && kwargs.empty();
	}

	void expectArgs(const std::string & method_name, const std::pair<size_t, size_t> & pos_count, const std::pair<size_t, size_t> & kw_count) {
	if (args.size() < pos_count.first \|\| args.size() > pos_count.second \|\| kwargs.size() < kw_count.first \|\| kwargs.size() > kw_count.second) {
	std::ostringstream out;
	out << method_name << " must have between " << pos_count.first << " and " << pos_count.second << " positional arguments and between " << kw_count.first << " and " << kw_count.second << " keyword arguments";
	throw std::runtime_error(out.str());
	}
	}
	};

	template <>
	inline json Value::get<json>() const {
	if (is_primitive()) return primitive_;
	if (is_null()) return json();
	if (array_) {
	std::vector<json> res;
	for (const auto& item : *array_) {
	res.push_back(item.get<json>());
	}
	return res;
	}
	if (object_) {
	json res = json::object();
	for (const auto& [key, value] : *object_) {
	if (key.is_string()) {
	res[key.get<std::string>()] = value.get<json>();
	} else if (key.is_primitive()) {
	res[key.dump()] = value.get<json>();
	} else {
	throw std::runtime_error("Invalid key type for conversion to JSON: " + key.dump());
	}
	}
	if (is_callable()) {
	res["__callable__"] = true;
	}
	return res;
	}
	throw std::runtime_error("get<json> not defined for this value type: " + dump());
	}

	} // namespace minja

	namespace std {
	template <>
	struct hash<minja::Value> {
	size_t operator()(const minja::Value & v) const {
	if (!v.is_hashable())
	throw std::runtime_error("Unsupported type for hashing: " + v.dump());
	return std::hash<json>()(v.get<json>());
	}
	};
	} // namespace std

	namespace minja {

	static std::string error_location_suffix(const std::string & source, size_t pos) {
	auto get_line = [&](size_t line) {
	auto start = source.begin();
	for (size_t i = 1; i < line; ++i) {
	start = std::find(start, source.end(), '\n') + 1;
	}
	auto end = std::find(start, source.end(), '\n');
	return std::string(start, end);
	};
	auto start = source.begin();
	auto end = source.end();
	auto it = start + pos;
	auto line = std::count(start, it, '\n') + 1;
	auto max_line = std::count(start, end, '\n') + 1;
	auto col = pos - std::string(start, it).rfind('\n');
	std::ostringstream out;
	out << " at row " << line << ", column " << col << ":\n";
	if (line > 1) out << get_line(line - 1) << "\n";
	out << get_line(line) << "\n";
	out << std::string(col - 1, ' ') << "^\n";
	if (line < max_line) out << get_line(line + 1) << "\n";

	return out.str();
	}

	class Context : public std::enable_shared_from_this<Context> {
	protected:
	Value values_;
	std::shared_ptr<Context> parent_;
	public:
	Context(Value && values, const std::shared_ptr<Context> & parent = nullptr) : values_(std::move(values)), parent_(parent) {
	if (!values_.is_object()) throw std::runtime_error("Context values must be an object: " + values_.dump());
	}
	virtual ~Context() {}

	static std::shared_ptr<Context> builtins();
	static std::shared_ptr<Context> make(Value && values, const std::shared_ptr<Context> & parent = builtins());

	std::vector<Value> keys() {
	return values_.keys();
	}
	virtual Value get(const Value & key) {
	if (values_.contains(key)) return values_.at(key);
	if (parent_) return parent_->get(key);
	return Value();
	}
	virtual Value & at(const Value & key) {
	if (values_.contains(key)) return values_.at(key);
	if (parent_) return parent_->at(key);
	throw std::runtime_error("Undefined variable: " + key.dump());
	}
	virtual bool contains(const Value & key) {
	if (values_.contains(key)) return true;
	if (parent_) return parent_->contains(key);
	return false;
	}
	virtual void set(const Value & key, const Value & value) {
	values_.set(key, value);
	}
	};

	struct Location {
	std::shared_ptr<std::string> source;
	size_t pos;
	};

	class Expression {
	protected:
	virtual Value do_evaluate(const std::shared_ptr<Context> & context) const = 0;
	public:
	using Parameters = std::vector<std::pair<std::string, std::shared_ptr<Expression>>>;

	Location location;

	Expression(const Location & location) : location(location) {}
	virtual ~Expression() = default;

	Value evaluate(const std::shared_ptr<Context> & context) const {
	try {
	return do_evaluate(context);
	} catch (const std::exception & e) {
	std::ostringstream out;
	out << e.what();
	if (location.source) out << error_location_suffix(*location.source, location.pos);
	throw std::runtime_error(out.str());
	}
	}
	};

	class VariableExpr : public Expression {
	std::string name;
	public:
	VariableExpr(const Location & location, const std::string& n)
	: Expression(location), name(n) {}
	std::string get_name() const { return name; }
	Value do_evaluate(const std::shared_ptr<Context> & context) const override {
	if (!context->contains(name)) {
	return Value();
	}
	return context->at(name);
	}
	};

	static void destructuring_assign(const std::vector<std::string> & var_names, const std::shared_ptr<Context> & context, Value& item) {
	if (var_names.size() == 1) {
	Value name(var_names[0]);
	context->set(name, item);
	} else {
	if (!item.is_array() \|\| item.size() != var_names.size()) {
	throw std::runtime_error("Mismatched number of variables and items in destructuring assignment");
	}
	for (size_t i = 0; i < var_names.size(); ++i) {
	context->set(var_names[i], item.at(i));
	}
	}
	}

	enum SpaceHandling { Keep, Strip, StripSpaces, StripNewline };

	class TemplateToken {
	public:
	enum class Type { Text, Expression, If, Else, Elif, EndIf, For, EndFor, Generation, EndGeneration, Set, EndSet, Comment, Macro, EndMacro, Filter, EndFilter, Break, Continue };

	static std::string typeToString(Type t) {
	switch (t) {
	case Type::Text: return "text";
	case Type::Expression: return "expression";
	case Type::If: return "if";
	case Type::Else: return "else";
	case Type::Elif: return "elif";
	case Type::EndIf: return "endif";
	case Type::For: return "for";
	case Type::EndFor: return "endfor";
	case Type::Set: return "set";
	case Type::EndSet: return "endset";
	case Type::Comment: return "comment";
	case Type::Macro: return "macro";
	case Type::EndMacro: return "endmacro";
	case Type::Filter: return "filter";
	case Type::EndFilter: return "endfilter";
	case Type::Generation: return "generation";
	case Type::EndGeneration: return "endgeneration";
	case Type::Break: return "break";
	case Type::Continue: return "continue";
	}
	return "Unknown";
	}

	TemplateToken(Type type, const Location & location, SpaceHandling pre, SpaceHandling post) : type(type), location(location), pre_space(pre), post_space(post) {}
	virtual ~TemplateToken() = default;

	Type type;
	Location location;
	SpaceHandling pre_space = SpaceHandling::Keep;
	SpaceHandling post_space = SpaceHandling::Keep;
	};

	struct TextTemplateToken : public TemplateToken {
	std::string text;
	TextTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post, const std::string& t) : TemplateToken(Type::Text, location, pre, post), text(t) {}
	};

	struct ExpressionTemplateToken : public TemplateToken {
	std::shared_ptr<Expression> expr;
	ExpressionTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post, std::shared_ptr<Expression> && e) : TemplateToken(Type::Expression, location, pre, post), expr(std::move(e)) {}
	};

	struct IfTemplateToken : public TemplateToken {
	std::shared_ptr<Expression> condition;
	IfTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post, std::shared_ptr<Expression> && c) : TemplateToken(Type::If, location, pre, post), condition(std::move(c)) {}
	};

	struct ElifTemplateToken : public TemplateToken {
	std::shared_ptr<Expression> condition;
	ElifTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post, std::shared_ptr<Expression> && c) : TemplateToken(Type::Elif, location, pre, post), condition(std::move(c)) {}
	};

	struct ElseTemplateToken : public TemplateToken {
	ElseTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post) : TemplateToken(Type::Else, location, pre, post) {}
	};

	struct EndIfTemplateToken : public TemplateToken {
	EndIfTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post) : TemplateToken(Type::EndIf, location, pre, post) {}
	};

	struct MacroTemplateToken : public TemplateToken {
	std::shared_ptr<VariableExpr> name;
	Expression::Parameters params;
	MacroTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post, std::shared_ptr<VariableExpr> && n, Expression::Parameters && p)
	: TemplateToken(Type::Macro, location, pre, post), name(std::move(n)), params(std::move(p)) {}
	};

	struct EndMacroTemplateToken : public TemplateToken {
	EndMacroTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post) : TemplateToken(Type::EndMacro, location, pre, post) {}
	};

	struct FilterTemplateToken : public TemplateToken {
	std::shared_ptr<Expression> filter;
	FilterTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post, std::shared_ptr<Expression> && filter)
	: TemplateToken(Type::Filter, location, pre, post), filter(std::move(filter)) {}
	};

	struct EndFilterTemplateToken : public TemplateToken {
	EndFilterTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post) : TemplateToken(Type::EndFilter, location, pre, post) {}
	};

	struct ForTemplateToken : public TemplateToken {
	std::vector<std::string> var_names;
	std::shared_ptr<Expression> iterable;
	std::shared_ptr<Expression> condition;
	bool recursive;
	ForTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post, const std::vector<std::string> & vns, std::shared_ptr<Expression> && iter,
	std::shared_ptr<Expression> && c, bool r)
	: TemplateToken(Type::For, location, pre, post), var_names(vns), iterable(std::move(iter)), condition(std::move(c)), recursive(r) {}
	};

	struct EndForTemplateToken : public TemplateToken {
	EndForTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post) : TemplateToken(Type::EndFor, location, pre, post) {}
	};

	struct GenerationTemplateToken : public TemplateToken {
	GenerationTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post) : TemplateToken(Type::Generation, location, pre, post) {}
	};

	struct EndGenerationTemplateToken : public TemplateToken {
	EndGenerationTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post) : TemplateToken(Type::EndGeneration, location, pre, post) {}
	};

	struct SetTemplateToken : public TemplateToken {
	std::string ns;
	std::vector<std::string> var_names;
	std::shared_ptr<Expression> value;
	SetTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post, const std::string & ns, const std::vector<std::string> & vns, std::shared_ptr<Expression> && v)
	: TemplateToken(Type::Set, location, pre, post), ns(ns), var_names(vns), value(std::move(v)) {}
	};

	struct EndSetTemplateToken : public TemplateToken {
	EndSetTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post) : TemplateToken(Type::EndSet, location, pre, post) {}
	};

	struct CommentTemplateToken : public TemplateToken {
	std::string text;
	CommentTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post, const std::string& t) : TemplateToken(Type::Comment, location, pre, post), text(t) {}
	};

	enum class LoopControlType { Break, Continue };

	class LoopControlException : public std::runtime_error {
	public:
	LoopControlType control_type;
	LoopControlException(const std::string & message, LoopControlType control_type) : std::runtime_error(message), control_type(control_type) {}
	LoopControlException(LoopControlType control_type)
	: std::runtime_error((control_type == LoopControlType::Continue ? "continue" : "break") + std::string(" outside of a loop")),
	control_type(control_type) {}
	};

	struct LoopControlTemplateToken : public TemplateToken {
	LoopControlType control_type;
	LoopControlTemplateToken(const Location & location, SpaceHandling pre, SpaceHandling post, LoopControlType control_type) : TemplateToken(Type::Break, location, pre, post), control_type(control_type) {}
	};

	class TemplateNode {
	Location location_;
	protected:
	virtual void do_render(std::ostringstream & out, const std::shared_ptr<Context> & context) const = 0;

	public:
	TemplateNode(const Location & location) : location_(location) {}
	void render(std::ostringstream & out, const std::shared_ptr<Context> & context) const {
	try {
	do_render(out, context);
	} catch (const LoopControlException & e) {
	// TODO: make stack creation lazy. Only needed if it was thrown outside of a loop.
	std::ostringstream err;
	err << e.what();
	if (location_.source) err << error_location_suffix(*location_.source, location_.pos);
	throw LoopControlException(err.str(), e.control_type);
	} catch (const std::exception & e) {
	std::ostringstream err;
	err << e.what();
	if (location_.source) err << error_location_suffix(*location_.source, location_.pos);
	throw std::runtime_error(err.str());
	}
	}
	const Location & location() const { return location_; }
	virtual ~TemplateNode() = default;
	std::string render(const std::shared_ptr<Context> & context) const {
	std::ostringstream out;
	render(out, context);
	return out.str();
	}
	};

	class SequenceNode : public TemplateNode {
	std::vector<std::shared_ptr<TemplateNode>> children;
	public:
	SequenceNode(const Location & location, std::vector<std::shared_ptr<TemplateNode>> && c)
	: TemplateNode(location), children(std::move(c)) {}
	void do_render(std::ostringstream & out, const std::shared_ptr<Context> & context) const override {
	for (const auto& child : children) child->render(out, context);
	}
	};

	class TextNode : public TemplateNode {
	std::string text;
	public:
	TextNode(const Location & location, const std::string& t) : TemplateNode(location), text(t) {}
	void do_render(std::ostringstream & out, const std::shared_ptr<Context> &) const override {
	out << text;
	}
	};

	class ExpressionNode : public TemplateNode {
	std::shared_ptr<Expression> expr;
	public:
	ExpressionNode(const Location & location, std::shared_ptr<Expression> && e) : TemplateNode(location), expr(std::move(e)) {}
	void do_render(std::ostringstream & out, const std::shared_ptr<Context> & context) const override {
	if (!expr) throw std::runtime_error("ExpressionNode.expr is null");
	auto result = expr->evaluate(context);
	if (result.is_string()) {
	out << result.get<std::string>();
	} else if (result.is_boolean()) {
	out << (result.get<bool>() ? "True" : "False");
	} else if (!result.is_null()) {
	out << result.dump();
	}
	}
	};

	class IfNode : public TemplateNode {
	std::vector<std::pair<std::shared_ptr<Expression>, std::shared_ptr<TemplateNode>>> cascade;
	public:
	IfNode(const Location & location, std::vector<std::pair<std::shared_ptr<Expression>, std::shared_ptr<TemplateNode>>> && c)
	: TemplateNode(location), cascade(std::move(c)) {}
	void do_render(std::ostringstream & out, const std::shared_ptr<Context> & context) const override {
	for (const auto& branch : cascade) {
	auto enter_branch = true;
	if (branch.first) {
	enter_branch = branch.first->evaluate(context).to_bool();
	}
	if (enter_branch) {
	if (!branch.second) throw std::runtime_error("IfNode.cascade.second is null");
	branch.second->render(out, context);
	return;
	}
	}
	}
	};

	class LoopControlNode : public TemplateNode {
	LoopControlType control_type_;
	public:
	LoopControlNode(const Location & location, LoopControlType control_type) : TemplateNode(location), control_type_(control_type) {}
	void do_render(std::ostringstream &, const std::shared_ptr<Context> &) const override {
	throw LoopControlException(control_type_);
	}
	};

	class ForNode : public TemplateNode {
	std::vector<std::string> var_names;
	std::shared_ptr<Expression> iterable;
	std::shared_ptr<Expression> condition;
	std::shared_ptr<TemplateNode> body;
	bool recursive;
	std::shared_ptr<TemplateNode> else_body;
	public:
	ForNode(const Location & location, std::vector<std::string> && var_names, std::shared_ptr<Expression> && iterable,
	std::shared_ptr<Expression> && condition, std::shared_ptr<TemplateNode> && body, bool recursive, std::shared_ptr<TemplateNode> && else_body)
	: TemplateNode(location), var_names(var_names), iterable(std::move(iterable)), condition(std::move(condition)), body(std::move(body)), recursive(recursive), else_body(std::move(else_body)) {}

	void do_render(std::ostringstream & out, const std::shared_ptr<Context> & context) const override {
	// https://jinja.palletsprojects.com/en/3.0.x/templates/#for
	if (!iterable) throw std::runtime_error("ForNode.iterable is null");
	if (!body) throw std::runtime_error("ForNode.body is null");

	auto iterable_value = iterable->evaluate(context);
	Value::CallableType loop_function;

	std::function<void(Value&)> visit = [&](Value& iter) {
	auto filtered_items = Value::array();
	if (!iter.is_null()) {
	if (!iterable_value.is_iterable()) {
	throw std::runtime_error("For loop iterable must be iterable: " + iterable_value.dump());
	}
	iterable_value.for_each([&](Value & item) {
	destructuring_assign(var_names, context, item);
	if (!condition \|\| condition->evaluate(context).to_bool()) {
	filtered_items.push_back(item);
	}
	});
	}
	if (filtered_items.empty()) {
	if (else_body) {
	else_body->render(out, context);
	}
	} else {
	auto loop = recursive ? Value::callable(loop_function) : Value::object();
	loop.set("length", (int64_t) filtered_items.size());

	size_t cycle_index = 0;
	loop.set("cycle", Value::callable([&](const std::shared_ptr<Context> &, ArgumentsValue & args) {
	if (args.args.empty() \|\| !args.kwargs.empty()) {
	throw std::runtime_error("cycle() expects at least 1 positional argument and no named arg");
	}
	auto item = args.args[cycle_index];
	cycle_index = (cycle_index + 1) % args.args.size();
	return item;
	}));
	auto loop_context = Context::make(Value::object(), context);
	loop_context->set("loop", loop);
	for (size_t i = 0, n = filtered_items.size(); i < n; ++i) {
	auto & item = filtered_items.at(i);
	destructuring_assign(var_names, loop_context, item);
	loop.set("index", (int64_t) i + 1);
	loop.set("index0", (int64_t) i);
	loop.set("revindex", (int64_t) (n - i));
	loop.set("revindex0", (int64_t) (n - i - 1));
	loop.set("length", (int64_t) n);
	loop.set("first", i == 0);
	loop.set("last", i == (n - 1));
	loop.set("previtem", i > 0 ? filtered_items.at(i - 1) : Value());
	loop.set("nextitem", i < n - 1 ? filtered_items.at(i + 1) : Value());
	try {
	body->render(out, loop_context);
	} catch (const LoopControlException & e) {
	if (e.control_type == LoopControlType::Break) break;
	if (e.control_type == LoopControlType::Continue) continue;
	}
	}
	}
	};

	if (recursive) {
	loop_function = [&](const std::shared_ptr<Context> &, ArgumentsValue & args) {
	if (args.args.size() != 1 \|\| !args.kwargs.empty() \|\| !args.args[0].is_array()) {
	throw std::runtime_error("loop() expects exactly 1 positional iterable argument");
	}
	auto & items = args.args[0];
	visit(items);
	return Value();
	};
	}

	visit(iterable_value);
	}
	};

	class MacroNode : public TemplateNode {
	std::shared_ptr<VariableExpr> name;
	Expression::Parameters params;
	std::shared_ptr<TemplateNode> body;
	std::unordered_map<std::string, size_t> named_param_positions;
	public:
	MacroNode(const Location & location, std::shared_ptr<VariableExpr> && n, Expression::Parameters && p, std::shared_ptr<TemplateNode> && b)
	: TemplateNode(location), name(std::move(n)), params(std::move(p)), body(std::move(b)) {
	for (size_t i = 0; i < params.size(); ++i) {
	const auto & name = params[i].first;
	if (!name.empty()) {
	named_param_positions[name] = i;
	}
	}
	}
	void do_render(std::ostringstream &, const std::shared_ptr<Context> & macro_context) const override {
	if (!name) throw std::runtime_error("MacroNode.name is null");
	if (!body) throw std::runtime_error("MacroNode.body is null");
	auto callable = Value::callable([&](const std::shared_ptr<Context> & context, ArgumentsValue & args) {
	auto call_context = macro_context;
	std::vector<bool> param_set(params.size(), false);
	for (size_t i = 0, n = args.args.size(); i < n; i++) {
	auto & arg = args.args[i];
	if (i >= params.size()) throw std::runtime_error("Too many positional arguments for macro " + name->get_name());
	param_set[i] = true;
	auto & param_name = params[i].first;
	call_context->set(param_name, arg);
	}
	for (auto & [arg_name, value] : args.kwargs) {
	auto it = named_param_positions.find(arg_name);
	if (it == named_param_positions.end()) throw std::runtime_error("Unknown parameter name for macro " + name->get_name() + ": " + arg_name);

	call_context->set(arg_name, value);
	param_set[it->second] = true;
	}
	// Set default values for parameters that were not passed
	for (size_t i = 0, n = params.size(); i < n; i++) {
	if (!param_set[i] && params[i].second != nullptr) {
	auto val = params[i].second->evaluate(context);
	call_context->set(params[i].first, val);
	}
	}
	return body->render(call_context);
	});
	macro_context->set(name->get_name(), callable);
	}
	};

	class FilterNode : public TemplateNode {
	std::shared_ptr<Expression> filter;
	std::shared_ptr<TemplateNode> body;

	public:
	FilterNode(const Location & location, std::shared_ptr<Expression> && f, std::shared_ptr<TemplateNode> && b)
	: TemplateNode(location), filter(std::move(f)), body(std::move(b)) {}

	void do_render(std::ostringstream & out, const std::shared_ptr<Context> & context) const override {
	if (!filter) throw std::runtime_error("FilterNode.filter is null");
	if (!body) throw std::runtime_error("FilterNode.body is null");
	auto filter_value = filter->evaluate(context);
	if (!filter_value.is_callable()) {
	throw std::runtime_error("Filter must be a callable: " + filter_value.dump());
	}
	std::string rendered_body = body->render(context);

	ArgumentsValue filter_args = {{Value(rendered_body)}, {}};
	auto result = filter_value.call(context, filter_args);
	out << result.to_str();
	}
	};

	class SetNode : public TemplateNode {
	std::string ns;
	std::vector<std::string> var_names;
	std::shared_ptr<Expression> value;
	public:
	SetNode(const Location & location, const std::string & ns, const std::vector<std::string> & vns, std::shared_ptr<Expression> && v)
	: TemplateNode(location), ns(ns), var_names(vns), value(std::move(v)) {}
	void do_render(std::ostringstream &, const std::shared_ptr<Context> & context) const override {
	if (!value) throw std::runtime_error("SetNode.value is null");
	if (!ns.empty()) {
	if (var_names.size() != 1) {
	throw std::runtime_error("Namespaced set only supports a single variable name");
	}
	auto & name = var_names[0];
	auto ns_value = context->get(ns);
	if (!ns_value.is_object()) throw std::runtime_error("Namespace '" + ns + "' is not an object");
	ns_value.set(name, this->value->evaluate(context));
	} else {
	auto val = value->evaluate(context);
	destructuring_assign(var_names, context, val);
	}
	}
	};

	class SetTemplateNode : public TemplateNode {
	std::string name;
	std::shared_ptr<TemplateNode> template_value;
	public:
	SetTemplateNode(const Location & location, const std::string & name, std::shared_ptr<TemplateNode> && tv)
	: TemplateNode(location), name(name), template_value(std::move(tv)) {}
	void do_render(std::ostringstream &, const std::shared_ptr<Context> & context) const override {
	if (!template_value) throw std::runtime_error("SetTemplateNode.template_value is null");
	Value value { template_value->render(context) };
	context->set(name, value);
	}
	};

	class IfExpr : public Expression {
	std::shared_ptr<Expression> condition;
	std::shared_ptr<Expression> then_expr;
	std::shared_ptr<Expression> else_expr;
	public:
	IfExpr(const Location & location, std::shared_ptr<Expression> && c, std::shared_ptr<Expression> && t, std::shared_ptr<Expression> && e)
	: Expression(location), condition(std::move(c)), then_expr(std::move(t)), else_expr(std::move(e)) {}
	Value do_evaluate(const std::shared_ptr<Context> & context) const override {
	if (!condition) throw std::runtime_error("IfExpr.condition is null");
	if (!then_expr) throw std::runtime_error("IfExpr.then_expr is null");
	if (condition->evaluate(context).to_bool()) {
	return then_expr->evaluate(context);
	}
	if (else_expr) {
	return else_expr->evaluate(context);
	}
	return nullptr;
	}
	};

	class LiteralExpr : public Expression {
	Value value;
	public:
	LiteralExpr(const Location & location, const Value& v)
	: Expression(location), value(v) {}
	Value do_evaluate(const std::shared_ptr<Context> &) const override { return value; }
	};

	class ArrayExpr : public Expression {
	std::vector<std::shared_ptr<Expression>> elements;
	public:
	ArrayExpr(const Location & location, std::vector<std::shared_ptr<Expression>> && e)
	: Expression(location), elements(std::move(e)) {}
	Value do_evaluate(const std::shared_ptr<Context> & context) const override {
	auto result = Value::array();
	for (const auto& e : elements) {
	if (!e) throw std::runtime_error("Array element is null");
	result.push_back(e->evaluate(context));
	}
	return result;
	}
	};

	class DictExpr : public Expression {
	std::vector<std::pair<std::shared_ptr<Expression>, std::shared_ptr<Expression>>> elements;
	public:
	DictExpr(const Location & location, std::vector<std::pair<std::shared_ptr<Expression>, std::shared_ptr<Expression>>> && e)
	: Expression(location), elements(std::move(e)) {}
	Value do_evaluate(const std::shared_ptr<Context> & context) const override {
	auto result = Value::object();
	for (const auto& [key, value] : elements) {
	if (!key) throw std::runtime_error("Dict key is null");
	if (!value) throw std::runtime_error("Dict value is null");
	result.set(key->evaluate(context), value->evaluate(context));
	}
	return result;
	}
	};

	class SliceExpr : public Expression {
	public:
	std::shared_ptr<Expression> start, end;
	SliceExpr(const Location & location, std::shared_ptr<Expression> && s, std::shared_ptr<Expression> && e)
	: Expression(location), start(std::move(s)), end(std::move(e)) {}
	Value do_evaluate(const std::shared_ptr<Context> &) const override {
	throw std::runtime_error("SliceExpr not implemented");
	}
	};

	class SubscriptExpr : public Expression {
	std::shared_ptr<Expression> base;
	std::shared_ptr<Expression> index;
	public:
	SubscriptExpr(const Location & location, std::shared_ptr<Expression> && b, std::shared_ptr<Expression> && i)
	: Expression(location), base(std::move(b)), index(std::move(i)) {}
	Value do_evaluate(const std::shared_ptr<Context> & context) const override {
	if (!base) throw std::runtime_error("SubscriptExpr.base is null");
	if (!index) throw std::runtime_error("SubscriptExpr.index is null");
	auto target_value = base->evaluate(context);
	if (auto slice = dynamic_cast<SliceExpr*>(index.get())) {
	auto start = slice->start ? slice->start->evaluate(context).get<int64_t>() : 0;
	auto end = slice->end ? slice->end->evaluate(context).get<int64_t>() : (int64_t) target_value.size();
	if (target_value.is_string()) {
	std::string s = target_value.get<std::string>();
	if (start < 0) start = s.size() + start;
	if (end < 0) end = s.size() + end;
	return s.substr(start, end - start);
	} else if (target_value.is_array()) {
	if (start < 0) start = target_value.size() + start;
	if (end < 0) end = target_value.size() + end;
	auto result = Value::array();
	for (auto i = start; i < end; ++i) {
	result.push_back(target_value.at(i));
	}
	return result;
	} else {
	throw std::runtime_error(target_value.is_null() ? "Cannot subscript null" : "Subscripting only supported on arrays and strings");
	}
	} else {
	auto index_value = index->evaluate(context);
	if (target_value.is_null()) {
	if (auto t = dynamic_cast<VariableExpr*>(base.get())) {
	throw std::runtime_error("'" + t->get_name() + "' is " + (context->contains(t->get_name()) ? "null" : "not defined"));
	}
	throw std::runtime_error("Trying to access property '" + index_value.dump() + "' on null!");
	}
	return target_value.get(index_value);
	}
	}
	};

	class UnaryOpExpr : public Expression {
	public:
	enum class Op { Plus, Minus, LogicalNot, Expansion, ExpansionDict };
	std::shared_ptr<Expression> expr;
	Op op;
	UnaryOpExpr(const Location & location, std::shared_ptr<Expression> && e, Op o)
	: Expression(location), expr(std::move(e)), op(o) {}
	Value do_evaluate(const std::shared_ptr<Context> & context) const override {
	if (!expr) throw std::runtime_error("UnaryOpExpr.expr is null");
	auto e = expr->evaluate(context);
	switch (op) {
	case Op::Plus: return e;
	case Op::Minus: return -e;
	case Op::LogicalNot: return !e.to_bool();
	case Op::Expansion:
	case Op::ExpansionDict:
	throw std::runtime_error("Expansion operator is only supported in function calls and collections");

	}
	throw std::runtime_error("Unknown unary operator");
	}
	};

	class BinaryOpExpr : public Expression {
	public:
	enum class Op { StrConcat, Add, Sub, Mul, MulMul, Div, DivDiv, Mod, Eq, Ne, Lt, Gt, Le, Ge, And, Or, In, NotIn, Is, IsNot };
	private:
	std::shared_ptr<Expression> left;
	std::shared_ptr<Expression> right;
	Op op;
	public:
	BinaryOpExpr(const Location & location, std::shared_ptr<Expression> && l, std::shared_ptr<Expression> && r, Op o)
	: Expression(location), left(std::move(l)), right(std::move(r)), op(o) {}
	Value do_evaluate(const std::shared_ptr<Context> & context) const override {
	if (!left) throw std::runtime_error("BinaryOpExpr.left is null");
	if (!right) throw std::runtime_error("BinaryOpExpr.right is null");
	auto l = left->evaluate(context);

	auto do_eval = [&](const Value & l) -> Value {
	if (op == Op::Is \|\| op == Op::IsNot) {
	auto t = dynamic_cast<VariableExpr*>(right.get());
	if (!t) throw std::runtime_error("Right side of 'is' operator must be a variable");

	auto eval = [&]() {
	const auto & name = t->get_name();
	if (name == "none") return l.is_null();
	if (name == "boolean") return l.is_boolean();
	if (name == "integer") return l.is_number_integer();
	if (name == "float") return l.is_number_float();
	if (name == "number") return l.is_number();
	if (name == "string") return l.is_string();
	if (name == "mapping") return l.is_object();
	if (name == "iterable") return l.is_iterable();
	if (name == "sequence") return l.is_array();
	if (name == "defined") return !l.is_null();
	throw std::runtime_error("Unknown type for 'is' operator: " + name);
	};
	auto value = eval();
	return Value(op == Op::Is ? value : !value);
	}

	if (op == Op::And) {
	if (!l.to_bool()) return Value(false);
	return right->evaluate(context).to_bool();
	} else if (op == Op::Or) {
	if (l.to_bool()) return l;
	return right->evaluate(context);
	}

	auto r = right->evaluate(context);
	switch (op) {
	case Op::StrConcat: return l.to_str() + r.to_str();
	case Op::Add: return l + r;
	case Op::Sub: return l - r;
	case Op::Mul: return l * r;
	case Op::Div: return l / r;
	case Op::MulMul: return std::pow(l.get<double>(), r.get<double>());
	case Op::DivDiv: return l.get<int64_t>() / r.get<int64_t>();
	case Op::Mod: return l.get<int64_t>() % r.get<int64_t>();
	case Op::Eq: return l == r;
	case Op::Ne: return l != r;
	case Op::Lt: return l < r;
	case Op::Gt: return l > r;
	case Op::Le: return l <= r;
	case Op::Ge: return l >= r;
	case Op::In: return (r.is_array() \|\| r.is_object()) && r.contains(l);
	case Op::NotIn: return !(r.is_array() && r.contains(l));
	default: break;
	}
	throw std::runtime_error("Unknown binary operator");
	};

	if (l.is_callable()) {
	return Value::callable([l, do_eval](const std::shared_ptr<Context> & context, ArgumentsValue & args) {
	auto ll = l.call(context, args);
	return do_eval(ll); //args[0].second);
	});
	} else {
	return do_eval(l);
	}
	}
	};

	struct ArgumentsExpression {
	std::vector<std::shared_ptr<Expression>> args;
	std::vector<std::pair<std::string, std::shared_ptr<Expression>>> kwargs;

	ArgumentsValue evaluate(const std::shared_ptr<Context> & context) const {
	ArgumentsValue vargs;
	for (const auto& arg : this->args) {
	if (auto un_expr = std::dynamic_pointer_cast<UnaryOpExpr>(arg)) {
	if (un_expr->op == UnaryOpExpr::Op::Expansion) {
	auto array = un_expr->expr->evaluate(context);
	if (!array.is_array()) {
	throw std::runtime_error("Expansion operator only supported on arrays");
	}
	array.for_each([&](Value & value) {
	vargs.args.push_back(value);
	});
	continue;
	} else if (un_expr->op == UnaryOpExpr::Op::ExpansionDict) {
	auto dict = un_expr->expr->evaluate(context);
	if (!dict.is_object()) {
	throw std::runtime_error("ExpansionDict operator only supported on objects");
	}
	dict.for_each([&](const Value & key) {
	vargs.kwargs.push_back({key.get<std::string>(), dict.at(key)});
	});
	continue;
	}
	}
	vargs.args.push_back(arg->evaluate(context));
	}
	for (const auto& [name, value] : this->kwargs) {
	vargs.kwargs.push_back({name, value->evaluate(context)});
	}
	return vargs;
	}
	};

	static std::string strip(const std::string & s, const std::string & chars = "", bool left = true, bool right = true) {
	auto charset = chars.empty() ? " \t\n\r" : chars;
	auto start = left ? s.find_first_not_of(charset) : 0;
	if (start == std::string::npos) return "";
	auto end = right ? s.find_last_not_of(charset) : s.size() - 1;
	return s.substr(start, end - start + 1);
	}

	static std::vector<std::string> split(const std::string & s, const std::string & sep) {
	std::vector<std::string> result;
	size_t start = 0;
	size_t end = s.find(sep);
	while (end != std::string::npos) {
	result.push_back(s.substr(start, end - start));
	start = end + sep.length();
	end = s.find(sep, start);
	}
	result.push_back(s.substr(start));
	return result;
	}

	static std::string capitalize(const std::string & s) {
	if (s.empty()) return s;
	auto result = s;
	result[0] = std::toupper(result[0]);
	return result;
	}

	static std::string html_escape(const std::string & s) {
	std::string result;
	result.reserve(s.size());
	for (const auto & c : s) {
	switch (c) {
	case '&': result += "&"; break;
	case '<': result += "<"; break;
	case '>': result += ">"; break;
	case '"': result += """; break;
	case '\'': result += "'"; break;
	default: result += c; break;
	}
	}
	return result;
	}

	class MethodCallExpr : public Expression {
	std::shared_ptr<Expression> object;
	std::shared_ptr<VariableExpr> method;
	ArgumentsExpression args;
	public:
	MethodCallExpr(const Location & location, std::shared_ptr<Expression> && obj, std::shared_ptr<VariableExpr> && m, ArgumentsExpression && a)
	: Expression(location), object(std::move(obj)), method(std::move(m)), args(std::move(a)) {}
	Value do_evaluate(const std::shared_ptr<Context> & context) const override {
	if (!object) throw std::runtime_error("MethodCallExpr.object is null");
	if (!method) throw std::runtime_error("MethodCallExpr.method is null");
	auto obj = object->evaluate(context);
	auto vargs = args.evaluate(context);
	if (obj.is_null()) {
	throw std::runtime_error("Trying to call method '" + method->get_name() + "' on null");
	}
	if (obj.is_array()) {
	if (method->get_name() == "append") {
	vargs.expectArgs("append method", {1, 1}, {0, 0});
	obj.push_back(vargs.args[0]);
	return Value();
	} else if (method->get_name() == "pop") {
	vargs.expectArgs("pop method", {0, 1}, {0, 0});
	return obj.pop(vargs.args.empty() ? Value() : vargs.args[0]);
	} else if (method->get_name() == "insert") {
	vargs.expectArgs("insert method", {2, 2}, {0, 0});
	auto index = vargs.args[0].get<int64_t>();
	if (index < 0 \|\| index > (int64_t) obj.size()) throw std::runtime_error("Index out of range for insert method");
	obj.insert(index, vargs.args[1]);
	return Value();
	}
	} else if (obj.is_object()) {
	if (method->get_name() == "items") {
	vargs.expectArgs("items method", {0, 0}, {0, 0});
	auto result = Value::array();
	for (const auto& key : obj.keys()) {
	result.push_back(Value::array({key, obj.at(key)}));
	}
	return result;
	} else if (method->get_name() == "pop") {
	vargs.expectArgs("pop method", {1, 1}, {0, 0});
	return obj.pop(vargs.args[0]);
	} else if (method->get_name() == "get") {
	vargs.expectArgs("get method", {1, 2}, {0, 0});
	auto key = vargs.args[0];
	if (vargs.args.size() == 1) {
	return obj.contains(key) ? obj.at(key) : Value();
	} else {
	return obj.contains(key) ? obj.at(key) : vargs.args[1];
	}
	} else if (obj.contains(method->get_name())) {
	auto callable = obj.at(method->get_name());
	if (!callable.is_callable()) {
	throw std::runtime_error("Property '" + method->get_name() + "' is not callable");
	}
	return callable.call(context, vargs);
	}
	} else if (obj.is_string()) {
	auto str = obj.get<std::string>();
	if (method->get_name() == "strip") {
	vargs.expectArgs("strip method", {0, 1}, {0, 0});
	auto chars = vargs.args.empty() ? "" : vargs.args[0].get<std::string>();
	return Value(strip(str, chars));
	} else if (method->get_name() == "lstrip") {
	vargs.expectArgs("lstrip method", {0, 1}, {0, 0});
	auto chars = vargs.args.empty() ? "" : vargs.args[0].get<std::string>();
	return Value(strip(str, chars, /* left= / true, / right= */ false));
	} else if (method->get_name() == "rstrip") {
	vargs.expectArgs("rstrip method", {0, 1}, {0, 0});
	auto chars = vargs.args.empty() ? "" : vargs.args[0].get<std::string>();
	return Value(strip(str, chars, /* left= / false, / right= */ true));
	} else if (method->get_name() == "split") {
	vargs.expectArgs("split method", {1, 1}, {0, 0});
	auto sep = vargs.args[0].get<std::string>();
	auto parts = split(str, sep);
	Value result = Value::array();
	for (const auto& part : parts) {
	result.push_back(Value(part));
	}
	return result;
	} else if (method->get_name() == "capitalize") {
	vargs.expectArgs("capitalize method", {0, 0}, {0, 0});
	return Value(capitalize(str));
	} else if (method->get_name() == "endswith") {
	vargs.expectArgs("endswith method", {1, 1}, {0, 0});
	auto suffix = vargs.args[0].get<std::string>();
	return suffix.length() <= str.length() && std::equal(suffix.rbegin(), suffix.rend(), str.rbegin());
	} else if (method->get_name() == "title") {
	vargs.expectArgs("title method", {0, 0}, {0, 0});
	auto res = str;
	for (size_t i = 0, n = res.size(); i < n; ++i) {
	if (i == 0 \|\| std::isspace(res[i - 1])) res[i] = std::toupper(res[i]);
	else res[i] = std::tolower(res[i]);
	}
	return res;
	}
	}
	throw std::runtime_error("Unknown method: " + method->get_name());
	}
	};

	class CallExpr : public Expression {
	public:
	std::shared_ptr<Expression> object;
	ArgumentsExpression args;
	CallExpr(const Location & location, std::shared_ptr<Expression> && obj, ArgumentsExpression && a)
	: Expression(location), object(std::move(obj)), args(std::move(a)) {}
	Value do_evaluate(const std::shared_ptr<Context> & context) const override {
	if (!object) throw std::runtime_error("CallExpr.object is null");
	auto obj = object->evaluate(context);
	if (!obj.is_callable()) {
	throw std::runtime_error("Object is not callable: " + obj.dump(2));
	}
	auto vargs = args.evaluate(context);
	return obj.call(context, vargs);
	}
	};

	class FilterExpr : public Expression {
	std::vector<std::shared_ptr<Expression>> parts;
	public:
	FilterExpr(const Location & location, std::vector<std::shared_ptr<Expression>> && p)
	: Expression(location), parts(std::move(p)) {}
	Value do_evaluate(const std::shared_ptr<Context> & context) const override {
	Value result;
	bool first = true;
	for (const auto& part : parts) {
	if (!part) throw std::runtime_error("FilterExpr.part is null");
	if (first) {
	first = false;
	result = part->evaluate(context);
	} else {
	if (auto ce = dynamic_cast<CallExpr*>(part.get())) {
	auto target = ce->object->evaluate(context);
	ArgumentsValue args = ce->args.evaluate(context);
	args.args.insert(args.args.begin(), result);
	result = target.call(context, args);
	} else {
	auto callable = part->evaluate(context);
	ArgumentsValue args;
	args.args.insert(args.args.begin(), result);
	result = callable.call(context, args);
	}
	}
	}
	return result;
	}

	void prepend(std::shared_ptr<Expression> && e) {
	parts.insert(parts.begin(), std::move(e));
	}
	};

	class Parser {
	private:
	using CharIterator = std::string::const_iterator;

	std::shared_ptr<std::string> template_str;
	CharIterator start, end, it;
	Options options;

	Parser(const std::shared_ptr<std::string>& template_str, const Options & options) : template_str(template_str), options(options) {
	if (!template_str) throw std::runtime_error("Template string is null");
	start = it = this->template_str->begin();
	end = this->template_str->end();
	}

	bool consumeSpaces(SpaceHandling space_handling = SpaceHandling::Strip) {
	if (space_handling == SpaceHandling::Strip) {
	while (it != end && std::isspace(*it)) ++it;
	}
	return true;
	}

	std::unique_ptr<std::string> parseString() {
	auto doParse = [&](char quote) -> std::unique_ptr<std::string> {
	if (it == end \|\| *it != quote) return nullptr;
	std::string result;
	bool escape = false;
	for (++it; it != end; ++it) {
	if (escape) {
	escape = false;
	switch (*it) {
	case 'n': result += '\n'; break;
	case 'r': result += '\r'; break;
	case 't': result += '\t'; break;
	case 'b': result += '\b'; break;
	case 'f': result += '\f'; break;
	case '\\': result += '\\'; break;
	default:
	if (*it == quote) {
	result += quote;
	} else {
	result += *it;
	}
	break;
	}
	} else if (*it == '\\') {
	escape = true;
	} else if (*it == quote) {
	++it;
	return std::make_unique<std::string>(std::move(result));
	} else {
	result += *it;
	}
	}
	return nullptr;
	};

	consumeSpaces();
	if (it == end) return nullptr;
	if (*it == '"') return doParse('"');
	if (*it == '\'') return doParse('\'');
	return nullptr;
	}

	json parseNumber(CharIterator& it, const CharIterator& end) {
	auto before = it;
	consumeSpaces();
	auto start = it;
	bool hasDecimal = false;
	bool hasExponent = false;

	if (it != end && (it == '-' \|\| it == '+')) ++it;

	while (it != end) {
	if (std::isdigit(*it)) {
	++it;
	} else if (*it == '.') {
	if (hasDecimal) throw std::runtime_error("Multiple decimal points");
	hasDecimal = true;
	++it;
	} else if (it != start && (it == 'e' \|\| it == 'E')) {
	if (hasExponent) throw std::runtime_error("Multiple exponents");
	hasExponent = true;
	++it;
	} else {
	break;
	}
	}
	if (start == it) {
	it = before;
	return json(); // No valid characters found
	}

	std::string str(start, it);
	try {
	return json::parse(str);
	} catch (json::parse_error& e) {
	throw std::runtime_error("Failed to parse number: '" + str + "' (" + std::string(e.what()) + ")");
	return json();
	}
	}

	/** integer, float, bool, string */
	std::shared_ptr<Value> parseConstant() {
	auto start = it;
	consumeSpaces();
	if (it == end) return nullptr;
	if (it == '"' \|\| it == '\'') {
	auto str = parseString();
	if (str) return std::make_shared<Value>(*str);
	}
	static std::regex prim_tok(R"(true\b\|True\b\|false\b\|False\b\|None\b)");
	auto token = consumeToken(prim_tok);
	if (!token.empty()) {
	if (token == "true" \|\| token == "True") return std::make_shared<Value>(true);
	if (token == "false" \|\| token == "False") return std::make_shared<Value>(false);
	if (token == "None") return std::make_shared<Value>(nullptr);
	throw std::runtime_error("Unknown constant token: " + token);
	}

	auto number = parseNumber(it, end);
	if (!number.is_null()) return std::make_shared<Value>(number);

	it = start;
	return nullptr;
	}

	class expression_parsing_error : public std::runtime_error {
	const CharIterator it;
	public:
	expression_parsing_error(const std::string & message, const CharIterator & it)
	: std::runtime_error(message), it(it) {}
	size_t get_pos(const CharIterator & begin) const {
	return std::distance(begin, it);
	}
	};

	bool peekSymbols(const std::vector<std::string> & symbols) const {
	for (const auto & symbol : symbols) {
	if (std::distance(it, end) >= (int64_t) symbol.size() && std::string(it, it + symbol.size()) == symbol) {
	return true;
	}
	}
	return false;
	}

	std::vector<std::string> consumeTokenGroups(const std::regex & regex, SpaceHandling space_handling = SpaceHandling::Strip) {
	auto start = it;
	consumeSpaces(space_handling);
	std::smatch match;
	if (std::regex_search(it, end, match, regex) && match.position() == 0) {
	it += match[0].length();
	std::vector<std::string> ret;
	for (size_t i = 0, n = match.size(); i < n; ++i) {
	ret.push_back(match[i].str());
	}
	return ret;
	}
	it = start;
	return {};
	}
	std::string consumeToken(const std::regex & regex, SpaceHandling space_handling = SpaceHandling::Strip) {
	auto start = it;
	consumeSpaces(space_handling);
	std::smatch match;
	if (std::regex_search(it, end, match, regex) && match.position() == 0) {
	it += match[0].length();
	return match[0].str();
	}
	it = start;
	return "";
	}

	std::string consumeToken(const std::string & token, SpaceHandling space_handling = SpaceHandling::Strip) {
	auto start = it;
	consumeSpaces(space_handling);
	if (std::distance(it, end) >= (int64_t) token.size() && std::string(it, it + token.size()) == token) {
	it += token.size();
	return token;
	}
	it = start;
	return "";
	}

	std::shared_ptr<Expression> parseExpression(bool allow_if_expr = true) {
	auto left = parseLogicalOr();
	if (it == end) return left;

	if (!allow_if_expr) return left;

	static std::regex if_tok(R"(if\b)");
	if (consumeToken(if_tok).empty()) {
	return left;
	}

	auto location = get_location();
	auto [condition, else_expr] = parseIfExpression();
	return std::make_shared<IfExpr>(location, std::move(condition), std::move(left), std::move(else_expr));
	}

	Location get_location() const {
	return {template_str, (size_t) std::distance(start, it)};
	}

	std::pair<std::shared_ptr<Expression>, std::shared_ptr<Expression>> parseIfExpression() {
	auto condition = parseLogicalOr();
	if (!condition) throw std::runtime_error("Expected condition expression");

	static std::regex else_tok(R"(else\b)");
	std::shared_ptr<Expression> else_expr;
	if (!consumeToken(else_tok).empty()) {
	else_expr = parseExpression();
	if (!else_expr) throw std::runtime_error("Expected 'else' expression");
	}
	return std::pair(std::move(condition), std::move(else_expr));
	}

	std::shared_ptr<Expression> parseLogicalOr() {
	auto left = parseLogicalAnd();
	if (!left) throw std::runtime_error("Expected left side of 'logical or' expression");

	static std::regex or_tok(R"(or\b)");
	auto location = get_location();
	while (!consumeToken(or_tok).empty()) {
	auto right = parseLogicalAnd();
	if (!right) throw std::runtime_error("Expected right side of 'or' expression");
	left = std::make_shared<BinaryOpExpr>(location, std::move(left), std::move(right), BinaryOpExpr::Op::Or);
	}
	return left;
	}

	std::shared_ptr<Expression> parseLogicalNot() {
	static std::regex not_tok(R"(not\b)");
	auto location = get_location();

	if (!consumeToken(not_tok).empty()) {
	auto sub = parseLogicalNot();
	if (!sub) throw std::runtime_error("Expected expression after 'not' keyword");
	return std::make_shared<UnaryOpExpr>(location, std::move(sub), UnaryOpExpr::Op::LogicalNot);
	}
	return parseLogicalCompare();
	}

	std::shared_ptr<Expression> parseLogicalAnd() {
	auto left = parseLogicalNot();
	if (!left) throw std::runtime_error("Expected left side of 'logical and' expression");

	static std::regex and_tok(R"(and\b)");
	auto location = get_location();
	while (!consumeToken(and_tok).empty()) {
	auto right = parseLogicalNot();
	if (!right) throw std::runtime_error("Expected right side of 'and' expression");
	left = std::make_shared<BinaryOpExpr>(location, std::move(left), std::move(right), BinaryOpExpr::Op::And);
	}
	return left;
	}

	std::shared_ptr<Expression> parseLogicalCompare() {
	auto left = parseStringConcat();
	if (!left) throw std::runtime_error("Expected left side of 'logical compare' expression");

	static std::regex compare_tok(R"(==\|!=\|<=?\|>=?\|in\b\|is\b\|not\s+in\b)");
	static std::regex not_tok(R"(not\b)");
	std::string op_str;
	while (!(op_str = consumeToken(compare_tok)).empty()) {
	auto location = get_location();
	if (op_str == "is") {
	auto negated = !consumeToken(not_tok).empty();

	auto identifier = parseIdentifier();
	if (!identifier) throw std::runtime_error("Expected identifier after 'is' keyword");

	return std::make_shared<BinaryOpExpr>(
	left->location,
	std::move(left), std::move(identifier),
	negated ? BinaryOpExpr::Op::IsNot : BinaryOpExpr::Op::Is);
	}
	auto right = parseStringConcat();
	if (!right) throw std::runtime_error("Expected right side of 'logical compare' expression");
	BinaryOpExpr::Op op;
	if (op_str == "==") op = BinaryOpExpr::Op::Eq;
	else if (op_str == "!=") op = BinaryOpExpr::Op::Ne;
	else if (op_str == "<") op = BinaryOpExpr::Op::Lt;
	else if (op_str == ">") op = BinaryOpExpr::Op::Gt;
	else if (op_str == "<=") op = BinaryOpExpr::Op::Le;
	else if (op_str == ">=") op = BinaryOpExpr::Op::Ge;
	else if (op_str == "in") op = BinaryOpExpr::Op::In;
	else if (op_str.substr(0, 3) == "not") op = BinaryOpExpr::Op::NotIn;
	else throw std::runtime_error("Unknown comparison operator: " + op_str);
	left = std::make_shared<BinaryOpExpr>(get_location(), std::move(left), std::move(right), op);
	}
	return left;
	}

	Expression::Parameters parseParameters() {
	consumeSpaces();
	if (consumeToken("(").empty()) throw std::runtime_error("Expected opening parenthesis in param list");

	Expression::Parameters result;

	while (it != end) {
	if (!consumeToken(")").empty()) {
	return result;
	}
	auto expr = parseExpression();
	if (!expr) throw std::runtime_error("Expected expression in call args");

	if (auto ident = dynamic_cast<VariableExpr*>(expr.get())) {
	if (!consumeToken("=").empty()) {
	auto value = parseExpression();
	if (!value) throw std::runtime_error("Expected expression in for named arg");
	result.emplace_back(ident->get_name(), std::move(value));
	} else {
	result.emplace_back(ident->get_name(), nullptr);
	}
	} else {
	result.emplace_back(std::string(), std::move(expr));
	}
	if (consumeToken(",").empty()) {
	if (consumeToken(")").empty()) {
	throw std::runtime_error("Expected closing parenthesis in call args");
	}
	return result;
	}
	}
	throw std::runtime_error("Expected closing parenthesis in call args");
	}

	ArgumentsExpression parseCallArgs() {
	consumeSpaces();
	if (consumeToken("(").empty()) throw std::runtime_error("Expected opening parenthesis in call args");

	ArgumentsExpression result;

	while (it != end) {
	if (!consumeToken(")").empty()) {
	return result;
	}
	auto expr = parseExpression();
	if (!expr) throw std::runtime_error("Expected expression in call args");

	if (auto ident = dynamic_cast<VariableExpr*>(expr.get())) {
	if (!consumeToken("=").empty()) {
	auto value = parseExpression();
	if (!value) throw std::runtime_error("Expected expression in for named arg");
	result.kwargs.emplace_back(ident->get_name(), std::move(value));
	} else {
	result.args.emplace_back(std::move(expr));
	}
	} else {
	result.args.emplace_back(std::move(expr));
	}
	if (consumeToken(",").empty()) {
	if (consumeToken(")").empty()) {
	throw std::runtime_error("Expected closing parenthesis in call args");
	}
	return result;
	}
	}
	throw std::runtime_error("Expected closing parenthesis in call args");
	}

	std::shared_ptr<VariableExpr> parseIdentifier() {
	static std::regex ident_regex(R"((?!(?:not\|is\|and\|or\|del)\b)[a-zA-Z_]\w*)");
	auto location = get_location();
	auto ident = consumeToken(ident_regex);
	if (ident.empty())
	return nullptr;
	return std::make_shared<VariableExpr>(location, ident);
	}

	std::shared_ptr<Expression> parseStringConcat() {
	auto left = parseMathPow();
	if (!left) throw std::runtime_error("Expected left side of 'string concat' expression");

	static std::regex concat_tok(R"(~(?!\}))");
	if (!consumeToken(concat_tok).empty()) {
	auto right = parseLogicalAnd();
	if (!right) throw std::runtime_error("Expected right side of 'string concat' expression");
	left = std::make_shared<BinaryOpExpr>(get_location(), std::move(left), std::move(right), BinaryOpExpr::Op::StrConcat);
	}
	return left;
	}

	std::shared_ptr<Expression> parseMathPow() {
	auto left = parseMathPlusMinus();
	if (!left) throw std::runtime_error("Expected left side of 'math pow' expression");

	while (!consumeToken("**").empty()) {
	auto right = parseMathPlusMinus();
	if (!right) throw std::runtime_error("Expected right side of 'math pow' expression");
	left = std::make_shared<BinaryOpExpr>(get_location(), std::move(left), std::move(right), BinaryOpExpr::Op::MulMul);
	}
	return left;
	}

	std::shared_ptr<Expression> parseMathPlusMinus() {
	static std::regex plus_minus_tok(R"(\+\|-(?![}%#]\}))");

	auto left = parseMathMulDiv();
	if (!left) throw std::runtime_error("Expected left side of 'math plus/minus' expression");
	std::string op_str;
	while (!(op_str = consumeToken(plus_minus_tok)).empty()) {
	auto right = parseMathMulDiv();
	if (!right) throw std::runtime_error("Expected right side of 'math plus/minus' expression");
	auto op = op_str == "+" ? BinaryOpExpr::Op::Add : BinaryOpExpr::Op::Sub;
	left = std::make_shared<BinaryOpExpr>(get_location(), std::move(left), std::move(right), op);
	}
	return left;
	}

	std::shared_ptr<Expression> parseMathMulDiv() {
	auto left = parseMathUnaryPlusMinus();
	if (!left) throw std::runtime_error("Expected left side of 'math mul/div' expression");

	static std::regex mul_div_tok(R"(\\?\|//?\|%(?!\}))");
	std::string op_str;
	while (!(op_str = consumeToken(mul_div_tok)).empty()) {
	auto right = parseMathUnaryPlusMinus();
	if (!right) throw std::runtime_error("Expected right side of 'math mul/div' expression");
	auto op = op_str == "*" ? BinaryOpExpr::Op::Mul
	: op_str == "**" ? BinaryOpExpr::Op::MulMul
	: op_str == "/" ? BinaryOpExpr::Op::Div
	: op_str == "//" ? BinaryOpExpr::Op::DivDiv
	: BinaryOpExpr::Op::Mod;
	left = std::make_shared<BinaryOpExpr>(get_location(), std::move(left), std::move(right), op);
	}

	if (!consumeToken("\|").empty()) {
	auto expr = parseMathMulDiv();
	if (auto filter = dynamic_cast<FilterExpr*>(expr.get())) {
	filter->prepend(std::move(left));
	return expr;
	} else {
	std::vector<std::shared_ptr<Expression>> parts;
	parts.emplace_back(std::move(left));
	parts.emplace_back(std::move(expr));
	return std::make_shared<FilterExpr>(get_location(), std::move(parts));
	}
	}
	return left;
	}

	std::shared_ptr<Expression> call_func(const std::string & name, ArgumentsExpression && args) const {
	return std::make_shared<CallExpr>(get_location(), std::make_shared<VariableExpr>(get_location(), name), std::move(args));
	}

	std::shared_ptr<Expression> parseMathUnaryPlusMinus() {
	static std::regex unary_plus_minus_tok(R"(\+\|-(?![}%#]\}))");
	auto op_str = consumeToken(unary_plus_minus_tok);
	auto expr = parseExpansion();
	if (!expr) throw std::runtime_error("Expected expr of 'unary plus/minus/expansion' expression");

	if (!op_str.empty()) {
	auto op = op_str == "+" ? UnaryOpExpr::Op::Plus : UnaryOpExpr::Op::Minus;
	return std::make_shared<UnaryOpExpr>(get_location(), std::move(expr), op);
	}
	return expr;
	}

	std::shared_ptr<Expression> parseExpansion() {
	static std::regex expansion_tok(R"(\\?)");
	auto op_str = consumeToken(expansion_tok);
	auto expr = parseValueExpression();
	if (op_str.empty()) return expr;
	if (!expr) throw std::runtime_error("Expected expr of 'expansion' expression");
	return std::make_shared<UnaryOpExpr>(get_location(), std::move(expr), op_str == "*" ? UnaryOpExpr::Op::Expansion : UnaryOpExpr::Op::ExpansionDict);
	}

	std::shared_ptr<Expression> parseValueExpression() {
	auto parseValue = [&]() -> std::shared_ptr<Expression> {
	auto location = get_location();
	auto constant = parseConstant();
	if (constant) return std::make_shared<LiteralExpr>(location, *constant);

	static std::regex null_regex(R"(null\b)");
	if (!consumeToken(null_regex).empty()) return std::make_shared<LiteralExpr>(location, Value());

	auto identifier = parseIdentifier();
	if (identifier) return identifier;

	auto braced = parseBracedExpressionOrArray();
	if (braced) return braced;

	auto array = parseArray();
	if (array) return array;

	auto dictionary = parseDictionary();
	if (dictionary) return dictionary;

	throw std::runtime_error("Expected value expression");
	};

	auto value = parseValue();

	while (it != end && consumeSpaces() && peekSymbols({ "[", "." })) {
	if (!consumeToken("[").empty()) {
	std::shared_ptr<Expression> index;
	if (!consumeToken(":").empty()) {
	auto slice_end = parseExpression();
	index = std::make_shared<SliceExpr>(slice_end->location, nullptr, std::move(slice_end));
	} else {
	auto slice_start = parseExpression();
	if (!consumeToken(":").empty()) {
	consumeSpaces();
	if (peekSymbols({ "]" })) {
	index = std::make_shared<SliceExpr>(slice_start->location, std::move(slice_start), nullptr);
	} else {
	auto slice_end = parseExpression();
	index = std::make_shared<SliceExpr>(slice_start->location, std::move(slice_start), std::move(slice_end));
	}
	} else {
	index = std::move(slice_start);
	}
	}
	if (!index) throw std::runtime_error("Empty index in subscript");
	if (consumeToken("]").empty()) throw std::runtime_error("Expected closing bracket in subscript");

	value = std::make_shared<SubscriptExpr>(value->location, std::move(value), std::move(index));
	} else if (!consumeToken(".").empty()) {
	auto identifier = parseIdentifier();
	if (!identifier) throw std::runtime_error("Expected identifier in subscript");

	consumeSpaces();
	if (peekSymbols({ "(" })) {
	auto callParams = parseCallArgs();
	value = std::make_shared<MethodCallExpr>(identifier->location, std::move(value), std::move(identifier), std::move(callParams));
	} else {
	auto key = std::make_shared<LiteralExpr>(identifier->location, Value(identifier->get_name()));
	value = std::make_shared<SubscriptExpr>(identifier->location, std::move(value), std::move(key));
	}
	}
	consumeSpaces();
	}

	if (peekSymbols({ "(" })) {
	auto location = get_location();
	auto callParams = parseCallArgs();
	value = std::make_shared<CallExpr>(location, std::move(value), std::move(callParams));
	}
	return value;
	}

	std::shared_ptr<Expression> parseBracedExpressionOrArray() {
	if (consumeToken("(").empty()) return nullptr;

	auto expr = parseExpression();
	if (!expr) throw std::runtime_error("Expected expression in braced expression");

	if (!consumeToken(")").empty()) {
	return expr; // Drop the parentheses
	}

	std::vector<std::shared_ptr<Expression>> tuple;
	tuple.emplace_back(std::move(expr));

	while (it != end) {
	if (consumeToken(",").empty()) throw std::runtime_error("Expected comma in tuple");
	auto next = parseExpression();
	if (!next) throw std::runtime_error("Expected expression in tuple");
	tuple.push_back(std::move(next));

	if (!consumeToken(")").empty()) {
	return std::make_shared<ArrayExpr>(get_location(), std::move(tuple));
	}
	}
	throw std::runtime_error("Expected closing parenthesis");
	}

	std::shared_ptr<Expression> parseArray() {
	if (consumeToken("[").empty()) return nullptr;

	std::vector<std::shared_ptr<Expression>> elements;
	if (!consumeToken("]").empty()) {
	return std::make_shared<ArrayExpr>(get_location(), std::move(elements));
	}
	auto first_expr = parseExpression();
	if (!first_expr) throw std::runtime_error("Expected first expression in array");
	elements.push_back(std::move(first_expr));

	while (it != end) {
	if (!consumeToken(",").empty()) {
	auto expr = parseExpression();
	if (!expr) throw std::runtime_error("Expected expression in array");
	elements.push_back(std::move(expr));
	} else if (!consumeToken("]").empty()) {
	return std::make_shared<ArrayExpr>(get_location(), std::move(elements));
	} else {
	throw std::runtime_error("Expected comma or closing bracket in array");
	}
	}
	throw std::runtime_error("Expected closing bracket");
	}

	std::shared_ptr<Expression> parseDictionary() {
	if (consumeToken("{").empty()) return nullptr;

	std::vector<std::pair<std::shared_ptr<Expression>, std::shared_ptr<Expression>>> elements;
	if (!consumeToken("}").empty()) {
	return std::make_shared<DictExpr>(get_location(), std::move(elements));
	}

	auto parseKeyValuePair = [&]() {
	auto key = parseExpression();
	if (!key) throw std::runtime_error("Expected key in dictionary");
	if (consumeToken(":").empty()) throw std::runtime_error("Expected colon betweek key & value in dictionary");
	auto value = parseExpression();
	if (!value) throw std::runtime_error("Expected value in dictionary");
	elements.emplace_back(std::pair(std::move(key), std::move(value)));
	};

	parseKeyValuePair();

	while (it != end) {
	if (!consumeToken(",").empty()) {
	parseKeyValuePair();
	} else if (!consumeToken("}").empty()) {
	return std::make_shared<DictExpr>(get_location(), std::move(elements));
	} else {
	throw std::runtime_error("Expected comma or closing brace in dictionary");
	}
	}
	throw std::runtime_error("Expected closing brace");
	}

	SpaceHandling parsePreSpace(const std::string& s) const {
	if (s == "-")
	return SpaceHandling::Strip;
	return SpaceHandling::Keep;
	}

	SpaceHandling parsePostSpace(const std::string& s) const {
	if (s == "-") return SpaceHandling::Strip;
	return SpaceHandling::Keep;
	}

	using TemplateTokenVector = std::vector<std::unique_ptr<TemplateToken>>;
	using TemplateTokenIterator = TemplateTokenVector::const_iterator;

	std::vector<std::string> parseVarNames() {
	static std::regex varnames_regex(R"(((?:\w+)(?:\s,\s(?:\w+)))\s)");

	std::vector<std::string> group;
	if ((group = consumeTokenGroups(varnames_regex)).empty()) throw std::runtime_error("Expected variable names");
	std::vector<std::string> varnames;
	std::istringstream iss(group[1]);
	std::string varname;
	while (std::getline(iss, varname, ',')) {
	varnames.push_back(strip(varname));
	}
	return varnames;
	}

	std::runtime_error unexpected(const TemplateToken & token) const {
	return std::runtime_error("Unexpected " + TemplateToken::typeToString(token.type)
	+ error_location_suffix(*template_str, token.location.pos));
	}
	std::runtime_error unterminated(const TemplateToken & token) const {
	return std::runtime_error("Unterminated " + TemplateToken::typeToString(token.type)
	+ error_location_suffix(*template_str, token.location.pos));
	}

	TemplateTokenVector tokenize() {
	static std::regex comment_tok(R"(\{#([-~]?)([\s\S]*?)([-~]?)#\})");
	static std::regex expr_open_regex(R"(\{\{([-~])?)");
	static std::regex block_open_regex(R"(^\{%([-~])?\s*)");
	static std::regex block_keyword_tok(R"((if\|else\|elif\|endif\|for\|endfor\|generation\|endgeneration\|set\|endset\|block\|endblock\|macro\|endmacro\|filter\|endfilter\|break\|continue)\b)");
	static std::regex non_text_open_regex(R"(\{\{\|\{%\|\{#)");
	static std::regex expr_close_regex(R"(\s*([-~])?\}\})");
	static std::regex block_close_regex(R"(\s*([-~])?%\})");

	TemplateTokenVector tokens;
	std::vector<std::string> group;
	std::string text;
	std::smatch match;

	try {
	while (it != end) {
	auto location = get_location();

	if (!(group = consumeTokenGroups(comment_tok, SpaceHandling::Keep)).empty()) {
	auto pre_space = parsePreSpace(group[1]);
	auto content = group[2];
	auto post_space = parsePostSpace(group[3]);
	tokens.push_back(std::make_unique<CommentTemplateToken>(location, pre_space, post_space, content));
	} else if (!(group = consumeTokenGroups(expr_open_regex, SpaceHandling::Keep)).empty()) {
	auto pre_space = parsePreSpace(group[1]);
	auto expr = parseExpression();

	if ((group = consumeTokenGroups(expr_close_regex)).empty()) {
	throw std::runtime_error("Expected closing expression tag");
	}

	auto post_space = parsePostSpace(group[1]);
	tokens.push_back(std::make_unique<ExpressionTemplateToken>(location, pre_space, post_space, std::move(expr)));
	} else if (!(group = consumeTokenGroups(block_open_regex, SpaceHandling::Keep)).empty()) {
	auto pre_space = parsePreSpace(group[1]);

	std::string keyword;

	auto parseBlockClose = [&]() -> SpaceHandling {
	if ((group = consumeTokenGroups(block_close_regex)).empty()) throw std::runtime_error("Expected closing block tag");
	return parsePostSpace(group[1]);
	};

	if ((keyword = consumeToken(block_keyword_tok)).empty()) throw std::runtime_error("Expected block keyword");

	if (keyword == "if") {
	auto condition = parseExpression();
	if (!condition) throw std::runtime_error("Expected condition in if block");

	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<IfTemplateToken>(location, pre_space, post_space, std::move(condition)));
	} else if (keyword == "elif") {
	auto condition = parseExpression();
	if (!condition) throw std::runtime_error("Expected condition in elif block");

	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<ElifTemplateToken>(location, pre_space, post_space, std::move(condition)));
	} else if (keyword == "else") {
	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<ElseTemplateToken>(location, pre_space, post_space));
	} else if (keyword == "endif") {
	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<EndIfTemplateToken>(location, pre_space, post_space));
	} else if (keyword == "for") {
	static std::regex recursive_tok(R"(recursive\b)");
	static std::regex if_tok(R"(if\b)");

	auto varnames = parseVarNames();
	static std::regex in_tok(R"(in\b)");
	if (consumeToken(in_tok).empty()) throw std::runtime_error("Expected 'in' keyword in for block");
	auto iterable = parseExpression(/* allow_if_expr = */ false);
	if (!iterable) throw std::runtime_error("Expected iterable in for block");

	std::shared_ptr<Expression> condition;
	if (!consumeToken(if_tok).empty()) {
	condition = parseExpression();
	}
	auto recursive = !consumeToken(recursive_tok).empty();

	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<ForTemplateToken>(location, pre_space, post_space, std::move(varnames), std::move(iterable), std::move(condition), recursive));
	} else if (keyword == "endfor") {
	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<EndForTemplateToken>(location, pre_space, post_space));
	} else if (keyword == "generation") {
	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<GenerationTemplateToken>(location, pre_space, post_space));
	} else if (keyword == "endgeneration") {
	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<EndGenerationTemplateToken>(location, pre_space, post_space));
	} else if (keyword == "set") {
	static std::regex namespaced_var_regex(R"((\w+)\s\.\s(\w+))");

	std::string ns;
	std::vector<std::string> var_names;
	std::shared_ptr<Expression> value;
	if (!(group = consumeTokenGroups(namespaced_var_regex)).empty()) {
	ns = group[1];
	var_names.push_back(group[2]);

	if (consumeToken("=").empty()) throw std::runtime_error("Expected equals sign in set block");

	value = parseExpression();
	if (!value) throw std::runtime_error("Expected value in set block");
	} else {
	var_names = parseVarNames();

	if (!consumeToken("=").empty()) {
	value = parseExpression();
	if (!value) throw std::runtime_error("Expected value in set block");
	}
	}
	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<SetTemplateToken>(location, pre_space, post_space, ns, var_names, std::move(value)));
	} else if (keyword == "endset") {
	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<EndSetTemplateToken>(location, pre_space, post_space));
	} else if (keyword == "macro") {
	auto macroname = parseIdentifier();
	if (!macroname) throw std::runtime_error("Expected macro name in macro block");
	auto params = parseParameters();

	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<MacroTemplateToken>(location, pre_space, post_space, std::move(macroname), std::move(params)));
	} else if (keyword == "endmacro") {
	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<EndMacroTemplateToken>(location, pre_space, post_space));
	} else if (keyword == "filter") {
	auto filter = parseExpression();
	if (!filter) throw std::runtime_error("Expected expression in filter block");

	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<FilterTemplateToken>(location, pre_space, post_space, std::move(filter)));
	} else if (keyword == "endfilter") {
	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<EndFilterTemplateToken>(location, pre_space, post_space));
	} else if (keyword == "break" \|\| keyword == "continue") {
	auto post_space = parseBlockClose();
	tokens.push_back(std::make_unique<LoopControlTemplateToken>(location, pre_space, post_space, keyword == "break" ? LoopControlType::Break : LoopControlType::Continue));
	} else {
	throw std::runtime_error("Unexpected block: " + keyword);
	}
	} else if (std::regex_search(it, end, match, non_text_open_regex)) {
	if (!match.position()) {
	if (match[0] != "{#")
	throw std::runtime_error("Internal error: Expected a comment");
	throw std::runtime_error("Missing end of comment tag");
	}
	auto text_end = it + match.position();
	text = std::string(it, text_end);
	it = text_end;
	tokens.push_back(std::make_unique<TextTemplateToken>(location, SpaceHandling::Keep, SpaceHandling::Keep, text));
	} else {
	text = std::string(it, end);
	it = end;
	tokens.push_back(std::make_unique<TextTemplateToken>(location, SpaceHandling::Keep, SpaceHandling::Keep, text));
	}
	}
	return tokens;
	} catch (const std::exception & e) {
	throw std::runtime_error(e.what() + error_location_suffix(*template_str, std::distance(start, it)));
	}
	}

	std::shared_ptr<TemplateNode> parseTemplate(
	const TemplateTokenIterator & begin,
	TemplateTokenIterator & it,
	const TemplateTokenIterator & end,
	bool fully = false) const {
	std::vector<std::shared_ptr<TemplateNode>> children;
	while (it != end) {
	const auto start = it;
	const auto & token = *(it++);
	if (auto if_token = dynamic_cast<IfTemplateToken*>(token.get())) {
	std::vector<std::pair<std::shared_ptr<Expression>, std::shared_ptr<TemplateNode>>> cascade;
	cascade.emplace_back(std::move(if_token->condition), parseTemplate(begin, it, end));

	while (it != end && (*it)->type == TemplateToken::Type::Elif) {
	auto elif_token = dynamic_cast<ElifTemplateToken>(((it++)).get());
	cascade.emplace_back(std::move(elif_token->condition), parseTemplate(begin, it, end));
	}

	if (it != end && (*it)->type == TemplateToken::Type::Else) {
	cascade.emplace_back(nullptr, parseTemplate(begin, ++it, end));
	}
	if (it == end \|\| (*(it++))->type != TemplateToken::Type::EndIf) {
	throw unterminated(**start);
	}
	children.emplace_back(std::make_shared<IfNode>(token->location, std::move(cascade)));
	} else if (auto for_token = dynamic_cast<ForTemplateToken*>(token.get())) {
	auto body = parseTemplate(begin, it, end);
	auto else_body = std::shared_ptr<TemplateNode>();
	if (it != end && (*it)->type == TemplateToken::Type::Else) {
	else_body = parseTemplate(begin, ++it, end);
	}
	if (it == end \|\| (*(it++))->type != TemplateToken::Type::EndFor) {
	throw unterminated(**start);
	}
	children.emplace_back(std::make_shared<ForNode>(token->location, std::move(for_token->var_names), std::move(for_token->iterable), std::move(for_token->condition), std::move(body), for_token->recursive, std::move(else_body)));
	} else if (dynamic_cast<GenerationTemplateToken*>(token.get())) {
	auto body = parseTemplate(begin, it, end);
	if (it == end \|\| (*(it++))->type != TemplateToken::Type::EndGeneration) {
	throw unterminated(**start);
	}
	// Treat as a no-op, as our scope is templates for inference, not training (`{% generation %}` wraps generated tokens for masking).
	children.emplace_back(std::move(body));
	} else if (auto text_token = dynamic_cast<TextTemplateToken*>(token.get())) {
	SpaceHandling pre_space = (it - 1) != begin ? (*(it - 2))->post_space : SpaceHandling::Keep;
	SpaceHandling post_space = it != end ? (*it)->pre_space : SpaceHandling::Keep;

	auto text = text_token->text;
	if (post_space == SpaceHandling::Strip) {
	static std::regex trailing_space_regex(R"(\s+$)");
	text = std::regex_replace(text, trailing_space_regex, "");
	} else if (options.lstrip_blocks && it != end) {
	auto i = text.size();
	while (i > 0 && (text[i - 1] == ' ' \|\| text[i - 1] == '\t')) i--;
	if ((i == 0 && (it - 1) == begin) \|\| (i > 0 && text[i - 1] == '\n')) {
	text.resize(i);
	}
	}
	if (pre_space == SpaceHandling::Strip) {
	static std::regex leading_space_regex(R"(^\s+)");
	text = std::regex_replace(text, leading_space_regex, "");
	} else if (options.trim_blocks && (it - 1) != begin && !dynamic_cast<ExpressionTemplateToken>(((it - 2)).get())) {
	if (text.length() > 0 && text[0] == '\n') {
	text.erase(0, 1);
	}
	}
	if (it == end && !options.keep_trailing_newline) {
	auto i = text.size();
	if (i > 0 && text[i - 1] == '\n') {
	i--;
	if (i > 0 && text[i - 1] == '\r') i--;
	text.resize(i);
	}
	}
	children.emplace_back(std::make_shared<TextNode>(token->location, text));
	} else if (auto expr_token = dynamic_cast<ExpressionTemplateToken*>(token.get())) {
	children.emplace_back(std::make_shared<ExpressionNode>(token->location, std::move(expr_token->expr)));
	} else if (auto set_token = dynamic_cast<SetTemplateToken*>(token.get())) {
	if (set_token->value) {
	children.emplace_back(std::make_shared<SetNode>(token->location, set_token->ns, set_token->var_names, std::move(set_token->value)));
	} else {
	auto value_template = parseTemplate(begin, it, end);
	if (it == end \|\| (*(it++))->type != TemplateToken::Type::EndSet) {
	throw unterminated(**start);
	}
	if (!set_token->ns.empty()) throw std::runtime_error("Namespaced set not supported in set with template value");
	if (set_token->var_names.size() != 1) throw std::runtime_error("Structural assignment not supported in set with template value");
	auto & name = set_token->var_names[0];
	children.emplace_back(std::make_shared<SetTemplateNode>(token->location, name, std::move(value_template)));
	}
	} else if (auto macro_token = dynamic_cast<MacroTemplateToken*>(token.get())) {
	auto body = parseTemplate(begin, it, end);
	if (it == end \|\| (*(it++))->type != TemplateToken::Type::EndMacro) {
	throw unterminated(**start);
	}
	children.emplace_back(std::make_shared<MacroNode>(token->location, std::move(macro_token->name), std::move(macro_token->params), std::move(body)));
	} else if (auto filter_token = dynamic_cast<FilterTemplateToken*>(token.get())) {
	auto body = parseTemplate(begin, it, end);
	if (it == end \|\| (*(it++))->type != TemplateToken::Type::EndFilter) {
	throw unterminated(**start);
	}
	children.emplace_back(std::make_shared<FilterNode>(token->location, std::move(filter_token->filter), std::move(body)));
	} else if (dynamic_cast<CommentTemplateToken*>(token.get())) {
	// Ignore comments
	} else if (auto ctrl_token = dynamic_cast<LoopControlTemplateToken*>(token.get())) {
	children.emplace_back(std::make_shared<LoopControlNode>(token->location, ctrl_token->control_type));
	} else if (dynamic_cast<EndForTemplateToken*>(token.get())
	\|\| dynamic_cast<EndSetTemplateToken*>(token.get())
	\|\| dynamic_cast<EndMacroTemplateToken*>(token.get())
	\|\| dynamic_cast<EndFilterTemplateToken*>(token.get())
	\|\| dynamic_cast<EndIfTemplateToken*>(token.get())
	\|\| dynamic_cast<ElseTemplateToken*>(token.get())
	\|\| dynamic_cast<EndGenerationTemplateToken*>(token.get())
	\|\| dynamic_cast<ElifTemplateToken*>(token.get())) {
	it--; // unconsume the token
	break; // exit the loop
	} else {
	throw unexpected(**(it-1));
	}
	}
	if (fully && it != end) {
	throw unexpected(**it);
	}
	if (children.empty()) {
	return std::make_shared<TextNode>(Location { template_str, 0 }, std::string());
	} else if (children.size() == 1) {
	return std::move(children[0]);
	} else {
	return std::make_shared<SequenceNode>(children[0]->location(), std::move(children));
	}
	}

	public:

	static std::shared_ptr<TemplateNode> parse(const std::string& template_str, const Options & options) {
	Parser parser(std::make_shared<std::string>(normalize_newlines(template_str)), options);
	auto tokens = parser.tokenize();
	TemplateTokenIterator begin = tokens.begin();
	auto it = begin;
	TemplateTokenIterator end = tokens.end();
	return parser.parseTemplate(begin, it, end, /* full= */ true);
	}
	};

	static Value simple_function(const std::string & fn_name, const std::vector<std::string> & params, const std::function<Value(const std::shared_ptr<Context> &, Value & args)> & fn) {
	std::map<std::string, size_t> named_positions;
	for (size_t i = 0, n = params.size(); i < n; i++) named_positions[params[i]] = i;

	return Value::callable([=](const std::shared_ptr<Context> & context, ArgumentsValue & args) -> Value {
	auto args_obj = Value::object();
	std::vector<bool> provided_args(params.size());
	for (size_t i = 0, n = args.args.size(); i < n; i++) {
	auto & arg = args.args[i];
	if (i < params.size()) {
	args_obj.set(params[i], arg);
	provided_args[i] = true;
	} else {
	throw std::runtime_error("Too many positional params for " + fn_name);
	}
	}
	for (auto & [name, value] : args.kwargs) {
	auto named_pos_it = named_positions.find(name);
	if (named_pos_it == named_positions.end()) {
	throw std::runtime_error("Unknown argument " + name + " for function " + fn_name);
	}
	provided_args[named_pos_it->second] = true;
	args_obj.set(name, value);
	}
	return fn(context, args_obj);
	});
	}

	inline std::shared_ptr<Context> Context::builtins() {
	auto globals = Value::object();

	globals.set("raise_exception", simple_function("raise_exception", { "message" }, [](const std::shared_ptr<Context> &, Value & args) -> Value {
	throw std::runtime_error(args.at("message").get<std::string>());
	}));
	globals.set("tojson", simple_function("tojson", { "value", "indent" }, [](const std::shared_ptr<Context> &, Value & args) {
	return Value(args.at("value").dump(args.get<int64_t>("indent", -1), /* tojson= */ true));
	}));
	globals.set("items", simple_function("items", { "object" }, [](const std::shared_ptr<Context> &, Value & args) {
	auto items = Value::array();
	if (args.contains("object")) {
	auto & obj = args.at("object");
	if (obj.is_string()) {
	auto json_obj = json::parse(obj.get<std::string>());
	for (const auto & kv : json_obj.items()) {
	items.push_back(Value::array({kv.key(), kv.value()}));
	}
	} else if (!obj.is_null()) {
	for (auto & key : obj.keys()) {
	items.push_back(Value::array({key, obj.at(key)}));
	}
	}
	}
	return items;
	}));
	globals.set("last", simple_function("last", { "items" }, [](const std::shared_ptr<Context> &, Value & args) {
	auto items = args.at("items");
	if (!items.is_array()) throw std::runtime_error("object is not a list");
	if (items.size() == 0) return Value();
	return items.at(items.size() - 1);
	}));
	globals.set("trim", simple_function("trim", { "text" }, [](const std::shared_ptr<Context> &, Value & args) {
	auto & text = args.at("text");
	return text.is_null() ? text : Value(strip(text.get<std::string>()));
	}));
	globals.set("lower", simple_function("lower", { "text" }, [](const std::shared_ptr<Context> &, Value & args) {
	auto text = args.at("text");
	if (text.is_null()) return text;
	std::string res;
	auto str = text.get<std::string>();
	std::transform(str.begin(), str.end(), std::back_inserter(res), ::tolower);
	return Value(res);
	}));
	globals.set("default", Value::callable([=](const std::shared_ptr<Context> &, ArgumentsValue & args) {
	args.expectArgs("default", {2, 3}, {0, 1});
	auto & value = args.args[0];
	auto & default_value = args.args[1];
	bool boolean = false;
	if (args.args.size() == 3) {
	boolean = args.args[2].get<bool>();
	} else {
	Value bv = args.get_named("boolean");
	if (!bv.is_null()) {
	boolean = bv.get<bool>();
	}
	}
	return boolean ? (value.to_bool() ? value : default_value) : value.is_null() ? default_value : value;
	}));
	auto escape = simple_function("escape", { "text" }, [](const std::shared_ptr<Context> &, Value & args) {
	return Value(html_escape(args.at("text").get<std::string>()));
	});
	globals.set("e", escape);
	globals.set("escape", escape);
	globals.set("joiner", simple_function("joiner", { "sep" }, [](const std::shared_ptr<Context> &, Value & args) {
	auto sep = args.get<std::string>("sep", "");
	auto first = std::make_shared<bool>(true);
	return simple_function("", {}, [sep, first](const std::shared_ptr<Context> &, const Value &) -> Value {
	if (*first) {
	*first = false;
	return "";
	}
	return sep;
	});
	return Value(html_escape(args.at("text").get<std::string>()));
	}));
	globals.set("count", simple_function("count", { "items" }, [](const std::shared_ptr<Context> &, Value & args) {
	return Value((int64_t) args.at("items").size());
	}));
	globals.set("dictsort", simple_function("dictsort", { "value" }, [](const std::shared_ptr<Context> &, Value & args) {
	if (args.size() != 1) throw std::runtime_error("dictsort expects exactly 1 argument (TODO: fix implementation)");
	auto & value = args.at("value");
	auto keys = value.keys();
	std::sort(keys.begin(), keys.end());
	auto res = Value::array();
	for (auto & key : keys) {
	res.push_back(Value::array({key, value.at(key)}));
	}
	return res;
	}));
	globals.set("join", simple_function("join", { "items", "d" }, [](const std::shared_ptr<Context> &, Value & args) {
	auto do_join = [](Value & items, const std::string & sep) {
	if (!items.is_array()) throw std::runtime_error("object is not iterable: " + items.dump());
	std::ostringstream oss;
	auto first = true;
	for (size_t i = 0, n = items.size(); i < n; ++i) {
	if (first) first = false;
	else oss << sep;
	oss << items.at(i).to_str();
	}
	return Value(oss.str());
	};
	auto sep = args.get<std::string>("d", "");
	if (args.contains("items")) {
	auto & items = args.at("items");
	return do_join(items, sep);
	} else {
	return simple_function("", {"items"}, [sep, do_join](const std::shared_ptr<Context> &, Value & args) {
	auto & items = args.at("items");
	if (!items.to_bool() \|\| !items.is_array()) throw std::runtime_error("join expects an array for items, got: " + items.dump());
	return do_join(items, sep);
	});
	}
	}));
	globals.set("namespace", Value::callable([=](const std::shared_ptr<Context> &, ArgumentsValue & args) {
	auto ns = Value::object();
	args.expectArgs("namespace", {0, 0}, {0, (std::numeric_limits<size_t>::max)()});
	for (auto & [name, value] : args.kwargs) {
	ns.set(name, value);
	}
	return ns;
	}));
	auto equalto = simple_function("equalto", { "expected", "actual" }, [](const std::shared_ptr<Context> &, Value & args) -> Value {
	return args.at("actual") == args.at("expected");
	});
	globals.set("equalto", equalto);
	globals.set("==", equalto);
	globals.set("length", simple_function("length", { "items" }, [](const std::shared_ptr<Context> &, Value & args) -> Value {
	auto & items = args.at("items");
	return (int64_t) items.size();
	}));
	globals.set("safe", simple_function("safe", { "value" }, [](const std::shared_ptr<Context> &, Value & args) -> Value {
	return args.at("value").to_str();
	}));
	globals.set("string", simple_function("string", { "value" }, [](const std::shared_ptr<Context> &, Value & args) -> Value {
	return args.at("value").to_str();
	}));
	globals.set("int", simple_function("int", { "value" }, [](const std::shared_ptr<Context> &, Value & args) -> Value {
	return args.at("value").to_int();
	}));
	globals.set("list", simple_function("list", { "items" }, [](const std::shared_ptr<Context> &, Value & args) -> Value {
	auto & items = args.at("items");
	if (!items.is_array()) throw std::runtime_error("object is not iterable");
	return items;
	}));
	globals.set("unique", simple_function("unique", { "items" }, [](const std::shared_ptr<Context> &, Value & args) -> Value {
	auto & items = args.at("items");
	if (!items.is_array()) throw std::runtime_error("object is not iterable");
	std::unordered_set<Value> seen;
	auto result = Value::array();
	for (size_t i = 0, n = items.size(); i < n; i++) {
	auto pair = seen.insert(items.at(i));
	if (pair.second) {
	result.push_back(items.at(i));
	}
	}
	return result;
	}));
	auto make_filter = [](const Value & filter, Value & extra_args) -> Value {
	return simple_function("", { "value" }, [=](const std::shared_ptr<Context> & context, Value & args) {
	auto & value = args.at("value");
	ArgumentsValue actual_args;
	actual_args.args.emplace_back(value);
	for (size_t i = 0, n = extra_args.size(); i < n; i++) {
	actual_args.args.emplace_back(extra_args.at(i));
	}
	return filter.call(context, actual_args);
	});
	};
	auto select_or_reject = [make_filter](bool is_select) {
	return Value::callable([=](const std::shared_ptr<Context> & context, ArgumentsValue & args) {
	args.expectArgs(is_select ? "select" : "reject", {2, (std::numeric_limits<size_t>::max)()}, {0, 0});
	auto & items = args.args[0];
	if (items.is_null())
	return Value::array();
	if (!items.is_array()) throw std::runtime_error("object is not iterable: " + items.dump());

	auto filter_fn = context->get(args.args[1]);
	if (filter_fn.is_null()) throw std::runtime_error("Undefined filter: " + args.args[1].dump());

	auto filter_args = Value::array();
	for (size_t i = 2, n = args.args.size(); i < n; i++) {
	filter_args.push_back(args.args[i]);
	}
	auto filter = make_filter(filter_fn, filter_args);

	auto res = Value::array();
	for (size_t i = 0, n = items.size(); i < n; i++) {
	auto & item = items.at(i);
	ArgumentsValue filter_args;
	filter_args.args.emplace_back(item);
	auto pred_res = filter.call(context, filter_args);
	if (pred_res.to_bool() == (is_select ? true : false)) {
	res.push_back(item);
	}
	}
	return res;
	});
	};
	globals.set("select", select_or_reject(/* is_select= */ true));
	globals.set("reject", select_or_reject(/* is_select= */ false));
	globals.set("map", Value::callable([=](const std::shared_ptr<Context> & context, ArgumentsValue & args) {
	auto res = Value::array();
	if (args.args.size() == 1 &&
	((args.has_named("attribute") && args.kwargs.size() == 1) \|\| (args.has_named("default") && args.kwargs.size() == 2))) {
	auto & items = args.args[0];
	auto attr_name = args.get_named("attribute");
	auto default_value = args.get_named("default");
	for (size_t i = 0, n = items.size(); i < n; i++) {
	auto & item = items.at(i);
	auto attr = item.get(attr_name);
	res.push_back(attr.is_null() ? default_value : attr);
	}
	} else if (args.kwargs.empty() && args.args.size() >= 2) {
	auto fn = context->get(args.args[1]);
	if (fn.is_null()) throw std::runtime_error("Undefined filter: " + args.args[1].dump());
	ArgumentsValue filter_args { {Value()}, {} };
	for (size_t i = 2, n = args.args.size(); i < n; i++) {
	filter_args.args.emplace_back(args.args[i]);
	}
	for (size_t i = 0, n = args.args[0].size(); i < n; i++) {
	auto & item = args.args[0].at(i);
	filter_args.args[0] = item;
	res.push_back(fn.call(context, filter_args));
	}
	} else {
	throw std::runtime_error("Invalid or unsupported arguments for map");
	}
	return res;
	}));
	globals.set("indent", simple_function("indent", { "text", "indent", "first" }, [](const std::shared_ptr<Context> &, Value & args) {
	auto text = args.at("text").get<std::string>();
	auto first = args.get<bool>("first", false);
	std::string out;
	std::string indent(args.get<int64_t>("indent", 0), ' ');
	std::istringstream iss(text);
	std::string line;
	auto is_first = true;
	while (std::getline(iss, line, '\n')) {
	auto needs_indent = !is_first \|\| first;
	if (is_first) is_first = false;
	else out += "\n";
	if (needs_indent) out += indent;
	out += line;
	}
	if (!text.empty() && text.back() == '\n') out += "\n";
	return out;
	}));
	auto select_or_reject_attr = [](bool is_select) {
	return Value::callable([=](const std::shared_ptr<Context> & context, ArgumentsValue & args) {
	args.expectArgs(is_select ? "selectattr" : "rejectattr", {2, (std::numeric_limits<size_t>::max)()}, {0, 0});
	auto & items = args.args[0];
	if (items.is_null())
	return Value::array();
	if (!items.is_array()) throw std::runtime_error("object is not iterable: " + items.dump());
	auto attr_name = args.args[1].get<std::string>();

	bool has_test = false;
	Value test_fn;
	ArgumentsValue test_args {{Value()}, {}};
	if (args.args.size() >= 3) {
	has_test = true;
	test_fn = context->get(args.args[2]);
	if (test_fn.is_null()) throw std::runtime_error("Undefined test: " + args.args[2].dump());
	for (size_t i = 3, n = args.args.size(); i < n; i++) {
	test_args.args.emplace_back(args.args[i]);
	}
	test_args.kwargs = args.kwargs;
	}

	auto res = Value::array();
	for (size_t i = 0, n = items.size(); i < n; i++) {
	auto & item = items.at(i);
	auto attr = item.get(attr_name);
	if (has_test) {
	test_args.args[0] = attr;
	if (test_fn.call(context, test_args).to_bool() == (is_select ? true : false)) {
	res.push_back(item);
	}
	} else {
	res.push_back(attr);
	}
	}
	return res;
	});
	};
	globals.set("selectattr", select_or_reject_attr(/* is_select= */ true));
	globals.set("rejectattr", select_or_reject_attr(/* is_select= */ false));
	globals.set("range", Value::callable([=](const std::shared_ptr<Context> &, ArgumentsValue & args) {
	std::vector<int64_t> startEndStep(3);
	std::vector<bool> param_set(3);
	if (args.args.size() == 1) {
	startEndStep[1] = args.args[0].get<int64_t>();
	param_set[1] = true;
	} else {
	for (size_t i = 0; i < args.args.size(); i++) {
	auto & arg = args.args[i];
	auto v = arg.get<int64_t>();
	startEndStep[i] = v;
	param_set[i] = true;
	}
	}
	for (auto & [name, value] : args.kwargs) {
	size_t i;
	if (name == "start") i = 0;
	else if (name == "end") i = 1;
	else if (name == "step") i = 2;
	else throw std::runtime_error("Unknown argument " + name + " for function range");

	if (param_set[i]) {
	throw std::runtime_error("Duplicate argument " + name + " for function range");
	}
	startEndStep[i] = value.get<int64_t>();
	param_set[i] = true;
	}
	if (!param_set[1]) {
	throw std::runtime_error("Missing required argument 'end' for function range");
	}
	int64_t start = param_set[0] ? startEndStep[0] : 0;
	int64_t end = startEndStep[1];
	int64_t step = param_set[2] ? startEndStep[2] : 1;

	auto res = Value::array();
	if (step > 0) {
	for (int64_t i = start; i < end; i += step) {
	res.push_back(Value(i));
	}
	} else {
	for (int64_t i = start; i > end; i += step) {
	res.push_back(Value(i));
	}
	}
	return res;
	}));

	return std::make_shared<Context>(std::move(globals));
	}

	inline std::shared_ptr<Context> Context::make(Value && values, const std::shared_ptr<Context> & parent) {
	return std::make_shared<Context>(values.is_null() ? Value::object() : std::move(values), parent);
	}

	} // namespace minja