lib/test_linear_ranges.c - pub/scm/linux/kernel/git/cem/xfs-linux - Git at Google

 // 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[] = {
 	{
 		.min = RANGE1_MIN,
 		.min_sel = RANGE1_MIN_SEL,
 		.max_sel = RANGE1_MAX_SEL,
 		.step = RANGE1_STEP,
 	}, {
 		.min = RANGE2_MIN,
 		.min_sel = RANGE2_MIN_SEL,
 		.max_sel = RANGE2_MAX_SEL,
 		.step = RANGE2_STEP
 	},
 };

 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);

 MODULE_LICENSE("GPL");
	// 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[] = {
	{
	.min = RANGE1_MIN,
	.min_sel = RANGE1_MIN_SEL,
	.max_sel = RANGE1_MAX_SEL,
	.step = RANGE1_STEP,
	}, {
	.min = RANGE2_MIN,
	.min_sel = RANGE2_MIN_SEL,
	.max_sel = RANGE2_MAX_SEL,
	.step = RANGE2_STEP
	},
	};

	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);

	MODULE_LICENSE("GPL");