/* * Copyright © 2013 Red Hat, Inc. * Copyright © 2013 Marcin Slusarz * * 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 "config.h" #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "linux/input.h" #include #include #include #include #include #include #include #include #if HAVE_LIBSYSTEMD #include #endif #ifdef __FreeBSD__ #include #endif #include #include "litest.h" #include "litest-int.h" #include "libinput-util.h" #include "quirks.h" #include "builddir.h" #include #define evbit(t, c) ((t) << 16U | (c & 0xffff)) #define UDEV_RULES_D "/run/udev/rules.d" #define UDEV_FUZZ_OVERRIDE_RULE_FILE UDEV_RULES_D \ "/91-litest-fuzz-override-REMOVEME-XXXXXX.rules" #define UDEV_TEST_DEVICE_RULE_FILE UDEV_RULES_D \ "/91-litest-test-device-REMOVEME-XXXXXXX.rules" #define UDEV_DEVICE_GROUPS_FILE UDEV_RULES_D \ "/80-libinput-device-groups-litest-XXXXXX.rules" static int jobs; static bool in_debugger = false; static bool verbose = false; static bool run_deviceless = false; static bool use_system_rules_quirks = false; const char *filter_test = NULL; const char *filter_device = NULL; const char *filter_group = NULL; const char *xml_prefix = NULL; static struct quirks_context *quirks_context; struct created_file { struct list link; char *path; }; struct list created_files_list; /* list of all files to remove at the end of the test run */ static void litest_init_udev_rules(struct list *created_files_list); static void litest_remove_udev_rules(struct list *created_files_list); enum quirks_setup_mode { QUIRKS_SETUP_USE_SRCDIR, QUIRKS_SETUP_ONLY_DEVICE, QUIRKS_SETUP_FULL, }; static void litest_setup_quirks(struct list *created_files_list, enum quirks_setup_mode mode); /* defined for the litest selftest */ #ifndef LITEST_DISABLE_BACKTRACE_LOGGING #define litest_log(...) fprintf(stderr, __VA_ARGS__) #define litest_vlog(format_, args_) vfprintf(stderr, format_, args_) #else #define litest_log(...) { /* __VA_ARGS__ */ } #define litest_vlog(...) { /* __VA_ARGS__ */ } #endif static void litest_backtrace(void) { #if HAVE_GSTACK pid_t parent, child; int pipefd[2]; if (RUNNING_ON_VALGRIND) { litest_log(" Using valgrind, omitting backtrace\n"); return; } if (pipe(pipefd) == -1) return; parent = getpid(); child = fork(); if (child == 0) { char pid[8]; close(pipefd[0]); dup2(pipefd[1], STDOUT_FILENO); sprintf(pid, "%d", parent); execlp("gstack", "gstack", pid, NULL); exit(errno); } /* parent */ char buf[1024]; int status, nread; close(pipefd[1]); waitpid(child, &status, 0); status = WEXITSTATUS(status); if (status != 0) { litest_log("ERROR: gstack failed, no backtrace available: %s\n", strerror(status)); } else { litest_log("\nBacktrace:\n"); while ((nread = read(pipefd[0], buf, sizeof(buf) - 1)) > 0) { buf[nread] = '\0'; litest_log("%s", buf); } litest_log("\n"); } close(pipefd[0]); #endif } LIBINPUT_ATTRIBUTE_PRINTF(5, 6) __attribute__((noreturn)) void litest_fail_condition(const char *file, int line, const char *func, const char *condition, const char *message, ...) { litest_log("FAILED: %s\n", condition); if (message) { va_list args; va_start(args, message); litest_vlog(message, args); va_end(args); } litest_log("in %s() (%s:%d)\n", func, file, line); litest_backtrace(); abort(); } __attribute__((noreturn)) void litest_fail_comparison_int(const char *file, int line, const char *func, const char *operator, int a, int b, const char *astr, const char *bstr) { litest_log("FAILED COMPARISON: %s %s %s\n", astr, operator, bstr); litest_log("Resolved to: %d %s %d\n", a, operator, b); litest_log("in %s() (%s:%d)\n", func, file, line); litest_backtrace(); abort(); } __attribute__((noreturn)) void litest_fail_comparison_double(const char *file, int line, const char *func, const char *operator, double a, double b, const char *astr, const char *bstr) { litest_log("FAILED COMPARISON: %s %s %s\n", astr, operator, bstr); litest_log("Resolved to: %.3f %s %.3f\n", a, operator, b); litest_log("in %s() (%s:%d)\n", func, file, line); litest_backtrace(); abort(); } __attribute__((noreturn)) void litest_fail_comparison_ptr(const char *file, int line, const char *func, const char *comparison) { litest_log("FAILED COMPARISON: %s\n", comparison); litest_log("in %s() (%s:%d)\n", func, file, line); litest_backtrace(); abort(); } struct test { struct list node; char *name; char *devname; const void *func; void *setup; void *teardown; struct range range; bool deviceless; }; struct suite { struct list node; struct list tests; char *name; }; static struct litest_device *current_device; struct litest_device *litest_current_device(void) { return current_device; } static void grab_device(struct litest_device *device, bool mode) { struct libinput *li = libinput_device_get_context(device->libinput_device); struct litest_context *ctx = libinput_get_user_data(li); struct udev_device *udev_device; const char *devnode; struct path *p; udev_device = libinput_device_get_udev_device(device->libinput_device); litest_assert_ptr_notnull(udev_device); devnode = udev_device_get_devnode(udev_device); /* Note: in some tests we create multiple devices for the same path. * This will only grab the first device in the list but we're using * list_insert() so the first device is the latest that was * initialized, so we should be good. */ list_for_each(p, &ctx->paths, link) { if (streq(p->path, devnode)) { int rc = ioctl(p->fd, EVIOCGRAB, (void*)mode ? 1 : 0); ck_assert_int_gt(rc, -1); udev_device_unref(udev_device); return; } } litest_abort_msg("Failed to find device %s to %sgrab\n", devnode, mode ? "" : "un"); } void litest_grab_device(struct litest_device *device) { grab_device(device, true); } void litest_ungrab_device(struct litest_device *device) { grab_device(device, false); } void litest_set_current_device(struct litest_device *device) { current_device = device; } void litest_generic_device_teardown(void) { litest_delete_device(current_device); current_device = NULL; } struct list devices; static struct list all_tests; static inline void litest_system(const char *command) { int ret; ret = system(command); if (ret == -1) { litest_abort_msg("Failed to execute: %s", command); } else if (WIFEXITED(ret)) { if (WEXITSTATUS(ret)) litest_abort_msg("'%s' failed with %d", command, WEXITSTATUS(ret)); } else if (WIFSIGNALED(ret)) { litest_abort_msg("'%s' terminated with signal %d", command, WTERMSIG(ret)); } } static void litest_reload_udev_rules(void) { litest_system("udevadm control --reload-rules"); } static void litest_add_tcase_for_device(struct suite *suite, const char *funcname, const void *func, const struct litest_test_device *dev, const struct range *range) { struct test *t; t = zalloc(sizeof(*t)); t->name = safe_strdup(funcname); t->devname = safe_strdup(dev->shortname); t->func = func; t->setup = dev->setup; t->teardown = dev->teardown ? dev->teardown : litest_generic_device_teardown; if (range) t->range = *range; list_insert(&suite->tests, &t->node); } static void litest_add_tcase_no_device(struct suite *suite, const void *func, const char *funcname, const struct range *range) { struct test *t; const char *test_name = funcname; if (filter_device && strstr(test_name, filter_device) == NULL && fnmatch(filter_device, test_name, 0) != 0) return; t = zalloc(sizeof(*t)); t->name = safe_strdup(test_name); t->devname = safe_strdup("no device"); t->func = func; if (range) t->range = *range; t->setup = NULL; t->teardown = NULL; list_insert(&suite->tests, &t->node); } static void litest_add_tcase_deviceless(struct suite *suite, const void *func, const char *funcname, const struct range *range) { struct test *t; const char *test_name = funcname; if (filter_device && strstr(test_name, filter_device) == NULL && fnmatch(filter_device, test_name, 0) != 0) return; t = zalloc(sizeof(*t)); t->deviceless = true; t->name = safe_strdup(test_name); t->devname = safe_strdup("deviceless"); t->func = func; if (range) t->range = *range; t->setup = NULL; t->teardown = NULL; list_insert(&suite->tests, &t->node); } static struct suite * get_suite(const char *name) { struct suite *s; list_for_each(s, &all_tests, node) { if (streq(s->name, name)) return s; } s = zalloc(sizeof(*s)); s->name = safe_strdup(name); list_init(&s->tests); list_insert(&all_tests, &s->node); return s; } static void create_suite_name(const char *filename, char suitename[64]) { char *trunk = trunkname(filename); char *p = trunk; /* strip the test- prefix */ if (strstartswith(trunk, "test-")) p += 5; snprintf(suitename, 64, "%s", p); free(trunk); } static void litest_add_tcase(const char *filename, const char *funcname, const void *func, int64_t required, int64_t excluded, const struct range *range) { char suite_name[65]; struct suite *suite; bool added = false; litest_assert(required >= LITEST_DEVICELESS); litest_assert(excluded >= LITEST_DEVICELESS); if (filter_test && strstr(funcname, filter_test) == NULL && fnmatch(filter_test, funcname, 0) != 0) return; create_suite_name(filename, suite_name); if (filter_group && fnmatch(filter_group, suite_name, 0) != 0) return; suite = get_suite(suite_name); if (required == LITEST_DEVICELESS && excluded == LITEST_DEVICELESS) { litest_add_tcase_deviceless(suite, func, funcname, range); added = true; } else if (required == LITEST_DISABLE_DEVICE && excluded == LITEST_DISABLE_DEVICE) { litest_add_tcase_no_device(suite, func, funcname, range); added = true; } else if (required != LITEST_ANY || excluded != LITEST_ANY) { struct litest_test_device *dev; list_for_each(dev, &devices, node) { if (dev->features & LITEST_IGNORED) continue; if (filter_device && strstr(dev->shortname, filter_device) == NULL && fnmatch(filter_device, dev->shortname, 0) != 0) continue; if ((dev->features & required) != required || (dev->features & excluded) != 0) continue; litest_add_tcase_for_device(suite, funcname, func, dev, range); added = true; } } else { struct litest_test_device *dev; list_for_each(dev, &devices, node) { if (dev->features & LITEST_IGNORED) continue; if (filter_device && strstr(dev->shortname, filter_device) == NULL && fnmatch(filter_device, dev->shortname, 0) != 0) continue; litest_add_tcase_for_device(suite, funcname, func, dev, range); added = true; } } if (!added && filter_test == NULL && filter_device == NULL && filter_group == NULL) { fprintf(stderr, "Test '%s' does not match any devices. Aborting.\n", funcname); abort(); } } void _litest_add_no_device(const char *name, const char *funcname, const void *func) { _litest_add(name, funcname, func, LITEST_DISABLE_DEVICE, LITEST_DISABLE_DEVICE); } void _litest_add_ranged_no_device(const char *name, const char *funcname, const void *func, const struct range *range) { _litest_add_ranged(name, funcname, func, LITEST_DISABLE_DEVICE, LITEST_DISABLE_DEVICE, range); } void _litest_add_deviceless(const char *name, const char *funcname, const void *func) { _litest_add_ranged(name, funcname, func, LITEST_DEVICELESS, LITEST_DEVICELESS, NULL); } void _litest_add(const char *name, const char *funcname, const void *func, int64_t required, int64_t excluded) { _litest_add_ranged(name, funcname, func, required, excluded, NULL); } void _litest_add_ranged(const char *name, const char *funcname, const void *func, int64_t required, int64_t excluded, const struct range *range) { litest_add_tcase(name, funcname, func, required, excluded, range); } void _litest_add_for_device(const char *name, const char *funcname, const void *func, enum litest_device_type type) { _litest_add_ranged_for_device(name, funcname, func, type, NULL); } void _litest_add_ranged_for_device(const char *filename, const char *funcname, const void *func, enum litest_device_type type, const struct range *range) { struct suite *s; struct litest_test_device *dev; bool device_filtered = false; char suite_name[64]; litest_assert(type < LITEST_NO_DEVICE); if (filter_test && strstr(funcname, filter_test) == NULL && fnmatch(filter_test, funcname, 0) != 0) return; create_suite_name(filename, suite_name); if (filter_group && fnmatch(filter_group, suite_name, 0) != 0) return; s = get_suite(suite_name); list_for_each(dev, &devices, node) { if (filter_device && strstr(dev->shortname, filter_device) == NULL && fnmatch(filter_device, dev->shortname, 0) != 0) { device_filtered = true; continue; } if (dev->type == type) { litest_add_tcase_for_device(s, funcname, func, dev, range); return; } } /* only abort if no filter was set, that's a bug */ if (!device_filtered) litest_abort_msg("Invalid test device type\n"); } LIBINPUT_ATTRIBUTE_PRINTF(3, 0) static void litest_log_handler(struct libinput *libinput, enum libinput_log_priority pri, const char *format, va_list args) { static int is_tty = -1; const char *priority = NULL; const char *color; if (is_tty == -1) is_tty = isatty(STDERR_FILENO); switch(pri) { case LIBINPUT_LOG_PRIORITY_INFO: priority = "info "; color = ANSI_HIGHLIGHT; break; case LIBINPUT_LOG_PRIORITY_ERROR: priority = "error"; color = ANSI_BRIGHT_RED; break; case LIBINPUT_LOG_PRIORITY_DEBUG: priority = "debug"; color = ANSI_NORMAL; break; default: abort(); } if (!is_tty) color = ""; else if (strstr(format, "tap:")) color = ANSI_BLUE; else if (strstr(format, "thumb state:")) color = ANSI_YELLOW; else if (strstr(format, "button state:")) color = ANSI_MAGENTA; else if (strstr(format, "touch-size:") || strstr(format, "pressure:")) color = ANSI_GREEN; else if (strstr(format, "palm:") || strstr(format, "thumb:")) color = ANSI_CYAN; else if (strstr(format, "edge-scroll:")) color = ANSI_BRIGHT_GREEN; fprintf(stderr, "%slitest %s ", color, priority); vfprintf(stderr, format, args); if (is_tty) fprintf(stderr, ANSI_NORMAL); if (strstr(format, "client bug: ") || strstr(format, "libinput bug: ")) { /* valgrind is too slow and some of our offsets are too * short, don't abort if during a valgrind run we get a * negative offset */ if ((RUNNING_ON_VALGRIND && in_debugger) || !strstr(format, "scheduled expiry is in the past")) { /* noop */ } else if (!strstr(format, "event processing lagging behind")) { /* noop */ } else { litest_abort_msg("libinput bug triggered, aborting.\n"); } } if (strstr(format, "Touch jump detected and discarded")) { litest_abort_msg("libinput touch jump triggered, aborting.\n"); } } static void litest_init_device_udev_rules(struct litest_test_device *dev, FILE *f) { const struct key_value_str *kv; static int count; bool need_keyboard_builtin = false; if (dev->udev_properties[0].key == NULL) return; count++; fprintf(f, "# %s\n", dev->shortname); fprintf(f, "ACTION==\"remove\", GOTO=\"rule%d_end\"\n", count); fprintf(f, "KERNEL!=\"event*\", GOTO=\"rule%d_end\"\n", count); fprintf(f, "ATTRS{name}==\"litest %s*\"", dev->name); kv = dev->udev_properties; while (kv->key) { fprintf(f, ", \\\n\tENV{%s}=\"%s\"", kv->key, kv->value); if (strneq(kv->key, "EVDEV_ABS_", 10)) need_keyboard_builtin = true; kv++; } fprintf(f, "\n"); /* Special case: the udev keyboard builtin is only run for hwdb * matches but we don't set any up in litest. So instead scan the * device's udev properties for any EVDEV_ABS properties and where * they exist, force a (re-)run of the keyboard builtin to set up * the evdev device correctly. * This needs to be done as separate rule apparently, otherwise the * ENV variables aren't set yet by the time the builtin runs. */ if (need_keyboard_builtin) { fprintf(f, "" "ATTRS{name}==\"litest %s*\"," " IMPORT{builtin}=\"keyboard\"\n", dev->name); } fprintf(f, "LABEL=\"rule%d_end\"\n\n", count);; } static void litest_init_all_device_udev_rules(struct list *created_files) { struct created_file *file = zalloc(sizeof(*file)); struct litest_test_device *dev; char *path = NULL; FILE *f; int rc; int fd; rc = xasprintf(&path, "%s/99-litest-XXXXXX.rules", UDEV_RULES_D); litest_assert_int_gt(rc, 0); fd = mkstemps(path, 6); litest_assert_int_ne(fd, -1); f = fdopen(fd, "w"); litest_assert_notnull(f); list_for_each(dev, &devices, node) litest_init_device_udev_rules(dev, f); fclose(f); file->path = path; list_insert(created_files, &file->link); } static int open_restricted(const char *path, int flags, void *userdata) { const char prefix[] = "/dev/input/event"; struct litest_context *ctx = userdata; struct path *p; int fd; litest_assert_ptr_notnull(ctx); fd = open(path, flags); if (fd < 0) return -errno; if (strneq(path, prefix, strlen(prefix))) { p = zalloc(sizeof *p); p->path = safe_strdup(path); p->fd = fd; /* We specifically insert here so that the most-recently * opened path is the first one in the list. This helps when * we have multiple test devices with the same device path, * the fd of the most recent device is the first one to get * grabbed */ list_insert(&ctx->paths, &p->link); } return fd; } static void close_restricted(int fd, void *userdata) { struct litest_context *ctx = userdata; struct path *p; list_for_each_safe(p, &ctx->paths, link) { if (p->fd != fd) continue; list_remove(&p->link); free(p->path); free(p); } close(fd); } struct libinput_interface interface = { .open_restricted = open_restricted, .close_restricted = close_restricted, }; static void litest_signal(int sig) { struct created_file *f; list_for_each_safe(f, &created_files_list, link) { list_remove(&f->link); unlink(f->path); rmdir(f->path); /* in the sighandler, we can't free */ } if (fork() == 0) { /* child, we can run system() */ litest_reload_udev_rules(); exit(0); } exit(1); } static inline void litest_setup_sighandler(int sig) { struct sigaction act, oact; int rc; sigemptyset(&act.sa_mask); sigaddset(&act.sa_mask, sig); act.sa_flags = 0; act.sa_handler = litest_signal; rc = sigaction(sig, &act, &oact); litest_assert_int_ne(rc, -1); } static void litest_free_test_list(struct list *tests) { struct suite *s; list_for_each_safe(s, tests, node) { struct test *t; list_for_each_safe(t, &s->tests, node) { free(t->name); free(t->devname); list_remove(&t->node); free(t); } list_remove(&s->node); free(s->name); free(s); } } LIBINPUT_ATTRIBUTE_PRINTF(3, 0) static inline void quirk_log_handler(struct libinput *unused, enum libinput_log_priority priority, const char *format, va_list args) { if (priority < LIBINPUT_LOG_PRIORITY_ERROR) return; vfprintf(stderr, format, args); } static void litest_export_xml(SRunner *sr, const char *xml_prefix) { TestResult **results; int nresults, nfailed; char *filename; int fd; /* This is the minimum-effort implementation here because its only * real purpose is to make test logs look pretty in the gitlab CI. * * Which means: * - there's no filename validation, if you supply a filename that * mkstemps doesn't like, things go boom. * - every fork writes out a separate junit.xml file. gitlab is better * at collecting lots of files than I am at writing code to collect * this across forks to write out only one file. * - most of the content is pretty useless because libcheck only gives * us minimal information. the libcheck XML file has more info like * the duration of each test but it's more complicated to extract * and we don't need it for now. */ filename = safe_strdup(xml_prefix); fd = mkstemps(filename, 4); results = srunner_results(sr); nresults = srunner_ntests_run(sr); nfailed = srunner_ntests_failed(sr); dprintf(fd, "\n"); dprintf(fd, "\n", filename, nresults, nfailed); dprintf(fd, " \n"); for (int i = 0; i < nresults; i++) { TestResult *r = results[i]; dprintf(fd, " \n", tr_tcname(r), tr_tcname(r), tr_rtype(r) == CK_PASS ? "/" : ""); if (tr_rtype(r) != CK_PASS) { dprintf(fd, " \n", tr_lfile(r), tr_lno(r)); dprintf(fd, " %s:%d\n", tr_lfile(r), tr_lno(r)); dprintf(fd, " %s\n", tr_tcname(r)); dprintf(fd, "\n"); dprintf(fd, " %s\n", tr_msg(r)); dprintf(fd, " \n"); dprintf(fd, " \n"); } } dprintf(fd, " \n"); dprintf(fd, "\n"); free(results); close(fd); free(filename); } static int litest_run_suite(struct list *tests, int which, int max, int error_fd) { int failed = 0; SRunner *sr = NULL; struct suite *s; struct test *t; int count = -1; struct name { struct list node; char *name; }; struct name *n; struct list testnames; const char *data_path; data_path = getenv("LIBINPUT_QUIRKS_DIR"); if (!data_path) data_path = LIBINPUT_QUIRKS_DIR; quirks_context = quirks_init_subsystem(data_path, NULL, quirk_log_handler, NULL, QLOG_LIBINPUT_LOGGING); /* Check just takes the suite/test name pointers but doesn't strdup * them - we have to keep them around */ list_init(&testnames); /* For each test, create one test suite with one test case, then add it to the test runner. The only benefit suites give us in check is that we can filter them, but our test runner has a --filter-group anyway. */ list_for_each(s, tests, node) { list_for_each(t, &s->tests, node) { Suite *suite; TCase *tc; char *sname, *tname; /* We run deviceless tests as part of the normal * test suite runner, just in case. Filtering * all the other ones out just for the case where * we can't run the full runner. */ if (run_deviceless && !t->deviceless) continue; count = (count + 1) % max; if (max != 1 && (count % max) != which) continue; xasprintf(&sname, "%s:%s:%s", s->name, t->name, t->devname); litest_assert_ptr_notnull(sname); n = zalloc(sizeof(*n)); n->name = sname; list_insert(&testnames, &n->node); xasprintf(&tname, "%s:%s", t->name, t->devname); litest_assert_ptr_notnull(tname); n = zalloc(sizeof(*n)); n->name = tname; list_insert(&testnames, &n->node); tc = tcase_create(tname); tcase_add_checked_fixture(tc, t->setup, t->teardown); if (t->range.upper != t->range.lower) tcase_add_loop_test(tc, t->func, t->range.lower, t->range.upper); else tcase_add_test(tc, t->func); suite = suite_create(sname); suite_add_tcase(suite, tc); if (!sr) sr = srunner_create(suite); else srunner_add_suite(sr, suite); } } if (!sr) goto out; srunner_run_all(sr, CK_ENV); if (xml_prefix) litest_export_xml(sr, xml_prefix); failed = srunner_ntests_failed(sr); if (failed) { TestResult **trs; trs = srunner_failures(sr); for (int i = 0; i < failed; i++) { char tname[256]; char *c = tname; /* tr_tcname is in the form "suite:testcase", let's * convert this to "suite(testcase)" to make * double-click selection in the terminal a bit * easier. */ snprintf(tname, sizeof(tname), "%s)", tr_tcname(trs[i])); if ((c = index(c, ':'))) *c = '('; dprintf(error_fd, ":: Failure: %s:%d: %s\n", tr_lfile(trs[i]), tr_lno(trs[i]), tname); } free(trs); } srunner_free(sr); out: list_for_each_safe(n, &testnames, node) { free(n->name); free(n); } quirks_context_unref(quirks_context); return failed; } static int litest_fork_subtests(struct list *tests, int max_forks) { int failed = 0; int status; pid_t pid; int f; int pipes[max_forks]; for (f = 0; f < max_forks; f++) { int rc; int pipefd[2]; rc = pipe2(pipefd, O_NONBLOCK); assert(rc != -1); pid = fork(); if (pid == 0) { close(pipefd[0]); failed = litest_run_suite(tests, f, max_forks, pipefd[1]); litest_free_test_list(&all_tests); exit(failed); /* child always exits here */ } else { pipes[f] = pipefd[0]; close(pipefd[1]); } } /* parent process only */ while (wait(&status) != -1 && errno != ECHILD) { if (!WIFEXITED(status) || WEXITSTATUS(status) != 0) failed = 1; } for (f = 0; f < max_forks; f++) { char buf[1024] = {0}; int rc; while ((rc = read(pipes[f], buf, sizeof(buf) - 1)) > 0) { buf[rc] = '\0'; fprintf(stderr, "%s", buf); } close(pipes[f]); } return failed; } static inline int inhibit(void) { int lock_fd = -1; #if HAVE_LIBSYSTEMD sd_bus_error error = SD_BUS_ERROR_NULL; sd_bus_message *m = NULL; sd_bus *bus = NULL; int rc; if (run_deviceless) return -1; rc = sd_bus_open_system(&bus); if (rc != 0) { fprintf(stderr, "Warning: inhibit failed: %s\n", strerror(-rc)); goto out; } rc = sd_bus_call_method(bus, "org.freedesktop.login1", "/org/freedesktop/login1", "org.freedesktop.login1.Manager", "Inhibit", &error, &m, "ssss", "sleep:shutdown:handle-lid-switch:handle-power-key:handle-suspend-key:handle-hibernate-key", "libinput test-suite runner", "testing in progress", "block"); if (rc < 0) { fprintf(stderr, "Warning: inhibit failed: %s\n", error.message); goto out; } rc = sd_bus_message_read(m, "h", &lock_fd); if (rc < 0) { fprintf(stderr, "Warning: inhibit failed: %s\n", strerror(-rc)); goto out; } lock_fd = dup(lock_fd); out: sd_bus_error_free(&error); sd_bus_message_unref(m); sd_bus_close(bus); sd_bus_unref(bus); #endif return lock_fd; } static inline int litest_run(int argc, char **argv) { int failed = 0; int inhibit_lock_fd; list_init(&created_files_list); if (list_empty(&all_tests)) { fprintf(stderr, "Error: filters are too strict, no tests to run.\n"); return 1; } if (getenv("LITEST_VERBOSE")) verbose = true; if (run_deviceless) { litest_setup_quirks(&created_files_list, QUIRKS_SETUP_USE_SRCDIR); } else { enum quirks_setup_mode mode; litest_init_udev_rules(&created_files_list); mode = use_system_rules_quirks ? QUIRKS_SETUP_ONLY_DEVICE : QUIRKS_SETUP_FULL; litest_setup_quirks(&created_files_list, mode); } litest_setup_sighandler(SIGINT); inhibit_lock_fd = inhibit(); if (jobs == 1) failed = litest_run_suite(&all_tests, 1, 1, STDERR_FILENO); else failed = litest_fork_subtests(&all_tests, jobs); close(inhibit_lock_fd); litest_free_test_list(&all_tests); litest_remove_udev_rules(&created_files_list); return failed; } static struct input_absinfo * merge_absinfo(const struct input_absinfo *orig, const struct input_absinfo *override) { struct input_absinfo *abs; unsigned int nelem, i; size_t sz = ABS_MAX + 1; if (!orig) return NULL; abs = zalloc(sz * sizeof(*abs)); litest_assert_ptr_notnull(abs); nelem = 0; while (orig[nelem].value != -1) { abs[nelem] = orig[nelem]; nelem++; litest_assert_int_lt(nelem, sz); } /* just append, if the same axis is present twice, libevdev will only use the last value anyway */ i = 0; while (override && override[i].value != -1) { abs[nelem++] = override[i++]; litest_assert_int_lt(nelem, sz); } litest_assert_int_lt(nelem, sz); abs[nelem].value = -1; return abs; } static int* merge_events(const int *orig, const int *override) { int *events; unsigned int nelem, i; size_t sz = KEY_MAX * 3; if (!orig) return NULL; events = zalloc(sz * sizeof(int)); litest_assert_ptr_notnull(events); nelem = 0; while (orig[nelem] != -1) { events[nelem] = orig[nelem]; nelem++; litest_assert_int_lt(nelem, sz); } /* just append, if the same axis is present twice, libevdev will * ignore the double definition anyway */ i = 0; while (override && override[i] != -1) { events[nelem++] = override[i++]; litest_assert_int_le(nelem, sz); } litest_assert_int_lt(nelem, sz); events[nelem] = -1; return events; } static inline struct created_file * litest_copy_file(const char *dest, const char *src, const char *header, bool is_file) { int in, out, length; struct created_file *file; file = zalloc(sizeof(*file)); file->path = safe_strdup(dest); if (strstr(dest, "XXXXXX")) { int suffixlen; suffixlen = file->path + strlen(file->path) - rindex(file->path, '.'); out = mkstemps(file->path, suffixlen); } else { out = open(file->path, O_CREAT|O_WRONLY, 0644); } if (out == -1) litest_abort_msg("Failed to write to file %s (%s)\n", file->path, strerror(errno)); litest_assert_int_ne(chmod(file->path, 0644), -1); if (header) { length = strlen(header); litest_assert_int_eq(write(out, header, length), length); } if (is_file) { in = open(src, O_RDONLY); if (in == -1) litest_abort_msg("Failed to open file %s (%s)\n", src, strerror(errno)); /* lazy, just check for error and empty file copy */ litest_assert_int_gt(litest_send_file(out, in), 0); close(in); } else { size_t written = write(out, src, strlen(src)); litest_assert_int_eq(written, strlen(src)); } close(out); return file; } static inline void litest_install_model_quirks(struct list *created_files_list) { const char *warning = "#################################################################\n" "# WARNING: REMOVE THIS FILE\n" "# This is a run-time file for the libinput test suite and\n" "# should be removed on exit. If the test-suite is not currently \n" "# running, remove this file\n" "#################################################################\n\n"; struct created_file *file; const char *test_device_udev_rule = "KERNELS==\"*input*\", " "ATTRS{name}==\"litest *\", " "ENV{LIBINPUT_TEST_DEVICE}=\"1\""; file = litest_copy_file(UDEV_TEST_DEVICE_RULE_FILE, test_device_udev_rule, warning, false); list_insert(created_files_list, &file->link); /* Only install the litest device rule when we're running as system * test suite, we expect the others to be in place already */ if (use_system_rules_quirks) return; file = litest_copy_file(UDEV_DEVICE_GROUPS_FILE, LIBINPUT_DEVICE_GROUPS_RULES_FILE, warning, true); list_insert(created_files_list, &file->link); file = litest_copy_file(UDEV_FUZZ_OVERRIDE_RULE_FILE, LIBINPUT_FUZZ_OVERRIDE_UDEV_RULES_FILE, warning, true); list_insert(created_files_list, &file->link); } static char * litest_init_device_quirk_file(const char *data_dir, struct litest_test_device *dev) { int fd; FILE *f; char path[PATH_MAX]; static int count; if (!dev->quirk_file) return NULL; snprintf(path, sizeof(path), "%s/99-%03d-%s.quirks", data_dir, ++count, dev->shortname); fd = open(path, O_CREAT|O_WRONLY, 0644); litest_assert_int_ne(fd, -1); f = fdopen(fd, "w"); litest_assert_notnull(f); litest_assert_int_ge(fputs(dev->quirk_file, f), 0); fclose(f); return safe_strdup(path); } static int is_quirks_file(const struct dirent *dir) { return strendswith(dir->d_name, ".quirks"); } /** * Install the quirks from the quirks/ source directory. */ static void litest_install_source_quirks(struct list *created_files_list, const char *dirname) { struct dirent **namelist; int ndev; ndev = scandir(LIBINPUT_QUIRKS_SRCDIR, &namelist, is_quirks_file, versionsort); litest_assert_int_ge(ndev, 0); for (int idx = 0; idx < ndev; idx++) { struct created_file *file; char *filename; char dest[PATH_MAX]; char src[PATH_MAX]; filename = namelist[idx]->d_name; snprintf(src, sizeof(src), "%s/%s", LIBINPUT_QUIRKS_SRCDIR, filename); snprintf(dest, sizeof(dest), "%s/%s", dirname, filename); file = litest_copy_file(dest, src, NULL, true); list_append(created_files_list, &file->link); free(namelist[idx]); } free(namelist); } /** * Install the quirks from the various litest test devices */ static void litest_install_device_quirks(struct list *created_files_list, const char *dirname) { struct litest_test_device *dev; list_for_each(dev, &devices, node) { char *path; path = litest_init_device_quirk_file(dirname, dev); if (path) { struct created_file *file = zalloc(sizeof(*file)); file->path = path; list_insert(created_files_list, &file->link); } } } static void litest_setup_quirks(struct list *created_files_list, enum quirks_setup_mode mode) { struct created_file *file = NULL; const char *dirname; char tmpdir[] = "/run/litest-XXXXXX"; switch (mode) { case QUIRKS_SETUP_USE_SRCDIR: dirname = LIBINPUT_QUIRKS_SRCDIR; break; case QUIRKS_SETUP_ONLY_DEVICE: dirname = LIBINPUT_QUIRKS_DIR; litest_install_device_quirks(created_files_list, dirname); break; case QUIRKS_SETUP_FULL: litest_assert_notnull(mkdtemp(tmpdir)); litest_assert_int_ne(chmod(tmpdir, 0755), -1); file = zalloc(sizeof *file); file->path = safe_strdup(tmpdir); dirname = tmpdir; litest_install_source_quirks(created_files_list, dirname); litest_install_device_quirks(created_files_list, dirname); list_append(created_files_list, &file->link); break; } setenv("LIBINPUT_QUIRKS_DIR", dirname, 1); } static inline void mkdir_p(const char *dir) { char *path, *parent; int rc; if (streq(dir, "/")) return; path = safe_strdup(dir); parent = dirname(path); mkdir_p(parent); rc = mkdir(dir, 0755); if (rc == -1 && errno != EEXIST) { litest_abort_msg("Failed to create directory %s (%s)\n", dir, strerror(errno)); } free(path); } static inline void litest_init_udev_rules(struct list *created_files) { mkdir_p(UDEV_RULES_D); litest_install_model_quirks(created_files); litest_init_all_device_udev_rules(created_files); litest_reload_udev_rules(); } static inline void litest_remove_udev_rules(struct list *created_files_list) { struct created_file *f; bool reload_udev; reload_udev = !list_empty(created_files_list); list_for_each_safe(f, created_files_list, link) { list_remove(&f->link); unlink(f->path); rmdir(f->path); free(f->path); free(f); } if (reload_udev) litest_reload_udev_rules(); } /** * Creates a uinput device but does not add it to a libinput context */ struct litest_device * litest_create(enum litest_device_type which, const char *name_override, struct input_id *id_override, const struct input_absinfo *abs_override, const int *events_override) { struct litest_device *d = NULL; struct litest_test_device *dev; const char *name; const struct input_id *id; struct input_absinfo *abs; int *events, *e; const char *path; int fd, rc; bool found = false; bool create_device = true; list_for_each(dev, &devices, node) { if (dev->type == which) { found = true; break; } } if (!found) ck_abort_msg("Invalid device type %d\n", which); d = zalloc(sizeof(*d)); d->which = which; /* device has custom create method */ if (dev->create) { create_device = dev->create(d); if (abs_override || events_override) { litest_abort_msg("Custom create cannot be overridden"); } } abs = merge_absinfo(dev->absinfo, abs_override); events = merge_events(dev->events, events_override); name = name_override ? name_override : dev->name; id = id_override ? id_override : dev->id; if (create_device) { d->uinput = litest_create_uinput_device_from_description(name, id, abs, events); d->interface = dev->interface; for (e = events; *e != -1; e += 2) { unsigned int type = *e, code = *(e + 1); if (type == INPUT_PROP_MAX && code == INPUT_PROP_SEMI_MT) { d->semi_mt.is_semi_mt = true; break; } } } free(abs); free(events); path = libevdev_uinput_get_devnode(d->uinput); litest_assert_ptr_notnull(path); fd = open(path, O_RDWR|O_NONBLOCK); litest_assert_int_ne(fd, -1); rc = libevdev_new_from_fd(fd, &d->evdev); litest_assert_int_eq(rc, 0); return d; } struct libinput * litest_create_context(void) { struct libinput *libinput; struct litest_context *ctx; ctx = zalloc(sizeof *ctx); list_init(&ctx->paths); libinput = libinput_path_create_context(&interface, ctx); litest_assert_notnull(libinput); libinput_log_set_handler(libinput, litest_log_handler); if (verbose) libinput_log_set_priority(libinput, LIBINPUT_LOG_PRIORITY_DEBUG); return libinput; } void litest_destroy_context(struct libinput *li) { struct path *p; struct litest_context *ctx; ctx = libinput_get_user_data(li); litest_assert_ptr_notnull(ctx); libinput_unref(li); list_for_each_safe(p, &ctx->paths, link) { litest_abort_msg("Device paths should be removed by now"); } free(ctx); } void litest_disable_log_handler(struct libinput *libinput) { libinput_log_set_handler(libinput, NULL); } void litest_restore_log_handler(struct libinput *libinput) { libinput_log_set_handler(libinput, litest_log_handler); if (verbose) libinput_log_set_priority(libinput, LIBINPUT_LOG_PRIORITY_DEBUG); } LIBINPUT_ATTRIBUTE_PRINTF(3, 0) static void litest_bug_log_handler(struct libinput *libinput, enum libinput_log_priority pri, const char *format, va_list args) { if (strstr(format, "client bug: ") || strstr(format, "libinput bug: ") || strstr(format, "kernel bug: ")) return; litest_abort_msg("Expected bug statement in log msg, aborting.\n"); } void litest_set_log_handler_bug(struct libinput *libinput) { libinput_log_set_handler(libinput, litest_bug_log_handler); } struct litest_device * litest_add_device_with_overrides(struct libinput *libinput, enum litest_device_type which, const char *name_override, struct input_id *id_override, const struct input_absinfo *abs_override, const int *events_override) { struct udev_device *ud; struct litest_device *d; const char *path; d = litest_create(which, name_override, id_override, abs_override, events_override); path = libevdev_uinput_get_devnode(d->uinput); litest_assert_ptr_notnull(path); d->libinput = libinput; d->libinput_device = libinput_path_add_device(d->libinput, path); litest_assert_ptr_notnull(d->libinput_device); ud = libinput_device_get_udev_device(d->libinput_device); d->quirks = quirks_fetch_for_device(quirks_context, ud); udev_device_unref(ud); libinput_device_ref(d->libinput_device); if (d->interface) { unsigned int code; code = ABS_X; if (!libevdev_has_event_code(d->evdev, EV_ABS, code)) code = ABS_MT_POSITION_X; if (libevdev_has_event_code(d->evdev, EV_ABS, code)) { d->interface->min[ABS_X] = libevdev_get_abs_minimum(d->evdev, code); d->interface->max[ABS_X] = libevdev_get_abs_maximum(d->evdev, code); } code = ABS_Y; if (!libevdev_has_event_code(d->evdev, EV_ABS, code)) code = ABS_MT_POSITION_Y; if (libevdev_has_event_code(d->evdev, EV_ABS, code)) { d->interface->min[ABS_Y] = libevdev_get_abs_minimum(d->evdev, code); d->interface->max[ABS_Y] = libevdev_get_abs_maximum(d->evdev, code); } d->interface->tool_type = BTN_TOOL_PEN; } return d; } struct litest_device * litest_add_device(struct libinput *libinput, enum litest_device_type which) { return litest_add_device_with_overrides(libinput, which, NULL, NULL, NULL, NULL); } struct litest_device * litest_create_device_with_overrides(enum litest_device_type which, const char *name_override, struct input_id *id_override, const struct input_absinfo *abs_override, const int *events_override) { struct litest_device *dev = litest_add_device_with_overrides(litest_create_context(), which, name_override, id_override, abs_override, events_override); dev->owns_context = true; return dev; } struct litest_device * litest_create_device(enum litest_device_type which) { return litest_create_device_with_overrides(which, NULL, NULL, NULL, NULL); } static struct udev_monitor * udev_setup_monitor(void) { struct udev *udev; struct udev_monitor *udev_monitor; int rc; udev = udev_new(); litest_assert_notnull(udev); udev_monitor = udev_monitor_new_from_netlink(udev, "udev"); litest_assert_notnull(udev_monitor); udev_monitor_filter_add_match_subsystem_devtype(udev_monitor, "input", NULL); /* remove O_NONBLOCK */ rc = fcntl(udev_monitor_get_fd(udev_monitor), F_SETFL, 0); litest_assert_int_ne(rc, -1); litest_assert_int_eq(udev_monitor_enable_receiving(udev_monitor), 0); udev_unref(udev); return udev_monitor; } static struct udev_device * udev_wait_for_device_event(struct udev_monitor *udev_monitor, const char *udev_event, const char *syspath) { struct udev_device *udev_device = NULL; /* blocking, we don't want to continue until udev is ready */ while (1) { const char *udev_syspath = NULL; const char *udev_action; udev_device = udev_monitor_receive_device(udev_monitor); litest_assert_notnull(udev_device); udev_action = udev_device_get_action(udev_device); if (!udev_action || !streq(udev_action, udev_event)) { udev_device_unref(udev_device); continue; } udev_syspath = udev_device_get_syspath(udev_device); if (udev_syspath && strstartswith(udev_syspath, syspath)) break; udev_device_unref(udev_device); } return udev_device; } void litest_delete_device(struct litest_device *d) { struct udev_monitor *udev_monitor; struct udev_device *udev_device; char path[PATH_MAX]; if (!d) return; udev_monitor = udev_setup_monitor(); snprintf(path, sizeof(path), "%s/event", libevdev_uinput_get_syspath(d->uinput)); litest_assert_int_eq(d->skip_ev_syn, 0); quirks_unref(d->quirks); if (d->libinput_device) { libinput_path_remove_device(d->libinput_device); libinput_device_unref(d->libinput_device); } if (d->owns_context) { libinput_dispatch(d->libinput); litest_destroy_context(d->libinput); } close(libevdev_get_fd(d->evdev)); libevdev_free(d->evdev); libevdev_uinput_destroy(d->uinput); free(d->private); memset(d,0, sizeof(*d)); free(d); udev_device = udev_wait_for_device_event(udev_monitor, "remove", path); udev_device_unref(udev_device); udev_monitor_unref(udev_monitor); } void litest_event(struct litest_device *d, unsigned int type, unsigned int code, int value) { int ret; if (!libevdev_has_event_code(d->evdev, type, code)) return; if (d->skip_ev_syn && type == EV_SYN && code == SYN_REPORT) return; ret = libevdev_uinput_write_event(d->uinput, type, code, value); litest_assert_int_eq(ret, 0); } static bool axis_replacement_value(struct litest_device *d, struct axis_replacement *axes, int32_t evcode, int32_t *value) { struct axis_replacement *axis = axes; if (!axes) return false; while (axis->evcode != -1) { if (axis->evcode == evcode) { switch (evcode) { case ABS_MT_SLOT: case ABS_MT_TRACKING_ID: case ABS_MT_TOOL_TYPE: *value = axis->value; break; default: *value = litest_scale(d, evcode, axis->value); break; } return true; } axis++; } return false; } int litest_auto_assign_value(struct litest_device *d, const struct input_event *ev, int slot, double x, double y, struct axis_replacement *axes, bool touching) { static int tracking_id; int value = ev->value; if (value != LITEST_AUTO_ASSIGN || ev->type != EV_ABS) return value; switch (ev->code) { case ABS_X: case ABS_MT_POSITION_X: value = litest_scale(d, ABS_X, x); break; case ABS_Y: case ABS_MT_POSITION_Y: value = litest_scale(d, ABS_Y, y); break; case ABS_MT_TRACKING_ID: value = ++tracking_id; break; case ABS_MT_SLOT: value = slot; break; case ABS_MT_DISTANCE: value = touching ? 0 : 1; break; case ABS_MT_TOOL_TYPE: if (!axis_replacement_value(d, axes, ev->code, &value)) value = MT_TOOL_FINGER; break; default: if (!axis_replacement_value(d, axes, ev->code, &value) && d->interface->get_axis_default) { int error = d->interface->get_axis_default(d, ev->code, &value); if (error) { litest_abort_msg("Failed to get default axis value for %s (%d)\n", libevdev_event_code_get_name(EV_ABS, ev->code), ev->code); } } break; } return value; } static void send_btntool(struct litest_device *d, bool hover) { litest_event(d, EV_KEY, BTN_TOUCH, d->ntouches_down != 0 && !hover); litest_event(d, EV_KEY, BTN_TOOL_FINGER, d->ntouches_down == 1); litest_event(d, EV_KEY, BTN_TOOL_DOUBLETAP, d->ntouches_down == 2); litest_event(d, EV_KEY, BTN_TOOL_TRIPLETAP, d->ntouches_down == 3); litest_event(d, EV_KEY, BTN_TOOL_QUADTAP, d->ntouches_down == 4); litest_event(d, EV_KEY, BTN_TOOL_QUINTTAP, d->ntouches_down == 5); } static void slot_start(struct litest_device *d, unsigned int slot, double x, double y, struct axis_replacement *axes, bool touching, bool filter_abs_xy) { struct input_event *ev; litest_assert_int_ge(d->ntouches_down, 0); d->ntouches_down++; send_btntool(d, !touching); /* If the test device overrides touch_down and says it didn't * handle the event, let's continue normally */ if (d->interface->touch_down && d->interface->touch_down(d, slot, x, y)) return; for (ev = d->interface->touch_down_events; ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1; ev++) { int value = litest_auto_assign_value(d, ev, slot, x, y, axes, touching); if (value == LITEST_AUTO_ASSIGN) continue; if (filter_abs_xy && ev->type == EV_ABS && (ev->code == ABS_X || ev->code == ABS_Y)) continue; litest_event(d, ev->type, ev->code, value); } } static void slot_move(struct litest_device *d, unsigned int slot, double x, double y, struct axis_replacement *axes, bool touching, bool filter_abs_xy) { struct input_event *ev; if (d->interface->touch_move && d->interface->touch_move(d, slot, x, y)) return; for (ev = d->interface->touch_move_events; ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1; ev++) { int value = litest_auto_assign_value(d, ev, slot, x, y, axes, touching); if (value == LITEST_AUTO_ASSIGN) continue; if (filter_abs_xy && ev->type == EV_ABS && (ev->code == ABS_X || ev->code == ABS_Y)) continue; litest_event(d, ev->type, ev->code, value); } } static void touch_up(struct litest_device *d, unsigned int slot) { struct input_event *ev; struct input_event up[] = { { .type = EV_ABS, .code = ABS_MT_SLOT, .value = LITEST_AUTO_ASSIGN }, { .type = EV_ABS, .code = ABS_MT_TRACKING_ID, .value = -1 }, { .type = EV_ABS, .code = ABS_MT_PRESSURE, .value = 0 }, { .type = EV_ABS, .code = ABS_MT_TOUCH_MAJOR, .value = 0 }, { .type = EV_ABS, .code = ABS_MT_TOUCH_MINOR, .value = 0 }, { .type = EV_SYN, .code = SYN_REPORT, .value = 0 }, { .type = -1, .code = -1 } }; litest_assert_int_gt(d->ntouches_down, 0); d->ntouches_down--; send_btntool(d, false); if (d->interface->touch_up && d->interface->touch_up(d, slot)) { return; } else if (d->interface->touch_up_events) { ev = d->interface->touch_up_events; } else ev = up; for ( /* */; ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1; ev++) { int value = litest_auto_assign_value(d, ev, slot, 0, 0, NULL, false); litest_event(d, ev->type, ev->code, value); } } static void litest_slot_start(struct litest_device *d, unsigned int slot, double x, double y, struct axis_replacement *axes, bool touching) { double t, l, r = 0, b = 0; /* top, left, right, bottom */ bool filter_abs_xy = false; if (!d->semi_mt.is_semi_mt) { slot_start(d, slot, x, y, axes, touching, filter_abs_xy); return; } if (d->ntouches_down >= 2 || slot > 1) return; slot = d->ntouches_down; if (d->ntouches_down == 0) { l = x; t = y; } else { int other = (slot + 1) % 2; l = min(x, d->semi_mt.touches[other].x); t = min(y, d->semi_mt.touches[other].y); r = max(x, d->semi_mt.touches[other].x); b = max(y, d->semi_mt.touches[other].y); } litest_push_event_frame(d); if (d->ntouches_down == 0) slot_start(d, 0, l, t, axes, touching, filter_abs_xy); else slot_move(d, 0, l, t, axes, touching, filter_abs_xy); if (slot == 1) { filter_abs_xy = true; slot_start(d, 1, r, b, axes, touching, filter_abs_xy); } litest_pop_event_frame(d); d->semi_mt.touches[slot].x = x; d->semi_mt.touches[slot].y = y; } void litest_touch_sequence(struct litest_device *d, unsigned int slot, double x_from, double y_from, double x_to, double y_to, int steps) { litest_touch_down(d, slot, x_from, y_from); litest_touch_move_to(d, slot, x_from, y_from, x_to, y_to, steps); litest_touch_up(d, slot); } void litest_touch_down(struct litest_device *d, unsigned int slot, double x, double y) { litest_slot_start(d, slot, x, y, NULL, true); } void litest_touch_down_extended(struct litest_device *d, unsigned int slot, double x, double y, struct axis_replacement *axes) { litest_slot_start(d, slot, x, y, axes, true); } static void litest_slot_move(struct litest_device *d, unsigned int slot, double x, double y, struct axis_replacement *axes, bool touching) { double t, l, r = 0, b = 0; /* top, left, right, bottom */ bool filter_abs_xy = false; if (!d->semi_mt.is_semi_mt) { slot_move(d, slot, x, y, axes, touching, filter_abs_xy); return; } if (d->ntouches_down > 2 || slot > 1) return; if (d->ntouches_down == 1) { l = x; t = y; } else { int other = (slot + 1) % 2; l = min(x, d->semi_mt.touches[other].x); t = min(y, d->semi_mt.touches[other].y); r = max(x, d->semi_mt.touches[other].x); b = max(y, d->semi_mt.touches[other].y); } litest_push_event_frame(d); slot_move(d, 0, l, t, axes, touching, filter_abs_xy); if (d->ntouches_down == 2) { filter_abs_xy = true; slot_move(d, 1, r, b, axes, touching, filter_abs_xy); } litest_pop_event_frame(d); d->semi_mt.touches[slot].x = x; d->semi_mt.touches[slot].y = y; } void litest_touch_up(struct litest_device *d, unsigned int slot) { if (!d->semi_mt.is_semi_mt) { touch_up(d, slot); return; } if (d->ntouches_down > 2 || slot > 1) return; litest_push_event_frame(d); touch_up(d, d->ntouches_down - 1); /* if we have one finger left, send x/y coords for that finger left. this is likely to happen with a real touchpad */ if (d->ntouches_down == 1) { bool touching = true; bool filter_abs_xy = false; int other = (slot + 1) % 2; slot_move(d, 0, d->semi_mt.touches[other].x, d->semi_mt.touches[other].y, NULL, touching, filter_abs_xy); } litest_pop_event_frame(d); } void litest_touch_move(struct litest_device *d, unsigned int slot, double x, double y) { litest_slot_move(d, slot, x, y, NULL, true); } void litest_touch_move_extended(struct litest_device *d, unsigned int slot, double x, double y, struct axis_replacement *axes) { litest_slot_move(d, slot, x, y, axes, true); } void litest_touch_move_to(struct litest_device *d, unsigned int slot, double x_from, double y_from, double x_to, double y_to, int steps) { litest_touch_move_to_extended(d, slot, x_from, y_from, x_to, y_to, NULL, steps); } void litest_touch_move_to_extended(struct litest_device *d, unsigned int slot, double x_from, double y_from, double x_to, double y_to, struct axis_replacement *axes, int steps) { int sleep_ms = 10; for (int i = 1; i < steps; i++) { litest_touch_move_extended(d, slot, x_from + (x_to - x_from)/steps * i, y_from + (y_to - y_from)/steps * i, axes); libinput_dispatch(d->libinput); msleep(sleep_ms); libinput_dispatch(d->libinput); } litest_touch_move_extended(d, slot, x_to, y_to, axes); } static int auto_assign_tablet_value(struct litest_device *d, const struct input_event *ev, int x, int y, struct axis_replacement *axes) { static int tracking_id; int value = ev->value; if (value != LITEST_AUTO_ASSIGN || ev->type != EV_ABS) return value; switch (ev->code) { case ABS_MT_TRACKING_ID: value = ++tracking_id; break; case ABS_X: case ABS_MT_POSITION_X: value = litest_scale(d, ABS_X, x); break; case ABS_Y: case ABS_MT_POSITION_Y: value = litest_scale(d, ABS_Y, y); break; default: if (!axis_replacement_value(d, axes, ev->code, &value) && d->interface->get_axis_default) { int error = d->interface->get_axis_default(d, ev->code, &value); if (error) { litest_abort_msg("Failed to get default axis value for %s (%d)\n", libevdev_event_code_get_name(EV_ABS, ev->code), ev->code); } } break; } return value; } static int tablet_ignore_event(const struct input_event *ev, int value) { return value == -1 && (ev->code == ABS_PRESSURE || ev->code == ABS_DISTANCE); } void litest_tablet_set_tool_type(struct litest_device *d, unsigned int code) { switch (code) { case BTN_TOOL_PEN: case BTN_TOOL_RUBBER: case BTN_TOOL_BRUSH: case BTN_TOOL_PENCIL: case BTN_TOOL_AIRBRUSH: case BTN_TOOL_MOUSE: case BTN_TOOL_LENS: break; default: abort(); } d->interface->tool_type = code; } static void litest_tool_event(struct litest_device *d, int value) { unsigned int tool = d->interface->tool_type; litest_event(d, EV_KEY, tool, value); } void litest_tablet_proximity_in(struct litest_device *d, int x, int y, struct axis_replacement *axes) { struct input_event *ev; /* If the test device overrides proximity_in and says it didn't * handle the event, let's continue normally */ if (d->interface->tablet_proximity_in && d->interface->tablet_proximity_in(d, d->interface->tool_type, x, y, axes)) return; ev = d->interface->tablet_proximity_in_events; while (ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1) { int value; switch (evbit(ev->type, ev->code)) { case evbit(EV_KEY, LITEST_BTN_TOOL_AUTO): litest_tool_event(d, ev->value); break; default: value = auto_assign_tablet_value(d, ev, x, y, axes); if (!tablet_ignore_event(ev, value)) litest_event(d, ev->type, ev->code, value); } ev++; } } void litest_tablet_proximity_out(struct litest_device *d) { struct input_event *ev; /* If the test device overrides proximity_out and says it didn't * handle the event, let's continue normally */ if (d->interface->tablet_proximity_out && d->interface->tablet_proximity_out(d, d->interface->tool_type)) return; ev = d->interface->tablet_proximity_out_events; while (ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1) { int value; switch (evbit(ev->type, ev->code)) { case evbit(EV_KEY, LITEST_BTN_TOOL_AUTO): litest_tool_event(d, ev->value); break; default: value = auto_assign_tablet_value(d, ev, -1, -1, NULL); if (!tablet_ignore_event(ev, value)) litest_event(d, ev->type, ev->code, value); break; } ev++; } } void litest_tablet_motion(struct litest_device *d, int x, int y, struct axis_replacement *axes) { struct input_event *ev; ev = d->interface->tablet_motion_events; while (ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1) { int value = auto_assign_tablet_value(d, ev, x, y, axes); if (!tablet_ignore_event(ev, value)) litest_event(d, ev->type, ev->code, value); ev++; } } void litest_touch_move_two_touches(struct litest_device *d, double x0, double y0, double x1, double y1, double dx, double dy, int steps) { int sleep_ms = 10; for (int i = 1; i < steps; i++) { litest_push_event_frame(d); litest_touch_move(d, 0, x0 + dx / steps * i, y0 + dy / steps * i); litest_touch_move(d, 1, x1 + dx / steps * i, y1 + dy / steps * i); litest_pop_event_frame(d); libinput_dispatch(d->libinput); msleep(sleep_ms); libinput_dispatch(d->libinput); } litest_push_event_frame(d); litest_touch_move(d, 0, x0 + dx, y0 + dy); litest_touch_move(d, 1, x1 + dx, y1 + dy); litest_pop_event_frame(d); } void litest_touch_move_three_touches(struct litest_device *d, double x0, double y0, double x1, double y1, double x2, double y2, double dx, double dy, int steps) { int sleep_ms = 10; for (int i = 1; i <= steps; i++) { double step_x = dx / steps * i; double step_y = dy / steps * i; litest_push_event_frame(d); litest_touch_move(d, 0, x0 + step_x, y0 + step_y); litest_touch_move(d, 1, x1 + step_x, y1 + step_y); litest_touch_move(d, 2, x2 + step_x, y2 + step_y); litest_pop_event_frame(d); libinput_dispatch(d->libinput); msleep(sleep_ms); } libinput_dispatch(d->libinput); } void litest_hover_start(struct litest_device *d, unsigned int slot, double x, double y) { struct axis_replacement axes[] = { {ABS_MT_PRESSURE, 0 }, {ABS_PRESSURE, 0 }, {-1, -1 }, }; litest_slot_start(d, slot, x, y, axes, 0); } void litest_hover_end(struct litest_device *d, unsigned int slot) { struct input_event *ev; struct input_event up[] = { { .type = EV_ABS, .code = ABS_MT_SLOT, .value = LITEST_AUTO_ASSIGN }, { .type = EV_ABS, .code = ABS_MT_DISTANCE, .value = 1 }, { .type = EV_ABS, .code = ABS_MT_TRACKING_ID, .value = -1 }, { .type = EV_SYN, .code = SYN_REPORT, .value = 0 }, { .type = -1, .code = -1 } }; litest_assert_int_gt(d->ntouches_down, 0); d->ntouches_down--; send_btntool(d, true); if (d->interface->touch_up) { d->interface->touch_up(d, slot); return; } else if (d->interface->touch_up_events) { ev = d->interface->touch_up_events; } else ev = up; while (ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1) { int value = litest_auto_assign_value(d, ev, slot, 0, 0, NULL, false); litest_event(d, ev->type, ev->code, value); ev++; } } void litest_hover_move(struct litest_device *d, unsigned int slot, double x, double y) { struct axis_replacement axes[] = { {ABS_MT_PRESSURE, 0 }, {ABS_PRESSURE, 0 }, {-1, -1 }, }; litest_slot_move(d, slot, x, y, axes, false); } void litest_hover_move_to(struct litest_device *d, unsigned int slot, double x_from, double y_from, double x_to, double y_to, int steps) { int sleep_ms = 10; for (int i = 0; i < steps - 1; i++) { litest_hover_move(d, slot, x_from + (x_to - x_from)/steps * i, y_from + (y_to - y_from)/steps * i); libinput_dispatch(d->libinput); msleep(sleep_ms); libinput_dispatch(d->libinput); } litest_hover_move(d, slot, x_to, y_to); } void litest_hover_move_two_touches(struct litest_device *d, double x0, double y0, double x1, double y1, double dx, double dy, int steps) { int sleep_ms = 10; for (int i = 0; i < steps - 1; i++) { litest_push_event_frame(d); litest_hover_move(d, 0, x0 + dx / steps * i, y0 + dy / steps * i); litest_hover_move(d, 1, x1 + dx / steps * i, y1 + dy / steps * i); litest_pop_event_frame(d); libinput_dispatch(d->libinput); msleep(sleep_ms); libinput_dispatch(d->libinput); } litest_push_event_frame(d); litest_hover_move(d, 0, x0 + dx, y0 + dy); litest_hover_move(d, 1, x1 + dx, y1 + dy); litest_pop_event_frame(d); } void litest_button_click(struct litest_device *d, unsigned int button, bool is_press) { struct input_event *ev; struct input_event click[] = { { .type = EV_KEY, .code = button, .value = is_press ? 1 : 0 }, { .type = EV_SYN, .code = SYN_REPORT, .value = 0 }, }; ARRAY_FOR_EACH(click, ev) litest_event(d, ev->type, ev->code, ev->value); } void litest_button_click_debounced(struct litest_device *d, struct libinput *li, unsigned int button, bool is_press) { litest_button_click(d, button, is_press); libinput_dispatch(li); litest_timeout_debounce(); libinput_dispatch(li); } void litest_button_scroll(struct litest_device *dev, unsigned int button, double dx, double dy) { struct libinput *li = dev->libinput; litest_button_click_debounced(dev, li, button, 1); libinput_dispatch(li); litest_timeout_buttonscroll(); libinput_dispatch(li); litest_event(dev, EV_REL, REL_X, dx); litest_event(dev, EV_REL, REL_Y, dy); litest_event(dev, EV_SYN, SYN_REPORT, 0); litest_button_click_debounced(dev, li, button, 0); libinput_dispatch(li); } void litest_button_scroll_locked(struct litest_device *dev, unsigned int button, double dx, double dy) { struct libinput *li = dev->libinput; litest_button_click_debounced(dev, li, button, 1); litest_button_click_debounced(dev, li, button, 0); libinput_dispatch(li); litest_timeout_buttonscroll(); libinput_dispatch(li); litest_event(dev, EV_REL, REL_X, dx); litest_event(dev, EV_REL, REL_Y, dy); litest_event(dev, EV_SYN, SYN_REPORT, 0); libinput_dispatch(li); } void litest_keyboard_key(struct litest_device *d, unsigned int key, bool is_press) { struct input_event *ev; struct input_event click[] = { { .type = EV_KEY, .code = key, .value = is_press ? 1 : 0 }, { .type = EV_SYN, .code = SYN_REPORT, .value = 0 }, }; ARRAY_FOR_EACH(click, ev) litest_event(d, ev->type, ev->code, ev->value); } void litest_switch_action(struct litest_device *dev, enum libinput_switch sw, enum libinput_switch_state state) { unsigned int code; switch (sw) { case LIBINPUT_SWITCH_LID: code = SW_LID; break; case LIBINPUT_SWITCH_TABLET_MODE: code = SW_TABLET_MODE; break; default: litest_abort_msg("Invalid switch %d", sw); break; } litest_event(dev, EV_SW, code, state); litest_event(dev, EV_SYN, SYN_REPORT, 0); } static int litest_scale_axis(const struct litest_device *d, unsigned int axis, double val) { const struct input_absinfo *abs; litest_assert_double_ge(val, 0.0); /* major/minor must be able to beyond 100% for large fingers */ if (axis != ABS_MT_TOUCH_MAJOR && axis != ABS_MT_TOUCH_MINOR) { litest_assert_double_le(val, 100.0); } abs = libevdev_get_abs_info(d->evdev, axis); litest_assert_notnull(abs); return (abs->maximum - abs->minimum) * val/100.0 + abs->minimum; } static inline int litest_scale_range(int min, int max, double val) { litest_assert_int_ge((int)val, 0); litest_assert_int_le((int)val, 100); return (max - min) * val/100.0 + min; } int litest_scale(const struct litest_device *d, unsigned int axis, double val) { int min, max; litest_assert_double_ge(val, 0.0); /* major/minor must be able to beyond 100% for large fingers */ if (axis != ABS_MT_TOUCH_MAJOR && axis != ABS_MT_TOUCH_MINOR) litest_assert_double_le(val, 100.0); if (axis <= ABS_Y) { min = d->interface->min[axis]; max = d->interface->max[axis]; return litest_scale_range(min, max, val); } else { return litest_scale_axis(d, axis, val); } } static inline int auto_assign_pad_value(struct litest_device *dev, struct input_event *ev, double value) { const struct input_absinfo *abs; if (ev->value != LITEST_AUTO_ASSIGN || ev->type != EV_ABS) return value; abs = libevdev_get_abs_info(dev->evdev, ev->code); litest_assert_notnull(abs); if (ev->code == ABS_RX || ev->code == ABS_RY) { double min = abs->minimum != 0 ? log2(abs->minimum) : 0, max = abs->maximum != 0 ? log2(abs->maximum) : 0; /* Value 0 is reserved for finger up, so a value of 0% is * actually 1 */ if (value == 0.0) { return 1; } else { value = litest_scale_range(min, max, value); return pow(2, value); } } else { return litest_scale_range(abs->minimum, abs->maximum, value); } } void litest_pad_ring_start(struct litest_device *d, double value) { struct input_event *ev; ev = d->interface->pad_ring_start_events; while (ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1) { value = auto_assign_pad_value(d, ev, value); litest_event(d, ev->type, ev->code, value); ev++; } } void litest_pad_ring_change(struct litest_device *d, double value) { struct input_event *ev; ev = d->interface->pad_ring_change_events; while (ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1) { value = auto_assign_pad_value(d, ev, value); litest_event(d, ev->type, ev->code, value); ev++; } } void litest_pad_ring_end(struct litest_device *d) { struct input_event *ev; ev = d->interface->pad_ring_end_events; while (ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1) { litest_event(d, ev->type, ev->code, ev->value); ev++; } } void litest_pad_strip_start(struct litest_device *d, double value) { struct input_event *ev; ev = d->interface->pad_strip_start_events; while (ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1) { value = auto_assign_pad_value(d, ev, value); litest_event(d, ev->type, ev->code, value); ev++; } } void litest_pad_strip_change(struct litest_device *d, double value) { struct input_event *ev; ev = d->interface->pad_strip_change_events; while (ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1) { value = auto_assign_pad_value(d, ev, value); litest_event(d, ev->type, ev->code, value); ev++; } } void litest_pad_strip_end(struct litest_device *d) { struct input_event *ev; ev = d->interface->pad_strip_end_events; while (ev && (int16_t)ev->type != -1 && (int16_t)ev->code != -1) { litest_event(d, ev->type, ev->code, ev->value); ev++; } } void litest_wait_for_event(struct libinput *li) { return litest_wait_for_event_of_type(li, -1); } void litest_wait_for_event_of_type(struct libinput *li, ...) { va_list args; enum libinput_event_type types[32] = {LIBINPUT_EVENT_NONE}; size_t ntypes = 0; enum libinput_event_type type; struct pollfd fds; va_start(args, li); type = va_arg(args, int); while ((int)type != -1) { litest_assert_int_gt(type, 0U); litest_assert_int_lt(ntypes, ARRAY_LENGTH(types)); types[ntypes++] = type; type = va_arg(args, int); } va_end(args); fds.fd = libinput_get_fd(li); fds.events = POLLIN; fds.revents = 0; while (1) { size_t i; struct libinput_event *event; while ((type = libinput_next_event_type(li)) == LIBINPUT_EVENT_NONE) { int rc = poll(&fds, 1, 2000); litest_assert_int_gt(rc, 0); libinput_dispatch(li); } /* no event mask means wait for any event */ if (ntypes == 0) return; for (i = 0; i < ntypes; i++) { if (type == types[i]) return; } event = libinput_get_event(li); libinput_event_destroy(event); } } void litest_drain_events(struct libinput *li) { struct libinput_event *event; libinput_dispatch(li); while ((event = libinput_get_event(li))) { libinput_event_destroy(event); libinput_dispatch(li); } } void litest_drain_events_of_type(struct libinput *li, ...) { enum libinput_event_type type; enum libinput_event_type types[32] = {LIBINPUT_EVENT_NONE}; size_t ntypes = 0; va_list args; va_start(args, li); type = va_arg(args, int); while ((int)type != -1) { litest_assert_int_gt(type, 0U); litest_assert_int_lt(ntypes, ARRAY_LENGTH(types)); types[ntypes++] = type; type = va_arg(args, int); } va_end(args); libinput_dispatch(li); type = libinput_next_event_type(li); while (type != LIBINPUT_EVENT_NONE) { struct libinput_event *event; bool found = false; type = libinput_next_event_type(li); for (size_t i = 0; i < ntypes; i++) { if (type == types[i]) { found = true; break; } } if (!found) return; event = libinput_get_event(li); libinput_event_destroy(event); libinput_dispatch(li); } } static const char * litest_event_type_str(enum libinput_event_type type) { const char *str = NULL; switch (type) { case LIBINPUT_EVENT_NONE: abort(); case LIBINPUT_EVENT_DEVICE_ADDED: str = "ADDED"; break; case LIBINPUT_EVENT_DEVICE_REMOVED: str = "REMOVED"; break; case LIBINPUT_EVENT_KEYBOARD_KEY: str = "KEY"; break; case LIBINPUT_EVENT_POINTER_MOTION: str = "MOTION"; break; case LIBINPUT_EVENT_POINTER_MOTION_ABSOLUTE: str = "ABSOLUTE"; break; case LIBINPUT_EVENT_POINTER_BUTTON: str = "BUTTON"; break; case LIBINPUT_EVENT_POINTER_AXIS: str = "AXIS"; break; case LIBINPUT_EVENT_POINTER_SCROLL_WHEEL: str = "SCROLL_WHEEL"; break; case LIBINPUT_EVENT_POINTER_SCROLL_FINGER: str = "SCROLL_FINGER"; break; case LIBINPUT_EVENT_POINTER_SCROLL_CONTINUOUS: str = "SCROLL_CONTINUOUS"; break; case LIBINPUT_EVENT_TOUCH_DOWN: str = "TOUCH DOWN"; break; case LIBINPUT_EVENT_TOUCH_UP: str = "TOUCH UP"; break; case LIBINPUT_EVENT_TOUCH_MOTION: str = "TOUCH MOTION"; break; case LIBINPUT_EVENT_TOUCH_CANCEL: str = "TOUCH CANCEL"; break; case LIBINPUT_EVENT_TOUCH_FRAME: str = "TOUCH FRAME"; break; case LIBINPUT_EVENT_GESTURE_SWIPE_BEGIN: str = "GESTURE SWIPE BEGIN"; break; case LIBINPUT_EVENT_GESTURE_SWIPE_UPDATE: str = "GESTURE SWIPE UPDATE"; break; case LIBINPUT_EVENT_GESTURE_SWIPE_END: str = "GESTURE SWIPE END"; break; case LIBINPUT_EVENT_GESTURE_PINCH_BEGIN: str = "GESTURE PINCH BEGIN"; break; case LIBINPUT_EVENT_GESTURE_PINCH_UPDATE: str = "GESTURE PINCH UPDATE"; break; case LIBINPUT_EVENT_GESTURE_PINCH_END: str = "GESTURE PINCH END"; break; case LIBINPUT_EVENT_GESTURE_HOLD_BEGIN: str = "GESTURE HOLD BEGIN"; break; case LIBINPUT_EVENT_GESTURE_HOLD_END: str = "GESTURE HOLD END"; break; case LIBINPUT_EVENT_TABLET_TOOL_AXIS: str = "TABLET TOOL AXIS"; break; case LIBINPUT_EVENT_TABLET_TOOL_PROXIMITY: str = "TABLET TOOL PROX"; break; case LIBINPUT_EVENT_TABLET_TOOL_TIP: str = "TABLET TOOL TIP"; break; case LIBINPUT_EVENT_TABLET_TOOL_BUTTON: str = "TABLET TOOL BUTTON"; break; case LIBINPUT_EVENT_TABLET_PAD_BUTTON: str = "TABLET PAD BUTTON"; break; case LIBINPUT_EVENT_TABLET_PAD_RING: str = "TABLET PAD RING"; break; case LIBINPUT_EVENT_TABLET_PAD_STRIP: str = "TABLET PAD STRIP"; break; case LIBINPUT_EVENT_TABLET_PAD_KEY: str = "TABLET PAD KEY"; break; case LIBINPUT_EVENT_SWITCH_TOGGLE: str = "SWITCH TOGGLE"; break; } return str; } static const char * litest_event_get_type_str(struct libinput_event *event) { return litest_event_type_str(libinput_event_get_type(event)); } static void litest_print_event(struct libinput_event *event) { struct libinput_event_pointer *p; struct libinput_event_tablet_tool *t; struct libinput_event_tablet_pad *pad; struct libinput_device *dev; enum libinput_event_type type; double x, y; dev = libinput_event_get_device(event); type = libinput_event_get_type(event); fprintf(stderr, "device %s (%s) type %s ", libinput_device_get_sysname(dev), libinput_device_get_name(dev), litest_event_get_type_str(event)); switch (type) { case LIBINPUT_EVENT_POINTER_MOTION: p = libinput_event_get_pointer_event(event); x = libinput_event_pointer_get_dx(p); y = libinput_event_pointer_get_dy(p); fprintf(stderr, "%.2f/%.2f", x, y); break; case LIBINPUT_EVENT_POINTER_MOTION_ABSOLUTE: p = libinput_event_get_pointer_event(event); x = libinput_event_pointer_get_absolute_x(p); y = libinput_event_pointer_get_absolute_y(p); fprintf(stderr, "%.2f/%.2f", x, y); break; case LIBINPUT_EVENT_POINTER_BUTTON: p = libinput_event_get_pointer_event(event); fprintf(stderr, "button %d state %d", libinput_event_pointer_get_button(p), libinput_event_pointer_get_button_state(p)); break; case LIBINPUT_EVENT_POINTER_AXIS: p = libinput_event_get_pointer_event(event); x = 0.0; y = 0.0; if (libinput_event_pointer_has_axis(p, LIBINPUT_POINTER_AXIS_SCROLL_VERTICAL)) y = libinput_event_pointer_get_axis_value(p, LIBINPUT_POINTER_AXIS_SCROLL_VERTICAL); if (libinput_event_pointer_has_axis(p, LIBINPUT_POINTER_AXIS_SCROLL_HORIZONTAL)) x = libinput_event_pointer_get_axis_value(p, LIBINPUT_POINTER_AXIS_SCROLL_HORIZONTAL); fprintf(stderr, "vert %.2f horiz %.2f", y, x); break; case LIBINPUT_EVENT_TABLET_TOOL_PROXIMITY: t = libinput_event_get_tablet_tool_event(event); fprintf(stderr, "proximity %d", libinput_event_tablet_tool_get_proximity_state(t)); break; case LIBINPUT_EVENT_TABLET_TOOL_TIP: t = libinput_event_get_tablet_tool_event(event); fprintf(stderr, "tip %d", libinput_event_tablet_tool_get_tip_state(t)); break; case LIBINPUT_EVENT_TABLET_TOOL_BUTTON: t = libinput_event_get_tablet_tool_event(event); fprintf(stderr, "button %d state %d", libinput_event_tablet_tool_get_button(t), libinput_event_tablet_tool_get_button_state(t)); break; case LIBINPUT_EVENT_TABLET_PAD_BUTTON: pad = libinput_event_get_tablet_pad_event(event); fprintf(stderr, "button %d state %d", libinput_event_tablet_pad_get_button_number(pad), libinput_event_tablet_pad_get_button_state(pad)); break; case LIBINPUT_EVENT_TABLET_PAD_RING: pad = libinput_event_get_tablet_pad_event(event); fprintf(stderr, "ring %d position %.2f source %d", libinput_event_tablet_pad_get_ring_number(pad), libinput_event_tablet_pad_get_ring_position(pad), libinput_event_tablet_pad_get_ring_source(pad)); break; case LIBINPUT_EVENT_TABLET_PAD_STRIP: pad = libinput_event_get_tablet_pad_event(event); fprintf(stderr, "strip %d position %.2f source %d", libinput_event_tablet_pad_get_ring_number(pad), libinput_event_tablet_pad_get_ring_position(pad), libinput_event_tablet_pad_get_ring_source(pad)); break; default: break; } fprintf(stderr, "\n"); } #define litest_assert_event_type_is_one_of(...) \ _litest_assert_event_type_is_one_of(__VA_ARGS__, -1) static void _litest_assert_event_type_is_one_of(struct libinput_event *event, ...) { va_list args; enum libinput_event_type expected_type; enum libinput_event_type actual_type = libinput_event_get_type(event); bool match = false; va_start(args, event); expected_type = va_arg(args, int); while ((int)expected_type != -1 && !match) { match = (actual_type == expected_type); expected_type = va_arg(args, int); } va_end(args); if (match) return; fprintf(stderr, "FAILED EVENT TYPE: %s: have %s (%d) but want ", libinput_device_get_name(libinput_event_get_device(event)), litest_event_get_type_str(event), libinput_event_get_type(event)); va_start(args, event); expected_type = va_arg(args, int); while ((int)expected_type != -1) { fprintf(stderr, "%s (%d)", litest_event_type_str(expected_type), expected_type); expected_type = va_arg(args, int); if ((int)expected_type != -1) fprintf(stderr, " || "); } fprintf(stderr, "\nWrong event is: "); litest_print_event(event); litest_backtrace(); abort(); } void litest_assert_event_type(struct libinput_event *event, enum libinput_event_type want) { litest_assert_event_type_is_one_of(event, want); } void litest_assert_empty_queue(struct libinput *li) { bool empty_queue = true; struct libinput_event *event; libinput_dispatch(li); while ((event = libinput_get_event(li))) { empty_queue = false; fprintf(stderr, "Unexpected event: "); litest_print_event(event); libinput_event_destroy(event); libinput_dispatch(li); } litest_assert(empty_queue); } static struct libevdev_uinput * litest_create_uinput(const char *name, const struct input_id *id, const struct input_absinfo *abs_info, const int *events) { struct libevdev_uinput *uinput; struct libevdev *dev; int type, code; int rc, fd; const struct input_absinfo *abs; const struct input_absinfo default_abs = { .value = 0, .minimum = 0, .maximum = 100, .fuzz = 0, .flat = 0, .resolution = 100 }; char buf[512]; const char *devnode; dev = libevdev_new(); litest_assert_ptr_notnull(dev); snprintf(buf, sizeof(buf), "litest %s", name); libevdev_set_name(dev, buf); if (id) { libevdev_set_id_bustype(dev, id->bustype); libevdev_set_id_vendor(dev, id->vendor); libevdev_set_id_product(dev, id->product); libevdev_set_id_version(dev, id->version); } abs = abs_info; while (abs && abs->value != -1) { struct input_absinfo a = *abs; /* abs_info->value is used for the code and may be outside of [min, max] */ a.value = abs->minimum; rc = libevdev_enable_event_code(dev, EV_ABS, abs->value, &a); litest_assert_int_eq(rc, 0); abs++; } while (events && (type = *events++) != -1 && (code = *events++) != -1) { if (type == INPUT_PROP_MAX) { rc = libevdev_enable_property(dev, code); } else { rc = libevdev_enable_event_code(dev, type, code, type == EV_ABS ? &default_abs : NULL); } litest_assert_int_eq(rc, 0); } rc = libevdev_uinput_create_from_device(dev, LIBEVDEV_UINPUT_OPEN_MANAGED, &uinput); /* workaround for a bug in libevdev pre-1.3 http://cgit.freedesktop.org/libevdev/commit/?id=debe9b030c8069cdf78307888ef3b65830b25122 */ if (rc == -EBADF) rc = -EACCES; litest_assert_msg(rc == 0, "Failed to create uinput device: %s\n", strerror(-rc)); libevdev_free(dev); devnode = libevdev_uinput_get_devnode(uinput); litest_assert_notnull(devnode); fd = open(devnode, O_RDONLY); litest_assert_int_gt(fd, -1); rc = libevdev_new_from_fd(fd, &dev); litest_assert_int_eq(rc, 0); /* uinput before kernel 4.5 + libevdev 1.5.0 does not support * setting the resolution, so we set it afterwards. This is of * course racy as hell but the way we _generally_ use this function * by the time libinput uses the device, we're finished here. * * If you have kernel 4.5 and libevdev 1.5.0 or later, this code * just keeps the room warm. */ abs = abs_info; while (abs && abs->value != -1) { if (abs->resolution != 0) { if (libevdev_get_abs_resolution(dev, abs->value) == abs->resolution) break; rc = libevdev_kernel_set_abs_info(dev, abs->value, abs); litest_assert_int_eq(rc, 0); } abs++; } close(fd); libevdev_free(dev); return uinput; } struct libevdev_uinput * litest_create_uinput_device_from_description(const char *name, const struct input_id *id, const struct input_absinfo *abs_info, const int *events) { struct libevdev_uinput *uinput; const char *syspath; char path[PATH_MAX]; struct udev_monitor *udev_monitor; struct udev_device *udev_device; udev_monitor = udev_setup_monitor(); uinput = litest_create_uinput(name, id, abs_info, events); syspath = libevdev_uinput_get_syspath(uinput); snprintf(path, sizeof(path), "%s/event", syspath); udev_device = udev_wait_for_device_event(udev_monitor, "add", path); litest_assert(udev_device_get_property_value(udev_device, "ID_INPUT")); udev_device_unref(udev_device); udev_monitor_unref(udev_monitor); return uinput; } static struct libevdev_uinput * litest_create_uinput_abs_device_v(const char *name, struct input_id *id, const struct input_absinfo *abs, va_list args) { int events[KEY_MAX * 2 + 2]; /* increase this if not sufficient */ int *event = events; int type, code; while ((type = va_arg(args, int)) != -1 && (code = va_arg(args, int)) != -1) { *event++ = type; *event++ = code; litest_assert(event < &events[ARRAY_LENGTH(events) - 2]); } *event++ = -1; *event++ = -1; return litest_create_uinput_device_from_description(name, id, abs, events); } struct libevdev_uinput * litest_create_uinput_abs_device(const char *name, struct input_id *id, const struct input_absinfo *abs, ...) { struct libevdev_uinput *uinput; va_list args; va_start(args, abs); uinput = litest_create_uinput_abs_device_v(name, id, abs, args); va_end(args); return uinput; } struct libevdev_uinput * litest_create_uinput_device(const char *name, struct input_id *id, ...) { struct libevdev_uinput *uinput; va_list args; va_start(args, id); uinput = litest_create_uinput_abs_device_v(name, id, NULL, args); va_end(args); return uinput; } struct libinput_event_pointer* litest_is_button_event(struct libinput_event *event, unsigned int button, enum libinput_button_state state) { struct libinput_event_pointer *ptrev; enum libinput_event_type type = LIBINPUT_EVENT_POINTER_BUTTON; litest_assert_ptr_notnull(event); litest_assert_event_type(event, type); ptrev = libinput_event_get_pointer_event(event); litest_assert_int_eq(libinput_event_pointer_get_button(ptrev), button); litest_assert_int_eq(libinput_event_pointer_get_button_state(ptrev), state); return ptrev; } struct libinput_event_pointer * litest_is_axis_event(struct libinput_event *event, enum libinput_event_type axis_type, enum libinput_pointer_axis axis, enum libinput_pointer_axis_source source) { struct libinput_event_pointer *ptrev; litest_assert(axis_type == LIBINPUT_EVENT_POINTER_SCROLL_WHEEL || axis_type == LIBINPUT_EVENT_POINTER_SCROLL_FINGER || axis_type == LIBINPUT_EVENT_POINTER_SCROLL_CONTINUOUS); litest_assert_ptr_notnull(event); litest_assert_event_type_is_one_of(event, LIBINPUT_EVENT_POINTER_AXIS, axis_type); ptrev = libinput_event_get_pointer_event(event); litest_assert(libinput_event_pointer_has_axis(ptrev, axis)); if (source != 0) litest_assert_int_eq(litest_event_pointer_get_axis_source(ptrev), source); return ptrev; } bool litest_is_high_res_axis_event(struct libinput_event *event) { litest_assert_event_type_is_one_of(event, LIBINPUT_EVENT_POINTER_AXIS, LIBINPUT_EVENT_POINTER_SCROLL_WHEEL, LIBINPUT_EVENT_POINTER_SCROLL_FINGER, LIBINPUT_EVENT_POINTER_SCROLL_CONTINUOUS); return (libinput_event_get_type(event) != LIBINPUT_EVENT_POINTER_AXIS); } struct libinput_event_pointer * litest_is_motion_event(struct libinput_event *event) { struct libinput_event_pointer *ptrev; enum libinput_event_type type = LIBINPUT_EVENT_POINTER_MOTION; double x, y, ux, uy; litest_assert_ptr_notnull(event); litest_assert_event_type(event, type); ptrev = libinput_event_get_pointer_event(event); x = libinput_event_pointer_get_dx(ptrev); y = libinput_event_pointer_get_dy(ptrev); ux = libinput_event_pointer_get_dx_unaccelerated(ptrev); uy = libinput_event_pointer_get_dy_unaccelerated(ptrev); /* No 0 delta motion events */ litest_assert(x != 0.0 || y != 0.0 || ux != 0.0 || uy != 0.0); return ptrev; } void litest_assert_key_event(struct libinput *li, unsigned int key, enum libinput_key_state state) { struct libinput_event *event; litest_wait_for_event(li); event = libinput_get_event(li); litest_is_keyboard_event(event, key, state); libinput_event_destroy(event); } void litest_assert_button_event(struct libinput *li, unsigned int button, enum libinput_button_state state) { struct libinput_event *event; litest_wait_for_event(li); event = libinput_get_event(li); litest_is_button_event(event, button, state); libinput_event_destroy(event); } struct libinput_event_touch * litest_is_touch_event(struct libinput_event *event, enum libinput_event_type type) { struct libinput_event_touch *touch; litest_assert_ptr_notnull(event); if (type == 0) type = libinput_event_get_type(event); switch (type) { case LIBINPUT_EVENT_TOUCH_DOWN: case LIBINPUT_EVENT_TOUCH_UP: case LIBINPUT_EVENT_TOUCH_MOTION: case LIBINPUT_EVENT_TOUCH_FRAME: case LIBINPUT_EVENT_TOUCH_CANCEL: litest_assert_event_type(event, type); break; default: ck_abort_msg("%s: invalid touch type %d\n", __func__, type); } touch = libinput_event_get_touch_event(event); return touch; } struct libinput_event_keyboard * litest_is_keyboard_event(struct libinput_event *event, unsigned int key, enum libinput_key_state state) { struct libinput_event_keyboard *kevent; enum libinput_event_type type = LIBINPUT_EVENT_KEYBOARD_KEY; litest_assert_ptr_notnull(event); litest_assert_event_type(event, type); kevent = libinput_event_get_keyboard_event(event); litest_assert_ptr_notnull(kevent); litest_assert_int_eq(libinput_event_keyboard_get_key(kevent), key); litest_assert_int_eq(libinput_event_keyboard_get_key_state(kevent), state); return kevent; } struct libinput_event_gesture * litest_is_gesture_event(struct libinput_event *event, enum libinput_event_type type, int nfingers) { struct libinput_event_gesture *gevent; litest_assert_ptr_notnull(event); litest_assert_event_type(event, type); gevent = libinput_event_get_gesture_event(event); litest_assert_ptr_notnull(gevent); if (nfingers != -1) litest_assert_int_eq(libinput_event_gesture_get_finger_count(gevent), nfingers); return gevent; } void litest_assert_gesture_event(struct libinput *li, enum libinput_event_type type, int nfingers) { struct libinput_event *event; litest_wait_for_event(li); event = libinput_get_event(li); litest_is_gesture_event(event, type, nfingers); libinput_event_destroy(event); } struct libinput_event_tablet_tool * litest_is_tablet_event(struct libinput_event *event, enum libinput_event_type type) { struct libinput_event_tablet_tool *tevent; litest_assert_ptr_notnull(event); litest_assert_event_type(event, type); tevent = libinput_event_get_tablet_tool_event(event); litest_assert_ptr_notnull(tevent); return tevent; } void litest_assert_tablet_button_event(struct libinput *li, unsigned int button, enum libinput_button_state state) { struct libinput_event *event; struct libinput_event_tablet_tool *tev; enum libinput_event_type type = LIBINPUT_EVENT_TABLET_TOOL_BUTTON; litest_wait_for_event(li); event = libinput_get_event(li); litest_assert_notnull(event); litest_assert_event_type(event, type); tev = libinput_event_get_tablet_tool_event(event); litest_assert_int_eq(libinput_event_tablet_tool_get_button(tev), button); litest_assert_int_eq(libinput_event_tablet_tool_get_button_state(tev), state); libinput_event_destroy(event); } struct libinput_event_tablet_tool * litest_is_proximity_event(struct libinput_event *event, enum libinput_tablet_tool_proximity_state state) { struct libinput_event_tablet_tool *tev; enum libinput_event_type type = LIBINPUT_EVENT_TABLET_TOOL_PROXIMITY; litest_assert_notnull(event); litest_assert_event_type(event, type); tev = libinput_event_get_tablet_tool_event(event); litest_assert_int_eq(libinput_event_tablet_tool_get_proximity_state(tev), state); return tev; } double litest_event_pointer_get_value(struct libinput_event_pointer *ptrev, enum libinput_pointer_axis axis) { struct libinput_event *event; enum libinput_event_type type; event = libinput_event_pointer_get_base_event(ptrev); type = libinput_event_get_type(event); switch (type) { case LIBINPUT_EVENT_POINTER_AXIS: return libinput_event_pointer_get_axis_value(ptrev, axis); case LIBINPUT_EVENT_POINTER_SCROLL_WHEEL: return libinput_event_pointer_get_scroll_value_v120(ptrev, axis); case LIBINPUT_EVENT_POINTER_SCROLL_FINGER: case LIBINPUT_EVENT_POINTER_SCROLL_CONTINUOUS: return libinput_event_pointer_get_scroll_value(ptrev, axis); default: abort(); } } enum libinput_pointer_axis_source litest_event_pointer_get_axis_source(struct libinput_event_pointer *ptrev) { struct libinput_event *event; enum libinput_event_type type; event = libinput_event_pointer_get_base_event(ptrev); type = libinput_event_get_type(event); if (type == LIBINPUT_EVENT_POINTER_AXIS) return libinput_event_pointer_get_axis_source(ptrev); switch (type) { case LIBINPUT_EVENT_POINTER_SCROLL_WHEEL: return LIBINPUT_POINTER_AXIS_SOURCE_WHEEL; case LIBINPUT_EVENT_POINTER_SCROLL_FINGER: return LIBINPUT_POINTER_AXIS_SOURCE_FINGER; case LIBINPUT_EVENT_POINTER_SCROLL_CONTINUOUS: return LIBINPUT_POINTER_AXIS_SOURCE_CONTINUOUS; default: abort(); } } void litest_assert_tablet_proximity_event(struct libinput *li, enum libinput_tablet_tool_proximity_state state) { struct libinput_event *event; litest_wait_for_event(li); event = libinput_get_event(li); litest_is_proximity_event(event, state); libinput_event_destroy(event); } void litest_assert_tablet_tip_event(struct libinput *li, enum libinput_tablet_tool_tip_state state) { struct libinput_event *event; struct libinput_event_tablet_tool *tev; enum libinput_event_type type = LIBINPUT_EVENT_TABLET_TOOL_TIP; litest_wait_for_event(li); event = libinput_get_event(li); litest_assert_notnull(event); litest_assert_event_type(event, type); tev = libinput_event_get_tablet_tool_event(event); litest_assert_int_eq(libinput_event_tablet_tool_get_tip_state(tev), state); libinput_event_destroy(event); } struct libinput_event_tablet_pad * litest_is_pad_button_event(struct libinput_event *event, unsigned int button, enum libinput_button_state state) { struct libinput_event_tablet_pad *p; enum libinput_event_type type = LIBINPUT_EVENT_TABLET_PAD_BUTTON; litest_assert_ptr_notnull(event); litest_assert_event_type(event, type); p = libinput_event_get_tablet_pad_event(event); litest_assert_ptr_notnull(p); litest_assert_int_eq(libinput_event_tablet_pad_get_button_number(p), button); litest_assert_int_eq(libinput_event_tablet_pad_get_button_state(p), state); return p; } struct libinput_event_tablet_pad * litest_is_pad_ring_event(struct libinput_event *event, unsigned int number, enum libinput_tablet_pad_ring_axis_source source) { struct libinput_event_tablet_pad *p; enum libinput_event_type type = LIBINPUT_EVENT_TABLET_PAD_RING; litest_assert_ptr_notnull(event); litest_assert_event_type(event, type); p = libinput_event_get_tablet_pad_event(event); litest_assert_int_eq(libinput_event_tablet_pad_get_ring_number(p), number); litest_assert_int_eq(libinput_event_tablet_pad_get_ring_source(p), source); return p; } struct libinput_event_tablet_pad * litest_is_pad_strip_event(struct libinput_event *event, unsigned int number, enum libinput_tablet_pad_strip_axis_source source) { struct libinput_event_tablet_pad *p; enum libinput_event_type type = LIBINPUT_EVENT_TABLET_PAD_STRIP; litest_assert_ptr_notnull(event); litest_assert_event_type(event, type); p = libinput_event_get_tablet_pad_event(event); litest_assert_int_eq(libinput_event_tablet_pad_get_strip_number(p), number); litest_assert_int_eq(libinput_event_tablet_pad_get_strip_source(p), source); return p; } struct libinput_event_tablet_pad * litest_is_pad_key_event(struct libinput_event *event, unsigned int key, enum libinput_key_state state) { struct libinput_event_tablet_pad *p; enum libinput_event_type type = LIBINPUT_EVENT_TABLET_PAD_KEY; litest_assert(event != NULL); litest_assert_event_type(event, type); p = libinput_event_get_tablet_pad_event(event); litest_assert(p != NULL); litest_assert_int_eq(libinput_event_tablet_pad_get_key(p), key); litest_assert_int_eq(libinput_event_tablet_pad_get_key_state(p), state); return p; } struct libinput_event_switch * litest_is_switch_event(struct libinput_event *event, enum libinput_switch sw, enum libinput_switch_state state) { struct libinput_event_switch *swev; enum libinput_event_type type = LIBINPUT_EVENT_SWITCH_TOGGLE; litest_assert_notnull(event); litest_assert_event_type(event, type); swev = libinput_event_get_switch_event(event); litest_assert_int_eq(libinput_event_switch_get_switch(swev), sw); litest_assert_int_eq(libinput_event_switch_get_switch_state(swev), state); return swev; } void litest_assert_pad_button_event(struct libinput *li, unsigned int button, enum libinput_button_state state) { struct libinput_event *event; litest_wait_for_event(li); event = libinput_get_event(li); litest_is_pad_button_event(event, button, state); libinput_event_destroy(event); } void litest_assert_pad_key_event(struct libinput *li, unsigned int key, enum libinput_key_state state) { struct libinput_event *event; litest_wait_for_event(li); event = libinput_get_event(li); litest_is_pad_key_event(event, key, state); libinput_event_destroy(event); } void litest_assert_scroll(struct libinput *li, enum libinput_event_type axis_type, enum libinput_pointer_axis axis, int minimum_movement) { struct libinput_event *event; struct libinput_event_pointer *ptrev; bool last_hi_res_event_found, last_low_res_event_found; int value; int nevents = 0; litest_assert(axis_type == LIBINPUT_EVENT_POINTER_SCROLL_WHEEL || axis_type == LIBINPUT_EVENT_POINTER_SCROLL_FINGER || axis_type == LIBINPUT_EVENT_POINTER_SCROLL_CONTINUOUS); last_hi_res_event_found = false; last_low_res_event_found = false; event = libinput_get_event(li); litest_assert_ptr_notnull(event); while (event) { int min = minimum_movement; ptrev = litest_is_axis_event(event, axis_type, axis, 0); nevents++; /* Due to how the hysteresis works on touchpad * events, the first event is reduced by the * hysteresis margin that can cause the first event * go under the minimum we expect for all other * events */ if (nevents == 1) min = minimum_movement/2; value = litest_event_pointer_get_value(ptrev, axis); if (litest_is_high_res_axis_event(event)) { litest_assert(!last_hi_res_event_found); if (axis_type == LIBINPUT_EVENT_POINTER_SCROLL_WHEEL) min *= 120; if (value == 0) last_hi_res_event_found = true; } else { litest_assert(!last_low_res_event_found); if (value == 0) last_low_res_event_found = true; } if (value != 0) { if (minimum_movement > 0) litest_assert_int_ge(value, min); else litest_assert_int_le(value, min); } libinput_event_destroy(event); event = libinput_get_event(li); } litest_assert(last_low_res_event_found); litest_assert(last_hi_res_event_found); } void litest_assert_axis_end_sequence(struct libinput *li, enum libinput_event_type axis_type, enum libinput_pointer_axis axis, enum libinput_pointer_axis_source source) { struct libinput_event *event; struct libinput_event_pointer *ptrev; bool last_hi_res_event_found, last_low_res_event_found; double val; int i; litest_assert(axis_type == LIBINPUT_EVENT_POINTER_SCROLL_WHEEL || axis_type == LIBINPUT_EVENT_POINTER_SCROLL_FINGER || axis_type == LIBINPUT_EVENT_POINTER_SCROLL_CONTINUOUS); last_hi_res_event_found = false; last_low_res_event_found = false; /* both high and low scroll end events must be sent */ for (i = 0; i < 2; i++) { event = libinput_get_event(li); ptrev = litest_is_axis_event(event, axis_type, axis, source); val = litest_event_pointer_get_value(ptrev, axis); ck_assert(val == 0.0); if (litest_is_high_res_axis_event(event)) { litest_assert(!last_hi_res_event_found); last_hi_res_event_found = true; } else { litest_assert(!last_low_res_event_found); last_low_res_event_found = true; } libinput_event_destroy(event); } litest_assert(last_low_res_event_found); litest_assert(last_hi_res_event_found); } void litest_assert_only_typed_events(struct libinput *li, enum libinput_event_type type) { struct libinput_event *event; litest_assert(type != LIBINPUT_EVENT_NONE); libinput_dispatch(li); event = libinput_get_event(li); litest_assert_notnull(event); while (event) { litest_assert_event_type(event, type); libinput_event_destroy(event); libinput_dispatch(li); event = libinput_get_event(li); } } void litest_assert_only_axis_events(struct libinput *li, enum libinput_event_type axis_type) { struct libinput_event *event; litest_assert(axis_type == LIBINPUT_EVENT_POINTER_SCROLL_WHEEL || axis_type == LIBINPUT_EVENT_POINTER_SCROLL_FINGER || axis_type == LIBINPUT_EVENT_POINTER_SCROLL_CONTINUOUS); libinput_dispatch(li); event = libinput_get_event(li); litest_assert_notnull(event); while (event) { litest_assert_event_type_is_one_of(event, LIBINPUT_EVENT_POINTER_AXIS, axis_type); libinput_event_destroy(event); libinput_dispatch(li); event = libinput_get_event(li); } } void litest_assert_no_typed_events(struct libinput *li, enum libinput_event_type type) { struct libinput_event *event; litest_assert(type != LIBINPUT_EVENT_NONE); libinput_dispatch(li); event = libinput_get_event(li); while (event) { litest_assert_int_ne(libinput_event_get_type(event), type); libinput_event_destroy(event); libinput_dispatch(li); event = libinput_get_event(li); } } void litest_assert_touch_sequence(struct libinput *li) { struct libinput_event *event; struct libinput_event_touch *tev; int slot; event = libinput_get_event(li); tev = litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_DOWN); slot = libinput_event_touch_get_slot(tev); libinput_event_destroy(event); event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_FRAME); libinput_event_destroy(event); event = libinput_get_event(li); do { tev = litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_MOTION); litest_assert_int_eq(slot, libinput_event_touch_get_slot(tev)); libinput_event_destroy(event); event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_FRAME); libinput_event_destroy(event); event = libinput_get_event(li); litest_assert_notnull(event); } while (libinput_event_get_type(event) != LIBINPUT_EVENT_TOUCH_UP); tev = litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_UP); litest_assert_int_eq(slot, libinput_event_touch_get_slot(tev)); libinput_event_destroy(event); event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_FRAME); libinput_event_destroy(event); } void litest_assert_touch_motion_frame(struct libinput *li) { struct libinput_event *event; /* expect at least one, but maybe more */ event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_MOTION); libinput_event_destroy(event); event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_FRAME); libinput_event_destroy(event); event = libinput_get_event(li); while (event) { litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_MOTION); libinput_event_destroy(event); event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_FRAME); libinput_event_destroy(event); event = libinput_get_event(li); } } void litest_assert_touch_down_frame(struct libinput *li) { struct libinput_event *event; event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_DOWN); libinput_event_destroy(event); event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_FRAME); libinput_event_destroy(event); } void litest_assert_touch_up_frame(struct libinput *li) { struct libinput_event *event; event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_UP); libinput_event_destroy(event); event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_FRAME); libinput_event_destroy(event); } void litest_assert_touch_cancel(struct libinput *li) { struct libinput_event *event; event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_CANCEL); libinput_event_destroy(event); event = libinput_get_event(li); litest_is_touch_event(event, LIBINPUT_EVENT_TOUCH_FRAME); libinput_event_destroy(event); } void litest_timeout_tap(void) { msleep(300); } void litest_timeout_tapndrag(void) { msleep(520); } void litest_timeout_debounce(void) { msleep(30); } void litest_timeout_softbuttons(void) { msleep(300); } void litest_timeout_buttonscroll(void) { msleep(300); } void litest_timeout_finger_switch(void) { msleep(120); } void litest_timeout_edgescroll(void) { msleep(300); } void litest_timeout_middlebutton(void) { msleep(70); } void litest_timeout_dwt_short(void) { msleep(220); } void litest_timeout_dwt_long(void) { msleep(520); } void litest_timeout_gesture(void) { msleep(120); } void litest_timeout_gesture_scroll(void) { msleep(180); } void litest_timeout_gesture_hold(void) { msleep(300); } void litest_timeout_gesture_quick_hold(void) { msleep(60); } void litest_timeout_trackpoint(void) { msleep(320); } void litest_timeout_tablet_proxout(void) { msleep(170); } void litest_timeout_touch_arbitration(void) { msleep(100); } void litest_timeout_hysteresis(void) { msleep(90); } void litest_push_event_frame(struct litest_device *dev) { litest_assert_int_ge(dev->skip_ev_syn, 0); dev->skip_ev_syn++; } void litest_pop_event_frame(struct litest_device *dev) { litest_assert_int_gt(dev->skip_ev_syn, 0); dev->skip_ev_syn--; if (dev->skip_ev_syn == 0) litest_event(dev, EV_SYN, SYN_REPORT, 0); } void litest_filter_event(struct litest_device *dev, unsigned int type, unsigned int code) { libevdev_disable_event_code(dev->evdev, type, code); } void litest_unfilter_event(struct litest_device *dev, unsigned int type, unsigned int code) { /* would need an non-NULL argument for re-enabling, so simply abort * until we need to be more sophisticated */ litest_assert_int_ne(type, (unsigned int)EV_ABS); libevdev_enable_event_code(dev->evdev, type, code, NULL); } static void send_abs_xy(struct litest_device *d, double x, double y) { struct input_event e; int val; e.type = EV_ABS; e.code = ABS_X; e.value = LITEST_AUTO_ASSIGN; val = litest_auto_assign_value(d, &e, 0, x, y, NULL, true); litest_event(d, EV_ABS, ABS_X, val); e.code = ABS_Y; val = litest_auto_assign_value(d, &e, 0, x, y, NULL, true); litest_event(d, EV_ABS, ABS_Y, val); } static void send_abs_mt_xy(struct litest_device *d, double x, double y) { struct input_event e; int val; e.type = EV_ABS; e.code = ABS_MT_POSITION_X; e.value = LITEST_AUTO_ASSIGN; val = litest_auto_assign_value(d, &e, 0, x, y, NULL, true); litest_event(d, EV_ABS, ABS_MT_POSITION_X, val); e.code = ABS_MT_POSITION_Y; e.value = LITEST_AUTO_ASSIGN; val = litest_auto_assign_value(d, &e, 0, x, y, NULL, true); litest_event(d, EV_ABS, ABS_MT_POSITION_Y, val); } void litest_semi_mt_touch_down(struct litest_device *d, struct litest_semi_mt *semi_mt, unsigned int slot, double x, double y) { double t, l, r = 0, b = 0; /* top, left, right, bottom */ if (d->ntouches_down > 2 || slot > 1) return; if (d->ntouches_down == 1) { l = x; t = y; } else { int other = (slot + 1) % 2; l = min(x, semi_mt->touches[other].x); t = min(y, semi_mt->touches[other].y); r = max(x, semi_mt->touches[other].x); b = max(y, semi_mt->touches[other].y); } send_abs_xy(d, l, t); litest_event(d, EV_ABS, ABS_MT_SLOT, 0); if (d->ntouches_down == 1) litest_event(d, EV_ABS, ABS_MT_TRACKING_ID, ++semi_mt->tracking_id); send_abs_mt_xy(d, l, t); if (d->ntouches_down == 2) { litest_event(d, EV_ABS, ABS_MT_SLOT, 1); litest_event(d, EV_ABS, ABS_MT_TRACKING_ID, ++semi_mt->tracking_id); send_abs_mt_xy(d, r, b); } litest_event(d, EV_SYN, SYN_REPORT, 0); semi_mt->touches[slot].x = x; semi_mt->touches[slot].y = y; } void litest_semi_mt_touch_move(struct litest_device *d, struct litest_semi_mt *semi_mt, unsigned int slot, double x, double y) { double t, l, r = 0, b = 0; /* top, left, right, bottom */ if (d->ntouches_down > 2 || slot > 1) return; if (d->ntouches_down == 1) { l = x; t = y; } else { int other = (slot + 1) % 2; l = min(x, semi_mt->touches[other].x); t = min(y, semi_mt->touches[other].y); r = max(x, semi_mt->touches[other].x); b = max(y, semi_mt->touches[other].y); } send_abs_xy(d, l, t); litest_event(d, EV_ABS, ABS_MT_SLOT, 0); send_abs_mt_xy(d, l, t); if (d->ntouches_down == 2) { litest_event(d, EV_ABS, ABS_MT_SLOT, 1); send_abs_mt_xy(d, r, b); } litest_event(d, EV_SYN, SYN_REPORT, 0); semi_mt->touches[slot].x = x; semi_mt->touches[slot].y = y; } void litest_semi_mt_touch_up(struct litest_device *d, struct litest_semi_mt *semi_mt, unsigned int slot) { /* note: ntouches_down is decreased before we get here */ if (d->ntouches_down >= 2 || slot > 1) return; litest_event(d, EV_ABS, ABS_MT_SLOT, d->ntouches_down); litest_event(d, EV_ABS, ABS_MT_TRACKING_ID, -1); /* if we have one finger left, send x/y coords for that finger left. this is likely to happen with a real touchpad */ if (d->ntouches_down == 1) { int other = (slot + 1) % 2; send_abs_xy(d, semi_mt->touches[other].x, semi_mt->touches[other].y); litest_event(d, EV_ABS, ABS_MT_SLOT, 0); send_abs_mt_xy(d, semi_mt->touches[other].x, semi_mt->touches[other].y); } litest_event(d, EV_SYN, SYN_REPORT, 0); } enum litest_mode { LITEST_MODE_ERROR, LITEST_MODE_TEST, LITEST_MODE_LIST, }; static inline enum litest_mode litest_parse_argv(int argc, char **argv) { enum { OPT_FILTER_TEST, OPT_FILTER_DEVICE, OPT_FILTER_GROUP, OPT_FILTER_DEVICELESS, OPT_XML_PREFIX, OPT_JOBS, OPT_LIST, OPT_VERBOSE, }; static const struct option opts[] = { { "filter-test", 1, 0, OPT_FILTER_TEST }, { "filter-device", 1, 0, OPT_FILTER_DEVICE }, { "filter-group", 1, 0, OPT_FILTER_GROUP }, { "filter-deviceless", 0, 0, OPT_FILTER_DEVICELESS }, { "xml-output", 1, 0, OPT_XML_PREFIX }, { "jobs", 1, 0, OPT_JOBS }, { "list", 0, 0, OPT_LIST }, { "verbose", 0, 0, OPT_VERBOSE }, { "help", 0, 0, 'h'}, { 0, 0, 0, 0} }; enum { JOBS_DEFAULT, JOBS_SINGLE, JOBS_CUSTOM } want_jobs = JOBS_DEFAULT; char *builddir; char *jobs_env; /* If we are not running from the builddir, we assume we're running * against the system as installed */ builddir = builddir_lookup(); if (!builddir) use_system_rules_quirks = true; free(builddir); if (in_debugger) want_jobs = JOBS_SINGLE; if ((jobs_env = getenv("LITEST_JOBS"))) { if (!safe_atoi(jobs_env, &jobs)) { fprintf(stderr, "LITEST_JOBS environment variable must be positive integer\n"); exit(EXIT_FAILURE); } } while(1) { int c; int option_index = 0; c = getopt_long(argc, argv, "j:", opts, &option_index); if (c == -1) break; switch(c) { default: case 'h': printf("Usage: %s [--verbose] [--jobs] [--filter-...]\n" "\n" "Options:\n" " --filter-test=.... \n" " Glob to filter on test names\n" " --filter-device=.... \n" " Glob to filter on device names\n" " --filter-group=.... \n" " Glob to filter on test groups\n" " --filter-deviceless=.... \n" " Glob to filter on tests that do not create test devices\n" " --xml-output=/path/to/file-XXXXXXX.xml\n" " Write test output in libcheck's XML format\n" " to the given files. The file must match the format\n" " prefix-XXXXXX.xml and only the prefix is your choice.\n" " --verbose\n" " Enable verbose output\n" " --jobs 8\n" " Number of parallel test suites to run (default: 8).\n" " This overrides the LITEST_JOBS environment variable.\n" " --list\n" " List all tests\n" "\n" "See the libinput-test-suite(1) man page for details.\n", program_invocation_short_name); exit(c != 'h'); break; case OPT_FILTER_TEST: filter_test = optarg; if (want_jobs == JOBS_DEFAULT) want_jobs = JOBS_SINGLE; break; case OPT_FILTER_DEVICE: filter_device = optarg; if (want_jobs == JOBS_DEFAULT) want_jobs = JOBS_SINGLE; break; case OPT_FILTER_GROUP: filter_group = optarg; break; case OPT_XML_PREFIX: xml_prefix = optarg; break; case 'j': case OPT_JOBS: jobs = atoi(optarg); want_jobs = JOBS_CUSTOM; break; case OPT_LIST: return LITEST_MODE_LIST; case OPT_VERBOSE: verbose = true; break; case OPT_FILTER_DEVICELESS: run_deviceless = true; break; } } if (want_jobs == JOBS_SINGLE) jobs = 1; return LITEST_MODE_TEST; } #ifndef LITEST_NO_MAIN static bool is_debugger_attached(void) { int status; bool rc; int pid = fork(); if (pid == -1) return 0; if (pid == 0) { int ppid = getppid(); if (ptrace(PTRACE_ATTACH, ppid, NULL, 0) == 0) { waitpid(ppid, NULL, 0); ptrace(PTRACE_CONT, ppid, NULL, 0); ptrace(PTRACE_DETACH, ppid, NULL, 0); rc = false; } else { rc = true; } _exit(rc); } else { waitpid(pid, &status, 0); rc = WEXITSTATUS(status); } return !!rc; } static void litest_list_tests(struct list *tests) { struct suite *s; const char *last_test_name = NULL; list_for_each(s, tests, node) { struct test *t; printf("%s:\n", s->name); list_for_each(t, &s->tests, node) { if (!last_test_name || !streq(last_test_name, t->name)) printf(" %s:\n", t->name); last_test_name = t->name; printf(" %s\n", t->devname); } } } extern const struct test_device __start_test_section, __stop_test_section; static void litest_init_test_devices(void) { const struct test_device *t; list_init(&devices); for (t = &__start_test_section; t < &__stop_test_section; t++) list_append(&devices, &t->device->node); } extern const struct test_collection __start_test_collection_section, __stop_test_collection_section; static void setup_tests(void) { const struct test_collection *c; for (c = &__start_test_collection_section; c < &__stop_test_collection_section; c++) { c->setup(); } } static int check_device_access(void) { if (getuid() != 0) { fprintf(stderr, "%s must be run as root.\n", program_invocation_short_name); return 77; } if (access("/dev/uinput", F_OK) == -1 && access("/dev/input/uinput", F_OK) == -1) { fprintf(stderr, "uinput device is missing, skipping tests.\n"); return 77; } return 0; } static int disable_tty(void) { int tty_mode = -1; /* If we're running 'normally' on the VT, disable the keyboard to * avoid messing up our host. But if we're inside gdb or running * without forking, leave it as-is. */ if (!run_deviceless && jobs > 1 && !in_debugger && getenv("CK_FORK") == NULL && isatty(STDIN_FILENO) && ioctl(STDIN_FILENO, KDGKBMODE, &tty_mode) == 0) { #ifdef __linux__ ioctl(STDIN_FILENO, KDSKBMODE, K_OFF); #elif __FreeBSD__ ioctl(STDIN_FILENO, KDSKBMODE, K_RAW); /* Put the tty into raw mode */ struct termios tios; if (tcgetattr(STDIN_FILENO, &tios)) fprintf(stderr, "Failed to get terminal attribute: %d - %s\n", errno, strerror(errno)); cfmakeraw(&tios); if (tcsetattr(STDIN_FILENO, TCSAFLUSH, &tios)) fprintf(stderr, "Failed to set terminal attribute: %d - %s\n", errno, strerror(errno)); #endif } return tty_mode; } int main(int argc, char **argv) { const struct rlimit corelimit = { 0, 0 }; enum litest_mode mode; int tty_mode = -1; int failed_tests; int rc; const char *meson_testthreads; in_debugger = is_debugger_attached(); if (in_debugger || RUNNING_ON_VALGRIND) setenv("CK_FORK", "no", 0); if ((meson_testthreads = getenv("MESON_TESTTHREADS")) == NULL || !safe_atoi(meson_testthreads, &jobs)) { jobs = get_nprocs(); if (!RUNNING_ON_VALGRIND) jobs *= 2; } mode = litest_parse_argv(argc, argv); if (mode == LITEST_MODE_ERROR) return EXIT_FAILURE; litest_init_test_devices(); list_init(&all_tests); setup_tests(); if (mode == LITEST_MODE_LIST) { litest_list_tests(&all_tests); return EXIT_SUCCESS; } if (!run_deviceless && (rc = check_device_access()) != 0) return rc; setenv("CK_DEFAULT_TIMEOUT", "30", 0); setenv("LIBINPUT_RUNNING_TEST_SUITE", "1", 1); if (setrlimit(RLIMIT_CORE, &corelimit) != 0) perror("WARNING: Core dumps not disabled"); tty_mode = disable_tty(); failed_tests = litest_run(argc, argv); if (tty_mode != -1) { ioctl(STDIN_FILENO, KDSKBMODE, tty_mode); #ifdef __FreeBSD__ /* Put the tty into "sane" mode */ struct termios tios; if (tcgetattr(STDIN_FILENO, &tios)) fprintf(stderr, "Failed to get terminal attribute: %d - %s\n", errno, strerror(errno)); cfmakesane(&tios); if (tcsetattr(STDIN_FILENO, TCSAFLUSH, &tios)) fprintf(stderr, "Failed to set terminal attribute: %d - %s\n", errno, strerror(errno)); #endif } return min(failed_tests, 255); } #endif