/*************************************************************************/
/*  test_expression.h                                                    */
/*************************************************************************/
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/* Copyright (c) 2007-2021 Juan Linietsky, Ariel Manzur.                 */
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#ifndef TEST_EXPRESSION_H
#define TEST_EXPRESSION_H

#include "core/math/expression.h"

#include "tests/test_macros.h"

namespace TestExpression {

TEST_CASE("[Expression] Integer arithmetic") {
	Expression expression;

	CHECK_MESSAGE(
			expression.parse("-123456") == OK,
			"Integer identity should parse successfully.");
	CHECK_MESSAGE(
			int(expression.execute()) == -123456,
			"Integer identity should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("2 + 3") == OK,
			"Integer addition should parse successfully.");
	CHECK_MESSAGE(
			int(expression.execute()) == 5,
			"Integer addition should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("999999999999 + 999999999999") == OK,
			"Large integer addition should parse successfully.");
	CHECK_MESSAGE(
			int64_t(expression.execute()) == 1'999'999'999'998,
			"Large integer addition should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("25 / 10") == OK,
			"Integer / integer division should parse successfully.");
	CHECK_MESSAGE(
			int(expression.execute()) == 2,
			"Integer / integer division should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("2 * (6 + 14) / 2 - 5") == OK,
			"Integer multiplication-addition-subtraction-division should parse successfully.");
	CHECK_MESSAGE(
			int(expression.execute()) == 15,
			"Integer multiplication-addition-subtraction-division should return the expected result.");
}

TEST_CASE("[Expression] Floating-point arithmetic") {
	Expression expression;

	CHECK_MESSAGE(
			expression.parse("-123.456") == OK,
			"Float identity should parse successfully.");
	CHECK_MESSAGE(
			Math::is_equal_approx(double(expression.execute()), -123.456),
			"Float identity should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("2.0 + 3.0") == OK,
			"Float addition should parse successfully.");
	CHECK_MESSAGE(
			Math::is_equal_approx(double(expression.execute()), 5),
			"Float addition should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("3.0 / 10") == OK,
			"Float / integer division should parse successfully.");
	CHECK_MESSAGE(
			Math::is_equal_approx(double(expression.execute()), 0.3),
			"Float / integer division should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("3 / 10.0") == OK,
			"Basic integer / float division should parse successfully.");
	CHECK_MESSAGE(
			Math::is_equal_approx(double(expression.execute()), 0.3),
			"Basic integer / float division should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("3.0 / 10.0") == OK,
			"Float / float division should parse successfully.");
	CHECK_MESSAGE(
			Math::is_equal_approx(double(expression.execute()), 0.3),
			"Float / float division should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("2.5 * (6.0 + 14.25) / 2.0 - 5.12345") == OK,
			"Float multiplication-addition-subtraction-division should parse successfully.");
	CHECK_MESSAGE(
			Math::is_equal_approx(double(expression.execute()), 20.18905),
			"Float multiplication-addition-subtraction-division should return the expected result.");
}

TEST_CASE("[Expression] Scientific notation") {
	Expression expression;

	CHECK_MESSAGE(
			expression.parse("2.e5") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			Math::is_equal_approx(double(expression.execute()), 200'000),
			"The expression should return the expected result.");

	// The middle "e" is ignored here.
	CHECK_MESSAGE(
			expression.parse("2e5") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			Math::is_equal_approx(double(expression.execute()), 25),
			"The expression should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("2e.5") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			Math::is_equal_approx(double(expression.execute()), 2),
			"The expression should return the expected result.");
}

TEST_CASE("[Expression] Underscored numeric literals") {
	Expression expression;

	CHECK_MESSAGE(
			expression.parse("1_000_000") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			expression.parse("1_000.000") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			expression.parse("0xff_99_00") == OK,
			"The expression should parse successfully.");
}

TEST_CASE("[Expression] Built-in functions") {
	Expression expression;

	CHECK_MESSAGE(
			expression.parse("sqrt(pow(3, 2) + pow(4, 2))") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			int(expression.execute()) == 5,
			"`sqrt(pow(3, 2) + pow(4, 2))` should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("snapped(sin(0.5), 0.01)") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			Math::is_equal_approx(double(expression.execute()), 0.48),
			"`snapped(sin(0.5), 0.01)` should return the expected result.");

	CHECK_MESSAGE(
			expression.parse("pow(2.0, -2500)") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			Math::is_zero_approx(double(expression.execute())),
			"`pow(2.0, -2500)` should return the expected result (asymptotically zero).");
}

TEST_CASE("[Expression] Boolean expressions") {
	Expression expression;

	CHECK_MESSAGE(
			expression.parse("24 >= 12") == OK,
			"The boolean expression should parse successfully.");
	CHECK_MESSAGE(
			bool(expression.execute()),
			"The boolean expression should evaluate to `true`.");

	CHECK_MESSAGE(
			expression.parse("1.0 < 1.25 && 1.25 < 2.0") == OK,
			"The boolean expression should parse successfully.");
	CHECK_MESSAGE(
			bool(expression.execute()),
			"The boolean expression should evaluate to `true`.");

	CHECK_MESSAGE(
			expression.parse("!2") == OK,
			"The boolean expression should parse successfully.");
	CHECK_MESSAGE(
			!bool(expression.execute()),
			"The boolean expression should evaluate to `false`.");

	CHECK_MESSAGE(
			expression.parse("!!2") == OK,
			"The boolean expression should parse successfully.");
	CHECK_MESSAGE(
			bool(expression.execute()),
			"The boolean expression should evaluate to `true`.");

	CHECK_MESSAGE(
			expression.parse("!0") == OK,
			"The boolean expression should parse successfully.");
	CHECK_MESSAGE(
			bool(expression.execute()),
			"The boolean expression should evaluate to `true`.");

	CHECK_MESSAGE(
			expression.parse("!!0") == OK,
			"The boolean expression should parse successfully.");
	CHECK_MESSAGE(
			!bool(expression.execute()),
			"The boolean expression should evaluate to `false`.");

	CHECK_MESSAGE(
			expression.parse("2 && 5") == OK,
			"The boolean expression should parse successfully.");
	CHECK_MESSAGE(
			bool(expression.execute()),
			"The boolean expression should evaluate to `true`.");

	CHECK_MESSAGE(
			expression.parse("0 || 0") == OK,
			"The boolean expression should parse successfully.");
	CHECK_MESSAGE(
			!bool(expression.execute()),
			"The boolean expression should evaluate to `false`.");

	CHECK_MESSAGE(
			expression.parse("(2 <= 4) && (2 > 5)") == OK,
			"The boolean expression should parse successfully.");
	CHECK_MESSAGE(
			!bool(expression.execute()),
			"The boolean expression should evaluate to `false`.");
}

TEST_CASE("[Expression] Expressions with variables") {
	Expression expression;

	PackedStringArray parameter_names;
	parameter_names.push_back("foo");
	parameter_names.push_back("bar");
	CHECK_MESSAGE(
			expression.parse("foo + bar + 50", parameter_names) == OK,
			"The expression should parse successfully.");
	Array values;
	values.push_back(60);
	values.push_back(20);
	CHECK_MESSAGE(
			int(expression.execute(values)) == 130,
			"The expression should return the expected value.");

	PackedStringArray parameter_names_invalid;
	parameter_names_invalid.push_back("foo");
	parameter_names_invalid.push_back("baz"); // Invalid parameter name.
	CHECK_MESSAGE(
			expression.parse("foo + bar + 50", parameter_names_invalid) == OK,
			"The expression should parse successfully.");
	Array values_invalid;
	values_invalid.push_back(60);
	values_invalid.push_back(20);
	// Invalid parameters will parse successfully but print an error message when executing.
	ERR_PRINT_OFF;
	CHECK_MESSAGE(
			int(expression.execute(values_invalid)) == 0,
			"The expression should return the expected value.");
	ERR_PRINT_ON;

	// Mismatched argument count (more values than parameters).
	PackedStringArray parameter_names_mismatch;
	parameter_names_mismatch.push_back("foo");
	parameter_names_mismatch.push_back("bar");
	CHECK_MESSAGE(
			expression.parse("foo + bar + 50", parameter_names_mismatch) == OK,
			"The expression should parse successfully.");
	Array values_mismatch;
	values_mismatch.push_back(60);
	values_mismatch.push_back(20);
	values_mismatch.push_back(110);
	CHECK_MESSAGE(
			int(expression.execute(values_mismatch)) == 130,
			"The expression should return the expected value.");

	// Mismatched argument count (more parameters than values).
	PackedStringArray parameter_names_mismatch2;
	parameter_names_mismatch2.push_back("foo");
	parameter_names_mismatch2.push_back("bar");
	parameter_names_mismatch2.push_back("baz");
	CHECK_MESSAGE(
			expression.parse("foo + bar + baz + 50", parameter_names_mismatch2) == OK,
			"The expression should parse successfully.");
	Array values_mismatch2;
	values_mismatch2.push_back(60);
	values_mismatch2.push_back(20);
	// Having more parameters than values will parse successfully but print an
	// error message when executing.
	ERR_PRINT_OFF;
	CHECK_MESSAGE(
			int(expression.execute(values_mismatch2)) == 0,
			"The expression should return the expected value.");
	ERR_PRINT_ON;
}

TEST_CASE("[Expression] Invalid expressions") {
	Expression expression;

	CHECK_MESSAGE(
			expression.parse("\\") == ERR_INVALID_PARAMETER,
			"The expression shouldn't parse successfully.");

	CHECK_MESSAGE(
			expression.parse("0++") == ERR_INVALID_PARAMETER,
			"The expression shouldn't parse successfully.");

	CHECK_MESSAGE(
			expression.parse("()") == ERR_INVALID_PARAMETER,
			"The expression shouldn't parse successfully.");

	CHECK_MESSAGE(
			expression.parse("()()") == ERR_INVALID_PARAMETER,
			"The expression shouldn't parse successfully.");

	CHECK_MESSAGE(
			expression.parse("() - ()") == ERR_INVALID_PARAMETER,
			"The expression shouldn't parse successfully.");

	CHECK_MESSAGE(
			expression.parse("() * 12345") == ERR_INVALID_PARAMETER,
			"The expression shouldn't parse successfully.");

	CHECK_MESSAGE(
			expression.parse("() * 12345") == ERR_INVALID_PARAMETER,
			"The expression shouldn't parse successfully.");

	CHECK_MESSAGE(
			expression.parse("123'456") == ERR_INVALID_PARAMETER,
			"The expression shouldn't parse successfully.");

	CHECK_MESSAGE(
			expression.parse("123\"456") == ERR_INVALID_PARAMETER,
			"The expression shouldn't parse successfully.");
}

TEST_CASE("[Expression] Unusual expressions") {
	Expression expression;

	// Redundant parentheses don't cause a parse error as long as they're matched.
	CHECK_MESSAGE(
			expression.parse("(((((((((((((((666)))))))))))))))") == OK,
			"The expression should parse successfully.");

	// Using invalid identifiers doesn't cause a parse error.
	ERR_PRINT_OFF;
	CHECK_MESSAGE(
			expression.parse("hello + hello") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			int(expression.execute()) == 0,
			"The expression should return the expected result.");
	ERR_PRINT_ON;

	ERR_PRINT_OFF;
	CHECK_MESSAGE(
			expression.parse("$1.00 + ???5") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			int(expression.execute()) == 0,
			"The expression should return the expected result.");
	ERR_PRINT_ON;

	// Commas can't be used as a decimal parameter.
	CHECK_MESSAGE(
			expression.parse("123,456") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			int(expression.execute()) == 123,
			"The expression should return the expected result.");

	// Spaces can't be used as a separator for large numbers.
	CHECK_MESSAGE(
			expression.parse("123 456") == OK,
			"The expression should parse successfully.");
	CHECK_MESSAGE(
			int(expression.execute()) == 123,
			"The expression should return the expected result.");

	// Division by zero is accepted, even though it prints an error message normally.
	CHECK_MESSAGE(
			expression.parse("-25.4 / 0") == OK,
			"The expression should parse successfully.");
	ERR_PRINT_OFF;
	CHECK_MESSAGE(
			Math::is_inf(double(expression.execute())),
			"`-25.4 / 0` should return inf.");
	ERR_PRINT_ON;

	CHECK_MESSAGE(
			expression.parse("0 / 0") == OK,
			"The expression should parse successfully.");
	ERR_PRINT_OFF;
	CHECK_MESSAGE(
			int(expression.execute()) == 0,
			"`0 / 0` should return 0.");
	ERR_PRINT_ON;

	// The tests below currently crash the engine.
	//
	//CHECK_MESSAGE(
	//		expression.parse("(-9223372036854775807 - 1) % -1") == OK,
	//		"The expression should parse successfully.");
	//CHECK_MESSAGE(
	//		int64_t(expression.execute()) == 0,
	//		"`(-9223372036854775807 - 1) % -1` should return the expected result.");
	//
	//CHECK_MESSAGE(
	//		expression.parse("(-9223372036854775807 - 1) / -1") == OK,
	//		"The expression should parse successfully.");
	//CHECK_MESSAGE(
	//		int64_t(expression.execute()) == 0,
	//		"`(-9223372036854775807 - 1) / -1` should return the expected result.");
}
} // namespace TestExpression

#endif // TEST_EXPRESSION_H