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libinput/tools/libinput-record.c
Peter Hutterer 9925594257 tools/record: print the wall clock time every few seconds 
For long-running recordings it's useful to know what the actual time was when
a particular event occured. A user can simply check the clock or system logs
for the time and thus know which portion of the recording to focus on.

Let's print the time into the recording, every 5 seconds (aligned at the 5,
10, 15s marks) or, if no events occured in the last 5 seconds, before the next
event. This granularity should be enough to identify the interesting parts of
a recording.

Let's print this as a comment until we have a use-case that requires parsing
this data.

The timer is the simplest approach, it just repeats at a fixed 5 seconds
interval from startup. There may be time drift, we can fix that if needed.

Fixes #560

Signed-off-by: Peter Hutterer <peter.hutterer@who-t.net>
2021-01-29 07:31:46 +10:00

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/*
* Copyright © 2018 Red Hat, Inc.
*
* Permission is hereby granted, free of charge, to any person obtaining a
* copy of this software and associated documentation files (the "Software"),
* to deal in the Software without restriction, including without limitation
* the rights to use, copy, modify, merge, publish, distribute, sublicense,
* and/or sell copies of the Software, and to permit persons to whom the
* Software is furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice (including the next
* paragraph) shall be included in all copies or substantial portions of the
* Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING
* FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
* DEALINGS IN THE SOFTWARE.
*/
#include "config.h"
#include <errno.h>
#include <inttypes.h>
#include <linux/input.h>
#include <libevdev/libevdev.h>
#include <libudev.h>
#include <sys/signalfd.h>
#include <sys/timerfd.h>
#include <sys/utsname.h>
#include <sys/stat.h>
#include <string.h>
#include <dirent.h>
#include <fcntl.h>
#include <getopt.h>
#include <poll.h>
#include <unistd.h>
#include <signal.h>
#include <stdbool.h>
#include <time.h>
#include "libinput-versionsort.h"
#include "libinput-version.h"
#include "libinput-git-version.h"
#include "shared.h"
#include "builddir.h"
#include "util-list.h"
#include "util-time.h"
#include "util-input-event.h"
#include "util-macros.h"
static const int FILE_VERSION_NUMBER = 1;
/* libinput is not designed to keep events past immediate use so we need to
* cache our events. Simplest way to do this is to just cache the printf
* output */
struct li_event {
char msg[256];
};
enum event_type {
NONE,
EVDEV,
LIBINPUT,
COMMENT,
};
struct event {
enum event_type type;
uint64_t time;
union {
struct input_event evdev;
struct li_event libinput;
char comment[200];
} u;
};
struct record_device {
struct list link;
char *devnode; /* device node of the source device */
struct libevdev *evdev;
struct libevdev *evdev_prev; /* previous value, used for EV_ABS
deltas */
struct libinput_device *device;
struct event *events;
size_t nevents;
size_t events_sz;
struct {
bool is_touch_device;
uint16_t slot_state;
uint16_t last_slot_state;
} touch;
};
struct record_context {
int timeout;
bool show_keycodes;
uint64_t offset;
struct list devices;
int ndevices;
char *outfile; /* file name given on cmdline */
char *output_file; /* full file name with suffix */
int out_fd;
unsigned int indent;
struct libinput *libinput;
};
static inline bool
obfuscate_keycode(struct input_event *ev)
{
switch (ev->type) {
case EV_KEY:
if (ev->code >= KEY_ESC && ev->code < KEY_ZENKAKUHANKAKU) {
ev->code = KEY_A;
return true;
}
break;
case EV_MSC:
if (ev->code == MSC_SCAN) {
ev->value = 30; /* KEY_A scancode */
return true;
}
break;
}
return false;
}
static inline void
indent_push(struct record_context *ctx)
{
ctx->indent += 2;
}
static inline void
indent_pop(struct record_context *ctx)
{
assert(ctx->indent >= 2);
ctx->indent -= 2;
}
/**
* Indented dprintf, indentation is given as second parameter.
*/
static inline void
iprintf(const struct record_context *ctx, const char *format, ...)
{
va_list args;
char fmt[1024];
static const char space[] = " ";
static const size_t len = sizeof(space);
unsigned int indent = ctx->indent;
int rc;
assert(indent < len);
assert(strlen(format) > 1);
/* Special case: if we're printing a new list item, we want less
* indentation because the '- ' takes up one level of indentation
*
* This is only needed because I don't want to deal with open/close
* lists statements.
*/
if (format[0] == '-')
indent -= 2;
snprintf(fmt, sizeof(fmt), "%s%s", &space[len - indent - 1], format);
va_start(args, format);
rc = vdprintf(ctx->out_fd, fmt, args);
va_end(args);
assert(rc != -1 && (unsigned int)rc > indent);
}
/**
* Normal printf, just wrapped for the context
*/
static inline void
noiprintf(const struct record_context *ctx, const char *format, ...)
{
va_list args;
int rc;
va_start(args, format);
rc = vdprintf(ctx->out_fd, format, args);
va_end(args);
assert(rc != -1 && (unsigned int)rc > 0);
}
static inline uint64_t
time_offset(struct record_context *ctx, uint64_t time)
{
return ctx->offset ? time - ctx->offset : 0;
}
static inline void
print_evdev_event(struct record_context *ctx,
struct record_device *dev,
struct input_event *ev)
{
const char *tname, *cname;
bool was_modified = false;
char desc[1024];
uint64_t time = input_event_time(ev) - ctx->offset;
input_event_set_time(ev, time);
/* Don't leak passwords unless the user wants to */
if (!ctx->show_keycodes)
was_modified = obfuscate_keycode(ev);
tname = libevdev_event_type_get_name(ev->type);
cname = libevdev_event_code_get_name(ev->type, ev->code);
if (ev->type == EV_SYN && ev->code == SYN_MT_REPORT) {
snprintf(desc,
sizeof(desc),
"++++++++++++ %s (%d) ++++++++++",
cname,
ev->value);
} else if (ev->type == EV_SYN) {
static unsigned long last_ms = 0;
unsigned long time, dt;
time = us2ms(input_event_time(ev));
dt = time - last_ms;
last_ms = time;
snprintf(desc,
sizeof(desc),
"------------ %s (%d) ---------- %+ldms",
cname,
ev->value,
dt);
} else if (ev->type == EV_ABS) {
int oldval = 0;
enum { DELTA, SLOT_DELTA, NO_DELTA } want = DELTA;
int delta = 0;
/* We want to print deltas for abs axes but there are a few
* that we don't care about for actual deltas because
* they're meaningless.
*
* Also, any slotted axis needs to be printed per slot
*/
switch (ev->code) {
case ABS_MT_SLOT:
libevdev_set_event_value(dev->evdev_prev,
ev->type,
ev->code,
ev->value);
want = NO_DELTA;
break;
case ABS_MT_TRACKING_ID:
case ABS_MT_BLOB_ID:
want = NO_DELTA;
break;
case ABS_MT_TOUCH_MAJOR ... ABS_MT_POSITION_Y:
case ABS_MT_PRESSURE ... ABS_MT_TOOL_Y:
if (libevdev_get_num_slots(dev->evdev_prev) > 0)
want = SLOT_DELTA;
break;
default:
break;
}
switch (want) {
case DELTA:
oldval = libevdev_get_event_value(dev->evdev_prev,
ev->type,
ev->code);
libevdev_set_event_value(dev->evdev_prev,
ev->type,
ev->code,
ev->value);
break;
case SLOT_DELTA: {
int slot = libevdev_get_current_slot(dev->evdev_prev);
oldval = libevdev_get_slot_value(dev->evdev_prev,
slot,
ev->code);
libevdev_set_slot_value(dev->evdev_prev,
slot,
ev->code,
ev->value);
break;
}
case NO_DELTA:
break;
}
delta = ev->value - oldval;
switch (want) {
case DELTA:
case SLOT_DELTA:
snprintf(desc,
sizeof(desc),
"%s / %-20s %6d (%+d)",
tname,
cname,
ev->value,
delta);
break;
case NO_DELTA:
snprintf(desc,
sizeof(desc),
"%s / %-20s %6d",
tname,
cname,
ev->value);
break;
}
} else {
snprintf(desc,
sizeof(desc),
"%s / %-20s %6d%s",
tname,
cname,
ev->value,
was_modified ? " (obfuscated)" : "");
}
iprintf(ctx,
"- [%3lu, %6u, %3d, %3d, %7d] # %s\n",
ev->input_event_sec,
(unsigned int)ev->input_event_usec,
ev->type,
ev->code,
ev->value,
desc);
}
#define resize(array_, sz_) \
{ \
size_t new_size = (sz_) + 1000; \
void *tmp = realloc((array_), new_size * sizeof(*(array_))); \
assert(tmp); \
(array_) = tmp; \
(sz_) = new_size; \
}
static inline size_t
handle_evdev_frame(struct record_context *ctx, struct record_device *d)
{
struct libevdev *evdev = d->evdev;
struct input_event e;
size_t count = 0;
uint32_t last_time = 0;
struct event *event;
while (libevdev_next_event(evdev,
LIBEVDEV_READ_FLAG_NORMAL,
&e) == LIBEVDEV_READ_STATUS_SUCCESS) {
uint64_t time = input_event_time(&e);
if (ctx->offset == 0)
ctx->offset = time;
else
time = time_offset(ctx, time);
if (d->nevents == d->events_sz)
resize(d->events, d->events_sz);
event = &d->events[d->nevents++];
event->type = EVDEV;
event->time = time;
event->u.evdev = e;
count++;
if (d->touch.is_touch_device &&
e.type == EV_ABS &&
e.code == ABS_MT_TRACKING_ID) {
unsigned int slot = libevdev_get_current_slot(evdev);
assert(slot < sizeof(d->touch.slot_state) * 8);
if (e.value != -1)
d->touch.slot_state |= 1 << slot;
else
d->touch.slot_state &= ~(1 << slot);
}
last_time = event->time;
if (e.type == EV_SYN && e.code == SYN_REPORT)
break;
}
if (d->touch.slot_state != d->touch.last_slot_state) {
d->touch.last_slot_state = d->touch.slot_state;
if (d->nevents == d->events_sz)
resize(d->events, d->events_sz);
if (d->touch.slot_state == 0) {
event = &d->events[d->nevents++];
event->type = COMMENT;
event->time = last_time;
snprintf(event->u.comment,
sizeof(event->u.comment),
" # Touch device in neutral state\n");
count++;
}
}
return count;
}
static void
buffer_device_notify(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_device *dev = libinput_event_get_device(e);
struct libinput_seat *seat = libinput_device_get_seat(dev);
const char *type = NULL;
switch(libinput_event_get_type(e)) {
case LIBINPUT_EVENT_DEVICE_ADDED:
type = "DEVICE_ADDED";
break;
case LIBINPUT_EVENT_DEVICE_REMOVED:
type = "DEVICE_REMOVED";
break;
default:
abort();
}
event->time = 0;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{type: %s, seat: %5s, logical_seat: %7s}",
type,
libinput_seat_get_physical_name(seat),
libinput_seat_get_logical_name(seat));
}
static void
buffer_key_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_event_keyboard *k = libinput_event_get_keyboard_event(e);
enum libinput_key_state state;
uint32_t key;
uint64_t time;
const char *type;
switch(libinput_event_get_type(e)) {
case LIBINPUT_EVENT_KEYBOARD_KEY:
type = "KEYBOARD_KEY";
break;
default:
abort();
}
time = time_offset(ctx, libinput_event_keyboard_get_time_usec(k));
state = libinput_event_keyboard_get_key_state(k);
key = libinput_event_keyboard_get_key(k);
if (!ctx->show_keycodes &&
(key >= KEY_ESC && key < KEY_ZENKAKUHANKAKU))
key = -1;
event->time = time;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, key: %d, state: %s}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
key,
state == LIBINPUT_KEY_STATE_PRESSED ? "pressed" : "released");
}
static void
buffer_motion_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_event_pointer *p = libinput_event_get_pointer_event(e);
double x = libinput_event_pointer_get_dx(p),
y = libinput_event_pointer_get_dy(p);
double uax = libinput_event_pointer_get_dx_unaccelerated(p),
uay = libinput_event_pointer_get_dy_unaccelerated(p);
uint64_t time;
const char *type;
switch(libinput_event_get_type(e)) {
case LIBINPUT_EVENT_POINTER_MOTION:
type = "POINTER_MOTION";
break;
default:
abort();
}
time = time_offset(ctx, libinput_event_pointer_get_time_usec(p));
event->time = time;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, delta: [%6.2f, %6.2f], unaccel: [%6.2f, %6.2f]}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
x, y,
uax, uay);
}
static void
buffer_absmotion_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_event_pointer *p = libinput_event_get_pointer_event(e);
double x = libinput_event_pointer_get_absolute_x(p),
y = libinput_event_pointer_get_absolute_y(p);
double tx = libinput_event_pointer_get_absolute_x_transformed(p, 100),
ty = libinput_event_pointer_get_absolute_y_transformed(p, 100);
uint64_t time;
const char *type;
switch(libinput_event_get_type(e)) {
case LIBINPUT_EVENT_POINTER_MOTION_ABSOLUTE:
type = "POINTER_MOTION_ABSOLUTE";
break;
default:
abort();
}
time = time_offset(ctx, libinput_event_pointer_get_time_usec(p));
event->time = time;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, point: [%6.2f, %6.2f], transformed: [%6.2f, %6.2f]}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
x, y,
tx, ty);
}
static void
buffer_pointer_button_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_event_pointer *p = libinput_event_get_pointer_event(e);
enum libinput_button_state state;
int button;
uint64_t time;
const char *type;
switch(libinput_event_get_type(e)) {
case LIBINPUT_EVENT_POINTER_BUTTON:
type = "POINTER_BUTTON";
break;
default:
abort();
}
time = time_offset(ctx, libinput_event_pointer_get_time_usec(p));
button = libinput_event_pointer_get_button(p);
state = libinput_event_pointer_get_button_state(p);
event->time = time;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, button: %d, state: %s, seat_count: %u}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
button,
state == LIBINPUT_BUTTON_STATE_PRESSED ? "pressed" : "released",
libinput_event_pointer_get_seat_button_count(p));
}
static void
buffer_pointer_axis_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_event_pointer *p = libinput_event_get_pointer_event(e);
uint64_t time;
const char *type, *source;
double h = 0, v = 0;
int hd = 0, vd = 0;
switch(libinput_event_get_type(e)) {
case LIBINPUT_EVENT_POINTER_AXIS:
type = "POINTER_AXIS";
break;
default:
abort();
}
time = time_offset(ctx, libinput_event_pointer_get_time_usec(p));
if (libinput_event_pointer_has_axis(p,
LIBINPUT_POINTER_AXIS_SCROLL_HORIZONTAL)) {
h = libinput_event_pointer_get_axis_value(p,
LIBINPUT_POINTER_AXIS_SCROLL_HORIZONTAL);
hd = libinput_event_pointer_get_axis_value_discrete(p,
LIBINPUT_POINTER_AXIS_SCROLL_HORIZONTAL);
}
if (libinput_event_pointer_has_axis(p,
LIBINPUT_POINTER_AXIS_SCROLL_VERTICAL)) {
v = libinput_event_pointer_get_axis_value(p,
LIBINPUT_POINTER_AXIS_SCROLL_VERTICAL);
vd = libinput_event_pointer_get_axis_value_discrete(p,
LIBINPUT_POINTER_AXIS_SCROLL_VERTICAL);
}
switch(libinput_event_pointer_get_axis_source(p)) {
case LIBINPUT_POINTER_AXIS_SOURCE_WHEEL: source = "wheel"; break;
case LIBINPUT_POINTER_AXIS_SOURCE_FINGER: source = "finger"; break;
case LIBINPUT_POINTER_AXIS_SOURCE_CONTINUOUS: source = "continuous"; break;
case LIBINPUT_POINTER_AXIS_SOURCE_WHEEL_TILT: source = "wheel-tilt"; break;
default:
source = "unknown";
break;
}
event->time = time;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, axes: [%2.2f, %2.2f], discrete: [%d, %d], source: %s}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
h, v,
hd, vd,
source);
}
static void
buffer_touch_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
enum libinput_event_type etype = libinput_event_get_type(e);
struct libinput_event_touch *t = libinput_event_get_touch_event(e);
const char *type;
double x, y;
double tx, ty;
uint64_t time;
int32_t slot, seat_slot;
switch(etype) {
case LIBINPUT_EVENT_TOUCH_DOWN:
type = "TOUCH_DOWN";
break;
case LIBINPUT_EVENT_TOUCH_UP:
type = "TOUCH_UP";
break;
case LIBINPUT_EVENT_TOUCH_MOTION:
type = "TOUCH_MOTION";
break;
case LIBINPUT_EVENT_TOUCH_CANCEL:
type = "TOUCH_CANCEL";
break;
case LIBINPUT_EVENT_TOUCH_FRAME:
type = "TOUCH_FRAME";
break;
default:
abort();
}
time = time_offset(ctx, libinput_event_touch_get_time_usec(t));
if (etype != LIBINPUT_EVENT_TOUCH_FRAME) {
slot = libinput_event_touch_get_slot(t);
seat_slot = libinput_event_touch_get_seat_slot(t);
}
event->time = time;
switch (etype) {
case LIBINPUT_EVENT_TOUCH_FRAME:
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type);
break;
case LIBINPUT_EVENT_TOUCH_DOWN:
case LIBINPUT_EVENT_TOUCH_MOTION:
x = libinput_event_touch_get_x(t);
y = libinput_event_touch_get_y(t);
tx = libinput_event_touch_get_x_transformed(t, 100);
ty = libinput_event_touch_get_y_transformed(t, 100);
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, slot: %d, seat_slot: %d, point: [%6.2f, %6.2f], transformed: [%6.2f, %6.2f]}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
slot,
seat_slot,
x, y,
tx, ty);
break;
case LIBINPUT_EVENT_TOUCH_UP:
case LIBINPUT_EVENT_TOUCH_CANCEL:
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, slot: %d, seat_slot: %d}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
slot,
seat_slot);
break;
default:
abort();
}
}
static void
buffer_gesture_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
enum libinput_event_type etype = libinput_event_get_type(e);
struct libinput_event_gesture *g = libinput_event_get_gesture_event(e);
const char *type;
uint64_t time;
switch(etype) {
case LIBINPUT_EVENT_GESTURE_PINCH_BEGIN:
type = "GESTURE_PINCH_BEGIN";
break;
case LIBINPUT_EVENT_GESTURE_PINCH_UPDATE:
type = "GESTURE_PINCH_UPDATE";
break;
case LIBINPUT_EVENT_GESTURE_PINCH_END:
type = "GESTURE_PINCH_END";
break;
case LIBINPUT_EVENT_GESTURE_SWIPE_BEGIN:
type = "GESTURE_SWIPE_BEGIN";
break;
case LIBINPUT_EVENT_GESTURE_SWIPE_UPDATE:
type = "GESTURE_SWIPE_UPDATE";
break;
case LIBINPUT_EVENT_GESTURE_SWIPE_END:
type = "GESTURE_SWIPE_END";
break;
default:
abort();
}
time = time_offset(ctx, libinput_event_gesture_get_time_usec(g));
event->time = time;
switch (etype) {
case LIBINPUT_EVENT_GESTURE_PINCH_BEGIN:
case LIBINPUT_EVENT_GESTURE_PINCH_UPDATE:
case LIBINPUT_EVENT_GESTURE_PINCH_END:
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, nfingers: %d, "
"delta: [%6.2f, %6.2f], unaccel: [%6.2f, %6.2f], "
"angle_delta: %6.2f, scale: %6.2f}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
libinput_event_gesture_get_finger_count(g),
libinput_event_gesture_get_dx(g),
libinput_event_gesture_get_dy(g),
libinput_event_gesture_get_dx_unaccelerated(g),
libinput_event_gesture_get_dy_unaccelerated(g),
libinput_event_gesture_get_angle_delta(g),
libinput_event_gesture_get_scale(g)
);
break;
case LIBINPUT_EVENT_GESTURE_SWIPE_BEGIN:
case LIBINPUT_EVENT_GESTURE_SWIPE_UPDATE:
case LIBINPUT_EVENT_GESTURE_SWIPE_END:
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, nfingers: %d, "
"delta: [%6.2f, %6.2f], unaccel: [%6.2f, %6.2f]}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
libinput_event_gesture_get_finger_count(g),
libinput_event_gesture_get_dx(g),
libinput_event_gesture_get_dy(g),
libinput_event_gesture_get_dx_unaccelerated(g),
libinput_event_gesture_get_dy_unaccelerated(g)
);
break;
default:
abort();
}
}
static char *
buffer_tablet_axes(struct libinput_event_tablet_tool *t)
{
const int MAX_AXES = 10;
struct libinput_tablet_tool *tool;
char *s = NULL;
int idx = 0;
int len;
double x, y;
char **strv;
tool = libinput_event_tablet_tool_get_tool(t);
strv = zalloc(MAX_AXES * sizeof *strv);
x = libinput_event_tablet_tool_get_x(t);
y = libinput_event_tablet_tool_get_y(t);
len = xasprintf(&strv[idx++], "point: [%.2f, %.2f]", x, y);
if (len <= 0)
goto out;
if (libinput_tablet_tool_has_tilt(tool)) {
x = libinput_event_tablet_tool_get_tilt_x(t);
y = libinput_event_tablet_tool_get_tilt_y(t);
len = xasprintf(&strv[idx++], "tilt: [%.2f, %.2f]", x, y);
if (len <= 0)
goto out;
}
if (libinput_tablet_tool_has_distance(tool) ||
libinput_tablet_tool_has_pressure(tool)) {
double dist, pressure;
dist = libinput_event_tablet_tool_get_distance(t);
pressure = libinput_event_tablet_tool_get_pressure(t);
if (dist)
len = xasprintf(&strv[idx++], "distance: %.2f", dist);
else
len = xasprintf(&strv[idx++], "pressure: %.2f", pressure);
if (len <= 0)
goto out;
}
if (libinput_tablet_tool_has_rotation(tool)) {
double rotation;
rotation = libinput_event_tablet_tool_get_rotation(t);
len = xasprintf(&strv[idx++], "rotation: %.2f", rotation);
if (len <= 0)
goto out;
}
if (libinput_tablet_tool_has_slider(tool)) {
double slider;
slider = libinput_event_tablet_tool_get_slider_position(t);
len = xasprintf(&strv[idx++], "slider: %.2f", slider);
if (len <= 0)
goto out;
}
if (libinput_tablet_tool_has_wheel(tool)) {
double wheel;
int delta;
wheel = libinput_event_tablet_tool_get_wheel_delta(t);
len = xasprintf(&strv[idx++], "wheel: %.2f", wheel);
if (len <= 0)
goto out;
delta = libinput_event_tablet_tool_get_wheel_delta_discrete(t);
len = xasprintf(&strv[idx++], "wheel-discrete: %d", delta);
if (len <= 0)
goto out;
}
assert(idx < MAX_AXES);
s = strv_join(strv, ", ");
out:
strv_free(strv);
return s;
}
static void
buffer_tablet_tool_proximity_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_event_tablet_tool *t =
libinput_event_get_tablet_tool_event(e);
struct libinput_tablet_tool *tool =
libinput_event_tablet_tool_get_tool(t);
uint64_t time;
const char *type, *tool_type;
char *axes;
char caps[10] = {0};
enum libinput_tablet_tool_proximity_state prox;
size_t idx;
switch (libinput_event_get_type(e)) {
case LIBINPUT_EVENT_TABLET_TOOL_PROXIMITY:
type = "TABLET_TOOL_PROXIMITY";
break;
default:
abort();
}
switch (libinput_tablet_tool_get_type(tool)) {
case LIBINPUT_TABLET_TOOL_TYPE_PEN:
tool_type = "pen";
break;
case LIBINPUT_TABLET_TOOL_TYPE_ERASER:
tool_type = "eraser";
break;
case LIBINPUT_TABLET_TOOL_TYPE_BRUSH:
tool_type = "brush";
break;
case LIBINPUT_TABLET_TOOL_TYPE_PENCIL:
tool_type = "brush";
break;
case LIBINPUT_TABLET_TOOL_TYPE_AIRBRUSH:
tool_type = "airbrush";
break;
case LIBINPUT_TABLET_TOOL_TYPE_MOUSE:
tool_type = "mouse";
break;
case LIBINPUT_TABLET_TOOL_TYPE_LENS:
tool_type = "lens";
break;
default:
tool_type = "unknown";
break;
}
prox = libinput_event_tablet_tool_get_proximity_state(t);
time = time_offset(ctx, libinput_event_tablet_tool_get_time_usec(t));
axes = buffer_tablet_axes(t);
idx = 0;
if (libinput_tablet_tool_has_pressure(tool))
caps[idx++] = 'p';
if (libinput_tablet_tool_has_distance(tool))
caps[idx++] = 'd';
if (libinput_tablet_tool_has_tilt(tool))
caps[idx++] = 't';
if (libinput_tablet_tool_has_rotation(tool))
caps[idx++] = 'r';
if (libinput_tablet_tool_has_slider(tool))
caps[idx++] = 's';
if (libinput_tablet_tool_has_wheel(tool))
caps[idx++] = 'w';
assert(idx <= ARRAY_LENGTH(caps));
event->time = time;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, proximity: %s, tool-type: %s, serial: %" PRIu64 ", axes: %s, %s}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
prox ? "in" : "out",
tool_type,
libinput_tablet_tool_get_serial(tool),
caps,
axes);
free(axes);
}
static void
buffer_tablet_tool_button_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_event_tablet_tool *t =
libinput_event_get_tablet_tool_event(e);
uint64_t time;
const char *type;
uint32_t button;
enum libinput_button_state state;
switch(libinput_event_get_type(e)) {
case LIBINPUT_EVENT_TABLET_TOOL_BUTTON:
type = "TABLET_TOOL_BUTTON";
break;
default:
abort();
}
button = libinput_event_tablet_tool_get_button(t);
state = libinput_event_tablet_tool_get_button_state(t);
time = time_offset(ctx, libinput_event_tablet_tool_get_time_usec(t));
event->time = time;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, button: %d, state: %s}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
button,
state ? "pressed" : "released");
}
static void
buffer_tablet_tool_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_event_tablet_tool *t =
libinput_event_get_tablet_tool_event(e);
uint64_t time;
const char *type;
char *axes;
enum libinput_tablet_tool_tip_state tip;
char btn_buffer[30] = {0};
switch(libinput_event_get_type(e)) {
case LIBINPUT_EVENT_TABLET_TOOL_AXIS:
type = "TABLET_TOOL_AXIS";
break;
case LIBINPUT_EVENT_TABLET_TOOL_TIP:
type = "TABLET_TOOL_TIP";
break;
case LIBINPUT_EVENT_TABLET_TOOL_BUTTON:
type = "TABLET_TOOL_BUTTON";
break;
default:
abort();
}
if (libinput_event_get_type(e) == LIBINPUT_EVENT_TABLET_TOOL_BUTTON) {
uint32_t button;
enum libinput_button_state state;
button = libinput_event_tablet_tool_get_button(t);
state = libinput_event_tablet_tool_get_button_state(t);
snprintf(btn_buffer, sizeof(btn_buffer),
", button: %d, state: %s\n",
button,
state ? "pressed" : "released");
}
tip = libinput_event_tablet_tool_get_tip_state(t);
time = time_offset(ctx, libinput_event_tablet_tool_get_time_usec(t));
axes = buffer_tablet_axes(t);
event->time = time;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s%s, tip: %s, %s}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
btn_buffer, /* may be empty string */
tip ? "down" : "up",
axes);
free(axes);
}
static void
buffer_tablet_pad_button_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_event_tablet_pad *p =
libinput_event_get_tablet_pad_event(e);
struct libinput_tablet_pad_mode_group *group;
enum libinput_button_state state;
unsigned int button, mode;
const char *type;
uint64_t time;
switch(libinput_event_get_type(e)) {
case LIBINPUT_EVENT_TABLET_PAD_BUTTON:
type = "TABLET_PAD_BUTTON";
break;
default:
abort();
}
time = time_offset(ctx, libinput_event_tablet_pad_get_time_usec(p));
button = libinput_event_tablet_pad_get_button_number(p),
state = libinput_event_tablet_pad_get_button_state(p);
mode = libinput_event_tablet_pad_get_mode(p);
group = libinput_event_tablet_pad_get_mode_group(p);
event->time = time;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, button: %d, state: %s, mode: %d, is-toggle: %s}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
button,
state == LIBINPUT_BUTTON_STATE_PRESSED ? "pressed" : "released",
mode,
libinput_tablet_pad_mode_group_button_is_toggle(group, button) ? "true" : "false"
);
}
static void
buffer_tablet_pad_ringstrip_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_event_tablet_pad *p =
libinput_event_get_tablet_pad_event(e);
const char *source = NULL;
unsigned int mode, number;
const char *type;
uint64_t time;
double pos;
switch(libinput_event_get_type(e)) {
case LIBINPUT_EVENT_TABLET_PAD_RING:
type = "TABLET_PAD_RING";
number = libinput_event_tablet_pad_get_ring_number(p);
pos = libinput_event_tablet_pad_get_ring_position(p);
switch (libinput_event_tablet_pad_get_ring_source(p)) {
case LIBINPUT_TABLET_PAD_RING_SOURCE_FINGER:
source = "finger";
break;
case LIBINPUT_TABLET_PAD_RING_SOURCE_UNKNOWN:
source = "unknown";
break;
}
break;
case LIBINPUT_EVENT_TABLET_PAD_STRIP:
type = "TABLET_PAD_STRIP";
number = libinput_event_tablet_pad_get_strip_number(p);
pos = libinput_event_tablet_pad_get_strip_position(p);
switch (libinput_event_tablet_pad_get_strip_source(p)) {
case LIBINPUT_TABLET_PAD_STRIP_SOURCE_FINGER:
source = "finger";
break;
case LIBINPUT_TABLET_PAD_STRIP_SOURCE_UNKNOWN:
source = "unknown";
break;
}
break;
default:
abort();
}
time = time_offset(ctx, libinput_event_tablet_pad_get_time_usec(p));
mode = libinput_event_tablet_pad_get_mode(p);
event->time = time;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, number: %d, position: %.2f, source: %s, mode: %d}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
number,
pos,
source,
mode);
}
static void
buffer_switch_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
struct libinput_event_switch *s = libinput_event_get_switch_event(e);
enum libinput_switch_state state;
uint32_t sw;
const char *type;
uint64_t time;
switch(libinput_event_get_type(e)) {
case LIBINPUT_EVENT_SWITCH_TOGGLE:
type = "SWITCH_TOGGLE";
break;
default:
abort();
}
time = time_offset(ctx, libinput_event_switch_get_time_usec(s));
sw = libinput_event_switch_get_switch(s);
state = libinput_event_switch_get_switch_state(s);
event->time = time;
snprintf(event->u.libinput.msg,
sizeof(event->u.libinput.msg),
"{time: %ld.%06ld, type: %s, switch: %d, state: %s}",
(long)(time / (int)1e6),
(long)(time % (int)1e6),
type,
sw,
state == LIBINPUT_SWITCH_STATE_ON ? "on" : "off");
}
static void
buffer_libinput_event(struct record_context *ctx,
struct libinput_event *e,
struct event *event)
{
switch (libinput_event_get_type(e)) {
case LIBINPUT_EVENT_NONE:
abort();
case LIBINPUT_EVENT_DEVICE_ADDED:
case LIBINPUT_EVENT_DEVICE_REMOVED:
buffer_device_notify(ctx, e, event);
break;
case LIBINPUT_EVENT_KEYBOARD_KEY:
buffer_key_event(ctx, e, event);
break;
case LIBINPUT_EVENT_POINTER_MOTION:
buffer_motion_event(ctx, e, event);
break;
case LIBINPUT_EVENT_POINTER_MOTION_ABSOLUTE:
buffer_absmotion_event(ctx, e, event);
break;
case LIBINPUT_EVENT_POINTER_BUTTON:
buffer_pointer_button_event(ctx, e, event);
break;
case LIBINPUT_EVENT_POINTER_AXIS:
buffer_pointer_axis_event(ctx, e, event);
break;
case LIBINPUT_EVENT_TOUCH_DOWN:
case LIBINPUT_EVENT_TOUCH_UP:
case LIBINPUT_EVENT_TOUCH_MOTION:
case LIBINPUT_EVENT_TOUCH_CANCEL:
case LIBINPUT_EVENT_TOUCH_FRAME:
buffer_touch_event(ctx, e, event);
break;
case LIBINPUT_EVENT_GESTURE_PINCH_BEGIN:
case LIBINPUT_EVENT_GESTURE_PINCH_UPDATE:
case LIBINPUT_EVENT_GESTURE_PINCH_END:
case LIBINPUT_EVENT_GESTURE_SWIPE_BEGIN:
case LIBINPUT_EVENT_GESTURE_SWIPE_UPDATE:
case LIBINPUT_EVENT_GESTURE_SWIPE_END:
buffer_gesture_event(ctx, e, event);
break;
case LIBINPUT_EVENT_TABLET_TOOL_PROXIMITY:
buffer_tablet_tool_proximity_event(ctx, e, event);
break;
case LIBINPUT_EVENT_TABLET_TOOL_AXIS:
case LIBINPUT_EVENT_TABLET_TOOL_TIP:
buffer_tablet_tool_event(ctx, e, event);
break;
case LIBINPUT_EVENT_TABLET_TOOL_BUTTON:
buffer_tablet_tool_button_event(ctx, e, event);
break;
case LIBINPUT_EVENT_TABLET_PAD_BUTTON:
buffer_tablet_pad_button_event(ctx, e, event);
break;
case LIBINPUT_EVENT_TABLET_PAD_RING:
case LIBINPUT_EVENT_TABLET_PAD_STRIP:
buffer_tablet_pad_ringstrip_event(ctx, e, event);
break;
case LIBINPUT_EVENT_SWITCH_TOGGLE:
buffer_switch_event(ctx, e, event);
break;
default:
break;
}
}
static void
print_cached_events(struct record_context *ctx,
struct record_device *d,
unsigned int offset,
int len)
{
unsigned int idx;
enum event_type last_type;
uint64_t last_time;
if (len == -1)
len = d->nevents - offset;
assert(offset + len <= d->nevents);
if (offset == 0) {
last_type = NONE;
last_time = 0;
} else {
last_type = d->events[offset - 1].type;
last_time = d->events[offset - 1].time;
}
idx = offset;
indent_push(ctx);
while (idx < offset + len) {
struct event *e;
e = &d->events[idx++];
if (e->type != last_type || e->time != last_time) {
bool new_frame = false;
if (last_time == 0 || e->time != last_time)
new_frame = true;
indent_pop(ctx);
switch(e->type) {
case EVDEV:
if (new_frame)
iprintf(ctx, "- evdev:\n");
else
iprintf(ctx, "evdev:\n");
break;
case LIBINPUT:
if (new_frame)
iprintf(ctx, "- libinput:\n");
else
iprintf(ctx, "libinput:\n");
break;
case COMMENT:
break;
default:
abort();
}
indent_push(ctx);
last_type = e->type;
}
switch (e->type) {
case EVDEV:
print_evdev_event(ctx, d, &e->u.evdev);
break;
case LIBINPUT:
iprintf(ctx, "- %s\n", e->u.libinput.msg);
break;
case COMMENT:
iprintf(ctx, "%s", e->u.comment);
break;
default:
abort();
}
last_time = e->time;
}
indent_pop(ctx);
}
static inline size_t
handle_libinput_events(struct record_context *ctx,
struct record_device *d)
{
struct libinput_event *e;
size_t count = 0;
struct record_device *current = d;
libinput_dispatch(ctx->libinput);
while ((e = libinput_get_event(ctx->libinput)) != NULL) {
struct libinput_device *device = libinput_event_get_device(e);
struct event *event;
if (device != current->device) {
struct record_device *tmp;
bool found = false;
list_for_each(tmp, &ctx->devices, link) {
if (device == tmp->device) {
current = tmp;
found = true;
break;
}
}
assert(found);
}
if (current->nevents == current->events_sz)
resize(current->events, current->events_sz);
event = &current->events[current->nevents++];
event->type = LIBINPUT;
buffer_libinput_event(ctx, e, event);
if (current == d)
count++;
libinput_event_destroy(e);
}
return count;
}
static inline void
handle_events(struct record_context *ctx, struct record_device *d, bool print)
{
while(true) {
size_t first_idx = d->nevents;
size_t evcount = 0,
licount = 0;
evcount = handle_evdev_frame(ctx, d);
if (ctx->libinput)
licount = handle_libinput_events(ctx, d);
if (evcount == 0 && licount == 0)
break;
if (!print)
continue;
print_cached_events(ctx, d, first_idx, evcount + licount);
}
}
static inline void
print_libinput_header(struct record_context *ctx)
{
iprintf(ctx, "libinput:\n");
indent_push(ctx);
iprintf(ctx, "version: \"%s\"\n", LIBINPUT_VERSION);
iprintf(ctx, "git: \"%s\"\n", LIBINPUT_GIT_VERSION);
if (ctx->timeout > 0)
iprintf(ctx, "autorestart: %d\n", ctx->timeout);
indent_pop(ctx);
}
static inline void
print_system_header(struct record_context *ctx)
{
struct utsname u;
const char *kernel = "unknown";
FILE *dmi, *osrelease;
char dmistr[2048] = "unknown";
iprintf(ctx, "system:\n");
indent_push(ctx);
/* /etc/os-release version and distribution name */
osrelease = fopen("/etc/os-release", "r");
if (!osrelease)
osrelease = fopen("/usr/lib/os-release", "r");
if (osrelease) {
char *distro = NULL, *version = NULL;
char osrstr[256] = "unknown";
while (fgets(osrstr, sizeof(osrstr), osrelease)) {
osrstr[strlen(osrstr) - 1] = '\0'; /* linebreak */
if (!distro && strneq(osrstr, "ID=", 3))
distro = strstrip(&osrstr[3], "\"'");
else if (!version && strneq(osrstr, "VERSION_ID=", 11))
version = strstrip(&osrstr[11], "\"'");
if (distro && version) {
iprintf(ctx, "os: \"%s:%s\"\n", distro, version);
break;
}
}
free(distro);
free(version);
fclose(osrelease);
}
/* kernel version */
if (uname(&u) != -1)
kernel = u.release;
iprintf(ctx, "kernel: \"%s\"\n", kernel);
/* dmi modalias */
dmi = fopen("/sys/class/dmi/id/modalias", "r");
if (dmi) {
if (fgets(dmistr, sizeof(dmistr), dmi)) {
dmistr[strlen(dmistr) - 1] = '\0'; /* linebreak */
} else {
sprintf(dmistr, "unknown");
}
fclose(dmi);
}
iprintf(ctx, "dmi: \"%s\"\n", dmistr);
indent_pop(ctx);
}
static inline void
print_header(struct record_context *ctx)
{
iprintf(ctx, "version: %d\n", FILE_VERSION_NUMBER);
iprintf(ctx, "ndevices: %d\n", ctx->ndevices);
print_libinput_header(ctx);
print_system_header(ctx);
}
static inline void
print_description_abs(struct record_context *ctx,
struct libevdev *dev,
unsigned int code)
{
const struct input_absinfo *abs;
abs = libevdev_get_abs_info(dev, code);
assert(abs);
iprintf(ctx, "# Value %6d\n", abs->value);
iprintf(ctx, "# Min %6d\n", abs->minimum);
iprintf(ctx, "# Max %6d\n", abs->maximum);
iprintf(ctx, "# Fuzz %6d\n", abs->fuzz);
iprintf(ctx, "# Flat %6d\n", abs->flat);
iprintf(ctx, "# Resolution %6d\n", abs->resolution);
}
static inline void
print_description_state(struct record_context *ctx,
struct libevdev *dev,
unsigned int type,
unsigned int code)
{
int state = libevdev_get_event_value(dev, type, code);
iprintf(ctx, "# State %d\n", state);
}
static inline void
print_description_codes(struct record_context *ctx,
struct libevdev *dev,
unsigned int type)
{
int max;
max = libevdev_event_type_get_max(type);
if (max == -1)
return;
iprintf(ctx,
"# Event type %d (%s)\n",
type,
libevdev_event_type_get_name(type));
if (type == EV_SYN)
return;
for (unsigned int code = 0; code <= (unsigned int)max; code++) {
if (!libevdev_has_event_code(dev, type, code))
continue;
iprintf(ctx,
"# Event code %d (%s)\n",
code,
libevdev_event_code_get_name(type,
code));
switch (type) {
case EV_ABS:
print_description_abs(ctx, dev, code);
break;
case EV_LED:
case EV_SW:
print_description_state(ctx, dev, type, code);
break;
}
}
}
static inline void
print_description(struct record_context *ctx, struct libevdev *dev)
{
const struct input_absinfo *x, *y;
iprintf(ctx, "# Name: %s\n", libevdev_get_name(dev));
iprintf(ctx,
"# ID: bus %#02x vendor %#02x product %#02x version %#02x\n",
libevdev_get_id_bustype(dev),
libevdev_get_id_vendor(dev),
libevdev_get_id_product(dev),
libevdev_get_id_version(dev));
x = libevdev_get_abs_info(dev, ABS_X);
y = libevdev_get_abs_info(dev, ABS_Y);
if (x && y) {
if (x->resolution && y->resolution) {
int w, h;
w = (x->maximum - x->minimum)/x->resolution;
h = (y->maximum - y->minimum)/y->resolution;
iprintf(ctx, "# Size in mm: %dx%d\n", w, h);
} else {
iprintf(ctx,
"# Size in mm: unknown, missing resolution\n");
}
}
iprintf(ctx, "# Supported Events:\n");
for (unsigned int type = 0; type < EV_CNT; type++) {
if (!libevdev_has_event_type(dev, type))
continue;
print_description_codes(ctx, dev, type);
}
iprintf(ctx, "# Properties:\n");
for (unsigned int prop = 0; prop < INPUT_PROP_CNT; prop++) {
if (libevdev_has_property(dev, prop)) {
iprintf(ctx,
"# Property %d (%s)\n",
prop,
libevdev_property_get_name(prop));
}
}
}
static inline void
print_bits_info(struct record_context *ctx, struct libevdev *dev)
{
iprintf(ctx, "name: \"%s\"\n", libevdev_get_name(dev));
iprintf(ctx,
"id: [%d, %d, %d, %d]\n",
libevdev_get_id_bustype(dev),
libevdev_get_id_vendor(dev),
libevdev_get_id_product(dev),
libevdev_get_id_version(dev));
}
static inline void
print_bits_absinfo(struct record_context *ctx, struct libevdev *dev)
{
const struct input_absinfo *abs;
if (!libevdev_has_event_type(dev, EV_ABS))
return;
iprintf(ctx, "absinfo:\n");
indent_push(ctx);
for (unsigned int code = 0; code < ABS_CNT; code++) {
abs = libevdev_get_abs_info(dev, code);
if (!abs)
continue;
iprintf(ctx,
"%d: [%d, %d, %d, %d, %d]\n",
code,
abs->minimum,
abs->maximum,
abs->fuzz,
abs->flat,
abs->resolution);
}
indent_pop(ctx);
}
static inline void
print_bits_codes(struct record_context *ctx,
struct libevdev *dev,
unsigned int type)
{
int max;
bool first = true;
max = libevdev_event_type_get_max(type);
if (max == -1)
return;
iprintf(ctx, "%d: [", type);
for (unsigned int code = 0; code <= (unsigned int)max; code++) {
if (!libevdev_has_event_code(dev, type, code))
continue;
noiprintf(ctx, "%s%d", first ? "" : ", ", code);
first = false;
}
noiprintf(ctx, "] # %s\n", libevdev_event_type_get_name(type));
}
static inline void
print_bits_types(struct record_context *ctx, struct libevdev *dev)
{
iprintf(ctx, "codes:\n");
indent_push(ctx);
for (unsigned int type = 0; type < EV_CNT; type++) {
if (!libevdev_has_event_type(dev, type))
continue;
print_bits_codes(ctx, dev, type);
}
indent_pop(ctx);
}
static inline void
print_bits_props(struct record_context *ctx, struct libevdev *dev)
{
bool first = true;
iprintf(ctx, "properties: [");
for (unsigned int prop = 0; prop < INPUT_PROP_CNT; prop++) {
if (libevdev_has_property(dev, prop)) {
noiprintf(ctx, "%s%d", first ? "" : ", ", prop);
first = false;
}
}
noiprintf(ctx, "]\n"); /* last entry, no comma */
}
static inline void
print_evdev_description(struct record_context *ctx, struct record_device *dev)
{
struct libevdev *evdev = dev->evdev;
iprintf(ctx, "evdev:\n");
indent_push(ctx);
print_description(ctx, evdev);
print_bits_info(ctx, evdev);
print_bits_types(ctx, evdev);
print_bits_absinfo(ctx, evdev);
print_bits_props(ctx, evdev);
indent_pop(ctx);
}
static inline void
print_hid_report_descriptor(struct record_context *ctx,
struct record_device *dev)
{
const char *prefix = "/dev/input/event";
const char *node;
char syspath[PATH_MAX];
unsigned char buf[1024];
int len;
int fd;
bool first = true;
/* we take the shortcut rather than the proper udev approach, the
report_descriptor is available in sysfs and two devices up from
our device. 2 digits for the event number should be enough.
This approach won't work for /dev/input/by-id devices. */
if (!strstartswith(dev->devnode, prefix) ||
strlen(dev->devnode) > strlen(prefix) + 2)
return;
node = &dev->devnode[strlen(prefix)];
len = snprintf(syspath,
sizeof(syspath),
"/sys/class/input/event%s/device/device/report_descriptor",
node);
if (len < 55 || len > 56)
return;
fd = open(syspath, O_RDONLY);
if (fd == -1)
return;
iprintf(ctx, "hid: [");
while ((len = read(fd, buf, sizeof(buf))) > 0) {
for (int i = 0; i < len; i++) {
/* YAML requires decimal */
noiprintf(ctx, "%s%u",first ? "" : ", ", buf[i]);
first = false;
}
}
noiprintf(ctx, " ]\n");
close(fd);
}
static inline void
print_udev_properties(struct record_context *ctx, struct record_device *dev)
{
struct udev *udev = NULL;
struct udev_device *udev_device = NULL;
struct udev_list_entry *entry;
struct stat st;
if (stat(dev->devnode, &st) < 0)
return;
udev = udev_new();
if (!udev)
goto out;
udev_device = udev_device_new_from_devnum(udev, 'c', st.st_rdev);
if (!udev_device)
goto out;
iprintf(ctx, "udev:\n");
indent_push(ctx);
iprintf(ctx, "properties:\n");
indent_push(ctx);
entry = udev_device_get_properties_list_entry(udev_device);
while (entry) {
const char *key, *value;
key = udev_list_entry_get_name(entry);
if (strneq(key, "ID_INPUT", 8) ||
strneq(key, "LIBINPUT", 8) ||
strneq(key, "EVDEV_ABS", 9) ||
strneq(key, "MOUSE_DPI", 9) ||
strneq(key, "POINTINGSTICK_", 14)) {
value = udev_list_entry_get_value(entry);
iprintf(ctx, "- %s=%s\n", key, value);
}
entry = udev_list_entry_get_next(entry);
}
indent_pop(ctx);
indent_pop(ctx);
out:
udev_device_unref(udev_device);
udev_unref(udev);
}
static void
quirks_log_handler(struct libinput *this_is_null,
enum libinput_log_priority priority,
const char *format,
va_list args)
{
}
static void
list_print(void *userdata, const char *val)
{
struct record_context *ctx = userdata;
iprintf(ctx, "- %s\n", val);
}
static inline void
print_device_quirks(struct record_context *ctx, struct record_device *dev)
{
struct udev *udev = NULL;
struct udev_device *udev_device = NULL;
struct stat st;
struct quirks_context *quirks;
const char *data_path = LIBINPUT_QUIRKS_DIR;
const char *override_file = LIBINPUT_QUIRKS_OVERRIDE_FILE;
char *builddir = NULL;
if (stat(dev->devnode, &st) < 0)
return;
if ((builddir = builddir_lookup())) {
setenv("LIBINPUT_QUIRKS_DIR", LIBINPUT_QUIRKS_SRCDIR, 0);
data_path = LIBINPUT_QUIRKS_SRCDIR;
override_file = NULL;
}
free(builddir);
quirks = quirks_init_subsystem(data_path,
override_file,
quirks_log_handler,
NULL,
QLOG_CUSTOM_LOG_PRIORITIES);
if (!quirks) {
fprintf(stderr,
"Failed to initialize the device quirks. "
"Please see the above errors "
"and/or re-run with --verbose for more details\n");
return;
}
udev = udev_new();
if (!udev)
goto out;
udev_device = udev_device_new_from_devnum(udev, 'c', st.st_rdev);
if (!udev_device)
goto out;
iprintf(ctx, "quirks:\n");
indent_push(ctx);
tools_list_device_quirks(quirks, udev_device, list_print, ctx);
indent_pop(ctx);
out:
udev_device_unref(udev_device);
udev_unref(udev);
quirks_context_unref(quirks);
}
static inline void
print_libinput_description(struct record_context *ctx,
struct record_device *dev)
{
struct libinput_device *device = dev->device;
double w, h;
struct cap {
enum libinput_device_capability cap;
const char *name;
} caps[] = {
{LIBINPUT_DEVICE_CAP_KEYBOARD, "keyboard"},
{LIBINPUT_DEVICE_CAP_POINTER, "pointer"},
{LIBINPUT_DEVICE_CAP_TOUCH, "touch"},
{LIBINPUT_DEVICE_CAP_TABLET_TOOL, "tablet"},
{LIBINPUT_DEVICE_CAP_TABLET_PAD, "pad"},
{LIBINPUT_DEVICE_CAP_GESTURE, "gesture"},
{LIBINPUT_DEVICE_CAP_SWITCH, "switch"},
};
struct cap *cap;
bool is_first;
if (!device)
return;
iprintf(ctx, "libinput:\n");
indent_push(ctx);
if (libinput_device_get_size(device, &w, &h) == 0)
iprintf(ctx, "size: [%.f, %.f]\n", w, h);
iprintf(ctx, "capabilities: [");
is_first = true;
ARRAY_FOR_EACH(caps, cap) {
if (!libinput_device_has_capability(device, cap->cap))
continue;
noiprintf(ctx, "%s%s", is_first ? "" : ", ", cap->name);
is_first = false;
}
noiprintf(ctx, "]\n");
/* Configuration options should be printed here, but since they
* don't reflect the user-configured ones their usefulness is
* questionable. We need the ability to specify the options like in
* debug-events.
*/
indent_pop(ctx);
}
static inline void
print_device_description(struct record_context *ctx, struct record_device *dev)
{
iprintf(ctx, "- node: %s\n", dev->devnode);
print_evdev_description(ctx, dev);
print_hid_report_descriptor(ctx, dev);
print_udev_properties(ctx, dev);
print_device_quirks(ctx, dev);
print_libinput_description(ctx, dev);
}
static int is_event_node(const struct dirent *dir) {
return strneq(dir->d_name, "event", 5);
}
static inline char *
select_device(void)
{
struct dirent **namelist;
int ndev, selected_device;
int rc;
char *device_path;
bool has_eaccess = false;
int available_devices = 0;
const char *prefix = "";
if (!isatty(STDERR_FILENO))
prefix = "# ";
ndev = scandir("/dev/input", &namelist, is_event_node, versionsort);
if (ndev <= 0)
return NULL;
fprintf(stderr, "%sAvailable devices:\n", prefix);
for (int i = 0; i < ndev; i++) {
struct libevdev *device;
char path[PATH_MAX];
int fd = -1;
snprintf(path,
sizeof(path),
"/dev/input/%s",
namelist[i]->d_name);
fd = open(path, O_RDONLY);
if (fd < 0) {
if (errno == EACCES)
has_eaccess = true;
continue;
}
rc = libevdev_new_from_fd(fd, &device);
close(fd);
if (rc != 0)
continue;
fprintf(stderr, "%s%s: %s\n", prefix, path, libevdev_get_name(device));
libevdev_free(device);
available_devices++;
}
for (int i = 0; i < ndev; i++)
free(namelist[i]);
free(namelist);
if (available_devices == 0) {
fprintf(stderr,
"No devices available.%s\n",
has_eaccess ? " Please re-run as root." : "");
return NULL;
}
fprintf(stderr, "%sSelect the device event number: ", prefix);
rc = scanf("%d", &selected_device);
if (rc != 1 || selected_device < 0)
return NULL;
rc = xasprintf(&device_path, "/dev/input/event%d", selected_device);
if (rc == -1)
return NULL;
return device_path;
}
static inline char **
all_devices(void)
{
struct dirent **namelist;
int ndev;
int rc;
char **devices = NULL;
ndev = scandir("/dev/input", &namelist, is_event_node, versionsort);
if (ndev <= 0)
return NULL;
devices = zalloc((ndev + 1)* sizeof *devices); /* NULL-terminated */
for (int i = 0; i < ndev; i++) {
char *device_path;
rc = xasprintf(&device_path,
"/dev/input/%s",
namelist[i]->d_name);
if (rc == -1)
goto error;
devices[i] = device_path;
}
return devices;
error:
if (devices)
strv_free(devices);
return NULL;
}
static char *
init_output_file(const char *file, bool is_prefix)
{
char name[PATH_MAX];
assert(file != NULL);
if (is_prefix) {
struct tm *tm;
time_t t;
char suffix[64];
t = time(NULL);
tm = localtime(&t);
strftime(suffix, sizeof(suffix), "%F-%T", tm);
snprintf(name,
sizeof(name),
"%s.%s",
file,
suffix);
} else {
snprintf(name, sizeof(name), "%s", file);
}
return strdup(name);
}
static bool
open_output_file(struct record_context *ctx, bool is_prefix)
{
int out_fd;
if (ctx->outfile) {
char *fname = init_output_file(ctx->outfile, is_prefix);
ctx->output_file = fname;
out_fd = open(fname, O_WRONLY|O_CREAT|O_TRUNC, 0666);
if (out_fd < 0)
return false;
} else {
ctx->output_file = safe_strdup("stdout");
out_fd = STDOUT_FILENO;
}
ctx->out_fd = out_fd;
return true;
}
static inline void
print_progress_bar(void)
{
static uint8_t foo = 0;
if (!isatty(STDERR_FILENO))
return;
if (++foo > 20)
foo = 1;
fprintf(stderr, "\rReceiving events: [%*s%*s]", foo, "*", 21 - foo, " ");
}
static inline void
print_wall_time(struct record_context *ctx)
{
time_t t = time(NULL);
struct tm tm;
localtime_r(&t, &tm);
iprintf(ctx, "# Current time is %02d:%02d:%02d\n", tm.tm_hour, tm.tm_min, tm.tm_sec);
}
static inline void
arm_timer(int timerfd)
{
time_t t = time(NULL);
struct tm tm;
struct itimerspec interval = {
.it_value = { 0, 0 },
.it_interval = { 5, 0 },
};
localtime_r(&t, &tm);
interval.it_value.tv_sec = 5 - (tm.tm_sec % 5);
timerfd_settime(timerfd, 0, &interval, NULL);
}
static int
mainloop(struct record_context *ctx)
{
bool autorestart = (ctx->timeout > 0);
struct pollfd fds[ctx->ndevices + 3];
struct pollfd *signal_fd = &fds[0];
struct pollfd *time_fd = &fds[1];
struct pollfd *libinput_fd = NULL;
unsigned int nfds = 0;
struct record_device *d = NULL;
sigset_t mask;
assert(ctx->timeout != 0);
assert(!list_empty(&ctx->devices));
sigemptyset(&mask);
sigaddset(&mask, SIGINT);
sigaddset(&mask, SIGQUIT);
sigprocmask(SIG_BLOCK, &mask, NULL);
for (size_t i = 0; i < ARRAY_LENGTH(fds); i++) {
fds[i] = (struct pollfd) {
.fd = -1,
.events = POLLIN,
.revents = 0,
};
}
signal_fd->fd = signalfd(-1, &mask, SFD_NONBLOCK);
assert(signal_fd->fd != -1);
nfds++;
time_fd->fd = timerfd_create(CLOCK_MONOTONIC, TFD_CLOEXEC | TFD_NONBLOCK);
assert(time_fd->fd != -1);
arm_timer(time_fd->fd);
nfds++;
if (ctx->libinput) {
libinput_fd = &fds[nfds++];
libinput_fd->fd = libinput_get_fd(ctx->libinput);
}
list_for_each(d, &ctx->devices, link) {
fds[nfds].fd = libevdev_get_fd(d->evdev);
assert(fds[nfds].fd != -1);
nfds++;
}
/* If we have more than one device, the time starts at recording
* start time. Otherwise, the first event starts the recording time.
*/
if (ctx->ndevices > 1) {
struct timespec ts;
clock_gettime(CLOCK_MONOTONIC, &ts);
ctx->offset = s2us(ts.tv_sec) + ns2us(ts.tv_nsec);
}
do {
int rc;
bool had_events = false; /* we delete files without events */
bool had_events_since_last_time = false;
bool skipped_timer_print = false;
struct record_device *first_device = NULL;
if (!open_output_file(ctx, autorestart)) {
fprintf(stderr,
"Failed to open '%s'\n",
ctx->output_file);
break;
}
fprintf(stderr, "%sRecording to '%s'.\n",
isatty(STDERR_FILENO) ? "" : "# ",
ctx->output_file);
print_header(ctx);
if (autorestart)
iprintf(ctx,
"# Autorestart timeout: %d\n",
ctx->timeout);
iprintf(ctx, "devices:\n");
indent_push(ctx);
/* we only print the first device's description, the
* rest is assembled after CTRL+C */
first_device = list_first_entry(&ctx->devices,
first_device,
link);
print_device_description(ctx, first_device);
print_wall_time(ctx);
iprintf(ctx, "events:\n");
indent_push(ctx);
if (ctx->libinput) {
size_t count;
libinput_dispatch(ctx->libinput);
count = handle_libinput_events(ctx, first_device);
print_cached_events(ctx, first_device, 0, count);
}
while (true) {
rc = poll(fds, nfds, ctx->timeout);
if (rc == -1) { /* error */
fprintf(stderr, "Error: %m\n");
autorestart = false;
break;
}
if (rc == 0) {
fprintf(stderr,
" ... timeout%s\n",
had_events ? "" : " (file is empty)");
break;
}
if (signal_fd->revents != 0) { /* signal */
autorestart = false;
break;
}
if (time_fd->revents) { /* timer expiry */
char discard[64];
read(time_fd->fd, discard, sizeof(discard));
if (had_events_since_last_time) {
print_wall_time(ctx);
had_events_since_last_time = false;
skipped_timer_print = false;
} else {
skipped_timer_print = true;
}
if (rc == 1) /* no other fds have data */
continue;
}
if (skipped_timer_print) {
print_wall_time(ctx);
had_events_since_last_time = false;
skipped_timer_print = false;
}
/* Pull off the evdev events first since they cause
* libinput events.
* handle_events de-queues libinput events so by the
* time we finish that, we hopefully have all evdev
* events and libinput events roughly in sync.
*/
had_events = true;
had_events_since_last_time = true;
list_for_each(d, &ctx->devices, link)
handle_events(ctx, d, d == first_device);
/* This shouldn't pull any events off unless caused
* by libinput-internal timeouts (e.g. tapping) */
if (ctx->libinput && libinput_fd->revents) {
size_t count, offset;
libinput_dispatch(ctx->libinput);
offset = first_device->nevents;
count = handle_libinput_events(ctx,
first_device);
if (count) {
print_cached_events(ctx,
first_device,
offset,
count);
}
rc--;
}
if (ctx->out_fd != STDOUT_FILENO)
print_progress_bar();
}
indent_pop(ctx); /* events: */
if (autorestart) {
noiprintf(ctx,
"# Closing after %ds inactivity",
ctx->timeout/1000);
}
/* First device is printed, now append all the data from the
* other devices, if any */
list_for_each(d, &ctx->devices, link) {
if (d == list_first_entry(&ctx->devices, d, link))
continue;
print_device_description(ctx, d);
iprintf(ctx, "events:\n");
indent_push(ctx);
print_cached_events(ctx, d, 0, -1);
indent_pop(ctx);
}
indent_pop(ctx); /* devices: */
assert(ctx->indent == 0);
fsync(ctx->out_fd);
/* If we didn't have events, delete the file. */
if (!isatty(ctx->out_fd)) {
if (!had_events && ctx->output_file) {
fprintf(stderr, "No events recorded, deleting '%s'\n", ctx->output_file);
unlink(ctx->output_file);
}
close(ctx->out_fd);
ctx->out_fd = -1;
}
free(ctx->output_file);
ctx->output_file = NULL;
} while (autorestart);
close(signal_fd->fd);
close(time_fd->fd);
sigprocmask(SIG_UNBLOCK, &mask, NULL);
return 0;
}
static inline bool
init_device(struct record_context *ctx, char *path, bool grab)
{
struct record_device *d;
int fd, rc;
d = zalloc(sizeof(*d));
d->devnode = path;
d->nevents = 0;
d->events_sz = 5000;
d->events = zalloc(d->events_sz * sizeof(*d->events));
fd = open(d->devnode, O_RDONLY|O_NONBLOCK);
if (fd < 0) {
fprintf(stderr,
"Failed to open device %s (%m)\n",
d->devnode);
goto error;
}
rc = libevdev_new_from_fd(fd, &d->evdev);
if (rc == 0)
rc = libevdev_new_from_fd(fd, &d->evdev_prev);
if (rc != 0) {
fprintf(stderr,
"Failed to create context for %s (%s)\n",
d->devnode,
strerror(-rc));
goto error;
}
if (grab) {
rc = libevdev_grab(d->evdev, LIBEVDEV_GRAB);
if (rc != 0) {
fprintf(stderr,
"Grab failed on %s: %s\n",
path,
strerror(-rc));
goto error;
}
}
libevdev_set_clock_id(d->evdev, CLOCK_MONOTONIC);
if (libevdev_get_num_slots(d->evdev) > 0)
d->touch.is_touch_device = true;
list_insert(&ctx->devices, &d->link);
ctx->ndevices++;
return true;
error:
close(fd);
free(d);
return false;
}
static int
open_restricted(const char *path, int flags, void *user_data)
{
int fd = open(path, flags);
return fd == -1 ? -errno : fd;
}
static void close_restricted(int fd, void *user_data)
{
close(fd);
}
const struct libinput_interface interface = {
.open_restricted = open_restricted,
.close_restricted = close_restricted,
};
static inline bool
init_libinput(struct record_context *ctx)
{
struct record_device *dev;
struct libinput *li;
li = libinput_path_create_context(&interface, NULL);
if (li == NULL) {
fprintf(stderr,
"Failed to create libinput context\n");
return false;
}
ctx->libinput = li;
list_for_each(dev, &ctx->devices, link) {
struct libinput_device *d;
d = libinput_path_add_device(li, dev->devnode);
if (!d) {
fprintf(stderr,
"Failed to add device %s\n",
dev->devnode);
continue;
}
dev->device = libinput_device_ref(d);
/* FIXME: this needs to be a commandline option */
libinput_device_config_tap_set_enabled(d,
LIBINPUT_CONFIG_TAP_ENABLED);
}
return true;
}
static inline void
usage(void)
{
printf("Usage: %s [--help] [--all] [--autorestart] [--output-file filename] [/dev/input/event0] [...]\n"
"Common use-cases:\n"
"\n"
" sudo %s -o recording.yml\n"
" Then select the device to record and it Ctrl+C to stop.\n"
" The recorded data is in recording.yml and can be attached to a bug report.\n"
"\n"
" sudo %s -o recording.yml --autorestart 2\n"
" As above, but restarts after 2s of inactivity on the device.\n"
" Note, the output file is only the prefix.\n"
"\n"
" sudo %s -o recording.yml /dev/input/event3 /dev/input/event4\n"
" Records the two devices into the same recordings file.\n"
"\n"
"For more information, see the %s(1) man page\n",
program_invocation_short_name,
program_invocation_short_name,
program_invocation_short_name,
program_invocation_short_name,
program_invocation_short_name);
}
enum ftype {
F_FILE = 8,
F_DEVICE,
F_NOEXIST,
};
static inline enum ftype is_char_dev(const char *path)
{
struct stat st;
if (strneq(path, "/dev", 4))
return F_DEVICE;
if (stat(path, &st) != 0) {
if (errno == ENOENT)
return F_NOEXIST;
return F_FILE;
}
return S_ISCHR(st.st_mode) ? F_DEVICE : F_FILE;
}
enum options {
OPT_AUTORESTART,
OPT_HELP,
OPT_OUTFILE,
OPT_KEYCODES,
OPT_MULTIPLE,
OPT_ALL,
OPT_LIBINPUT,
OPT_GRAB,
};
int
main(int argc, char **argv)
{
struct record_context ctx = {
.timeout = -1,
.show_keycodes = false,
};
struct option opts[] = {
{ "autorestart", required_argument, 0, OPT_AUTORESTART },
{ "output-file", required_argument, 0, OPT_OUTFILE },
{ "show-keycodes", no_argument, 0, OPT_KEYCODES },
{ "multiple", no_argument, 0, OPT_MULTIPLE },
{ "all", no_argument, 0, OPT_ALL },
{ "help", no_argument, 0, OPT_HELP },
{ "with-libinput", no_argument, 0, OPT_LIBINPUT },
{ "grab", no_argument, 0, OPT_GRAB },
{ 0, 0, 0, 0 },
};
struct record_device *d, *tmp;
const char *output_arg = NULL;
bool all = false, with_libinput = false, grab = false;
int ndevices;
int rc = EXIT_FAILURE;
list_init(&ctx.devices);
while (1) {
int c;
int option_index = 0;
c = getopt_long(argc, argv, "ho:", opts, &option_index);
if (c == -1)
break;
switch (c) {
case 'h':
case OPT_HELP:
usage();
rc = EXIT_SUCCESS;
goto out;
case OPT_AUTORESTART:
if (!safe_atoi(optarg, &ctx.timeout) ||
ctx.timeout <= 0) {
usage();
rc = EXIT_INVALID_USAGE;
goto out;
}
ctx.timeout = ctx.timeout * 1000;
break;
case 'o':
case OPT_OUTFILE:
output_arg = optarg;
break;
case OPT_KEYCODES:
ctx.show_keycodes = true;
break;
case OPT_MULTIPLE: /* deprecated */
break;
case OPT_ALL:
all = true;
break;
case OPT_LIBINPUT:
with_libinput = true;
break;
case OPT_GRAB:
grab = true;
break;
default:
usage();
rc = EXIT_INVALID_USAGE;
goto out;
}
}
ndevices = argc - optind;
/* We allow for multiple arguments after the options, *one* of which
* may be the output file. That one must be the first or the last to
* prevent users from running
* libinput record /dev/input/event0 output.yml /dev/input/event1
* because this will only backfire anyway.
*/
if (ndevices >= 1 && output_arg == NULL) {
char *first, *last;
enum ftype ftype_first;
first = argv[optind];
last = argv[argc - 1];
ftype_first = is_char_dev(first);
if (ndevices == 1) {
/* arg is *not* a char device, so let's assume it's
* the output file */
if (ftype_first != F_DEVICE) {
output_arg = first;
optind++;
ndevices--;
}
/* multiple arguments, yay */
} else {
enum ftype ftype_last = is_char_dev(last);
/*
first is device, last is file -> last
first is device, last is device -> noop
first is device, last !exist -> last
first is file, last is device -> first
first is file, last is file -> error
first is file, last !exist -> error
first !exist, last is device -> first
first !exist, last is file -> error
first !exit, last !exist -> error
*/
#define _m(f, l) (((f) << 8) | (l))
switch (_m(ftype_first, ftype_last)) {
case _m(F_FILE, F_DEVICE):
case _m(F_FILE, F_NOEXIST):
case _m(F_NOEXIST, F_DEVICE):
output_arg = first;
optind++;
ndevices--;
break;
case _m(F_DEVICE, F_FILE):
case _m(F_DEVICE, F_NOEXIST):
output_arg = last;
ndevices--;
break;
case _m(F_DEVICE, F_DEVICE):
break;
case _m(F_FILE, F_FILE):
case _m(F_NOEXIST, F_FILE):
case _m(F_NOEXIST, F_NOEXIST):
fprintf(stderr, "Ambiguous device vs output file list. Please use --output-file.\n");
rc = EXIT_INVALID_USAGE;
goto out;
}
#undef _m
}
}
if (ctx.timeout > 0 && output_arg == NULL) {
fprintf(stderr,
"Option --autorestart requires --output-file\n");
rc = EXIT_INVALID_USAGE;
goto out;
}
ctx.outfile = safe_strdup(output_arg);
if (all) {
char **devices; /* NULL-terminated */
char **d;
if (output_arg == NULL) {
fprintf(stderr,
"Option --all requires an output file\n");
rc = EXIT_INVALID_USAGE;
goto out;
}
devices = all_devices();
d = devices;
while (*d) {
if (!init_device(&ctx, safe_strdup(*d), grab)) {
strv_free(devices);
goto out;
}
d++;
}
strv_free(devices);
} else if (ndevices > 1) {
if (ndevices > 1 && output_arg == NULL) {
fprintf(stderr,
"Recording multiple devices requires an output file\n");
rc = EXIT_INVALID_USAGE;
goto out;
}
for (int i = ndevices; i > 0; i -= 1) {
char *devnode = safe_strdup(argv[optind + i - 1]);
if (!init_device(&ctx, devnode, grab))
goto out;
}
} else {
char *path;
path = ndevices <= 0 ? select_device() : safe_strdup(argv[optind++]);
if (path == NULL) {
goto out;
}
if (!init_device(&ctx, path, grab))
goto out;
}
if (with_libinput && !init_libinput(&ctx))
goto out;
rc = mainloop(&ctx);
out:
list_for_each_safe(d, tmp, &ctx.devices, link) {
if (d->device)
libinput_device_unref(d->device);
free(d->events);
free(d->devnode);
libevdev_free(d->evdev);
}
libinput_unref(ctx.libinput);
return rc;
}
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