glib/gio/tests/gsubprocess.c

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#include <gio/gio.h>
#include <string.h>
#ifdef G_OS_UNIX
#include <sys/wait.h>
#include <glib-unix.h>
#include <gio/gunixinputstream.h>
#include <gio/gfiledescriptorbased.h>
GSubprocessLauncher: allow to close passed FDs By default, when using g_subprocess_launcher_take_fd() to pass an FD to a child, the GSubprocessLauncher object also takes ownership of the FD in the parent, and closes it during finalize(). This is a reasonable assumption in the majority of the cases, but sometimes it isn't a good idea. An example is when creating a GSubprocessLauncher in JavaScript: here, the destruction process is managed by the Garbage Collector, which means that those sockets will remain opened for some time after all the references to the object has been droped. This means that it could be not possible to detect when the child has closed that same FD, because in order to make that work, both FDs instances (the one in the parent and the one in the children) must be closed. This can be a problem in, as an example, a process that launches a child that communicates with Wayland using an specific socket (like when using the new API MetaWaylandClient). Of course, it isn't a valid solution to manually call close() in the parent process just after the call to spawn(), because the FD number could be reused in the time between it is manually closed, and when the object is destroyed and closes again that FD. If that happens, it will close an incorrect FD. One solution could be to call run_dispose() from Javascript on the GSubprocessLauncher object, to force freeing the resources. Unfortunately, the current code frees them in the finalize() method, not in dispose() (this is fixed in !1670 (merged) ) but it isn't a very elegant solution. This proposal adds a new method, g_subprocess_launcher_close(), that allows to close the FDs passed to the child. To avoid problems, after closing an FD with this method, no more spawns are allowed. Fix: https://gitlab.gnome.org/GNOME/glib/-/merge_requests/1677
2020-10-04 14:34:41 +02:00
#include <unistd.h>
#include <fcntl.h>
#endif
/* We write 2^1 + 2^2 ... + 2^10 or 2047 copies of "Hello World!\n"
* ultimately
*/
#define TOTAL_HELLOS 2047
#define HELLO_WORLD "hello world!\n"
#ifdef G_OS_WIN32
#define LINEEND "\r\n"
#define EXEEXT ".exe"
#define SPLICELEN (TOTAL_HELLOS * (strlen (HELLO_WORLD) + 1)) /* because \r */
#else
#define LINEEND "\n"
#define EXEEXT
#define SPLICELEN (TOTAL_HELLOS * strlen (HELLO_WORLD))
#endif
static GPtrArray *
get_test_subprocess_args (const char *mode,
...) G_GNUC_NULL_TERMINATED;
static GPtrArray *
get_test_subprocess_args (const char *mode,
...)
{
GPtrArray *ret;
char *path;
const char *binname;
va_list args;
gpointer arg;
ret = g_ptr_array_new_with_free_func (g_free);
#ifdef G_OS_WIN32
binname = "gsubprocess-testprog.exe";
#else
binname = "gsubprocess-testprog";
#endif
path = g_test_build_filename (G_TEST_BUILT, binname, NULL);
g_ptr_array_add (ret, path);
g_ptr_array_add (ret, g_strdup (mode));
va_start (args, mode);
while ((arg = va_arg (args, gpointer)) != NULL)
g_ptr_array_add (ret, g_strdup (arg));
va_end (args);
g_ptr_array_add (ret, NULL);
return ret;
}
static void
test_noop (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GPtrArray *args;
GSubprocess *proc;
args = get_test_subprocess_args ("noop", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata, G_SUBPROCESS_FLAGS_NONE, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
g_subprocess_wait_check (proc, NULL, error);
g_assert_no_error (local_error);
g_assert_true (g_subprocess_get_successful (proc));
g_object_unref (proc);
}
static void
check_ready (GObject *source,
GAsyncResult *res,
gpointer user_data)
{
gboolean ret;
GError *error = NULL;
ret = g_subprocess_wait_check_finish (G_SUBPROCESS (source),
res,
&error);
g_assert_true (ret);
g_assert_no_error (error);
g_object_unref (source);
}
static void
test_noop_all_to_null (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GPtrArray *args;
GSubprocess *proc;
args = get_test_subprocess_args ("noop", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata,
G_SUBPROCESS_FLAGS_STDOUT_SILENCE | G_SUBPROCESS_FLAGS_STDERR_SILENCE,
error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
g_subprocess_wait_check_async (proc, NULL, check_ready, NULL);
}
static void
test_noop_no_wait (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GPtrArray *args;
GSubprocess *proc;
args = get_test_subprocess_args ("noop", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata, G_SUBPROCESS_FLAGS_NONE, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
g_object_unref (proc);
}
static void
test_noop_stdin_inherit (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GPtrArray *args;
GSubprocess *proc;
args = get_test_subprocess_args ("noop", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata, G_SUBPROCESS_FLAGS_STDIN_INHERIT, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
g_subprocess_wait_check (proc, NULL, error);
g_assert_no_error (local_error);
g_object_unref (proc);
}
#ifdef G_OS_UNIX
static void
test_search_path (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocess *proc;
proc = g_subprocess_new (G_SUBPROCESS_FLAGS_NONE, error, "true", NULL);
g_assert_no_error (local_error);
g_subprocess_wait_check (proc, NULL, error);
g_assert_no_error (local_error);
g_object_unref (proc);
}
#endif
static void
test_exit1 (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GPtrArray *args;
GSubprocess *proc;
args = get_test_subprocess_args ("exit1", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata, G_SUBPROCESS_FLAGS_NONE, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
g_subprocess_wait_check (proc, NULL, error);
g_assert_error (local_error, G_SPAWN_EXIT_ERROR, 1);
g_clear_error (error);
g_object_unref (proc);
}
typedef struct {
GMainLoop *loop;
GCancellable *cancellable;
gboolean cb_called;
} TestExit1CancelData;
static gboolean
test_exit1_cancel_idle_quit_cb (gpointer user_data)
{
GMainLoop *loop = user_data;
g_main_loop_quit (loop);
return G_SOURCE_REMOVE;
}
static void
test_exit1_cancel_wait_check_cb (GObject *source,
GAsyncResult *result,
gpointer user_data)
{
GSubprocess *subprocess = G_SUBPROCESS (source);
TestExit1CancelData *data = user_data;
gboolean ret;
GError *error = NULL;
g_assert_false (data->cb_called);
data->cb_called = TRUE;
ret = g_subprocess_wait_check_finish (subprocess, result, &error);
g_assert_false (ret);
g_assert_error (error, G_IO_ERROR, G_IO_ERROR_CANCELLED);
g_clear_error (&error);
g_idle_add (test_exit1_cancel_idle_quit_cb, data->loop);
}
static void
test_exit1_cancel (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GPtrArray *args;
GSubprocess *proc;
TestExit1CancelData data = { 0 };
g_test_bug ("https://bugzilla.gnome.org/show_bug.cgi?id=786456");
args = get_test_subprocess_args ("exit1", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata, G_SUBPROCESS_FLAGS_NONE, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
data.loop = g_main_loop_new (NULL, FALSE);
data.cancellable = g_cancellable_new ();
g_subprocess_wait_check_async (proc, data.cancellable, test_exit1_cancel_wait_check_cb, &data);
g_subprocess_wait_check (proc, NULL, error);
g_assert_error (local_error, G_SPAWN_EXIT_ERROR, 1);
g_clear_error (error);
g_cancellable_cancel (data.cancellable);
g_main_loop_run (data.loop);
g_object_unref (proc);
g_main_loop_unref (data.loop);
g_clear_object (&data.cancellable);
}
static void
test_exit1_cancel_in_cb_wait_check_cb (GObject *source,
GAsyncResult *result,
gpointer user_data)
{
GSubprocess *subprocess = G_SUBPROCESS (source);
TestExit1CancelData *data = user_data;
gboolean ret;
GError *error = NULL;
g_assert_false (data->cb_called);
data->cb_called = TRUE;
ret = g_subprocess_wait_check_finish (subprocess, result, &error);
g_assert_false (ret);
g_assert_error (error, G_SPAWN_EXIT_ERROR, 1);
g_clear_error (&error);
g_cancellable_cancel (data->cancellable);
g_idle_add (test_exit1_cancel_idle_quit_cb, data->loop);
}
static void
test_exit1_cancel_in_cb (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GPtrArray *args;
GSubprocess *proc;
TestExit1CancelData data = { 0 };
g_test_bug ("https://bugzilla.gnome.org/show_bug.cgi?id=786456");
args = get_test_subprocess_args ("exit1", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata, G_SUBPROCESS_FLAGS_NONE, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
data.loop = g_main_loop_new (NULL, FALSE);
data.cancellable = g_cancellable_new ();
g_subprocess_wait_check_async (proc, data.cancellable, test_exit1_cancel_in_cb_wait_check_cb, &data);
g_subprocess_wait_check (proc, NULL, error);
g_assert_error (local_error, G_SPAWN_EXIT_ERROR, 1);
g_clear_error (error);
g_main_loop_run (data.loop);
g_object_unref (proc);
g_main_loop_unref (data.loop);
g_clear_object (&data.cancellable);
}
static gchar *
splice_to_string (GInputStream *stream,
GError **error)
{
GMemoryOutputStream *buffer = NULL;
char *ret = NULL;
buffer = (GMemoryOutputStream*)g_memory_output_stream_new (NULL, 0, g_realloc, g_free);
if (g_output_stream_splice ((GOutputStream*)buffer, stream, 0, NULL, error) < 0)
goto out;
if (!g_output_stream_write ((GOutputStream*)buffer, "\0", 1, NULL, error))
goto out;
if (!g_output_stream_close ((GOutputStream*)buffer, NULL, error))
goto out;
ret = g_memory_output_stream_steal_data (buffer);
out:
g_clear_object (&buffer);
return ret;
}
static void
test_echo1 (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocess *proc;
GPtrArray *args;
GInputStream *stdout_stream;
gchar *result;
args = get_test_subprocess_args ("echo", "hello", "world!", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata, G_SUBPROCESS_FLAGS_STDOUT_PIPE, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
stdout_stream = g_subprocess_get_stdout_pipe (proc);
result = splice_to_string (stdout_stream, error);
g_assert_no_error (local_error);
g_assert_cmpstr (result, ==, "hello" LINEEND "world!" LINEEND);
g_free (result);
g_object_unref (proc);
}
#ifdef G_OS_UNIX
static void
test_echo_merged (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocess *proc;
GPtrArray *args;
GInputStream *stdout_stream;
gchar *result;
args = get_test_subprocess_args ("echo-stdout-and-stderr", "merge", "this", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata,
G_SUBPROCESS_FLAGS_STDOUT_PIPE | G_SUBPROCESS_FLAGS_STDERR_MERGE,
error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
stdout_stream = g_subprocess_get_stdout_pipe (proc);
result = splice_to_string (stdout_stream, error);
g_assert_no_error (local_error);
g_assert_cmpstr (result, ==, "merge\nmerge\nthis\nthis\n");
g_free (result);
g_object_unref (proc);
}
#endif
typedef struct {
guint events_pending;
GMainLoop *loop;
} TestCatData;
static void
test_cat_on_input_splice_complete (GObject *object,
GAsyncResult *result,
gpointer user_data)
{
TestCatData *data = user_data;
GError *error = NULL;
(void)g_output_stream_splice_finish ((GOutputStream*)object, result, &error);
g_assert_no_error (error);
data->events_pending--;
if (data->events_pending == 0)
g_main_loop_quit (data->loop);
}
static void
test_cat_utf8 (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocess *proc;
GPtrArray *args;
GBytes *input_buf;
GBytes *output_buf;
GInputStream *input_buf_stream = NULL;
GOutputStream *output_buf_stream = NULL;
GOutputStream *stdin_stream = NULL;
GInputStream *stdout_stream = NULL;
TestCatData data;
memset (&data, 0, sizeof (data));
data.loop = g_main_loop_new (NULL, TRUE);
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE | G_SUBPROCESS_FLAGS_STDOUT_PIPE,
error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
stdin_stream = g_subprocess_get_stdin_pipe (proc);
stdout_stream = g_subprocess_get_stdout_pipe (proc);
input_buf = g_bytes_new_static ("hello, world!", strlen ("hello, world!"));
input_buf_stream = g_memory_input_stream_new_from_bytes (input_buf);
g_bytes_unref (input_buf);
output_buf_stream = g_memory_output_stream_new (NULL, 0, g_realloc, g_free);
g_output_stream_splice_async (stdin_stream, input_buf_stream, G_OUTPUT_STREAM_SPLICE_CLOSE_SOURCE | G_OUTPUT_STREAM_SPLICE_CLOSE_TARGET,
G_PRIORITY_DEFAULT, NULL, test_cat_on_input_splice_complete,
&data);
data.events_pending++;
g_output_stream_splice_async (output_buf_stream, stdout_stream, G_OUTPUT_STREAM_SPLICE_CLOSE_SOURCE | G_OUTPUT_STREAM_SPLICE_CLOSE_TARGET,
G_PRIORITY_DEFAULT, NULL, test_cat_on_input_splice_complete,
&data);
data.events_pending++;
g_main_loop_run (data.loop);
g_subprocess_wait_check (proc, NULL, error);
g_assert_no_error (local_error);
output_buf = g_memory_output_stream_steal_as_bytes ((GMemoryOutputStream*)output_buf_stream);
g_assert_cmpmem (g_bytes_get_data (output_buf, NULL),
g_bytes_get_size (output_buf),
"hello, world!", 13);
g_bytes_unref (output_buf);
g_main_loop_unref (data.loop);
g_object_unref (input_buf_stream);
g_object_unref (output_buf_stream);
g_object_unref (proc);
}
static gpointer
cancel_soon (gpointer user_data)
{
GCancellable *cancellable = user_data;
g_usleep (G_TIME_SPAN_SECOND);
g_cancellable_cancel (cancellable);
g_object_unref (cancellable);
return NULL;
}
static void
test_cat_eof (void)
{
GCancellable *cancellable;
GError *error = NULL;
GSubprocess *cat;
gboolean result;
gchar buffer;
gssize s;
#ifdef G_OS_WIN32
g_test_skip ("This test has not been ported to Win32");
return;
#endif
/* Spawn 'cat' */
cat = g_subprocess_new (G_SUBPROCESS_FLAGS_STDIN_PIPE | G_SUBPROCESS_FLAGS_STDOUT_PIPE, &error, "cat", NULL);
g_assert_no_error (error);
g_assert_nonnull (cat);
/* Make sure that reading stdout blocks (until we cancel) */
cancellable = g_cancellable_new ();
g_thread_unref (g_thread_new ("cancel thread", cancel_soon, g_object_ref (cancellable)));
s = g_input_stream_read (g_subprocess_get_stdout_pipe (cat), &buffer, sizeof buffer, cancellable, &error);
g_assert_error (error, G_IO_ERROR, G_IO_ERROR_CANCELLED);
g_assert_cmpint (s, ==, -1);
g_object_unref (cancellable);
g_clear_error (&error);
/* Close the stream (EOF on cat's stdin) */
result = g_output_stream_close (g_subprocess_get_stdin_pipe (cat), NULL, &error);
g_assert_no_error (error);
g_assert_true (result);
/* Now check that reading cat's stdout gets us an EOF (since it quit) */
s = g_input_stream_read (g_subprocess_get_stdout_pipe (cat), &buffer, sizeof buffer, NULL, &error);
g_assert_no_error (error);
g_assert_false (s);
/* Check that the process has exited as a result of the EOF */
result = g_subprocess_wait (cat, NULL, &error);
g_assert_no_error (error);
g_assert_true (g_subprocess_get_if_exited (cat));
g_assert_cmpint (g_subprocess_get_exit_status (cat), ==, 0);
g_assert_true (result);
g_object_unref (cat);
}
typedef struct {
guint events_pending;
gboolean caught_error;
GError *error;
GMainLoop *loop;
gint counter;
GOutputStream *first_stdin;
} TestMultiSpliceData;
static void
on_one_multi_splice_done (GObject *obj,
GAsyncResult *res,
gpointer user_data)
{
TestMultiSpliceData *data = user_data;
if (!data->caught_error)
{
if (g_output_stream_splice_finish ((GOutputStream*)obj, res, &data->error) < 0)
data->caught_error = TRUE;
}
data->events_pending--;
if (data->events_pending == 0)
g_main_loop_quit (data->loop);
}
static gboolean
on_idle_multisplice (gpointer user_data)
{
TestMultiSpliceData *data = user_data;
if (data->counter >= TOTAL_HELLOS || data->caught_error)
{
if (!g_output_stream_close (data->first_stdin, NULL, &data->error))
data->caught_error = TRUE;
data->events_pending--;
if (data->events_pending == 0)
{
g_main_loop_quit (data->loop);
}
return FALSE;
}
else
{
int i;
for (i = 0; i < data->counter; i++)
{
gsize bytes_written;
if (!g_output_stream_write_all (data->first_stdin, HELLO_WORLD,
strlen (HELLO_WORLD), &bytes_written,
NULL, &data->error))
{
data->caught_error = TRUE;
return FALSE;
}
}
data->counter *= 2;
return TRUE;
}
}
static void
on_subprocess_exited (GObject *object,
GAsyncResult *result,
gpointer user_data)
{
GSubprocess *subprocess = G_SUBPROCESS (object);
TestMultiSpliceData *data = user_data;
GError *error = NULL;
if (!g_subprocess_wait_finish (subprocess, result, &error))
{
if (!data->caught_error)
{
data->caught_error = TRUE;
g_propagate_error (&data->error, error);
}
}
g_spawn_check_wait_status (g_subprocess_get_status (subprocess), &error);
g_assert_no_error (error);
data->events_pending--;
if (data->events_pending == 0)
g_main_loop_quit (data->loop);
}
static void
test_multi_1 (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GPtrArray *args;
GSubprocessLauncher *launcher;
GSubprocess *first;
GSubprocess *second;
GSubprocess *third;
GOutputStream *first_stdin;
GInputStream *first_stdout;
GOutputStream *second_stdin;
GInputStream *second_stdout;
GOutputStream *third_stdin;
GInputStream *third_stdout;
GOutputStream *membuf;
TestMultiSpliceData data;
int splice_flags = G_OUTPUT_STREAM_SPLICE_CLOSE_SOURCE | G_OUTPUT_STREAM_SPLICE_CLOSE_TARGET;
args = get_test_subprocess_args ("cat", NULL);
launcher = g_subprocess_launcher_new (G_SUBPROCESS_FLAGS_STDIN_PIPE | G_SUBPROCESS_FLAGS_STDOUT_PIPE);
first = g_subprocess_launcher_spawnv (launcher, (const gchar * const *) args->pdata, error);
g_assert_no_error (local_error);
second = g_subprocess_launcher_spawnv (launcher, (const gchar * const *) args->pdata, error);
g_assert_no_error (local_error);
third = g_subprocess_launcher_spawnv (launcher, (const gchar * const *) args->pdata, error);
g_assert_no_error (local_error);
g_ptr_array_free (args, TRUE);
membuf = g_memory_output_stream_new (NULL, 0, g_realloc, g_free);
first_stdin = g_subprocess_get_stdin_pipe (first);
first_stdout = g_subprocess_get_stdout_pipe (first);
second_stdin = g_subprocess_get_stdin_pipe (second);
second_stdout = g_subprocess_get_stdout_pipe (second);
third_stdin = g_subprocess_get_stdin_pipe (third);
third_stdout = g_subprocess_get_stdout_pipe (third);
memset (&data, 0, sizeof (data));
data.loop = g_main_loop_new (NULL, TRUE);
data.counter = 1;
data.first_stdin = first_stdin;
data.events_pending++;
g_output_stream_splice_async (second_stdin, first_stdout, splice_flags, G_PRIORITY_DEFAULT,
NULL, on_one_multi_splice_done, &data);
data.events_pending++;
g_output_stream_splice_async (third_stdin, second_stdout, splice_flags, G_PRIORITY_DEFAULT,
NULL, on_one_multi_splice_done, &data);
data.events_pending++;
g_output_stream_splice_async (membuf, third_stdout, splice_flags, G_PRIORITY_DEFAULT,
NULL, on_one_multi_splice_done, &data);
data.events_pending++;
g_timeout_add (250, on_idle_multisplice, &data);
data.events_pending++;
g_subprocess_wait_async (first, NULL, on_subprocess_exited, &data);
data.events_pending++;
g_subprocess_wait_async (second, NULL, on_subprocess_exited, &data);
data.events_pending++;
g_subprocess_wait_async (third, NULL, on_subprocess_exited, &data);
g_main_loop_run (data.loop);
g_assert_false (data.caught_error);
g_assert_no_error (data.error);
g_assert_cmpint (g_memory_output_stream_get_data_size ((GMemoryOutputStream*)membuf), ==, SPLICELEN);
g_main_loop_unref (data.loop);
g_object_unref (membuf);
g_object_unref (launcher);
g_object_unref (first);
g_object_unref (second);
g_object_unref (third);
}
typedef struct {
GSubprocessFlags flags;
gboolean is_utf8;
gboolean running;
GError *error;
} TestAsyncCommunicateData;
static void
on_communicate_complete (GObject *proc,
GAsyncResult *result,
gpointer user_data)
{
TestAsyncCommunicateData *data = user_data;
GBytes *stdout_bytes = NULL, *stderr_bytes = NULL;
char *stdout_str = NULL, *stderr_str = NULL;
const guint8 *stdout_data;
gsize stdout_len;
data->running = FALSE;
if (data->is_utf8)
(void) g_subprocess_communicate_utf8_finish ((GSubprocess*)proc, result,
&stdout_str, &stderr_str, &data->error);
else
(void) g_subprocess_communicate_finish ((GSubprocess*)proc, result,
&stdout_bytes, &stderr_bytes, &data->error);
if (data->error)
return;
if (data->flags & G_SUBPROCESS_FLAGS_STDOUT_PIPE)
{
if (data->is_utf8)
{
stdout_data = (guint8*)stdout_str;
stdout_len = strlen (stdout_str);
}
else
stdout_data = g_bytes_get_data (stdout_bytes, &stdout_len);
g_assert_cmpmem (stdout_data, stdout_len, "# hello world" LINEEND, 13 + strlen (LINEEND));
}
else
{
g_assert_null (stdout_str);
g_assert_null (stdout_bytes);
}
if (data->flags & G_SUBPROCESS_FLAGS_STDERR_PIPE)
{
if (data->is_utf8)
g_assert_nonnull (stderr_str);
else
g_assert_nonnull (stderr_bytes);
}
else
{
g_assert_null (stderr_str);
g_assert_null (stderr_bytes);
}
g_clear_pointer (&stdout_bytes, g_bytes_unref);
g_clear_pointer (&stderr_bytes, g_bytes_unref);
g_free (stdout_str);
g_free (stderr_str);
}
/* Test g_subprocess_communicate_async() works correctly with a variety of flags,
* as passed in via @test_data. */
static void
test_communicate_async (gconstpointer test_data)
{
GSubprocessFlags flags = GPOINTER_TO_INT (test_data);
GError *error = NULL;
GPtrArray *args;
TestAsyncCommunicateData data = { flags, 0, 0, NULL };
GSubprocess *proc;
GCancellable *cancellable = NULL;
GBytes *input;
const char *hellostring;
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar* const*)args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE | flags,
&error);
g_assert_no_error (error);
g_ptr_array_free (args, TRUE);
/* Include a leading hash and trailing newline so that if this gets onto the
* tests stdout, it doesnt mess up TAP output. */
hellostring = "# hello world\n";
input = g_bytes_new_static (hellostring, strlen (hellostring));
g_subprocess_communicate_async (proc, input,
cancellable,
on_communicate_complete,
&data);
data.running = TRUE;
while (data.running)
g_main_context_iteration (NULL, TRUE);
g_assert_no_error (data.error);
g_bytes_unref (input);
g_object_unref (proc);
}
/* Test g_subprocess_communicate() works correctly with a variety of flags,
* as passed in via @test_data. */
static void
test_communicate (gconstpointer test_data)
{
GSubprocessFlags flags = GPOINTER_TO_INT (test_data);
GError *error = NULL;
GPtrArray *args;
GSubprocess *proc;
GCancellable *cancellable = NULL;
GBytes *input;
const gchar *hellostring;
GBytes *stdout_bytes, *stderr_bytes;
const gchar *stdout_data;
gsize stdout_len;
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar* const*)args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE | flags,
&error);
g_assert_no_error (error);
g_ptr_array_free (args, TRUE);
/* Include a leading hash and trailing newline so that if this gets onto the
* tests stdout, it doesnt mess up TAP output. */
hellostring = "# hello world\n";
input = g_bytes_new_static (hellostring, strlen (hellostring));
g_subprocess_communicate (proc, input, cancellable, &stdout_bytes, &stderr_bytes, &error);
g_assert_no_error (error);
if (flags & G_SUBPROCESS_FLAGS_STDOUT_PIPE)
{
stdout_data = g_bytes_get_data (stdout_bytes, &stdout_len);
g_assert_cmpmem (stdout_data, stdout_len, "# hello world" LINEEND, 13 + strlen (LINEEND));
}
else
g_assert_null (stdout_bytes);
if (flags & G_SUBPROCESS_FLAGS_STDERR_PIPE)
g_assert_nonnull (stderr_bytes);
else
g_assert_null (stderr_bytes);
g_bytes_unref (input);
g_clear_pointer (&stdout_bytes, g_bytes_unref);
g_clear_pointer (&stderr_bytes, g_bytes_unref);
g_object_unref (proc);
}
typedef struct {
GSubprocess *proc;
GCancellable *cancellable;
gboolean is_utf8;
gboolean running;
GError *error;
} TestCancelledCommunicateData;
static gboolean
on_test_communicate_cancelled_idle (gpointer user_data)
{
TestCancelledCommunicateData *data = user_data;
GBytes *input;
const gchar *hellostring;
GBytes *stdout_bytes = NULL, *stderr_bytes = NULL;
gchar *stdout_buf = NULL, *stderr_buf = NULL;
/* Include a leading hash and trailing newline so that if this gets onto the
* tests stdout, it doesnt mess up TAP output. */
hellostring = "# hello world\n";
input = g_bytes_new_static (hellostring, strlen (hellostring));
if (data->is_utf8)
g_subprocess_communicate_utf8 (data->proc, hellostring, data->cancellable,
&stdout_buf, &stderr_buf, &data->error);
else
g_subprocess_communicate (data->proc, input, data->cancellable, &stdout_bytes,
&stderr_bytes, &data->error);
data->running = FALSE;
if (data->is_utf8)
{
g_assert_null (stdout_buf);
g_assert_null (stderr_buf);
}
else
{
g_assert_null (stdout_bytes);
g_assert_null (stderr_bytes);
}
g_bytes_unref (input);
return G_SOURCE_REMOVE;
}
/* Test g_subprocess_communicate() can be cancelled correctly */
static void
test_communicate_cancelled (gconstpointer test_data)
{
GSubprocessFlags flags = GPOINTER_TO_INT (test_data);
GPtrArray *args;
GSubprocess *proc;
GCancellable *cancellable = NULL;
GError *error = NULL;
TestCancelledCommunicateData data = { 0 };
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar* const*)args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE | flags,
&error);
g_assert_no_error (error);
g_ptr_array_free (args, TRUE);
cancellable = g_cancellable_new ();
data.proc = proc;
data.cancellable = cancellable;
data.error = error;
g_cancellable_cancel (cancellable);
g_idle_add (on_test_communicate_cancelled_idle, &data);
data.running = TRUE;
while (data.running)
g_main_context_iteration (NULL, TRUE);
g_assert_error (data.error, G_IO_ERROR, G_IO_ERROR_CANCELLED);
g_clear_error (&data.error);
g_object_unref (cancellable);
g_object_unref (proc);
}
static void
on_communicate_cancelled_complete (GObject *proc,
GAsyncResult *result,
gpointer user_data)
{
TestAsyncCommunicateData *data = user_data;
GBytes *stdout_bytes = NULL, *stderr_bytes = NULL;
char *stdout_str = NULL, *stderr_str = NULL;
data->running = FALSE;
if (data->is_utf8)
(void) g_subprocess_communicate_utf8_finish ((GSubprocess*)proc, result,
&stdout_str, &stderr_str, &data->error);
else
(void) g_subprocess_communicate_finish ((GSubprocess*)proc, result,
&stdout_bytes, &stderr_bytes, &data->error);
if (data->is_utf8)
{
g_assert_null (stdout_str);
g_assert_null (stderr_str);
}
else
{
g_assert_null (stdout_bytes);
g_assert_null (stderr_bytes);
}
}
/* Test g_subprocess_communicate_async() can be cancelled correctly,
* as passed in via @test_data. */
static void
test_communicate_cancelled_async (gconstpointer test_data)
{
GSubprocessFlags flags = GPOINTER_TO_INT (test_data);
GError *error = NULL;
GPtrArray *args;
TestAsyncCommunicateData data = { 0 };
GSubprocess *proc;
GCancellable *cancellable = NULL;
GBytes *input;
const char *hellostring;
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar* const*)args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE | flags,
&error);
g_assert_no_error (error);
g_ptr_array_free (args, TRUE);
/* Include a leading hash and trailing newline so that if this gets onto the
* tests stdout, it doesnt mess up TAP output. */
hellostring = "# hello world\n";
input = g_bytes_new_static (hellostring, strlen (hellostring));
cancellable = g_cancellable_new ();
g_subprocess_communicate_async (proc, input,
cancellable,
on_communicate_cancelled_complete,
&data);
g_cancellable_cancel (cancellable);
data.running = TRUE;
while (data.running)
g_main_context_iteration (NULL, TRUE);
g_assert_error (data.error, G_IO_ERROR, G_IO_ERROR_CANCELLED);
g_clear_error (&data.error);
g_bytes_unref (input);
g_object_unref (cancellable);
g_object_unref (proc);
}
/* Test g_subprocess_communicate_utf8_async() works correctly with a variety of
* flags, as passed in via @test_data. */
static void
test_communicate_utf8_async (gconstpointer test_data)
{
GSubprocessFlags flags = GPOINTER_TO_INT (test_data);
GError *error = NULL;
GPtrArray *args;
TestAsyncCommunicateData data = { flags, 0, 0, NULL };
GSubprocess *proc;
GCancellable *cancellable = NULL;
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar* const*)args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE | flags,
&error);
g_assert_no_error (error);
g_ptr_array_free (args, TRUE);
data.is_utf8 = TRUE;
g_subprocess_communicate_utf8_async (proc, "# hello world\n",
cancellable,
on_communicate_complete,
&data);
data.running = TRUE;
while (data.running)
g_main_context_iteration (NULL, TRUE);
g_assert_no_error (data.error);
g_object_unref (proc);
}
/* Test g_subprocess_communicate_utf8_async() can be cancelled correctly. */
static void
test_communicate_utf8_cancelled_async (gconstpointer test_data)
{
GSubprocessFlags flags = GPOINTER_TO_INT (test_data);
GError *error = NULL;
GPtrArray *args;
TestAsyncCommunicateData data = { flags, 0, 0, NULL };
GSubprocess *proc;
GCancellable *cancellable = NULL;
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar* const*)args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE | flags,
&error);
g_assert_no_error (error);
g_ptr_array_free (args, TRUE);
cancellable = g_cancellable_new ();
data.is_utf8 = TRUE;
g_subprocess_communicate_utf8_async (proc, "# hello world\n",
cancellable,
on_communicate_cancelled_complete,
&data);
g_cancellable_cancel (cancellable);
data.running = TRUE;
while (data.running)
g_main_context_iteration (NULL, TRUE);
g_assert_error (data.error, G_IO_ERROR, G_IO_ERROR_CANCELLED);
g_clear_error (&data.error);
g_object_unref (cancellable);
g_object_unref (proc);
}
/* Test g_subprocess_communicate_utf8() works correctly with a variety of flags,
* as passed in via @test_data. */
static void
test_communicate_utf8 (gconstpointer test_data)
{
GSubprocessFlags flags = GPOINTER_TO_INT (test_data);
GError *error = NULL;
GPtrArray *args;
GSubprocess *proc;
GCancellable *cancellable = NULL;
const gchar *stdin_buf;
gchar *stdout_buf, *stderr_buf;
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar* const*)args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE | flags,
&error);
g_assert_no_error (error);
g_ptr_array_free (args, TRUE);
/* Include a leading hash and trailing newline so that if this gets onto the
* tests stdout, it doesnt mess up TAP output. */
stdin_buf = "# hello world\n";
g_subprocess_communicate_utf8 (proc, stdin_buf, cancellable, &stdout_buf, &stderr_buf, &error);
g_assert_no_error (error);
if (flags & G_SUBPROCESS_FLAGS_STDOUT_PIPE)
g_assert_cmpstr (stdout_buf, ==, "# hello world" LINEEND);
else
g_assert_null (stdout_buf);
if (flags & G_SUBPROCESS_FLAGS_STDERR_PIPE)
g_assert_nonnull (stderr_buf);
else g_assert_null (stderr_buf);
g_free (stdout_buf);
g_free (stderr_buf);
g_object_unref (proc);
}
/* Test g_subprocess_communicate_utf8() can be cancelled correctly */
static void
test_communicate_utf8_cancelled (gconstpointer test_data)
{
GSubprocessFlags flags = GPOINTER_TO_INT (test_data);
GPtrArray *args;
GSubprocess *proc;
GCancellable *cancellable = NULL;
GError *error = NULL;
TestCancelledCommunicateData data = { 0 };
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar* const*)args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE | flags,
&error);
g_assert_no_error (error);
g_ptr_array_free (args, TRUE);
cancellable = g_cancellable_new ();
data.proc = proc;
data.cancellable = cancellable;
data.error = error;
g_cancellable_cancel (cancellable);
g_idle_add (on_test_communicate_cancelled_idle, &data);
data.is_utf8 = TRUE;
data.running = TRUE;
while (data.running)
g_main_context_iteration (NULL, TRUE);
g_assert_error (data.error, G_IO_ERROR, G_IO_ERROR_CANCELLED);
g_clear_error (&data.error);
g_object_unref (cancellable);
g_object_unref (proc);
}
static void
test_communicate_nothing (void)
{
GError *error = NULL;
GPtrArray *args;
GSubprocess *proc;
GCancellable *cancellable = NULL;
gchar *stdout_buf;
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar* const*)args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE
| G_SUBPROCESS_FLAGS_STDOUT_PIPE
| G_SUBPROCESS_FLAGS_STDERR_MERGE,
&error);
g_assert_no_error (error);
g_ptr_array_free (args, TRUE);
g_subprocess_communicate_utf8 (proc, "", cancellable, &stdout_buf, NULL, &error);
g_assert_no_error (error);
g_assert_cmpstr (stdout_buf, ==, "");
g_free (stdout_buf);
g_object_unref (proc);
}
static void
test_communicate_utf8_async_invalid (void)
{
GSubprocessFlags flags = G_SUBPROCESS_FLAGS_STDOUT_PIPE;
GError *error = NULL;
GPtrArray *args;
TestAsyncCommunicateData data = { flags, 0, 0, NULL };
GSubprocess *proc;
GCancellable *cancellable = NULL;
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar* const*)args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE | flags,
&error);
g_assert_no_error (error);
g_ptr_array_free (args, TRUE);
data.is_utf8 = TRUE;
g_subprocess_communicate_utf8_async (proc, "\xFF\xFF",
cancellable,
on_communicate_complete,
&data);
data.running = TRUE;
while (data.running)
g_main_context_iteration (NULL, TRUE);
g_assert_error (data.error, G_IO_ERROR, G_IO_ERROR_FAILED);
g_error_free (data.error);
g_object_unref (proc);
}
/* Test that invalid UTF-8 received using g_subprocess_communicate_utf8()
* results in an error. */
static void
test_communicate_utf8_invalid (void)
{
GSubprocessFlags flags = G_SUBPROCESS_FLAGS_STDOUT_PIPE;
GError *local_error = NULL;
gboolean ret;
GPtrArray *args;
gchar *stdout_str = NULL, *stderr_str = NULL;
GSubprocess *proc;
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_newv ((const gchar* const*)args->pdata,
G_SUBPROCESS_FLAGS_STDIN_PIPE | flags,
&local_error);
g_assert_no_error (local_error);
g_ptr_array_free (args, TRUE);
ret = g_subprocess_communicate_utf8 (proc, "\xFF\xFF", NULL,
&stdout_str, &stderr_str, &local_error);
g_assert_error (local_error, G_IO_ERROR, G_IO_ERROR_FAILED);
g_error_free (local_error);
g_assert_false (ret);
g_assert_null (stdout_str);
g_assert_null (stderr_str);
g_object_unref (proc);
}
static gboolean
send_terminate (gpointer user_data)
{
GSubprocess *proc = user_data;
g_subprocess_force_exit (proc);
return FALSE;
}
static void
on_request_quit_exited (GObject *object,
GAsyncResult *result,
gpointer user_data)
{
GSubprocess *subprocess = G_SUBPROCESS (object);
GError *error = NULL;
g_subprocess_wait_finish (subprocess, result, &error);
g_assert_no_error (error);
#ifdef G_OS_UNIX
g_assert_true (g_subprocess_get_if_signaled (subprocess));
g_assert_cmpint (g_subprocess_get_term_sig (subprocess), ==, 9);
#endif
g_spawn_check_wait_status (g_subprocess_get_status (subprocess), &error);
g_assert_nonnull (error);
g_clear_error (&error);
g_main_loop_quit ((GMainLoop*)user_data);
}
static void
test_terminate (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocess *proc;
GPtrArray *args;
GMainLoop *loop;
const gchar *id;
args = get_test_subprocess_args ("sleep-forever", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata, G_SUBPROCESS_FLAGS_NONE, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
id = g_subprocess_get_identifier (proc);
g_assert_nonnull (id);
loop = g_main_loop_new (NULL, TRUE);
g_subprocess_wait_async (proc, NULL, on_request_quit_exited, loop);
g_timeout_add_seconds (3, send_terminate, proc);
g_main_loop_run (loop);
g_main_loop_unref (loop);
g_object_unref (proc);
}
#ifdef G_OS_UNIX
static gboolean
send_signal (gpointer user_data)
{
GSubprocess *proc = user_data;
g_subprocess_send_signal (proc, SIGKILL);
return FALSE;
}
static void
test_signal (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocess *proc;
GPtrArray *args;
GMainLoop *loop;
args = get_test_subprocess_args ("sleep-forever", NULL);
proc = g_subprocess_newv ((const gchar * const *) args->pdata, G_SUBPROCESS_FLAGS_NONE, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
loop = g_main_loop_new (NULL, TRUE);
g_subprocess_wait_async (proc, NULL, on_request_quit_exited, loop);
g_timeout_add_seconds (3, send_signal, proc);
g_main_loop_run (loop);
g_main_loop_unref (loop);
g_object_unref (proc);
}
#endif
static void
test_env (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocessLauncher *launcher;
GSubprocess *proc;
GPtrArray *args;
GInputStream *stdout_stream;
gchar *result;
gchar *envp[] = { NULL, "ONE=1", "TWO=1", "THREE=3", "FOUR=1", NULL };
gchar **split;
envp[0] = g_strdup_printf ("PATH=%s", g_getenv ("PATH"));
args = get_test_subprocess_args ("env", NULL);
launcher = g_subprocess_launcher_new (G_SUBPROCESS_FLAGS_NONE);
g_subprocess_launcher_set_flags (launcher, G_SUBPROCESS_FLAGS_STDOUT_PIPE);
g_subprocess_launcher_set_environ (launcher, envp);
g_subprocess_launcher_setenv (launcher, "TWO", "2", TRUE);
g_subprocess_launcher_setenv (launcher, "THREE", "1", FALSE);
g_subprocess_launcher_unsetenv (launcher, "FOUR");
g_assert_null (g_subprocess_launcher_getenv (launcher, "FOUR"));
proc = g_subprocess_launcher_spawn (launcher, error, args->pdata[0], "env", NULL);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
g_free (envp[0]);
stdout_stream = g_subprocess_get_stdout_pipe (proc);
result = splice_to_string (stdout_stream, error);
split = g_strsplit (result, LINEEND, -1);
g_assert_cmpstr (g_environ_getenv (split, "ONE"), ==, "1");
g_assert_cmpstr (g_environ_getenv (split, "TWO"), ==, "2");
g_assert_cmpstr (g_environ_getenv (split, "THREE"), ==, "3");
g_assert_null (g_environ_getenv (split, "FOUR"));
g_strfreev (split);
g_free (result);
g_object_unref (proc);
g_object_unref (launcher);
}
/* Test that explicitly inheriting and modifying the parent process
* environment works. */
static void
test_env_inherit (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocessLauncher *launcher;
GSubprocess *proc;
GPtrArray *args;
GInputStream *stdout_stream;
gchar *result;
gchar **split;
g_setenv ("TEST_ENV_INHERIT1", "1", TRUE);
g_setenv ("TEST_ENV_INHERIT2", "2", TRUE);
args = get_test_subprocess_args ("env", NULL);
launcher = g_subprocess_launcher_new (G_SUBPROCESS_FLAGS_NONE);
g_subprocess_launcher_set_flags (launcher, G_SUBPROCESS_FLAGS_STDOUT_PIPE);
g_subprocess_launcher_set_environ (launcher, NULL);
g_subprocess_launcher_setenv (launcher, "TWO", "2", TRUE);
g_subprocess_launcher_unsetenv (launcher, "TEST_ENV_INHERIT1");
g_assert_null (g_subprocess_launcher_getenv (launcher, "TEST_ENV_INHERIT1"));
g_assert_cmpstr (g_subprocess_launcher_getenv (launcher, "TEST_ENV_INHERIT2"), ==, "2");
g_assert_cmpstr (g_subprocess_launcher_getenv (launcher, "TWO"), ==, "2");
proc = g_subprocess_launcher_spawn (launcher, error, args->pdata[0], "env", NULL);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
stdout_stream = g_subprocess_get_stdout_pipe (proc);
result = splice_to_string (stdout_stream, error);
split = g_strsplit (result, LINEEND, -1);
g_assert_null (g_environ_getenv (split, "TEST_ENV_INHERIT1"));
g_assert_cmpstr (g_environ_getenv (split, "TEST_ENV_INHERIT2"), ==, "2");
g_assert_cmpstr (g_environ_getenv (split, "TWO"), ==, "2");
g_strfreev (split);
g_free (result);
g_object_unref (proc);
g_object_unref (launcher);
}
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static void
test_cwd (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocessLauncher *launcher;
GSubprocess *proc;
GPtrArray *args;
GInputStream *stdout_stream;
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gchar *result;
const char *basename;
gchar *tmp_lineend;
const gchar *tmp_lineend_basename;
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args = get_test_subprocess_args ("cwd", NULL);
launcher = g_subprocess_launcher_new (G_SUBPROCESS_FLAGS_STDOUT_PIPE);
g_subprocess_launcher_set_flags (launcher, G_SUBPROCESS_FLAGS_STDOUT_PIPE);
g_subprocess_launcher_set_cwd (launcher, g_get_tmp_dir ());
tmp_lineend = g_strdup_printf ("%s%s", g_get_tmp_dir (), LINEEND);
tmp_lineend_basename = g_strrstr (tmp_lineend, G_DIR_SEPARATOR_S);
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proc = g_subprocess_launcher_spawnv (launcher, (const char * const *)args->pdata, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
stdout_stream = g_subprocess_get_stdout_pipe (proc);
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result = splice_to_string (stdout_stream, error);
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basename = g_strrstr (result, G_DIR_SEPARATOR_S);
g_assert_nonnull (basename);
g_assert_cmpstr (basename, ==, tmp_lineend_basename);
g_free (tmp_lineend);
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g_free (result);
g_object_unref (proc);
g_object_unref (launcher);
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}
#ifdef G_OS_UNIX
GSubprocessLauncher: allow to close passed FDs By default, when using g_subprocess_launcher_take_fd() to pass an FD to a child, the GSubprocessLauncher object also takes ownership of the FD in the parent, and closes it during finalize(). This is a reasonable assumption in the majority of the cases, but sometimes it isn't a good idea. An example is when creating a GSubprocessLauncher in JavaScript: here, the destruction process is managed by the Garbage Collector, which means that those sockets will remain opened for some time after all the references to the object has been droped. This means that it could be not possible to detect when the child has closed that same FD, because in order to make that work, both FDs instances (the one in the parent and the one in the children) must be closed. This can be a problem in, as an example, a process that launches a child that communicates with Wayland using an specific socket (like when using the new API MetaWaylandClient). Of course, it isn't a valid solution to manually call close() in the parent process just after the call to spawn(), because the FD number could be reused in the time between it is manually closed, and when the object is destroyed and closes again that FD. If that happens, it will close an incorrect FD. One solution could be to call run_dispose() from Javascript on the GSubprocessLauncher object, to force freeing the resources. Unfortunately, the current code frees them in the finalize() method, not in dispose() (this is fixed in !1670 (merged) ) but it isn't a very elegant solution. This proposal adds a new method, g_subprocess_launcher_close(), that allows to close the FDs passed to the child. To avoid problems, after closing an FD with this method, no more spawns are allowed. Fix: https://gitlab.gnome.org/GNOME/glib/-/merge_requests/1677
2020-10-04 14:34:41 +02:00
static void
test_subprocess_launcher_close (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocessLauncher *launcher;
GSubprocess *proc;
GPtrArray *args;
int fd, fd2;
GSubprocessLauncher: allow to close passed FDs By default, when using g_subprocess_launcher_take_fd() to pass an FD to a child, the GSubprocessLauncher object also takes ownership of the FD in the parent, and closes it during finalize(). This is a reasonable assumption in the majority of the cases, but sometimes it isn't a good idea. An example is when creating a GSubprocessLauncher in JavaScript: here, the destruction process is managed by the Garbage Collector, which means that those sockets will remain opened for some time after all the references to the object has been droped. This means that it could be not possible to detect when the child has closed that same FD, because in order to make that work, both FDs instances (the one in the parent and the one in the children) must be closed. This can be a problem in, as an example, a process that launches a child that communicates with Wayland using an specific socket (like when using the new API MetaWaylandClient). Of course, it isn't a valid solution to manually call close() in the parent process just after the call to spawn(), because the FD number could be reused in the time between it is manually closed, and when the object is destroyed and closes again that FD. If that happens, it will close an incorrect FD. One solution could be to call run_dispose() from Javascript on the GSubprocessLauncher object, to force freeing the resources. Unfortunately, the current code frees them in the finalize() method, not in dispose() (this is fixed in !1670 (merged) ) but it isn't a very elegant solution. This proposal adds a new method, g_subprocess_launcher_close(), that allows to close the FDs passed to the child. To avoid problems, after closing an FD with this method, no more spawns are allowed. Fix: https://gitlab.gnome.org/GNOME/glib/-/merge_requests/1677
2020-10-04 14:34:41 +02:00
gboolean is_open;
/* Open two arbitrary FDs. One of them, @fd, will be transferred to the
* launcher, and the others FD integer will be used as its target FD, giving
* the mapping `fd fd2` if a child process were to be spawned.
*
* The launcher will then be closed, which should close @fd but *not* @fd2,
* as the value of @fd2 is only valid as an FD in a child process. (A child
* process is not actually spawned in this test.)
*/
fd = dup (0);
fd2 = dup (0);
GSubprocessLauncher: allow to close passed FDs By default, when using g_subprocess_launcher_take_fd() to pass an FD to a child, the GSubprocessLauncher object also takes ownership of the FD in the parent, and closes it during finalize(). This is a reasonable assumption in the majority of the cases, but sometimes it isn't a good idea. An example is when creating a GSubprocessLauncher in JavaScript: here, the destruction process is managed by the Garbage Collector, which means that those sockets will remain opened for some time after all the references to the object has been droped. This means that it could be not possible to detect when the child has closed that same FD, because in order to make that work, both FDs instances (the one in the parent and the one in the children) must be closed. This can be a problem in, as an example, a process that launches a child that communicates with Wayland using an specific socket (like when using the new API MetaWaylandClient). Of course, it isn't a valid solution to manually call close() in the parent process just after the call to spawn(), because the FD number could be reused in the time between it is manually closed, and when the object is destroyed and closes again that FD. If that happens, it will close an incorrect FD. One solution could be to call run_dispose() from Javascript on the GSubprocessLauncher object, to force freeing the resources. Unfortunately, the current code frees them in the finalize() method, not in dispose() (this is fixed in !1670 (merged) ) but it isn't a very elegant solution. This proposal adds a new method, g_subprocess_launcher_close(), that allows to close the FDs passed to the child. To avoid problems, after closing an FD with this method, no more spawns are allowed. Fix: https://gitlab.gnome.org/GNOME/glib/-/merge_requests/1677
2020-10-04 14:34:41 +02:00
launcher = g_subprocess_launcher_new (G_SUBPROCESS_FLAGS_NONE);
g_subprocess_launcher_take_fd (launcher, fd, fd2);
GSubprocessLauncher: allow to close passed FDs By default, when using g_subprocess_launcher_take_fd() to pass an FD to a child, the GSubprocessLauncher object also takes ownership of the FD in the parent, and closes it during finalize(). This is a reasonable assumption in the majority of the cases, but sometimes it isn't a good idea. An example is when creating a GSubprocessLauncher in JavaScript: here, the destruction process is managed by the Garbage Collector, which means that those sockets will remain opened for some time after all the references to the object has been droped. This means that it could be not possible to detect when the child has closed that same FD, because in order to make that work, both FDs instances (the one in the parent and the one in the children) must be closed. This can be a problem in, as an example, a process that launches a child that communicates with Wayland using an specific socket (like when using the new API MetaWaylandClient). Of course, it isn't a valid solution to manually call close() in the parent process just after the call to spawn(), because the FD number could be reused in the time between it is manually closed, and when the object is destroyed and closes again that FD. If that happens, it will close an incorrect FD. One solution could be to call run_dispose() from Javascript on the GSubprocessLauncher object, to force freeing the resources. Unfortunately, the current code frees them in the finalize() method, not in dispose() (this is fixed in !1670 (merged) ) but it isn't a very elegant solution. This proposal adds a new method, g_subprocess_launcher_close(), that allows to close the FDs passed to the child. To avoid problems, after closing an FD with this method, no more spawns are allowed. Fix: https://gitlab.gnome.org/GNOME/glib/-/merge_requests/1677
2020-10-04 14:34:41 +02:00
is_open = fcntl (fd, F_GETFD) != -1;
g_assert_true (is_open);
is_open = fcntl (fd2, F_GETFD) != -1;
g_assert_true (is_open);
GSubprocessLauncher: allow to close passed FDs By default, when using g_subprocess_launcher_take_fd() to pass an FD to a child, the GSubprocessLauncher object also takes ownership of the FD in the parent, and closes it during finalize(). This is a reasonable assumption in the majority of the cases, but sometimes it isn't a good idea. An example is when creating a GSubprocessLauncher in JavaScript: here, the destruction process is managed by the Garbage Collector, which means that those sockets will remain opened for some time after all the references to the object has been droped. This means that it could be not possible to detect when the child has closed that same FD, because in order to make that work, both FDs instances (the one in the parent and the one in the children) must be closed. This can be a problem in, as an example, a process that launches a child that communicates with Wayland using an specific socket (like when using the new API MetaWaylandClient). Of course, it isn't a valid solution to manually call close() in the parent process just after the call to spawn(), because the FD number could be reused in the time between it is manually closed, and when the object is destroyed and closes again that FD. If that happens, it will close an incorrect FD. One solution could be to call run_dispose() from Javascript on the GSubprocessLauncher object, to force freeing the resources. Unfortunately, the current code frees them in the finalize() method, not in dispose() (this is fixed in !1670 (merged) ) but it isn't a very elegant solution. This proposal adds a new method, g_subprocess_launcher_close(), that allows to close the FDs passed to the child. To avoid problems, after closing an FD with this method, no more spawns are allowed. Fix: https://gitlab.gnome.org/GNOME/glib/-/merge_requests/1677
2020-10-04 14:34:41 +02:00
g_subprocess_launcher_close (launcher);
GSubprocessLauncher: allow to close passed FDs By default, when using g_subprocess_launcher_take_fd() to pass an FD to a child, the GSubprocessLauncher object also takes ownership of the FD in the parent, and closes it during finalize(). This is a reasonable assumption in the majority of the cases, but sometimes it isn't a good idea. An example is when creating a GSubprocessLauncher in JavaScript: here, the destruction process is managed by the Garbage Collector, which means that those sockets will remain opened for some time after all the references to the object has been droped. This means that it could be not possible to detect when the child has closed that same FD, because in order to make that work, both FDs instances (the one in the parent and the one in the children) must be closed. This can be a problem in, as an example, a process that launches a child that communicates with Wayland using an specific socket (like when using the new API MetaWaylandClient). Of course, it isn't a valid solution to manually call close() in the parent process just after the call to spawn(), because the FD number could be reused in the time between it is manually closed, and when the object is destroyed and closes again that FD. If that happens, it will close an incorrect FD. One solution could be to call run_dispose() from Javascript on the GSubprocessLauncher object, to force freeing the resources. Unfortunately, the current code frees them in the finalize() method, not in dispose() (this is fixed in !1670 (merged) ) but it isn't a very elegant solution. This proposal adds a new method, g_subprocess_launcher_close(), that allows to close the FDs passed to the child. To avoid problems, after closing an FD with this method, no more spawns are allowed. Fix: https://gitlab.gnome.org/GNOME/glib/-/merge_requests/1677
2020-10-04 14:34:41 +02:00
is_open = fcntl (fd, F_GETFD) != -1;
g_assert_false (is_open);
is_open = fcntl (fd2, F_GETFD) != -1;
g_assert_true (is_open);
/* Now test that actually trying to spawn the child gives %G_IO_ERROR_CLOSED,
* as g_subprocess_launcher_close() has been called. */
GSubprocessLauncher: allow to close passed FDs By default, when using g_subprocess_launcher_take_fd() to pass an FD to a child, the GSubprocessLauncher object also takes ownership of the FD in the parent, and closes it during finalize(). This is a reasonable assumption in the majority of the cases, but sometimes it isn't a good idea. An example is when creating a GSubprocessLauncher in JavaScript: here, the destruction process is managed by the Garbage Collector, which means that those sockets will remain opened for some time after all the references to the object has been droped. This means that it could be not possible to detect when the child has closed that same FD, because in order to make that work, both FDs instances (the one in the parent and the one in the children) must be closed. This can be a problem in, as an example, a process that launches a child that communicates with Wayland using an specific socket (like when using the new API MetaWaylandClient). Of course, it isn't a valid solution to manually call close() in the parent process just after the call to spawn(), because the FD number could be reused in the time between it is manually closed, and when the object is destroyed and closes again that FD. If that happens, it will close an incorrect FD. One solution could be to call run_dispose() from Javascript on the GSubprocessLauncher object, to force freeing the resources. Unfortunately, the current code frees them in the finalize() method, not in dispose() (this is fixed in !1670 (merged) ) but it isn't a very elegant solution. This proposal adds a new method, g_subprocess_launcher_close(), that allows to close the FDs passed to the child. To avoid problems, after closing an FD with this method, no more spawns are allowed. Fix: https://gitlab.gnome.org/GNOME/glib/-/merge_requests/1677
2020-10-04 14:34:41 +02:00
args = get_test_subprocess_args ("cat", NULL);
proc = g_subprocess_launcher_spawnv (launcher, (const gchar * const *) args->pdata, error);
g_ptr_array_free (args, TRUE);
g_assert_null (proc);
g_assert_error (local_error, G_IO_ERROR, G_IO_ERROR_CLOSED);
g_clear_error (error);
close (fd2);
GSubprocessLauncher: allow to close passed FDs By default, when using g_subprocess_launcher_take_fd() to pass an FD to a child, the GSubprocessLauncher object also takes ownership of the FD in the parent, and closes it during finalize(). This is a reasonable assumption in the majority of the cases, but sometimes it isn't a good idea. An example is when creating a GSubprocessLauncher in JavaScript: here, the destruction process is managed by the Garbage Collector, which means that those sockets will remain opened for some time after all the references to the object has been droped. This means that it could be not possible to detect when the child has closed that same FD, because in order to make that work, both FDs instances (the one in the parent and the one in the children) must be closed. This can be a problem in, as an example, a process that launches a child that communicates with Wayland using an specific socket (like when using the new API MetaWaylandClient). Of course, it isn't a valid solution to manually call close() in the parent process just after the call to spawn(), because the FD number could be reused in the time between it is manually closed, and when the object is destroyed and closes again that FD. If that happens, it will close an incorrect FD. One solution could be to call run_dispose() from Javascript on the GSubprocessLauncher object, to force freeing the resources. Unfortunately, the current code frees them in the finalize() method, not in dispose() (this is fixed in !1670 (merged) ) but it isn't a very elegant solution. This proposal adds a new method, g_subprocess_launcher_close(), that allows to close the FDs passed to the child. To avoid problems, after closing an FD with this method, no more spawns are allowed. Fix: https://gitlab.gnome.org/GNOME/glib/-/merge_requests/1677
2020-10-04 14:34:41 +02:00
g_object_unref (launcher);
}
static void
test_stdout_file (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocessLauncher *launcher;
GSubprocess *proc;
GPtrArray *args;
GFile *tmpfile;
GFileIOStream *iostream;
GOutputStream *stdin_stream;
const char *test_data = "this is some test data\n";
char *tmp_contents;
char *tmp_file_path;
tmpfile = g_file_new_tmp ("gsubprocessXXXXXX", &iostream, error);
g_assert_no_error (local_error);
g_clear_object (&iostream);
tmp_file_path = g_file_get_path (tmpfile);
args = get_test_subprocess_args ("cat", NULL);
launcher = g_subprocess_launcher_new (G_SUBPROCESS_FLAGS_STDIN_PIPE);
g_subprocess_launcher_set_stdout_file_path (launcher, tmp_file_path);
proc = g_subprocess_launcher_spawnv (launcher, (const gchar * const *) args->pdata, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
stdin_stream = g_subprocess_get_stdin_pipe (proc);
g_output_stream_write_all (stdin_stream, test_data, strlen (test_data), NULL, NULL, error);
g_assert_no_error (local_error);
g_output_stream_close (stdin_stream, NULL, error);
g_assert_no_error (local_error);
g_subprocess_wait_check (proc, NULL, error);
g_object_unref (launcher);
g_object_unref (proc);
g_file_load_contents (tmpfile, NULL, &tmp_contents, NULL, NULL, error);
g_assert_no_error (local_error);
g_assert_cmpstr (test_data, ==, tmp_contents);
g_free (tmp_contents);
(void) g_file_delete (tmpfile, NULL, NULL);
g_object_unref (tmpfile);
g_free (tmp_file_path);
}
static void
test_stdout_fd (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocessLauncher *launcher;
GSubprocess *proc;
GPtrArray *args;
GFile *tmpfile;
GFileIOStream *iostream;
GFileDescriptorBased *descriptor_stream;
GOutputStream *stdin_stream;
const char *test_data = "this is some test data\n";
char *tmp_contents;
tmpfile = g_file_new_tmp ("gsubprocessXXXXXX", &iostream, error);
g_assert_no_error (local_error);
args = get_test_subprocess_args ("cat", NULL);
launcher = g_subprocess_launcher_new (G_SUBPROCESS_FLAGS_STDIN_PIPE);
descriptor_stream = G_FILE_DESCRIPTOR_BASED (g_io_stream_get_output_stream (G_IO_STREAM (iostream)));
g_subprocess_launcher_take_stdout_fd (launcher, dup (g_file_descriptor_based_get_fd (descriptor_stream)));
proc = g_subprocess_launcher_spawnv (launcher, (const gchar * const *) args->pdata, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
g_clear_object (&iostream);
stdin_stream = g_subprocess_get_stdin_pipe (proc);
g_output_stream_write_all (stdin_stream, test_data, strlen (test_data), NULL, NULL, error);
g_assert_no_error (local_error);
g_output_stream_close (stdin_stream, NULL, error);
g_assert_no_error (local_error);
g_subprocess_wait_check (proc, NULL, error);
g_object_unref (launcher);
g_object_unref (proc);
g_file_load_contents (tmpfile, NULL, &tmp_contents, NULL, NULL, error);
g_assert_no_error (local_error);
g_assert_cmpstr (test_data, ==, tmp_contents);
g_free (tmp_contents);
(void) g_file_delete (tmpfile, NULL, NULL);
g_object_unref (tmpfile);
}
static void
child_setup (gpointer user_data)
{
dup2 (GPOINTER_TO_INT (user_data), 1);
}
static void
test_child_setup (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GSubprocessLauncher *launcher;
GSubprocess *proc;
GPtrArray *args;
GFile *tmpfile;
GFileIOStream *iostream;
GOutputStream *stdin_stream;
const char *test_data = "this is some test data\n";
char *tmp_contents;
int fd;
tmpfile = g_file_new_tmp ("gsubprocessXXXXXX", &iostream, error);
g_assert_no_error (local_error);
fd = g_file_descriptor_based_get_fd (G_FILE_DESCRIPTOR_BASED (g_io_stream_get_output_stream (G_IO_STREAM (iostream))));
args = get_test_subprocess_args ("cat", NULL);
launcher = g_subprocess_launcher_new (G_SUBPROCESS_FLAGS_STDIN_PIPE);
g_subprocess_launcher_set_child_setup (launcher, child_setup, GINT_TO_POINTER (fd), NULL);
proc = g_subprocess_launcher_spawnv (launcher, (const gchar * const *) args->pdata, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
g_clear_object (&iostream);
stdin_stream = g_subprocess_get_stdin_pipe (proc);
g_output_stream_write_all (stdin_stream, test_data, strlen (test_data), NULL, NULL, error);
g_assert_no_error (local_error);
g_output_stream_close (stdin_stream, NULL, error);
g_assert_no_error (local_error);
g_subprocess_wait_check (proc, NULL, error);
g_object_unref (launcher);
g_object_unref (proc);
g_file_load_contents (tmpfile, NULL, &tmp_contents, NULL, NULL, error);
g_assert_no_error (local_error);
g_assert_cmpstr (test_data, ==, tmp_contents);
g_free (tmp_contents);
(void) g_file_delete (tmpfile, NULL, NULL);
g_object_unref (tmpfile);
}
static void
test_pass_fd (void)
{
GError *local_error = NULL;
GError **error = &local_error;
GInputStream *child_input;
GDataInputStream *child_datainput;
GSubprocessLauncher *launcher;
GSubprocess *proc;
GPtrArray *args;
int basic_pipefds[2];
int needdup_pipefds[2];
char *buf;
gsize len;
char *basic_fd_str;
char *needdup_fd_str;
g_unix_open_pipe (basic_pipefds, FD_CLOEXEC, error);
g_assert_no_error (local_error);
g_unix_open_pipe (needdup_pipefds, FD_CLOEXEC, error);
g_assert_no_error (local_error);
basic_fd_str = g_strdup_printf ("%d", basic_pipefds[1]);
needdup_fd_str = g_strdup_printf ("%d", needdup_pipefds[1] + 1);
args = get_test_subprocess_args ("write-to-fds", basic_fd_str, needdup_fd_str, NULL);
launcher = g_subprocess_launcher_new (G_SUBPROCESS_FLAGS_NONE);
g_subprocess_launcher_take_fd (launcher, basic_pipefds[1], basic_pipefds[1]);
g_subprocess_launcher_take_fd (launcher, needdup_pipefds[1], needdup_pipefds[1] + 1);
proc = g_subprocess_launcher_spawnv (launcher, (const gchar * const *) args->pdata, error);
g_ptr_array_free (args, TRUE);
g_assert_no_error (local_error);
g_free (basic_fd_str);
g_free (needdup_fd_str);
child_input = g_unix_input_stream_new (basic_pipefds[0], TRUE);
child_datainput = g_data_input_stream_new (child_input);
buf = g_data_input_stream_read_line_utf8 (child_datainput, &len, NULL, error);
g_assert_no_error (local_error);
g_assert_cmpstr (buf, ==, "hello world");
g_object_unref (child_datainput);
g_object_unref (child_input);
g_free (buf);
child_input = g_unix_input_stream_new (needdup_pipefds[0], TRUE);
child_datainput = g_data_input_stream_new (child_input);
buf = g_data_input_stream_read_line_utf8 (child_datainput, &len, NULL, error);
g_assert_no_error (local_error);
g_assert_cmpstr (buf, ==, "hello world");
g_free (buf);
g_object_unref (child_datainput);
g_object_unref (child_input);
g_object_unref (launcher);
g_object_unref (proc);
}
#endif
static void
test_launcher_environment (void)
{
GSubprocessLauncher *launcher;
GError *error = NULL;
GSubprocess *proc;
GPtrArray *args;
gchar *out;
g_setenv ("A", "B", TRUE);
g_setenv ("C", "D", TRUE);
launcher = g_subprocess_launcher_new (G_SUBPROCESS_FLAGS_STDOUT_PIPE);
/* unset a variable */
g_subprocess_launcher_unsetenv (launcher, "A");
/* and set a different one */
g_subprocess_launcher_setenv (launcher, "E", "F", TRUE);
args = get_test_subprocess_args ("printenv", "A", "C", "E", NULL);
proc = g_subprocess_launcher_spawnv (launcher, (const gchar **) args->pdata, &error);
g_assert_no_error (error);
g_assert_nonnull (proc);
g_subprocess_communicate_utf8 (proc, NULL, NULL, &out, NULL, &error);
g_assert_no_error (error);
g_assert_cmpstr (out, ==, "C=D" LINEEND "E=F" LINEEND);
g_free (out);
g_object_unref (proc);
g_object_unref (launcher);
g_ptr_array_unref (args);
}
int
main (int argc, char **argv)
{
const struct
{
const gchar *subtest;
GSubprocessFlags flags;
}
flags_vectors[] =
{
{ "", G_SUBPROCESS_FLAGS_STDOUT_PIPE | G_SUBPROCESS_FLAGS_STDERR_MERGE },
{ "/no-pipes", G_SUBPROCESS_FLAGS_NONE },
{ "/separate-stderr", G_SUBPROCESS_FLAGS_STDOUT_PIPE | G_SUBPROCESS_FLAGS_STDERR_PIPE },
{ "/stdout-only", G_SUBPROCESS_FLAGS_STDOUT_PIPE },
{ "/stderr-only", G_SUBPROCESS_FLAGS_STDERR_PIPE },
{ "/stdout-silence", G_SUBPROCESS_FLAGS_STDOUT_SILENCE },
};
gsize i;
g_test_init (&argc, &argv, NULL);
g_test_add_func ("/gsubprocess/noop", test_noop);
g_test_add_func ("/gsubprocess/noop-all-to-null", test_noop_all_to_null);
g_test_add_func ("/gsubprocess/noop-no-wait", test_noop_no_wait);
g_test_add_func ("/gsubprocess/noop-stdin-inherit", test_noop_stdin_inherit);
#ifdef G_OS_UNIX
g_test_add_func ("/gsubprocess/search-path", test_search_path);
g_test_add_func ("/gsubprocess/signal", test_signal);
#endif
g_test_add_func ("/gsubprocess/exit1", test_exit1);
g_test_add_func ("/gsubprocess/exit1/cancel", test_exit1_cancel);
g_test_add_func ("/gsubprocess/exit1/cancel_in_cb", test_exit1_cancel_in_cb);
g_test_add_func ("/gsubprocess/echo1", test_echo1);
#ifdef G_OS_UNIX
g_test_add_func ("/gsubprocess/echo-merged", test_echo_merged);
#endif
g_test_add_func ("/gsubprocess/cat-utf8", test_cat_utf8);
g_test_add_func ("/gsubprocess/cat-eof", test_cat_eof);
g_test_add_func ("/gsubprocess/multi1", test_multi_1);
/* Add various tests for g_subprocess_communicate() with different flags. */
for (i = 0; i < G_N_ELEMENTS (flags_vectors); i++)
{
gchar *test_path = NULL;
test_path = g_strdup_printf ("/gsubprocess/communicate%s", flags_vectors[i].subtest);
g_test_add_data_func (test_path, GINT_TO_POINTER (flags_vectors[i].flags),
test_communicate);
g_free (test_path);
test_path = g_strdup_printf ("/gsubprocess/communicate/cancelled%s", flags_vectors[i].subtest);
g_test_add_data_func (test_path, GINT_TO_POINTER (flags_vectors[i].flags),
test_communicate_cancelled);
g_free (test_path);
test_path = g_strdup_printf ("/gsubprocess/communicate/async%s", flags_vectors[i].subtest);
g_test_add_data_func (test_path, GINT_TO_POINTER (flags_vectors[i].flags),
test_communicate_async);
g_free (test_path);
test_path = g_strdup_printf ("/gsubprocess/communicate/async/cancelled%s", flags_vectors[i].subtest);
g_test_add_data_func (test_path, GINT_TO_POINTER (flags_vectors[i].flags),
test_communicate_cancelled_async);
g_free (test_path);
test_path = g_strdup_printf ("/gsubprocess/communicate/utf8%s", flags_vectors[i].subtest);
g_test_add_data_func (test_path, GINT_TO_POINTER (flags_vectors[i].flags),
test_communicate_utf8);
g_free (test_path);
test_path = g_strdup_printf ("/gsubprocess/communicate/utf8/cancelled%s", flags_vectors[i].subtest);
g_test_add_data_func (test_path, GINT_TO_POINTER (flags_vectors[i].flags),
test_communicate_utf8_cancelled);
g_free (test_path);
test_path = g_strdup_printf ("/gsubprocess/communicate/utf8/async%s", flags_vectors[i].subtest);
g_test_add_data_func (test_path, GINT_TO_POINTER (flags_vectors[i].flags),
test_communicate_utf8_async);
g_free (test_path);
test_path = g_strdup_printf ("/gsubprocess/communicate/utf8/async/cancelled%s", flags_vectors[i].subtest);
g_test_add_data_func (test_path, GINT_TO_POINTER (flags_vectors[i].flags),
test_communicate_utf8_cancelled_async);
g_free (test_path);
}
g_test_add_func ("/gsubprocess/communicate/utf8/async/invalid", test_communicate_utf8_async_invalid);
g_test_add_func ("/gsubprocess/communicate/utf8/invalid", test_communicate_utf8_invalid);
g_test_add_func ("/gsubprocess/communicate/nothing", test_communicate_nothing);
g_test_add_func ("/gsubprocess/terminate", test_terminate);
g_test_add_func ("/gsubprocess/env", test_env);
g_test_add_func ("/gsubprocess/env/inherit", test_env_inherit);
2013-11-28 18:59:11 +01:00
g_test_add_func ("/gsubprocess/cwd", test_cwd);
#ifdef G_OS_UNIX
GSubprocessLauncher: allow to close passed FDs By default, when using g_subprocess_launcher_take_fd() to pass an FD to a child, the GSubprocessLauncher object also takes ownership of the FD in the parent, and closes it during finalize(). This is a reasonable assumption in the majority of the cases, but sometimes it isn't a good idea. An example is when creating a GSubprocessLauncher in JavaScript: here, the destruction process is managed by the Garbage Collector, which means that those sockets will remain opened for some time after all the references to the object has been droped. This means that it could be not possible to detect when the child has closed that same FD, because in order to make that work, both FDs instances (the one in the parent and the one in the children) must be closed. This can be a problem in, as an example, a process that launches a child that communicates with Wayland using an specific socket (like when using the new API MetaWaylandClient). Of course, it isn't a valid solution to manually call close() in the parent process just after the call to spawn(), because the FD number could be reused in the time between it is manually closed, and when the object is destroyed and closes again that FD. If that happens, it will close an incorrect FD. One solution could be to call run_dispose() from Javascript on the GSubprocessLauncher object, to force freeing the resources. Unfortunately, the current code frees them in the finalize() method, not in dispose() (this is fixed in !1670 (merged) ) but it isn't a very elegant solution. This proposal adds a new method, g_subprocess_launcher_close(), that allows to close the FDs passed to the child. To avoid problems, after closing an FD with this method, no more spawns are allowed. Fix: https://gitlab.gnome.org/GNOME/glib/-/merge_requests/1677
2020-10-04 14:34:41 +02:00
g_test_add_func ("/gsubprocess/launcher-close", test_subprocess_launcher_close);
g_test_add_func ("/gsubprocess/stdout-file", test_stdout_file);
g_test_add_func ("/gsubprocess/stdout-fd", test_stdout_fd);
g_test_add_func ("/gsubprocess/child-setup", test_child_setup);
g_test_add_func ("/gsubprocess/pass-fd", test_pass_fd);
#endif
g_test_add_func ("/gsubprocess/launcher-environment", test_launcher_environment);
return g_test_run ();
}