/* * Copyright © 2014 Red Hat, Inc. * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice (including the next * paragraph) shall be included in all copies or substantial portions of the * Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. */ #include #include #include #include #include "libinput-util.h" #define TEST_VERSIONSORT #include "libinput-versionsort.h" #include "check-double-macros.h" START_TEST(bitfield_helpers) { /* This value has a bit set on all of the word boundaries we want to * test: 0, 1, 7, 8, 31, 32, and 33 */ unsigned char read_bitfield[] = { 0x83, 0x1, 0x0, 0x80, 0x3 }; unsigned char write_bitfield[ARRAY_LENGTH(read_bitfield)] = {0}; size_t i; /* Now check that the bitfield we wrote to came out to be the same as * the bitfield we were writing from */ for (i = 0; i < ARRAY_LENGTH(read_bitfield) * 8; i++) { switch (i) { case 0: case 1: case 7: case 8: case 31: case 32: case 33: ck_assert(bit_is_set(read_bitfield, i)); set_bit(write_bitfield, i); break; default: ck_assert(!bit_is_set(read_bitfield, i)); clear_bit(write_bitfield, i); break; } } ck_assert_int_eq(memcmp(read_bitfield, write_bitfield, sizeof(read_bitfield)), 0); } END_TEST START_TEST(matrix_helpers) { struct matrix m1, m2, m3; float f[6] = { 1, 2, 3, 4, 5, 6 }; int x, y; int row, col; matrix_init_identity(&m1); for (row = 0; row < 3; row++) { for (col = 0; col < 3; col++) { ck_assert_int_eq(m1.val[row][col], (row == col) ? 1 : 0); } } ck_assert(matrix_is_identity(&m1)); matrix_from_farray6(&m2, f); ck_assert_int_eq(m2.val[0][0], 1); ck_assert_int_eq(m2.val[0][1], 2); ck_assert_int_eq(m2.val[0][2], 3); ck_assert_int_eq(m2.val[1][0], 4); ck_assert_int_eq(m2.val[1][1], 5); ck_assert_int_eq(m2.val[1][2], 6); ck_assert_int_eq(m2.val[2][0], 0); ck_assert_int_eq(m2.val[2][1], 0); ck_assert_int_eq(m2.val[2][2], 1); x = 100; y = 5; matrix_mult_vec(&m1, &x, &y); ck_assert_int_eq(x, 100); ck_assert_int_eq(y, 5); matrix_mult(&m3, &m1, &m1); ck_assert(matrix_is_identity(&m3)); matrix_init_scale(&m2, 2, 4); ck_assert_int_eq(m2.val[0][0], 2); ck_assert_int_eq(m2.val[0][1], 0); ck_assert_int_eq(m2.val[0][2], 0); ck_assert_int_eq(m2.val[1][0], 0); ck_assert_int_eq(m2.val[1][1], 4); ck_assert_int_eq(m2.val[1][2], 0); ck_assert_int_eq(m2.val[2][0], 0); ck_assert_int_eq(m2.val[2][1], 0); ck_assert_int_eq(m2.val[2][2], 1); matrix_mult_vec(&m2, &x, &y); ck_assert_int_eq(x, 200); ck_assert_int_eq(y, 20); matrix_init_translate(&m2, 10, 100); ck_assert_int_eq(m2.val[0][0], 1); ck_assert_int_eq(m2.val[0][1], 0); ck_assert_int_eq(m2.val[0][2], 10); ck_assert_int_eq(m2.val[1][0], 0); ck_assert_int_eq(m2.val[1][1], 1); ck_assert_int_eq(m2.val[1][2], 100); ck_assert_int_eq(m2.val[2][0], 0); ck_assert_int_eq(m2.val[2][1], 0); ck_assert_int_eq(m2.val[2][2], 1); matrix_mult_vec(&m2, &x, &y); ck_assert_int_eq(x, 210); ck_assert_int_eq(y, 120); matrix_to_farray6(&m2, f); ck_assert_int_eq(f[0], 1); ck_assert_int_eq(f[1], 0); ck_assert_int_eq(f[2], 10); ck_assert_int_eq(f[3], 0); ck_assert_int_eq(f[4], 1); ck_assert_int_eq(f[5], 100); } END_TEST START_TEST(ratelimit_helpers) { struct ratelimit rl; unsigned int i, j; /* 10 attempts every 1000ms */ ratelimit_init(&rl, ms2us(1000), 10); for (j = 0; j < 3; ++j) { /* a burst of 9 attempts must succeed */ for (i = 0; i < 9; ++i) { ck_assert_int_eq(ratelimit_test(&rl), RATELIMIT_PASS); } /* the 10th attempt reaches the threshold */ ck_assert_int_eq(ratelimit_test(&rl), RATELIMIT_THRESHOLD); /* ..then further attempts must fail.. */ ck_assert_int_eq(ratelimit_test(&rl), RATELIMIT_EXCEEDED); /* ..regardless of how often we try. */ for (i = 0; i < 100; ++i) { ck_assert_int_eq(ratelimit_test(&rl), RATELIMIT_EXCEEDED); } /* ..even after waiting 20ms */ msleep(100); for (i = 0; i < 100; ++i) { ck_assert_int_eq(ratelimit_test(&rl), RATELIMIT_EXCEEDED); } /* but after 1000ms the counter is reset */ msleep(950); /* +50ms to account for time drifts */ } } END_TEST struct parser_test { char *tag; int expected_value; }; START_TEST(dpi_parser) { struct parser_test tests[] = { { "450 *1800 3200", 1800 }, { "*450 1800 3200", 450 }, { "450 1800 *3200", 3200 }, { "450 1800 3200", 3200 }, { "450 1800 failboat", 0 }, { "450 1800 *failboat", 0 }, { "0 450 1800 *3200", 0 }, { "450@37 1800@12 *3200@6", 3200 }, { "450@125 1800@125 *3200@125 ", 3200 }, { "450@125 *1800@125 3200@125", 1800 }, { "*this @string fails", 0 }, { "12@34 *45@", 0 }, { "12@a *45@", 0 }, { "12@a *45@25", 0 }, { " * 12, 450, 800", 0 }, { " *12, 450, 800", 12 }, { "*12, *450, 800", 12 }, { "*-23412, 450, 800", 0 }, { "112@125, 450@125, 800@125, 900@-125", 0 }, { "", 0 }, { " ", 0 }, { "* ", 0 }, { NULL, 0 } }; int i, dpi; for (i = 0; tests[i].tag != NULL; i++) { dpi = parse_mouse_dpi_property(tests[i].tag); ck_assert_int_eq(dpi, tests[i].expected_value); } dpi = parse_mouse_dpi_property(NULL); ck_assert_int_eq(dpi, 0); } END_TEST START_TEST(wheel_click_parser) { struct parser_test tests[] = { { "1", 1 }, { "10", 10 }, { "-12", -12 }, { "360", 360 }, { "0", 0 }, { "-0", 0 }, { "a", 0 }, { "10a", 0 }, { "10-", 0 }, { "sadfasfd", 0 }, { "361", 0 }, { NULL, 0 } }; int i, angle; for (i = 0; tests[i].tag != NULL; i++) { angle = parse_mouse_wheel_click_angle_property(tests[i].tag); ck_assert_int_eq(angle, tests[i].expected_value); } } END_TEST START_TEST(wheel_click_count_parser) { struct parser_test tests[] = { { "1", 1 }, { "10", 10 }, { "-12", -12 }, { "360", 360 }, { "0", 0 }, { "-0", 0 }, { "a", 0 }, { "10a", 0 }, { "10-", 0 }, { "sadfasfd", 0 }, { "361", 0 }, { NULL, 0 } }; int i, angle; for (i = 0; tests[i].tag != NULL; i++) { angle = parse_mouse_wheel_click_count_property(tests[i].tag); ck_assert_int_eq(angle, tests[i].expected_value); } angle = parse_mouse_wheel_click_count_property(NULL); ck_assert_int_eq(angle, 0); } END_TEST START_TEST(dimension_prop_parser) { struct parser_test_dimension { char *tag; bool success; int x, y; } tests[] = { { "10x10", true, 10, 10 }, { "1x20", true, 1, 20 }, { "1x8000", true, 1, 8000 }, { "238492x428210", true, 238492, 428210 }, { "0x0", false, 0, 0 }, { "-10x10", false, 0, 0 }, { "-1", false, 0, 0 }, { "1x-99", false, 0, 0 }, { "0", false, 0, 0 }, { "100", false, 0, 0 }, { "", false, 0, 0 }, { "abd", false, 0, 0 }, { "xabd", false, 0, 0 }, { "0xaf", false, 0, 0 }, { "0x0x", false, 0, 0 }, { "x10", false, 0, 0 }, { NULL, false, 0, 0 } }; int i; size_t x, y; bool success; for (i = 0; tests[i].tag != NULL; i++) { x = y = 0xad; success = parse_dimension_property(tests[i].tag, &x, &y); ck_assert(success == tests[i].success); if (success) { ck_assert_int_eq(x, tests[i].x); ck_assert_int_eq(y, tests[i].y); } else { ck_assert_int_eq(x, 0xad); ck_assert_int_eq(y, 0xad); } } success = parse_dimension_property(NULL, &x, &y); ck_assert(success == false); } END_TEST START_TEST(reliability_prop_parser) { struct parser_test_reliability { char *tag; bool success; enum switch_reliability reliability; } tests[] = { { "reliable", true, RELIABILITY_RELIABLE }, { "unreliable", false, 0 }, { "", false, 0 }, { "0", false, 0 }, { "1", false, 0 }, { NULL, false, 0, } }; enum switch_reliability r; bool success; int i; for (i = 0; tests[i].tag != NULL; i++) { r = 0xaf; success = parse_switch_reliability_property(tests[i].tag, &r); ck_assert(success == tests[i].success); if (success) ck_assert_int_eq(r, tests[i].reliability); else ck_assert_int_eq(r, 0xaf); } success = parse_switch_reliability_property(NULL, &r); ck_assert(success == true); ck_assert_int_eq(r, RELIABILITY_UNKNOWN); success = parse_switch_reliability_property("foo", NULL); ck_assert(success == false); } END_TEST START_TEST(calibration_prop_parser) { #define DEFAULT_VALUES { 1.0, 2.0, 3.0, 4.0, 5.0, 6.0 } const float untouched[6] = DEFAULT_VALUES; struct parser_test_calibration { char *prop; bool success; float values[6]; } tests[] = { { "", false, DEFAULT_VALUES }, { "banana", false, DEFAULT_VALUES }, { "1 2 3 a 5 6", false, DEFAULT_VALUES }, { "2", false, DEFAULT_VALUES }, { "2 3 4 5 6", false, DEFAULT_VALUES }, { "1 2 3 4 5 6", true, DEFAULT_VALUES }, { "6.00012 3.244 4.238 5.2421 6.0134 8.860", true, { 6.00012, 3.244, 4.238, 5.2421, 6.0134, 8.860 }}, { "0xff 2 3 4 5 6", false, DEFAULT_VALUES }, { NULL, false, DEFAULT_VALUES } }; bool success; float calibration[6]; int rc; int i; for (i = 0; tests[i].prop != NULL; i++) { memcpy(calibration, untouched, sizeof(calibration)); success = parse_calibration_property(tests[i].prop, calibration); ck_assert_int_eq(success, tests[i].success); if (success) rc = memcmp(tests[i].values, calibration, sizeof(calibration)); else rc = memcmp(untouched, calibration, sizeof(calibration)); ck_assert_int_eq(rc, 0); } memcpy(calibration, untouched, sizeof(calibration)); success = parse_calibration_property(NULL, calibration); ck_assert(success == false); rc = memcmp(untouched, calibration, sizeof(calibration)); ck_assert_int_eq(rc, 0); } END_TEST START_TEST(range_prop_parser) { struct parser_test_range { char *tag; bool success; int hi, lo; } tests[] = { { "10:8", true, 10, 8 }, { "100:-1", true, 100, -1 }, { "-203813:-502023", true, -203813, -502023 }, { "238492:28210", true, 238492, 28210 }, { "none", true, 0, 0 }, { "0:0", false, 0, 0 }, { "", false, 0, 0 }, { "abcd", false, 0, 0 }, { "10:30:10", false, 0, 0 }, { NULL, false, 0, 0 } }; int i; int hi, lo; bool success; for (i = 0; tests[i].tag != NULL; i++) { hi = lo = 0xad; success = parse_range_property(tests[i].tag, &hi, &lo); ck_assert(success == tests[i].success); if (success) { ck_assert_int_eq(hi, tests[i].hi); ck_assert_int_eq(lo, tests[i].lo); } else { ck_assert_int_eq(hi, 0xad); ck_assert_int_eq(lo, 0xad); } } success = parse_range_property(NULL, NULL, NULL); ck_assert(success == false); } END_TEST START_TEST(evcode_prop_parser) { struct parser_test_tuple { const char *prop; bool success; size_t ntuples; int tuples[20]; } tests[] = { { "EV_KEY", true, 1, {EV_KEY, 0xffff} }, { "EV_ABS;", true, 1, {EV_ABS, 0xffff} }, { "ABS_X;", true, 1, {EV_ABS, ABS_X} }, { "SW_TABLET_MODE;", true, 1, {EV_SW, SW_TABLET_MODE} }, { "EV_SW", true, 1, {EV_SW, 0xffff} }, { "ABS_Y", true, 1, {EV_ABS, ABS_Y} }, { "EV_ABS:0x00", true, 1, {EV_ABS, ABS_X} }, { "EV_ABS:01", true, 1, {EV_ABS, ABS_Y} }, { "ABS_TILT_X;ABS_TILT_Y;", true, 2, { EV_ABS, ABS_TILT_X, EV_ABS, ABS_TILT_Y} }, { "BTN_TOOL_DOUBLETAP;EV_KEY;KEY_A", true, 3, { EV_KEY, BTN_TOOL_DOUBLETAP, EV_KEY, 0xffff, EV_KEY, KEY_A } }, { "REL_Y;ABS_Z;BTN_STYLUS", true, 3, { EV_REL, REL_Y, EV_ABS, ABS_Z, EV_KEY, BTN_STYLUS } }, { "REL_Y;EV_KEY:0x123;BTN_STYLUS", true, 3, { EV_REL, REL_Y, EV_KEY, 0x123, EV_KEY, BTN_STYLUS } }, { .prop = "", .success = false }, { .prop = "EV_FOO", .success = false }, { .prop = "EV_KEY;EV_FOO", .success = false }, { .prop = "BTN_STYLUS;EV_FOO", .success = false }, { .prop = "BTN_UNKNOWN", .success = false }, { .prop = "BTN_UNKNOWN;EV_KEY", .success = false }, { .prop = "PR_UNKNOWN", .success = false }, { .prop = "BTN_STYLUS;PR_UNKNOWN;ABS_X", .success = false }, { .prop = "EV_REL:0xffff", .success = false }, { .prop = "EV_REL:0x123.", .success = false }, { .prop = "EV_REL:ffff", .success = false }, { .prop = "EV_REL:blah", .success = false }, { .prop = "KEY_A:0x11", .success = false }, { .prop = "EV_KEY:0x11 ", .success = false }, { .prop = "EV_KEY:0x11not", .success = false }, { .prop = "none", .success = false }, { .prop = NULL }, }; struct parser_test_tuple *t; for (int i = 0; tests[i].prop; i++) { bool success; struct input_event events[32]; size_t nevents = ARRAY_LENGTH(events); t = &tests[i]; success = parse_evcode_property(t->prop, events, &nevents); ck_assert(success == t->success); if (!success) continue; ck_assert_int_eq(nevents, t->ntuples); for (size_t j = 0; j < nevents; j++) { int type, code; type = events[j].type; code = events[j].code; ck_assert_int_eq(t->tuples[j * 2], type); ck_assert_int_eq(t->tuples[j * 2 + 1], code); } } } END_TEST START_TEST(time_conversion) { ck_assert_int_eq(us(10), 10); ck_assert_int_eq(ns2us(10000), 10); ck_assert_int_eq(ms2us(10), 10000); ck_assert_int_eq(s2us(1), 1000000); ck_assert_int_eq(us2ms(10000), 10); } END_TEST struct atoi_test { char *str; bool success; int val; }; START_TEST(safe_atoi_test) { struct atoi_test tests[] = { { "10", true, 10 }, { "20", true, 20 }, { "-1", true, -1 }, { "2147483647", true, 2147483647 }, { "-2147483648", true, -2147483648 }, { "4294967295", false, 0 }, { "0x0", false, 0 }, { "-10x10", false, 0 }, { "1x-99", false, 0 }, { "", false, 0 }, { "abd", false, 0 }, { "xabd", false, 0 }, { "0xaf", false, 0 }, { "0x0x", false, 0 }, { "x10", false, 0 }, { NULL, false, 0 } }; int v; bool success; for (int i = 0; tests[i].str != NULL; i++) { v = 0xad; success = safe_atoi(tests[i].str, &v); ck_assert(success == tests[i].success); if (success) ck_assert_int_eq(v, tests[i].val); else ck_assert_int_eq(v, 0xad); } } END_TEST START_TEST(safe_atoi_base_16_test) { struct atoi_test tests[] = { { "10", true, 0x10 }, { "20", true, 0x20 }, { "-1", true, -1 }, { "0x10", true, 0x10 }, { "0xff", true, 0xff }, { "abc", true, 0xabc }, { "-10", true, -0x10 }, { "0x0", true, 0 }, { "0", true, 0 }, { "0x-99", false, 0 }, { "0xak", false, 0 }, { "0x", false, 0 }, { "x10", false, 0 }, { NULL, false, 0 } }; int v; bool success; for (int i = 0; tests[i].str != NULL; i++) { v = 0xad; success = safe_atoi_base(tests[i].str, &v, 16); ck_assert(success == tests[i].success); if (success) ck_assert_int_eq(v, tests[i].val); else ck_assert_int_eq(v, 0xad); } } END_TEST START_TEST(safe_atoi_base_8_test) { struct atoi_test tests[] = { { "7", true, 07 }, { "10", true, 010 }, { "20", true, 020 }, { "-1", true, -1 }, { "010", true, 010 }, { "0ff", false, 0 }, { "abc", false, 0}, { "0xabc", false, 0}, { "-10", true, -010 }, { "0", true, 0 }, { "00", true, 0 }, { "0x0", false, 0 }, { "0x-99", false, 0 }, { "0xak", false, 0 }, { "0x", false, 0 }, { "x10", false, 0 }, { NULL, false, 0 } }; int v; bool success; for (int i = 0; tests[i].str != NULL; i++) { v = 0xad; success = safe_atoi_base(tests[i].str, &v, 8); ck_assert(success == tests[i].success); if (success) ck_assert_int_eq(v, tests[i].val); else ck_assert_int_eq(v, 0xad); } } END_TEST struct atou_test { char *str; bool success; unsigned int val; }; START_TEST(safe_atou_test) { struct atou_test tests[] = { { "10", true, 10 }, { "20", true, 20 }, { "-1", false, 0 }, { "2147483647", true, 2147483647 }, { "-2147483648", false, 0}, { "0x0", false, 0 }, { "-10x10", false, 0 }, { "1x-99", false, 0 }, { "", false, 0 }, { "abd", false, 0 }, { "xabd", false, 0 }, { "0xaf", false, 0 }, { "0x0x", false, 0 }, { "x10", false, 0 }, { NULL, false, 0 } }; unsigned int v; bool success; for (int i = 0; tests[i].str != NULL; i++) { v = 0xad; success = safe_atou(tests[i].str, &v); ck_assert(success == tests[i].success); if (success) ck_assert_int_eq(v, tests[i].val); else ck_assert_int_eq(v, 0xad); } } END_TEST START_TEST(safe_atou_base_16_test) { struct atou_test tests[] = { { "10", true, 0x10 }, { "20", true, 0x20 }, { "-1", false, 0 }, { "0x10", true, 0x10 }, { "0xff", true, 0xff }, { "abc", true, 0xabc }, { "-10", false, 0 }, { "0x0", true, 0 }, { "0", true, 0 }, { "0x-99", false, 0 }, { "0xak", false, 0 }, { "0x", false, 0 }, { "x10", false, 0 }, { NULL, false, 0 } }; unsigned int v; bool success; for (int i = 0; tests[i].str != NULL; i++) { v = 0xad; success = safe_atou_base(tests[i].str, &v, 16); ck_assert(success == tests[i].success); if (success) ck_assert_int_eq(v, tests[i].val); else ck_assert_int_eq(v, 0xad); } } END_TEST START_TEST(safe_atou_base_8_test) { struct atou_test tests[] = { { "7", true, 07 }, { "10", true, 010 }, { "20", true, 020 }, { "-1", false, 0 }, { "010", true, 010 }, { "0ff", false, 0 }, { "abc", false, 0}, { "0xabc", false, 0}, { "-10", false, 0 }, { "0", true, 0 }, { "00", true, 0 }, { "0x0", false, 0 }, { "0x-99", false, 0 }, { "0xak", false, 0 }, { "0x", false, 0 }, { "x10", false, 0 }, { NULL, false, 0 } }; unsigned int v; bool success; for (int i = 0; tests[i].str != NULL; i++) { v = 0xad; success = safe_atou_base(tests[i].str, &v, 8); ck_assert(success == tests[i].success); if (success) ck_assert_int_eq(v, tests[i].val); else ck_assert_int_eq(v, 0xad); } } END_TEST START_TEST(safe_atod_test) { struct atod_test { char *str; bool success; double val; } tests[] = { { "10", true, 10 }, { "20", true, 20 }, { "-1", true, -1 }, { "2147483647", true, 2147483647 }, { "-2147483648", true, -2147483648 }, { "4294967295", true, 4294967295 }, { "0x0", false, 0 }, { "0x10", false, 0 }, { "0xaf", false, 0 }, { "x80", false, 0 }, { "0.0", true, 0.0 }, { "0.1", true, 0.1 }, { "1.2", true, 1.2 }, { "-324.9", true, -324.9 }, { "9324.9", true, 9324.9 }, { "NAN", false, 0 }, { "INFINITY", false, 0 }, { "-10x10", false, 0 }, { "1x-99", false, 0 }, { "", false, 0 }, { "abd", false, 0 }, { "xabd", false, 0 }, { "0x0x", false, 0 }, { NULL, false, 0 } }; double v; bool success; for (int i = 0; tests[i].str != NULL; i++) { v = 0xad; success = safe_atod(tests[i].str, &v); ck_assert(success == tests[i].success); if (success) ck_assert_int_eq(v, tests[i].val); else ck_assert_int_eq(v, 0xad); } } END_TEST START_TEST(strsplit_test) { struct strsplit_test { const char *string; const char *delim; const char *results[10]; } tests[] = { { "one two three", " ", { "one", "two", "three", NULL } }, { "one", " ", { "one", NULL } }, { "one two ", " ", { "one", "two", NULL } }, { "one two", " ", { "one", "two", NULL } }, { " one two", " ", { "one", "two", NULL } }, { "one", "\t \r", { "one", NULL } }, { "one two three", " t", { "one", "wo", "hree", NULL } }, { " one two three", "te", { " on", " ", "wo ", "hr", NULL } }, { "one", "ne", { "o", NULL } }, { "onene", "ne", { "o", NULL } }, { NULL, NULL, { NULL }} }; struct strsplit_test *t = tests; while (t->string) { char **strv; int idx = 0; strv = strv_from_string(t->string, t->delim); while (t->results[idx]) { ck_assert_str_eq(t->results[idx], strv[idx]); idx++; } ck_assert_ptr_eq(strv[idx], NULL); strv_free(strv); t++; } /* Special cases */ ck_assert_ptr_eq(strv_from_string("", " "), NULL); ck_assert_ptr_eq(strv_from_string(" ", " "), NULL); ck_assert_ptr_eq(strv_from_string(" ", " "), NULL); ck_assert_ptr_eq(strv_from_string("oneoneone", "one"), NULL); } END_TEST START_TEST(kvsplit_double_test) { struct kvsplit_dbl_test { const char *string; const char *psep; const char *kvsep; ssize_t nresults; struct { double a; double b; } results[32]; } tests[] = { { "1:2;3:4;5:6", ";", ":", 3, { {1, 2}, {3, 4}, {5, 6}}}, { "1.0x2.3 -3.2x4.5 8.090909x-6.00", " ", "x", 3, { {1.0, 2.3}, {-3.2, 4.5}, {8.090909, -6}}}, { "1:2", "x", ":", 1, {{1, 2}}}, { "1:2", ":", "x", -1, {}}, { "1:2", NULL, "x", -1, {}}, { "1:2", "", "x", -1, {}}, { "1:2", "x", NULL, -1, {}}, { "1:2", "x", "", -1, {}}, { "a:b", "x", ":", -1, {}}, { "", " ", "x", -1, {}}, { "1.2.3.4.5", ".", "", -1, {}}, { NULL } }; struct kvsplit_dbl_test *t = tests; while (t->string) { struct key_value_double *result = NULL; ssize_t npairs; npairs = kv_double_from_string(t->string, t->psep, t->kvsep, &result); ck_assert_int_eq(npairs, t->nresults); for (ssize_t i = 0; i < npairs; i++) { ck_assert_double_eq(t->results[i].a, result[i].key); ck_assert_double_eq(t->results[i].b, result[i].value); } free(result); t++; } } END_TEST START_TEST(strjoin_test) { struct strjoin_test { char *strv[10]; const char *joiner; const char *result; } tests[] = { { { "one", "two", "three", NULL }, " ", "one two three" }, { { "one", NULL }, "x", "one" }, { { "one", "two", NULL }, "x", "onextwo" }, { { "one", "two", NULL }, ",", "one,two" }, { { "one", "two", NULL }, ", ", "one, two" }, { { "one", "two", NULL }, "one", "oneonetwo" }, { { "one", "two", NULL }, NULL, NULL }, { { "", "", "", NULL }, " ", " " }, { { "a", "b", "c", NULL }, "", "abc" }, { { "", "b", "c", NULL }, "x", "xbxc" }, { { "", "", "", NULL }, "", "" }, { { NULL }, NULL, NULL } }; struct strjoin_test *t = tests; struct strjoin_test nulltest = { {NULL}, "x", NULL }; while (t->strv[0]) { char *str; str = strv_join(t->strv, t->joiner); if (t->result == NULL) ck_assert(str == NULL); else ck_assert_str_eq(str, t->result); free(str); t++; } ck_assert(strv_join(nulltest.strv, "x") == NULL); } END_TEST START_TEST(list_test_insert) { struct list_test { int val; struct list node; } tests[] = { { .val = 1 }, { .val = 2 }, { .val = 3 }, { .val = 4 }, }; struct list_test *t; struct list head; int val; list_init(&head); ARRAY_FOR_EACH(tests, t) { list_insert(&head, &t->node); } val = 4; list_for_each(t, &head, node) { ck_assert_int_eq(t->val, val); val--; } ck_assert_int_eq(val, 0); } END_TEST START_TEST(list_test_append) { struct list_test { int val; struct list node; } tests[] = { { .val = 1 }, { .val = 2 }, { .val = 3 }, { .val = 4 }, }; struct list_test *t; struct list head; int val; list_init(&head); ARRAY_FOR_EACH(tests, t) { list_append(&head, &t->node); } val = 1; list_for_each(t, &head, node) { ck_assert_int_eq(t->val, val); val++; } ck_assert_int_eq(val, 5); } END_TEST START_TEST(strverscmp_test) { ck_assert_int_eq(libinput_strverscmp("", ""), 0); ck_assert_int_gt(libinput_strverscmp("0.0.1", ""), 0); ck_assert_int_lt(libinput_strverscmp("", "0.0.1"), 0); ck_assert_int_eq(libinput_strverscmp("0.0.1", "0.0.1"), 0); ck_assert_int_eq(libinput_strverscmp("0.0.1", "0.0.2"), -1); ck_assert_int_eq(libinput_strverscmp("0.0.2", "0.0.1"), 1); ck_assert_int_eq(libinput_strverscmp("0.0.1", "0.1.0"), -1); ck_assert_int_eq(libinput_strverscmp("0.1.0", "0.0.1"), 1); } END_TEST static Suite * litest_utils_suite(void) { TCase *tc; Suite *s; s = suite_create("litest:utils"); tc = tcase_create("utils"); tcase_add_test(tc, bitfield_helpers); tcase_add_test(tc, matrix_helpers); tcase_add_test(tc, ratelimit_helpers); tcase_add_test(tc, dpi_parser); tcase_add_test(tc, wheel_click_parser); tcase_add_test(tc, wheel_click_count_parser); tcase_add_test(tc, dimension_prop_parser); tcase_add_test(tc, reliability_prop_parser); tcase_add_test(tc, calibration_prop_parser); tcase_add_test(tc, range_prop_parser); tcase_add_test(tc, evcode_prop_parser); tcase_add_test(tc, safe_atoi_test); tcase_add_test(tc, safe_atoi_base_16_test); tcase_add_test(tc, safe_atoi_base_8_test); tcase_add_test(tc, safe_atou_test); tcase_add_test(tc, safe_atou_base_16_test); tcase_add_test(tc, safe_atou_base_8_test); tcase_add_test(tc, safe_atod_test); tcase_add_test(tc, strsplit_test); tcase_add_test(tc, kvsplit_double_test); tcase_add_test(tc, strjoin_test); tcase_add_test(tc, time_conversion); tcase_add_test(tc, list_test_insert); tcase_add_test(tc, list_test_append); tcase_add_test(tc, strverscmp_test); return s; } int main(int argc, char **argv) { int nfailed; Suite *s; SRunner *sr; /* when running under valgrind we're using nofork mode, so a signal * raised by a test will fail in valgrind. There's nothing to * memcheck here anyway, so just skip the valgrind test */ if (RUNNING_ON_VALGRIND) return 77; s = litest_utils_suite(); sr = srunner_create(s); srunner_run_all(sr, CK_ENV); nfailed = srunner_ntests_failed(sr); srunner_free(sr); return (nfailed == 0) ? EXIT_SUCCESS : EXIT_FAILURE; }