path: root/core/variant/array.cpp

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/*  array.cpp                                                            */
/*************************************************************************/
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/* Copyright (c) 2007-2021 Juan Linietsky, Ariel Manzur.                 */
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#include "array.h"

#include "container_type_validate.h"
#include "core/object/class_db.h"
#include "core/object/script_language.h"
#include "core/templates/hashfuncs.h"
#include "core/templates/search_array.h"
#include "core/templates/vector.h"
#include "core/variant/callable.h"
#include "core/variant/variant.h"

class ArrayPrivate {
public:
	SafeRefCount refcount;
	Vector<Variant> array;

	ContainerTypeValidate typed;
};

void Array::_ref(const Array &p_from) const {
	ArrayPrivate *_fp = p_from._p;

	ERR_FAIL_COND(!_fp); // should NOT happen.

	if (_fp == _p) {
		return; // whatever it is, nothing to do here move along
	}

	bool success = _fp->refcount.ref();

	ERR_FAIL_COND(!success); // should really not happen either

	_unref();

	_p = p_from._p;
}

void Array::_unref() const {
	if (!_p) {
		return;
	}

	if (_p->refcount.unref()) {
		memdelete(_p);
	}
	_p = nullptr;
}

Variant &Array::operator[](int p_idx) {
	return _p->array.write[p_idx];
}

const Variant &Array::operator[](int p_idx) const {
	return _p->array[p_idx];
}

int Array::size() const {
	return _p->array.size();
}

bool Array::is_empty() const {
	return _p->array.is_empty();
}

void Array::clear() {
	_p->array.clear();
}

bool Array::operator==(const Array &p_array) const {
	return recursive_equal(p_array, 0);
}

bool Array::operator!=(const Array &p_array) const {
	return !recursive_equal(p_array, 0);
}

bool Array::recursive_equal(const Array &p_array, int recursion_count) const {
	// Cheap checks
	if (_p == p_array._p) {
		return true;
	}
	const Vector<Variant> &a1 = _p->array;
	const Vector<Variant> &a2 = p_array._p->array;
	const int size = a1.size();
	if (size != a2.size()) {
		return false;
	}

	// Heavy O(n) check
	if (recursion_count > MAX_RECURSION) {
		ERR_PRINT("Max recursion reached");
		return true;
	}
	recursion_count++;
	for (int i = 0; i < size; i++) {
		if (!a1[i].hash_compare(a2[i], recursion_count)) {
			return false;
		}
	}

	return true;
}

bool Array::operator<(const Array &p_array) const {
	int a_len = size();
	int b_len = p_array.size();

	int min_cmp = MIN(a_len, b_len);

	for (int i = 0; i < min_cmp; i++) {
		if (operator[](i) < p_array[i]) {
			return true;
		} else if (p_array[i] < operator[](i)) {
			return false;
		}
	}

	return a_len < b_len;
}

bool Array::operator<=(const Array &p_array) const {
	return !operator>(p_array);
}
bool Array::operator>(const Array &p_array) const {
	return p_array < *this;
}
bool Array::operator>=(const Array &p_array) const {
	return !operator<(p_array);
}

uint32_t Array::hash() const {
	return recursive_hash(0);
}

uint32_t Array::recursive_hash(int recursion_count) const {
	if (recursion_count > MAX_RECURSION) {
		ERR_PRINT("Max recursion reached");
		return 0;
	}

	uint32_t h = hash_djb2_one_32(Variant::ARRAY);

	recursion_count++;
	for (int i = 0; i < _p->array.size(); i++) {
		h = hash_djb2_one_32(_p->array[i].recursive_hash(recursion_count), h);
	}
	return h;
}

bool Array::_assign(const Array &p_array) {
	if (_p->typed.type != Variant::OBJECT && _p->typed.type == p_array._p->typed.type) {
		//same type or untyped, just reference, should be fine
		_ref(p_array);
	} else if (_p->typed.type == Variant::NIL) { //from typed to untyped, must copy, but this is cheap anyway
		_p->array = p_array._p->array;
	} else if (p_array._p->typed.type == Variant::NIL) { //from untyped to typed, must try to check if they are all valid
		if (_p->typed.type == Variant::OBJECT) {
			//for objects, it needs full validation, either can be converted or fail
			for (int i = 0; i < p_array._p->array.size(); i++) {
				if (!_p->typed.validate(p_array._p->array[i], "assign")) {
					return false;
				}
			}
			_p->array = p_array._p->array; //then just copy, which is cheap anyway

		} else {
			//for non objects, we need to check if there is a valid conversion, which needs to happen one by one, so this is the worst case.
			Vector<Variant> new_array;
			new_array.resize(p_array._p->array.size());
			for (int i = 0; i < p_array._p->array.size(); i++) {
				Variant src_val = p_array._p->array[i];
				if (src_val.get_type() == _p->typed.type) {
					new_array.write[i] = src_val;
				} else if (Variant::can_convert_strict(src_val.get_type(), _p->typed.type)) {
					Variant *ptr = &src_val;
					Callable::CallError ce;
					Variant::construct(_p->typed.type, new_array.write[i], (const Variant **)&ptr, 1, ce);
					if (ce.error != Callable::CallError::CALL_OK) {
						ERR_FAIL_V_MSG(false, "Unable to convert array index " + itos(i) + " from '" + Variant::get_type_name(src_val.get_type()) + "' to '" + Variant::get_type_name(_p->typed.type) + "'.");
					}
				} else {
					ERR_FAIL_V_MSG(false, "Unable to convert array index " + itos(i) + " from '" + Variant::get_type_name(src_val.get_type()) + "' to '" + Variant::get_type_name(_p->typed.type) + "'.");
				}
			}

			_p->array = new_array;
		}
	} else if (_p->typed.can_reference(p_array._p->typed)) { //same type or compatible
		_ref(p_array);
	} else {
		ERR_FAIL_V_MSG(false, "Assignment of arrays of incompatible types.");
	}
	return true;
}

void Array::operator=(const Array &p_array) {
	_ref(p_array);
}

void Array::push_back(const Variant &p_value) {
	ERR_FAIL_COND(!_p->typed.validate(p_value, "push_back"));
	_p->array.push_back(p_value);
}

void Array::append_array(const Array &p_array) {
	ERR_FAIL_COND(!_p->typed.validate(p_array, "append_array"));
	_p->array.append_array(p_array._p->array);
}

Error Array::resize(int p_new_size) {
	return _p->array.resize(p_new_size);
}

Error Array::insert(int p_pos, const Variant &p_value) {
	ERR_FAIL_COND_V(!_p->typed.validate(p_value, "insert"), ERR_INVALID_PARAMETER);
	return _p->array.insert(p_pos, p_value);
}

void Array::fill(const Variant &p_value) {
	ERR_FAIL_COND(!_p->typed.validate(p_value, "fill"));
	_p->array.fill(p_value);
}

void Array::erase(const Variant &p_value) {
	ERR_FAIL_COND(!_p->typed.validate(p_value, "erase"));
	_p->array.erase(p_value);
}

Variant Array::front() const {
	ERR_FAIL_COND_V_MSG(_p->array.size() == 0, Variant(), "Can't take value from empty array.");
	return operator[](0);
}

Variant Array::back() const {
	ERR_FAIL_COND_V_MSG(_p->array.size() == 0, Variant(), "Can't take value from empty array.");
	return operator[](_p->array.size() - 1);
}

int Array::find(const Variant &p_value, int p_from) const {
	ERR_FAIL_COND_V(!_p->typed.validate(p_value, "find"), -1);
	return _p->array.find(p_value, p_from);
}

int Array::rfind(const Variant &p_value, int p_from) const {
	if (_p->array.size() == 0) {
		return -1;
	}
	ERR_FAIL_COND_V(!_p->typed.validate(p_value, "rfind"), -1);

	if (p_from < 0) {
		// Relative offset from the end
		p_from = _p->array.size() + p_from;
	}
	if (p_from < 0 || p_from >= _p->array.size()) {
		// Limit to array boundaries
		p_from = _p->array.size() - 1;
	}

	for (int i = p_from; i >= 0; i--) {
		if (_p->array[i] == p_value) {
			return i;
		}
	}

	return -1;
}

int Array::find_last(const Variant &p_value) const {
	ERR_FAIL_COND_V(!_p->typed.validate(p_value, "find_last"), -1);
	return rfind(p_value);
}

int Array::count(const Variant &p_value) const {
	ERR_FAIL_COND_V(!_p->typed.validate(p_value, "count"), 0);
	if (_p->array.size() == 0) {
		return 0;
	}

	int amount = 0;
	for (int i = 0; i < _p->array.size(); i++) {
		if (_p->array[i] == p_value) {
			amount++;
		}
	}

	return amount;
}

bool Array::has(const Variant &p_value) const {
	ERR_FAIL_COND_V(!_p->typed.validate(p_value, "use 'has'"), false);

	return _p->array.find(p_value, 0) != -1;
}

void Array::remove_at(int p_pos) {
	_p->array.remove_at(p_pos);
}

void Array::set(int p_idx, const Variant &p_value) {
	ERR_FAIL_COND(!_p->typed.validate(p_value, "set"));

	operator[](p_idx) = p_value;
}

const Variant &Array::get(int p_idx) const {
	return operator[](p_idx);
}

Array Array::duplicate(bool p_deep) const {
	return recursive_duplicate(p_deep, 0);
}

Array Array::recursive_duplicate(bool p_deep, int recursion_count) const {
	Array new_arr;

	if (recursion_count > MAX_RECURSION) {
		ERR_PRINT("Max recursion reached");
		return new_arr;
	}

	int element_count = size();
	new_arr.resize(element_count);
	new_arr._p->typed = _p->typed;
	if (p_deep) {
		recursion_count++;
		for (int i = 0; i < element_count; i++) {
			new_arr[i] = get(i).recursive_duplicate(true, recursion_count);
		}
	} else {
		for (int i = 0; i < element_count; i++) {
			new_arr[i] = get(i);
		}
	}

	return new_arr;
}

int Array::_clamp_slice_index(int p_index) const {
	int arr_size = size();
	int fixed_index = CLAMP(p_index, -arr_size, arr_size - 1);
	if (fixed_index < 0) {
		fixed_index = arr_size + fixed_index;
	}
	return fixed_index;
}

Array Array::slice(int p_begin, int p_end, int p_step, bool p_deep) const { // like python, but inclusive on upper bound

	Array new_arr;

	ERR_FAIL_COND_V_MSG(p_step == 0, new_arr, "Array slice step size cannot be zero.");

	if (is_empty()) { // Don't try to slice empty arrays.
		return new_arr;
	}
	if (p_step > 0) {
		if (p_begin >= size() || p_end < -size()) {
			return new_arr;
		}
	} else { // p_step < 0
		if (p_begin < -size() || p_end >= size()) {
			return new_arr;
		}
	}

	int begin = _clamp_slice_index(p_begin);
	int end = _clamp_slice_index(p_end);

	int new_arr_size = MAX(((end - begin + p_step) / p_step), 0);
	new_arr.resize(new_arr_size);

	if (p_step > 0) {
		int dest_idx = 0;
		for (int idx = begin; idx <= end; idx += p_step) {
			ERR_FAIL_COND_V_MSG(dest_idx < 0 || dest_idx >= new_arr_size, Array(), "Bug in Array slice()");
			new_arr[dest_idx++] = p_deep ? get(idx).duplicate(p_deep) : get(idx);
		}
	} else { // p_step < 0
		int dest_idx = 0;
		for (int idx = begin; idx >= end; idx += p_step) {
			ERR_FAIL_COND_V_MSG(dest_idx < 0 || dest_idx >= new_arr_size, Array(), "Bug in Array slice()");
			new_arr[dest_idx++] = p_deep ? get(idx).duplicate(p_deep) : get(idx);
		}
	}

	return new_arr;
}

Array Array::filter(const Callable &p_callable) const {
	Array new_arr;
	new_arr.resize(size());
	int accepted_count = 0;

	const Variant *argptrs[1];
	for (int i = 0; i < size(); i++) {
		argptrs[0] = &get(i);

		Variant result;
		Callable::CallError ce;
		p_callable.call(argptrs, 1, result, ce);
		if (ce.error != Callable::CallError::CALL_OK) {
			ERR_FAIL_V_MSG(Array(), "Error calling method from 'filter': " + Variant::get_callable_error_text(p_callable, argptrs, 1, ce));
		}

		if (result.operator bool()) {
			new_arr[accepted_count] = get(i);
			accepted_count++;
		}
	}

	new_arr.resize(accepted_count);

	return new_arr;
}

Array Array::map(const Callable &p_callable) const {
	Array new_arr;
	new_arr.resize(size());

	const Variant *argptrs[1];
	for (int i = 0; i < size(); i++) {
		argptrs[0] = &get(i);

		Variant result;
		Callable::CallError ce;
		p_callable.call(argptrs, 1, result, ce);
		if (ce.error != Callable::CallError::CALL_OK) {
			ERR_FAIL_V_MSG(Array(), "Error calling method from 'map': " + Variant::get_callable_error_text(p_callable, argptrs, 1, ce));
		}

		new_arr[i] = result;
	}

	return new_arr;
}

Variant Array::reduce(const Callable &p_callable, const Variant &p_accum) const {
	int start = 0;
	Variant ret = p_accum;
	if (ret == Variant() && size() > 0) {
		ret = front();
		start = 1;
	}

	const Variant *argptrs[2];
	for (int i = start; i < size(); i++) {
		argptrs[0] = &ret;
		argptrs[1] = &get(i);

		Variant result;
		Callable::CallError ce;
		p_callable.call(argptrs, 2, result, ce);
		if (ce.error != Callable::CallError::CALL_OK) {
			ERR_FAIL_V_MSG(Variant(), "Error calling method from 'reduce': " + Variant::get_callable_error_text(p_callable, argptrs, 2, ce));
		}
		ret = result;
	}

	return ret;
}

struct _ArrayVariantSort {
	_FORCE_INLINE_ bool operator()(const Variant &p_l, const Variant &p_r) const {
		bool valid = false;
		Variant res;
		Variant::evaluate(Variant::OP_LESS, p_l, p_r, res, valid);
		if (!valid) {
			res = false;
		}
		return res;
	}
};

void Array::sort() {
	_p->array.sort_custom<_ArrayVariantSort>();
}

struct _ArrayVariantSortCustom {
	Callable func;

	_FORCE_INLINE_ bool operator()(const Variant &p_l, const Variant &p_r) const {
		const Variant *args[2] = { &p_l, &p_r };
		Callable::CallError err;
		Variant res;
		func.call(args, 2, res, err);
		ERR_FAIL_COND_V_MSG(err.error != Callable::CallError::CALL_OK, false,
				"Error calling sorting method: " + Variant::get_callable_error_text(func, args, 1, err));
		return res;
	}
};

void Array::sort_custom(Callable p_callable) {
	SortArray<Variant, _ArrayVariantSortCustom, true> avs;
	avs.compare.func = p_callable;
	avs.sort(_p->array.ptrw(), _p->array.size());
}

void Array::shuffle() {
	const int n = _p->array.size();
	if (n < 2) {
		return;
	}
	Variant *data = _p->array.ptrw();
	for (int i = n - 1; i >= 1; i--) {
		const int j = Math::rand() % (i + 1);
		const Variant tmp = data[j];
		data[j] = data[i];
		data[i] = tmp;
	}
}

int Array::bsearch(const Variant &p_value, bool p_before) {
	ERR_FAIL_COND_V(!_p->typed.validate(p_value, "binary search"), -1);
	SearchArray<Variant, _ArrayVariantSort> avs;
	return avs.bisect(_p->array.ptrw(), _p->array.size(), p_value, p_before);
}

int Array::bsearch_custom(const Variant &p_value, Callable p_callable, bool p_before) {
	ERR_FAIL_COND_V(!_p->typed.validate(p_value, "custom binary search"), -1);

	SearchArray<Variant, _ArrayVariantSortCustom> avs;
	avs.compare.func = p_callable;

	return avs.bisect(_p->array.ptrw(), _p->array.size(), p_value, p_before);
}

void Array::reverse() {
	_p->array.reverse();
}

void Array::push_front(const Variant &p_value) {
	ERR_FAIL_COND(!_p->typed.validate(p_value, "push_front"));
	_p->array.insert(0, p_value);
}

Variant Array::pop_back() {
	if (!_p->array.is_empty()) {
		const int n = _p->array.size() - 1;
		const Variant ret = _p->array.get(n);
		_p->array.resize(n);
		return ret;
	}
	return Variant();
}

Variant Array::pop_front() {
	if (!_p->array.is_empty()) {
		const Variant ret = _p->array.get(0);
		_p->array.remove_at(0);
		return ret;
	}
	return Variant();
}

Variant Array::pop_at(int p_pos) {
	if (_p->array.is_empty()) {
		// Return `null` without printing an error to mimic `pop_back()` and `pop_front()` behavior.
		return Variant();
	}

	if (p_pos < 0) {
		// Relative offset from the end
		p_pos = _p->array.size() + p_pos;
	}

	ERR_FAIL_INDEX_V_MSG(
			p_pos,
			_p->array.size(),
			Variant(),
			vformat(
					"The calculated index %s is out of bounds (the array has %s elements). Leaving the array untouched and returning `null`.",
					p_pos,
					_p->array.size()));

	const Variant ret = _p->array.get(p_pos);
	_p->array.remove_at(p_pos);
	return ret;
}

Variant Array::min() const {
	Variant minval;
	for (int i = 0; i < size(); i++) {
		if (i == 0) {
			minval = get(i);
		} else {
			bool valid;
			Variant ret;
			Variant test = get(i);
			Variant::evaluate(Variant::OP_LESS, test, minval, ret, valid);
			if (!valid) {
				return Variant(); //not a valid comparison
			}
			if (bool(ret)) {
				//is less
				minval = test;
			}
		}
	}
	return minval;
}

Variant Array::max() const {
	Variant maxval;
	for (int i = 0; i < size(); i++) {
		if (i == 0) {
			maxval = get(i);
		} else {
			bool valid;
			Variant ret;
			Variant test = get(i);
			Variant::evaluate(Variant::OP_GREATER, test, maxval, ret, valid);
			if (!valid) {
				return Variant(); //not a valid comparison
			}
			if (bool(ret)) {
				//is less
				maxval = test;
			}
		}
	}
	return maxval;
}

const void *Array::id() const {
	return _p->array.ptr();
}

Array::Array(const Array &p_from, uint32_t p_type, const StringName &p_class_name, const Variant &p_script) {
	_p = memnew(ArrayPrivate);
	_p->refcount.init();
	set_typed(p_type, p_class_name, p_script);
	_assign(p_from);
}

bool Array::typed_assign(const Array &p_other) {
	return _assign(p_other);
}

void Array::set_typed(uint32_t p_type, const StringName &p_class_name, const Variant &p_script) {
	ERR_FAIL_COND_MSG(_p->array.size() > 0, "Type can only be set when array is empty.");
	ERR_FAIL_COND_MSG(_p->refcount.get() > 1, "Type can only be set when array has no more than one user.");
	ERR_FAIL_COND_MSG(_p->typed.type != Variant::NIL, "Type can only be set once.");
	ERR_FAIL_COND_MSG(p_class_name != StringName() && p_type != Variant::OBJECT, "Class names can only be set for type OBJECT");
	Ref<Script> script = p_script;
	ERR_FAIL_COND_MSG(script.is_valid() && p_class_name == StringName(), "Script class can only be set together with base class name");

	_p->typed.type = Variant::Type(p_type);
	_p->typed.class_name = p_class_name;
	_p->typed.script = script;
	_p->typed.where = "TypedArray";
}

bool Array::is_typed() const {
	return _p->typed.type != Variant::NIL;
}

uint32_t Array::get_typed_builtin() const {
	return _p->typed.type;
}

StringName Array::get_typed_class_name() const {
	return _p->typed.class_name;
}

Variant Array::get_typed_script() const {
	return _p->typed.script;
}

Array::Array(const Array &p_from) {
	_p = nullptr;
	_ref(p_from);
}

Array::Array() {
	_p = memnew(ArrayPrivate);
	_p->refcount.init();
}

Array::~Array() {
	_unref();
}