2020-05-08 18:40:43 +03:00
// SPDX-License-Identifier: GPL-2.0
/*
* KUnit test for the linear_ranges helper .
*
* Copyright ( C ) 2020 , ROHM Semiconductors .
* Author : Matti Vaittinen < matti . vaittien @ fi . rohmeurope . com >
*/
# include <kunit/test.h>
# include <linux/linear_range.h>
/* First things first. I deeply dislike unit-tests. I have seen all the hell
* breaking loose when people who think the unit tests are " the silver bullet "
* to kill bugs get to decide how a company should implement testing strategy . . .
*
* Believe me , it may get _really_ ridiculous . It is tempting to think that
* walking through all the possible execution branches will nail down 100 % of
* bugs . This may lead to ideas about demands to get certain % of " test
* coverage " - measured as line coverage. And that is one of the worst things
* you can do .
*
* Ask people to provide line coverage and they do . I ' ve seen clever tools
* which generate test cases to test the existing functions - and by default
* these tools expect code to be correct and just generate checks which are
* passing when ran against current code - base . Run this generator and you ' ll get
* tests that do not test code is correct but just verify nothing changes .
* Problem is that testing working code is pointless . And if it is not
* working , your test must not assume it is working . You won ' t catch any bugs
* by such tests . What you can do is to generate a huge amount of tests .
* Especially if you were are asked to proivde 100 % line - coverage x_x . So what
* does these tests - which are not finding any bugs now - do ?
*
* They add inertia to every future development . I think it was Terry Pratchet
* who wrote someone having same impact as thick syrup has to chronometre .
* Excessive amount of unit - tests have this effect to development . If you do
* actually find _any_ bug from code in such environment and try fixing it . . .
* . . . chances are you also need to fix the test cases . In sunny day you fix one
* test . But I ' ve done refactoring which resulted 500 + broken tests ( which had
* really zero value other than proving to managers that we do do " quality " ) . . .
*
* After this being said - there are situations where UTs can be handy . If you
* have algorithms which take some input and should produce output - then you
* can implement few , carefully selected simple UT - cases which test this . I ' ve
* previously used this for example for netlink and device - tree data parsing
* functions . Feed some data examples to functions and verify the output is as
* expected . I am not covering all the cases but I will see the logic should be
* working .
*
* Here we also do some minor testing . I don ' t want to go through all branches
* or test more or less obvious things - but I want to see the main logic is
* working . And I definitely don ' t want to add 500 + test cases that break when
* some simple fix is done x_x . So - let ' s only add few , well selected tests
* which ensure as much logic is good as possible .
*/
/*
* Test Range 1 :
* selectors : 2 3 4 5 6
* values ( 5 ) : 10 20 30 40 50
*
* Test Range 2 :
* selectors : 7 8 9 10
* values ( 4 ) : 100 150 200 250
*/
# define RANGE1_MIN 10
# define RANGE1_MIN_SEL 2
# define RANGE1_STEP 10
/* 2, 3, 4, 5, 6 */
static const unsigned int range1_sels [ ] = { RANGE1_MIN_SEL , RANGE1_MIN_SEL + 1 ,
RANGE1_MIN_SEL + 2 ,
RANGE1_MIN_SEL + 3 ,
RANGE1_MIN_SEL + 4 } ;
/* 10, 20, 30, 40, 50 */
static const unsigned int range1_vals [ ] = { RANGE1_MIN , RANGE1_MIN +
RANGE1_STEP ,
RANGE1_MIN + RANGE1_STEP * 2 ,
RANGE1_MIN + RANGE1_STEP * 3 ,
RANGE1_MIN + RANGE1_STEP * 4 } ;
# define RANGE2_MIN 100
# define RANGE2_MIN_SEL 7
# define RANGE2_STEP 50
/* 7, 8, 9, 10 */
static const unsigned int range2_sels [ ] = { RANGE2_MIN_SEL , RANGE2_MIN_SEL + 1 ,
RANGE2_MIN_SEL + 2 ,
RANGE2_MIN_SEL + 3 } ;
/* 100, 150, 200, 250 */
static const unsigned int range2_vals [ ] = { RANGE2_MIN , RANGE2_MIN +
RANGE2_STEP ,
RANGE2_MIN + RANGE2_STEP * 2 ,
RANGE2_MIN + RANGE2_STEP * 3 } ;
# define RANGE1_NUM_VALS (ARRAY_SIZE(range1_vals))
# define RANGE2_NUM_VALS (ARRAY_SIZE(range2_vals))
# define RANGE_NUM_VALS (RANGE1_NUM_VALS + RANGE2_NUM_VALS)
# define RANGE1_MAX_SEL (RANGE1_MIN_SEL + RANGE1_NUM_VALS - 1)
# define RANGE1_MAX_VAL (range1_vals[RANGE1_NUM_VALS - 1])
# define RANGE2_MAX_SEL (RANGE2_MIN_SEL + RANGE2_NUM_VALS - 1)
# define RANGE2_MAX_VAL (range2_vals[RANGE2_NUM_VALS - 1])
# define SMALLEST_SEL RANGE1_MIN_SEL
# define SMALLEST_VAL RANGE1_MIN
static struct linear_range testr [ ] = {
2022-11-16 08:32:12 +03:00
LINEAR_RANGE ( RANGE1_MIN , RANGE1_MIN_SEL , RANGE1_MAX_SEL , RANGE1_STEP ) ,
LINEAR_RANGE ( RANGE2_MIN , RANGE2_MIN_SEL , RANGE2_MAX_SEL , RANGE2_STEP ) ,
2020-05-08 18:40:43 +03:00
} ;
static void range_test_get_value ( struct kunit * test )
{
int ret , i ;
unsigned int sel , val ;
for ( i = 0 ; i < RANGE1_NUM_VALS ; i + + ) {
sel = range1_sels [ i ] ;
ret = linear_range_get_value_array ( & testr [ 0 ] , 2 , sel , & val ) ;
KUNIT_EXPECT_EQ ( test , 0 , ret ) ;
KUNIT_EXPECT_EQ ( test , val , range1_vals [ i ] ) ;
}
for ( i = 0 ; i < RANGE2_NUM_VALS ; i + + ) {
sel = range2_sels [ i ] ;
ret = linear_range_get_value_array ( & testr [ 0 ] , 2 , sel , & val ) ;
KUNIT_EXPECT_EQ ( test , 0 , ret ) ;
KUNIT_EXPECT_EQ ( test , val , range2_vals [ i ] ) ;
}
ret = linear_range_get_value_array ( & testr [ 0 ] , 2 , sel + 1 , & val ) ;
KUNIT_EXPECT_NE ( test , 0 , ret ) ;
}
static void range_test_get_selector_high ( struct kunit * test )
{
int ret , i ;
unsigned int sel ;
bool found ;
for ( i = 0 ; i < RANGE1_NUM_VALS ; i + + ) {
ret = linear_range_get_selector_high ( & testr [ 0 ] , range1_vals [ i ] ,
& sel , & found ) ;
KUNIT_EXPECT_EQ ( test , 0 , ret ) ;
KUNIT_EXPECT_EQ ( test , sel , range1_sels [ i ] ) ;
KUNIT_EXPECT_TRUE ( test , found ) ;
}
ret = linear_range_get_selector_high ( & testr [ 0 ] , RANGE1_MAX_VAL + 1 ,
& sel , & found ) ;
KUNIT_EXPECT_LE ( test , ret , 0 ) ;
ret = linear_range_get_selector_high ( & testr [ 0 ] , RANGE1_MIN - 1 ,
& sel , & found ) ;
KUNIT_EXPECT_EQ ( test , 0 , ret ) ;
KUNIT_EXPECT_FALSE ( test , found ) ;
KUNIT_EXPECT_EQ ( test , sel , range1_sels [ 0 ] ) ;
}
static void range_test_get_value_amount ( struct kunit * test )
{
int ret ;
ret = linear_range_values_in_range_array ( & testr [ 0 ] , 2 ) ;
KUNIT_EXPECT_EQ ( test , ( int ) RANGE_NUM_VALS , ret ) ;
}
static void range_test_get_selector_low ( struct kunit * test )
{
int i , ret ;
unsigned int sel ;
bool found ;
for ( i = 0 ; i < RANGE1_NUM_VALS ; i + + ) {
ret = linear_range_get_selector_low_array ( & testr [ 0 ] , 2 ,
range1_vals [ i ] , & sel ,
& found ) ;
KUNIT_EXPECT_EQ ( test , 0 , ret ) ;
KUNIT_EXPECT_EQ ( test , sel , range1_sels [ i ] ) ;
KUNIT_EXPECT_TRUE ( test , found ) ;
}
for ( i = 0 ; i < RANGE2_NUM_VALS ; i + + ) {
ret = linear_range_get_selector_low_array ( & testr [ 0 ] , 2 ,
range2_vals [ i ] , & sel ,
& found ) ;
KUNIT_EXPECT_EQ ( test , 0 , ret ) ;
KUNIT_EXPECT_EQ ( test , sel , range2_sels [ i ] ) ;
KUNIT_EXPECT_TRUE ( test , found ) ;
}
/*
* Seek value greater than range max = > get_selector_ * _low should
* return Ok - but set found to false as value is not in range
*/
ret = linear_range_get_selector_low_array ( & testr [ 0 ] , 2 ,
range2_vals [ RANGE2_NUM_VALS - 1 ] + 1 ,
& sel , & found ) ;
KUNIT_EXPECT_EQ ( test , 0 , ret ) ;
KUNIT_EXPECT_EQ ( test , sel , range2_sels [ RANGE2_NUM_VALS - 1 ] ) ;
KUNIT_EXPECT_FALSE ( test , found ) ;
}
static struct kunit_case range_test_cases [ ] = {
KUNIT_CASE ( range_test_get_value_amount ) ,
KUNIT_CASE ( range_test_get_selector_high ) ,
KUNIT_CASE ( range_test_get_selector_low ) ,
KUNIT_CASE ( range_test_get_value ) ,
{ } ,
} ;
static struct kunit_suite range_test_module = {
. name = " linear-ranges-test " ,
. test_cases = range_test_cases ,
} ;
kunit_test_suites ( & range_test_module ) ;
2024-06-01 02:45:16 +03:00
MODULE_DESCRIPTION ( " KUnit test for the linear_ranges helper " ) ;
2020-05-08 18:40:43 +03:00
MODULE_LICENSE ( " GPL " ) ;