ardupilot/libraries/AP_Common/examples/AP_Var/AP_Var.pde

//
// Unit tests for the AP_MetaClass and AP_Var classes.
//

#include <FastSerial.h>
#include <AP_Common.h>
#include <string.h>

// we need to do this, even though normally it's a bad idea
#pragma GCC diagnostic ignored "-Wfloat-equal"

FastSerialPort(Serial, 0);

//
// Unit test framework
//
class Test
{
public:
	Test(const char *name) : _name(name), _fail(false) {}

	~Test()	{
		Serial.printf("%s: %s\n", _fail ? "FAILED" : "passed", _name);
		if (_fail) {
			_failed++;
		} else {
			_passed++;
		}
	}

	void	require(bool expr, const char *source) {
		if (!expr) {
			_fail = true;
			Serial.printf("%s: fail: %s\n", _name, source);
		}
	}

	static void	report() {
		Serial.printf("\n%d passed  %d failed\n", _passed, _failed);
	}

private:
	const char	*_name;
	bool		_fail;
	static int	_passed;
	static int	_failed;
};

int Test::_passed = 0;
int Test::_failed = 0;

#define TEST(name)		Test _test(#name)
#define	REQUIRE(expr)	_test.require(expr, #expr)

//
// Unit tests
//
void
setup(void)
{
	Serial.begin(38400);

	// MetaClass: test type ID
	{
		TEST(meta_type_id);

		AP_Float 	f1;
		AP_Float	f2;
		AP_Int8		i1;

		uint16_t	m1 = f1.meta_type_id();
		uint16_t	m2 = f2.meta_type_id();
		uint16_t	m3 = i1.meta_type_id();

		REQUIRE(m1 != 0);
		REQUIRE(m1 == m2);
		REQUIRE(m1 != m3);
		REQUIRE( AP_MetaClass::meta_type_equivalent(&f1, &f2));
		REQUIRE(!AP_MetaClass::meta_type_equivalent(&f1, &i1));
	}

	// MetaClass: test external handles
	{
		TEST(meta_handle);

		AP_Float					f;
		AP_MetaClass::AP_MetaHandle	h = f.meta_get_handle();

		REQUIRE(0 != h);
		REQUIRE(NULL != AP_MetaClass::meta_validate_handle(h));
		REQUIRE(NULL == AP_MetaClass::meta_validate_handle(h + 1));
	}

	// MetaClass: test meta_cast
	{
		TEST(meta_cast);

		AP_Float	f;

		REQUIRE(NULL != AP_MetaClass::meta_cast<AP_Float>(&f));
		REQUIRE(NULL == AP_MetaClass::meta_cast<AP_Int8>(&f));
	}

	// MetaClass: ... insert tests here ...

	// AP_Var: cast to type
	{
		TEST(var_cast_to_type);

		AP_Float	f(10.0);	REQUIRE(f == 10.0);
		f = 1.0;				REQUIRE(f == 1.0);
		f *= 2.0;				REQUIRE(f == 2.0);
		f /= 4;					REQUIRE(f == 0.5);
		f += f;					REQUIRE(f == 1.0);
	}

	// AP_Var: naming
	{
		TEST(var_naming);

		AP_Float	f(1.0, AP_Var::AP_VarNoAddress, PSTR("test"));
		char		name_buffer[16];

		f.copy_name(name_buffer, sizeof(name_buffer));
		REQUIRE(!strcmp(name_buffer, "test"));
	}

	// AP_Var: serialize
	{
		TEST(var_serialize);

		float		b = 0;
		AP_Float	f(10);
		size_t		s;

		s = f.serialize(&b, sizeof(b));
		REQUIRE(s == sizeof(b));
		REQUIRE(b == 10);
	}

	// AP_Var: unserialize
	{
		TEST(var_unserialize);

		float		b = 10;
		AP_Float	f(0);
		size_t		s;

		s = f.unserialize(&b, sizeof(b));
		REQUIRE(s == sizeof(b));
		REQUIRE(f == 10);
	}

	// AP_Var: load and save
	{
		TEST(var_load_save);

		AP_Float	f1(10, 4);
		AP_Float	f2(0,  4);

		f2.save();
		f2.load();
		REQUIRE(f2 == 0);

		f1.save();
		f2.load();
		REQUIRE(f2 == 10);
	}

	// AP_Var: enumeration
	// note that this test presumes the singly-linked list implementation of the list
	{
		TEST(var_enumeration);

		// test basic enumeration
		AP_Float f1(1.0, AP_Var::AP_VarNoAddress, PSTR("test1"));
		REQUIRE(AP_Var::lookup(0) == &f1);
		REQUIRE(AP_Var::lookup(1) == NULL);

		// test that new entries arrive in order
		{
			AP_Float f2(2.0, AP_Var::AP_VarNoAddress, PSTR("test2"));
			REQUIRE(AP_Var::lookup(0) == &f2);
			REQUIRE(AP_Var::lookup(1) == &f1);
			REQUIRE(AP_Var::lookup(2) == NULL);
		}

		// test that destruction removes from the list
		REQUIRE(AP_Var::lookup(0) == &f1);
		REQUIRE(AP_Var::lookup(1) == NULL);
	}

	// AP_Var: scope names
	{
		TEST(var_scope_names);

		AP_VarScope		scope(PSTR("scope_"));
		AP_Float		f(1.0, AP_Var::AP_VarNoAddress, PSTR("test"), &scope);
		char			name_buffer[16];

		f.copy_name(name_buffer, sizeof(name_buffer));
		REQUIRE(!strcmp(name_buffer, "scope_test"));
	}

	// AP_Var: scope address offsets
	{
		TEST(var_scope_addressing);

		AP_Float	f1(10.0, 8);
		AP_VarScope	scope(PSTR("scope"), 4);
		AP_Float	f2(1.0, 4, PSTR("var"), &scope);

		f1.save();
		f1.load();
		REQUIRE(f1 == 10);

		f2.save();
		f2.load();
		REQUIRE(f2 == 1);

		f1.load();
		REQUIRE(f1 == 1);
	}

	// AP_Var: derived types
	{
		TEST(var_derived);

		AP_Float16	f1(10.0, 20);

		REQUIRE(f1 == 10.0);
		f1.save();
		f1 = 0;
		REQUIRE(f1 == 0);
		f1.load();
		REQUIRE(f1 = 10.0);
	}


	Test::report();
}

void
loop(void)
{
}
Following discussions with James, a complete rewrite of AP_Var. The overriding principle here is to keep the use of AP_Vars as simple as possible, whilst letting the implementation do useful things behind the scenes. To that end, we define AP_Float, AP_Int8, AP_Int16 and AP_Int32. These are strongly typed, so that there is no ambiguity about what a variable "really" is. The classes behave like the variables they are storing; you can use an AP_Float in most places you would use a regular float; you can add to it, multiply by it, etc. If it has been given an address in EEPROM you can load and save it. Variables can be given names, and if they are named then they can be looked up. This allows e.g. a GCS or a test tool to find and traffic in variables that it may not explicitly know about. AP_Var does not attempt to solve the problem of EEPROM address space management. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1399 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 18:14:36 -04:00			`//`
			`// Unit tests for the AP_MetaClass and AP_Var classes.`
			`//`

			`#include <FastSerial.h>`
			`#include <AP_Common.h>`
Beef up the unit tests for AP_Var. Most of the basic functionality is now covered. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1403 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 22:29:17 -04:00			`#include <string.h>`

			`// we need to do this, even though normally it's a bad idea`
			`#pragma GCC diagnostic ignored "-Wfloat-equal"`
Following discussions with James, a complete rewrite of AP_Var. The overriding principle here is to keep the use of AP_Vars as simple as possible, whilst letting the implementation do useful things behind the scenes. To that end, we define AP_Float, AP_Int8, AP_Int16 and AP_Int32. These are strongly typed, so that there is no ambiguity about what a variable "really" is. The classes behave like the variables they are storing; you can use an AP_Float in most places you would use a regular float; you can add to it, multiply by it, etc. If it has been given an address in EEPROM you can load and save it. Variables can be given names, and if they are named then they can be looked up. This allows e.g. a GCS or a test tool to find and traffic in variables that it may not explicitly know about. AP_Var does not attempt to solve the problem of EEPROM address space management. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1399 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 18:14:36 -04:00
			`FastSerialPort(Serial, 0);`

Beef up the unit tests for AP_Var. Most of the basic functionality is now covered. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1403 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 22:29:17 -04:00			`//`
			`// Unit test framework`
			`//`
			`class Test`
			`{`
			`public:`
			`Test(const char *name) : _name(name), _fail(false) {}`

			`~Test() {`
			`Serial.printf("%s: %s\n", _fail ? "FAILED" : "passed", _name);`
			`if (_fail) {`
			`_failed++;`
			`} else {`
			`_passed++;`
			`}`
			`}`

			`void require(bool expr, const char *source) {`
			`if (!expr) {`
			`_fail = true;`
			`Serial.printf("%s: fail: %s\n", _name, source);`
			`}`
			`}`
Following discussions with James, a complete rewrite of AP_Var. The overriding principle here is to keep the use of AP_Vars as simple as possible, whilst letting the implementation do useful things behind the scenes. To that end, we define AP_Float, AP_Int8, AP_Int16 and AP_Int32. These are strongly typed, so that there is no ambiguity about what a variable "really" is. The classes behave like the variables they are storing; you can use an AP_Float in most places you would use a regular float; you can add to it, multiply by it, etc. If it has been given an address in EEPROM you can load and save it. Variables can be given names, and if they are named then they can be looked up. This allows e.g. a GCS or a test tool to find and traffic in variables that it may not explicitly know about. AP_Var does not attempt to solve the problem of EEPROM address space management. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1399 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 18:14:36 -04:00
Beef up the unit tests for AP_Var. Most of the basic functionality is now covered. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1403 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 22:29:17 -04:00			`static void report() {`
			`Serial.printf("\n%d passed %d failed\n", _passed, _failed);`
			`}`

			`private:`
			`const char *_name;`
			`bool _fail;`
			`static int _passed;`
			`static int _failed;`
			`};`

			`int Test::_passed = 0;`
			`int Test::_failed = 0;`

			`#define TEST(name) Test _test(#name)`
			`#define REQUIRE(expr) _test.require(expr, #expr)`

			`//`
			`// Unit tests`
			`//`
Following discussions with James, a complete rewrite of AP_Var. The overriding principle here is to keep the use of AP_Vars as simple as possible, whilst letting the implementation do useful things behind the scenes. To that end, we define AP_Float, AP_Int8, AP_Int16 and AP_Int32. These are strongly typed, so that there is no ambiguity about what a variable "really" is. The classes behave like the variables they are storing; you can use an AP_Float in most places you would use a regular float; you can add to it, multiply by it, etc. If it has been given an address in EEPROM you can load and save it. Variables can be given names, and if they are named then they can be looked up. This allows e.g. a GCS or a test tool to find and traffic in variables that it may not explicitly know about. AP_Var does not attempt to solve the problem of EEPROM address space management. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1399 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 18:14:36 -04:00			`void`
			`setup(void)`
			`{`
			`Serial.begin(38400);`

			`// MetaClass: test type ID`
			`{`
			`TEST(meta_type_id);`

			`AP_Float f1;`
			`AP_Float f2;`
			`AP_Int8 i1;`

			`uint16_t m1 = f1.meta_type_id();`
			`uint16_t m2 = f2.meta_type_id();`
			`uint16_t m3 = i1.meta_type_id();`

			`REQUIRE(m1 != 0);`
			`REQUIRE(m1 == m2);`
			`REQUIRE(m1 != m3);`
			`REQUIRE( AP_MetaClass::meta_type_equivalent(&f1, &f2));`
			`REQUIRE(!AP_MetaClass::meta_type_equivalent(&f1, &i1));`
			`}`

			`// MetaClass: test external handles`
			`{`
			`TEST(meta_handle);`

			`AP_Float f;`
			`AP_MetaClass::AP_MetaHandle h = f.meta_get_handle();`

			`REQUIRE(0 != h);`
			`REQUIRE(NULL != AP_MetaClass::meta_validate_handle(h));`
			`REQUIRE(NULL == AP_MetaClass::meta_validate_handle(h + 1));`
			`}`

Beef up the unit tests for AP_Var. Most of the basic functionality is now covered. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1403 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 22:29:17 -04:00			`// MetaClass: test meta_cast`
Following discussions with James, a complete rewrite of AP_Var. The overriding principle here is to keep the use of AP_Vars as simple as possible, whilst letting the implementation do useful things behind the scenes. To that end, we define AP_Float, AP_Int8, AP_Int16 and AP_Int32. These are strongly typed, so that there is no ambiguity about what a variable "really" is. The classes behave like the variables they are storing; you can use an AP_Float in most places you would use a regular float; you can add to it, multiply by it, etc. If it has been given an address in EEPROM you can load and save it. Variables can be given names, and if they are named then they can be looked up. This allows e.g. a GCS or a test tool to find and traffic in variables that it may not explicitly know about. AP_Var does not attempt to solve the problem of EEPROM address space management. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1399 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 18:14:36 -04:00			`{`
			`TEST(meta_cast);`

			`AP_Float f;`

			`REQUIRE(NULL != AP_MetaClass::meta_cast<AP_Float>(&f));`
			`REQUIRE(NULL == AP_MetaClass::meta_cast<AP_Int8>(&f));`
			`}`

Beef up the unit tests for AP_Var. Most of the basic functionality is now covered. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1403 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 22:29:17 -04:00			`// MetaClass: ... insert tests here ...`

			`// AP_Var: cast to type`
			`{`
			`TEST(var_cast_to_type);`

More unit tests. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1447 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-05 03:40:35 -04:00			`AP_Float f(10.0); REQUIRE(f == 10.0);`
			`f = 1.0; REQUIRE(f == 1.0);`
Beef up the unit tests for AP_Var. Most of the basic functionality is now covered. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1403 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 22:29:17 -04:00			`f *= 2.0; REQUIRE(f == 2.0);`
			`f /= 4; REQUIRE(f == 0.5);`
			`f += f; REQUIRE(f == 1.0);`
			`}`
Following discussions with James, a complete rewrite of AP_Var. The overriding principle here is to keep the use of AP_Vars as simple as possible, whilst letting the implementation do useful things behind the scenes. To that end, we define AP_Float, AP_Int8, AP_Int16 and AP_Int32. These are strongly typed, so that there is no ambiguity about what a variable "really" is. The classes behave like the variables they are storing; you can use an AP_Float in most places you would use a regular float; you can add to it, multiply by it, etc. If it has been given an address in EEPROM you can load and save it. Variables can be given names, and if they are named then they can be looked up. This allows e.g. a GCS or a test tool to find and traffic in variables that it may not explicitly know about. AP_Var does not attempt to solve the problem of EEPROM address space management. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1399 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 18:14:36 -04:00
Beef up the unit tests for AP_Var. Most of the basic functionality is now covered. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1403 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 22:29:17 -04:00			`// AP_Var: naming`
			`{`
			`TEST(var_naming);`

Unit tests for scope-based address offsetting. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1418 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-04 04:50:24 -04:00			`AP_Float f(1.0, AP_Var::AP_VarNoAddress, PSTR("test"));`
Beef up the unit tests for AP_Var. Most of the basic functionality is now covered. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1403 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 22:29:17 -04:00			`char name_buffer[16];`

			`f.copy_name(name_buffer, sizeof(name_buffer));`
			`REQUIRE(!strcmp(name_buffer, "test"));`
			`}`

			`// AP_Var: serialize`
			`{`
			`TEST(var_serialize);`

			`float b = 0;`
			`AP_Float f(10);`
			`size_t s;`

			`s = f.serialize(&b, sizeof(b));`
			`REQUIRE(s == sizeof(b));`
			`REQUIRE(b == 10);`
			`}`

			`// AP_Var: unserialize`
			`{`
			`TEST(var_unserialize);`

			`float b = 10;`
			`AP_Float f(0);`
			`size_t s;`

			`s = f.unserialize(&b, sizeof(b));`
			`REQUIRE(s == sizeof(b));`
			`REQUIRE(f == 10);`
			`}`

			`// AP_Var: load and save`
			`{`
			`TEST(var_load_save);`

			`AP_Float f1(10, 4);`
			`AP_Float f2(0, 4);`

			`f2.save();`
			`f2.load();`
			`REQUIRE(f2 == 0);`

			`f1.save();`
			`f2.load();`
			`REQUIRE(f2 == 10);`
			`}`

			`// AP_Var: enumeration`
			`// note that this test presumes the singly-linked list implementation of the list`
			`{`
			`TEST(var_enumeration);`

			`// test basic enumeration`
Unit tests for scope-based address offsetting. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1418 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-04 04:50:24 -04:00			`AP_Float f1(1.0, AP_Var::AP_VarNoAddress, PSTR("test1"));`
Beef up the unit tests for AP_Var. Most of the basic functionality is now covered. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1403 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 22:29:17 -04:00			`REQUIRE(AP_Var::lookup(0) == &f1);`
			`REQUIRE(AP_Var::lookup(1) == NULL);`

			`// test that new entries arrive in order`
			`{`
Unit tests for scope-based address offsetting. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1418 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-04 04:50:24 -04:00			`AP_Float f2(2.0, AP_Var::AP_VarNoAddress, PSTR("test2"));`
Beef up the unit tests for AP_Var. Most of the basic functionality is now covered. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1403 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 22:29:17 -04:00			`REQUIRE(AP_Var::lookup(0) == &f2);`
			`REQUIRE(AP_Var::lookup(1) == &f1);`
			`REQUIRE(AP_Var::lookup(2) == NULL);`
			`}`

			`// test that destruction removes from the list`
			`REQUIRE(AP_Var::lookup(0) == &f1);`
			`REQUIRE(AP_Var::lookup(1) == NULL);`
			`}`

Unit tests for scope-based address offsetting. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1418 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-04 04:50:24 -04:00			`// AP_Var: scope names`
			`{`
			`TEST(var_scope_names);`

			`AP_VarScope scope(PSTR("scope_"));`
			`AP_Float f(1.0, AP_Var::AP_VarNoAddress, PSTR("test"), &scope);`
			`char name_buffer[16];`

			`f.copy_name(name_buffer, sizeof(name_buffer));`
			`REQUIRE(!strcmp(name_buffer, "scope_test"));`
			`}`

			`// AP_Var: scope address offsets`
			`{`
			`TEST(var_scope_addressing);`

			`AP_Float f1(10.0, 8);`
			`AP_VarScope scope(PSTR("scope"), 4);`
			`AP_Float f2(1.0, 4, PSTR("var"), &scope);`

			`f1.save();`
			`f1.load();`
			`REQUIRE(f1 == 10);`

			`f2.save();`
			`f2.load();`
			`REQUIRE(f2 == 1);`

			`f1.load();`
			`REQUIRE(f1 == 1);`
			`}`

More unit tests. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1447 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-05 03:40:35 -04:00			`// AP_Var: derived types`
			`{`
			`TEST(var_derived);`

			`AP_Float16 f1(10.0, 20);`

			`REQUIRE(f1 == 10.0);`
			`f1.save();`
			`f1 = 0;`
			`REQUIRE(f1 == 0);`
			`f1.load();`
			`REQUIRE(f1 = 10.0);`
			`}`

Unit tests for scope-based address offsetting. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1418 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-04 04:50:24 -04:00
Beef up the unit tests for AP_Var. Most of the basic functionality is now covered. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1403 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 22:29:17 -04:00			`Test::report();`
			`}`
Following discussions with James, a complete rewrite of AP_Var. The overriding principle here is to keep the use of AP_Vars as simple as possible, whilst letting the implementation do useful things behind the scenes. To that end, we define AP_Float, AP_Int8, AP_Int16 and AP_Int32. These are strongly typed, so that there is no ambiguity about what a variable "really" is. The classes behave like the variables they are storing; you can use an AP_Float in most places you would use a regular float; you can add to it, multiply by it, etc. If it has been given an address in EEPROM you can load and save it. Variables can be given names, and if they are named then they can be looked up. This allows e.g. a GCS or a test tool to find and traffic in variables that it may not explicitly know about. AP_Var does not attempt to solve the problem of EEPROM address space management. git-svn-id: https://arducopter.googlecode.com/svn/trunk@1399 f9c3cf11-9bcb-44bc-f272-b75c42450872 2011-01-02 18:14:36 -04:00
			`void`
			`loop(void)`
			`{`
			`}`