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#include <fcntl.h>
#include <stdio.h>
#include <errno.h>
#include <string.h>
#include <unistd.h>
#include <sys/ioctl.h>
#include <libevdev/libevdev.h>
#include <limits.h>
#include <sys/types.h>
#include <dirent.h>
#include <linux/input.h>
#ifndef EVDEV_NO_UINPUT
#include <libevdev/libevdev-uinput.h>
#endif
#include "midimonster.h"
#include "evdev.h"
#define BACKEND_NAME "evdev"
static struct {
uint8_t detect;
} evdev_config = {
.detect = 0
};
MM_PLUGIN_API int init(){
backend evdev = {
.name = BACKEND_NAME,
.conf = evdev_configure,
.create = evdev_instance,
.conf_instance = evdev_configure_instance,
.channel = evdev_channel,
.handle = evdev_set,
.process = evdev_handle,
.start = evdev_start,
.shutdown = evdev_shutdown
};
if(sizeof(evdev_channel_ident) != sizeof(uint64_t)){
fprintf(stderr, "evdev channel identification union out of bounds\n");
return 1;
}
if(mm_backend_register(evdev)){
fprintf(stderr, "Failed to register evdev backend\n");
return 1;
}
return 0;
}
static int evdev_configure(char* option, char* value) {
if(!strcmp(option, "detect")){
evdev_config.detect = 1;
if(!strcmp(value, "off")){
evdev_config.detect = 0;
}
return 0;
}
fprintf(stderr, "Unknown configuration option %s for evdev backend\n", option);
return 1;
}
static instance* evdev_instance(){
instance* inst = mm_instance();
if(!inst){
return NULL;
}
evdev_instance_data* data = calloc(1, sizeof(evdev_instance_data));
if(!data){
fprintf(stderr, "Failed to allocate memory\n");
return NULL;
}
data->input_fd = -1;
#ifndef EVDEV_NO_UINPUT
data->output_proto = libevdev_new();
if(!data->output_proto){
fprintf(stderr, "Failed to initialize libevdev output prototype device\n");
free(data);
return NULL;
}
#endif
inst->impl = data;
return inst;
}
static int evdev_attach(instance* inst, evdev_instance_data* data, char* node){
if(data->input_fd >= 0){
fprintf(stderr, "Instance %s already was assigned an input device\n", inst->name);
return 1;
}
data->input_fd = open(node, O_RDONLY | O_NONBLOCK);
if(data->input_fd < 0){
fprintf(stderr, "Failed to open evdev input device node %s: %s\n", node, strerror(errno));
return 1;
}
if(libevdev_new_from_fd(data->input_fd, &data->input_ev)){
fprintf(stderr, "Failed to initialize libevdev for %s\n", node);
close(data->input_fd);
data->input_fd = -1;
return 1;
}
if(data->exclusive && libevdev_grab(data->input_ev, LIBEVDEV_GRAB)){
fprintf(stderr, "Failed to obtain exclusive device access on %s\n", node);
}
return 0;
}
static char* evdev_find(char* name){
int fd = -1;
struct dirent* file = NULL;
char file_path[PATH_MAX * 2];
DIR* nodes = opendir(INPUT_NODES);
char device_name[UINPUT_MAX_NAME_SIZE], *result = NULL;
if(!nodes){
fprintf(stderr, "Failed to query input device nodes in %s: %s", INPUT_NODES, strerror(errno));
return NULL;
}
for(file = readdir(nodes); file; file = readdir(nodes)){
if(!strncmp(file->d_name, INPUT_PREFIX, strlen(INPUT_PREFIX)) && file->d_type == DT_CHR){
snprintf(file_path, sizeof(file_path), "%s/%s", INPUT_NODES, file->d_name);
fd = open(file_path, O_RDONLY);
if(fd < 0){
fprintf(stderr, "Failed to access %s: %s\n", file_path, strerror(errno));
continue;
}
if(ioctl(fd, EVIOCGNAME(sizeof(device_name)), device_name) < 0){
fprintf(stderr, "Failed to read name for %s: %s\n", file_path, strerror(errno));
close(fd);
continue;
}
close(fd);
if(!strncmp(device_name, name, strlen(name))){
fprintf(stderr, "Matched name %s for %s: %s\n", device_name, name, file_path);
break;
}
}
}
if(file){
result = calloc(strlen(file_path) + 1, sizeof(char));
if(result){
strncpy(result, file_path, strlen(file_path));
}
}
closedir(nodes);
return result;
}
static int evdev_configure_instance(instance* inst, char* option, char* value) {
evdev_instance_data* data = (evdev_instance_data*) inst->impl;
char* next_token = NULL;
#ifndef EVDEV_NO_UINPUT
struct input_absinfo abs_info = {
0
};
#endif
if(!strcmp(option, "device")){
return evdev_attach(inst, data, value);
}
else if(!strcmp(option, "input")){
next_token = evdev_find(value);
if(!next_token){
fprintf(stderr, "Failed to find evdev input device with name %s for instance %s\n", value, inst->name);
return 1;
}
if(evdev_attach(inst, data, next_token)){
free(next_token);
return 1;
}
free(next_token);
return 0;
}
else if(!strcmp(option, "exclusive")){
if(data->input_fd >= 0 && libevdev_grab(data->input_ev, LIBEVDEV_GRAB)){
fprintf(stderr, "Failed to obtain exclusive device access on %s\n", inst->name);
}
data->exclusive = 1;
return 0;
}
else if(!strncmp(option, "relaxis.", 8)){
data->relative_axis = realloc(data->relative_axis, (data->relative_axes + 1) * sizeof(evdev_relaxis_config));
if(!data->relative_axis){
fprintf(stderr, "Failed to allocate memory\n");
return 1;
}
data->relative_axis[data->relative_axes].inverted = 0;
data->relative_axis[data->relative_axes].code = libevdev_event_code_from_name(EV_REL, option + 8);
data->relative_axis[data->relative_axes].max = strtoll(value, &next_token, 0);
if(data->relative_axis[data->relative_axes].max < 0){
data->relative_axis[data->relative_axes].max *= -1;
data->relative_axis[data->relative_axes].inverted = 1;
}
else if(data->relative_axis[data->relative_axes].max == 0){
fprintf(stderr, "Relative axis configuration for %s.%s has invalid range\n", inst->name, option + 8);
}
data->relative_axis[data->relative_axes].current = strtoul(next_token, NULL, 0);
if(data->relative_axis[data->relative_axes].code < 0){
fprintf(stderr, "Failed to configure relative axis extents for %s.%s\n", inst->name, option + 8);
return 1;
}
data->relative_axes++;
return 0;
}
#ifndef EVDEV_NO_UINPUT
else if(!strcmp(option, "output")){
data->output_enabled = 1;
libevdev_set_name(data->output_proto, value);
return 0;
}
else if(!strcmp(option, "id")){
next_token = value;
libevdev_set_id_vendor(data->output_proto, strtol(next_token, &next_token, 0));
libevdev_set_id_product(data->output_proto, strtol(next_token, &next_token, 0));
libevdev_set_id_version(data->output_proto, strtol(next_token, &next_token, 0));
return 0;
}
else if(!strncmp(option, "axis.", 5)){
//value minimum maximum fuzz flat resolution
next_token = value;
abs_info.value = strtol(next_token, &next_token, 0);
abs_info.minimum = strtol(next_token, &next_token, 0);
abs_info.maximum = strtol(next_token, &next_token, 0);
abs_info.fuzz = strtol(next_token, &next_token, 0);
abs_info.flat = strtol(next_token, &next_token, 0);
abs_info.resolution = strtol(next_token, &next_token, 0);
if(libevdev_enable_event_code(data->output_proto, EV_ABS, libevdev_event_code_from_name(EV_ABS, option + 5), &abs_info)){
fprintf(stderr, "Failed to enable absolute axis %s for output\n", option + 5);
return 1;
}
return 0;
}
#endif
fprintf(stderr, "Unknown instance configuration parameter %s for evdev instance %s\n", option, inst->name);
return 1;
}
static channel* evdev_channel(instance* inst, char* spec, uint8_t flags){
#ifndef EVDEV_NO_UINPUT
evdev_instance_data* data = (evdev_instance_data*) inst->impl;
#endif
char* separator = strchr(spec, '.');
evdev_channel_ident ident = {
.label = 0
};
if(!separator){
fprintf(stderr, "Invalid evdev channel specification %s\n", spec);
return NULL;
}
*(separator++) = 0;
if(libevdev_event_type_from_name(spec) < 0){
fprintf(stderr, "Invalid evdev type specification: %s", spec);
return NULL;
}
ident.fields.type = libevdev_event_type_from_name(spec);
if(libevdev_event_code_from_name(ident.fields.type, separator) >= 0){
ident.fields.code = libevdev_event_code_from_name(ident.fields.type, separator);
}
else{
fprintf(stderr, "evdev Code name not recognized, using as number: %s\n", separator);
ident.fields.code = strtoul(separator, NULL, 10);
}
#ifndef EVDEV_NO_UINPUT
if(data->output_enabled){
if(!libevdev_has_event_code(data->output_proto, ident.fields.type, ident.fields.code)){
//enable the event on the device
//the previous check is necessary to not fail while enabling axes, which require additional information
if(libevdev_enable_event_code(data->output_proto, ident.fields.type, ident.fields.code, NULL)){
fprintf(stderr, "Failed to enable output event %s.%s%s\n",
libevdev_event_type_get_name(ident.fields.type),
libevdev_event_code_get_name(ident.fields.type, ident.fields.code),
(ident.fields.type == EV_ABS) ? ": To output absolute axes, specify their details in the configuration":"");
return NULL;
}
}
}
#endif
return mm_channel(inst, ident.label, 1);
}
static int evdev_push_event(instance* inst, evdev_instance_data* data, struct input_event event){
uint64_t range = 0;
channel_value val;
evdev_channel_ident ident = {
.fields.type = event.type,
.fields.code = event.code
};
channel* chan = mm_channel(inst, ident.label, 0);
size_t axis;
if(chan){
val.raw.u64 = event.value;
switch(event.type){
case EV_REL:
for(axis = 0; axis < data->relative_axes; axis++){
if(data->relative_axis[axis].code == event.code){
if(data->relative_axis[axis].inverted){
event.value *= -1;
}
data->relative_axis[axis].current = clamp(data->relative_axis[axis].current + event.value, data->relative_axis[axis].max, 0);
val.normalised = (double) data->relative_axis[axis].current / (double) data->relative_axis[axis].max;
break;
}
}
if(axis == data->relative_axes){
val.normalised = 0.5 + ((event.value < 0) ? 0.5 : -0.5);
break;
}
break;
case EV_ABS:
range = libevdev_get_abs_maximum(data->input_ev, event.code) - libevdev_get_abs_minimum(data->input_ev, event.code);
val.normalised = clamp((event.value - libevdev_get_abs_minimum(data->input_ev, event.code)) / (double) range, 1.0, 0.0);
break;
case EV_KEY:
case EV_SW:
default:
val.normalised = clamp(1.0 * event.value, 1.0, 0.0);
break;
}
if(mm_channel_event(chan, val)){
fprintf(stderr, "Failed to push evdev channel event to core\n");
return 1;
}
}
if(evdev_config.detect){
fprintf(stderr, "Incoming evdev data for channel %s.%s.%s\n", inst->name, libevdev_event_type_get_name(event.type), libevdev_event_code_get_name(event.type, event.code));
}
return 0;
}
static int evdev_handle(size_t num, managed_fd* fds){
instance* inst = NULL;
evdev_instance_data* data = NULL;
size_t fd;
unsigned int read_flags = LIBEVDEV_READ_FLAG_NORMAL;
int read_status;
struct input_event ev;
if(!num){
return 0;
}
for(fd = 0; fd < num; fd++){
inst = (instance*) fds[fd].impl;
if(!inst){
fprintf(stderr, "evdev backend signaled for unknown fd\n");
continue;
}
data = (evdev_instance_data*) inst->impl;
for(read_status = libevdev_next_event(data->input_ev, read_flags, &ev); read_status >= 0; read_status = libevdev_next_event(data->input_ev, read_flags, &ev)){
read_flags = LIBEVDEV_READ_FLAG_NORMAL;
if(read_status == LIBEVDEV_READ_STATUS_SYNC){
read_flags = LIBEVDEV_READ_FLAG_SYNC;
}
//exclude synchronization events
if(ev.type == EV_SYN){
continue;
}
//handle event
if(evdev_push_event(inst, data, ev)){
return 1;
}
}
}
return 0;
}
static int evdev_start(size_t n, instance** inst){
size_t u, fds = 0;
evdev_instance_data* data = NULL;
for(u = 0; u < n; u++){
data = (evdev_instance_data*) inst[u]->impl;
#ifndef EVDEV_NO_UINPUT
if(data->output_enabled){
if(libevdev_uinput_create_from_device(data->output_proto, LIBEVDEV_UINPUT_OPEN_MANAGED, &data->output_ev)){
fprintf(stderr, "Failed to create evdev output device: %s\n", strerror(errno));
return 1;
}
fprintf(stderr, "Created device node %s for instance %s\n", libevdev_uinput_get_devnode(data->output_ev), inst[u]->name);
}
#endif
inst[u]->ident = data->input_fd;
if(data->input_fd >= 0){
if(mm_manage_fd(data->input_fd, BACKEND_NAME, 1, inst[u])){
fprintf(stderr, "Failed to register event input descriptor for instance %s\n", inst[u]->name);
return 1;
}
fds++;
}
if(data->input_fd <= 0 && !data->output_ev){
fprintf(stderr, "Instance %s has neither input nor output device set up\n", inst[u]->name);
}
}
fprintf(stderr, "evdev backend registered %zu descriptors to core\n", fds);
return 0;
}
static int evdev_set(instance* inst, size_t num, channel** c, channel_value* v) {
#ifndef EVDEV_NO_UINPUT
size_t evt = 0, axis = 0;
evdev_instance_data* data = (evdev_instance_data*) inst->impl;
evdev_channel_ident ident = {
.label = 0
};
int32_t value = 0;
uint64_t range = 0;
if(!num){
return 0;
}
if(!data->output_enabled){
fprintf(stderr, "Instance %s not enabled for output\n", inst->name);
return 0;
}
for(evt = 0; evt < num; evt++){
ident.label = c[evt]->ident;
switch(ident.fields.type){
case EV_REL:
for(axis = 0; axis < data->relative_axes; axis++){
if(data->relative_axis[axis].code == ident.fields.code){
value = (v[evt].normalised * data->relative_axis[axis].max) - data->relative_axis[axis].current;
data->relative_axis[axis].current = v[evt].normalised * data->relative_axis[axis].max;
if(data->relative_axis[axis].inverted){
value *= -1;
}
break;
}
}
if(axis == data->relative_axes){
value = (v[evt].normalised < 0.5) ? -1 : ((v[evt].normalised > 0.5) ? 1 : 0);
}
break;
case EV_ABS:
range = libevdev_get_abs_maximum(data->output_proto, ident.fields.code) - libevdev_get_abs_minimum(data->output_proto, ident.fields.code);
value = (range * v[evt].normalised) + libevdev_get_abs_minimum(data->output_proto, ident.fields.code);
break;
case EV_KEY:
case EV_SW:
default:
value = (v[evt].normalised > 0.9) ? 1 : 0;
break;
}
if(libevdev_uinput_write_event(data->output_ev, ident.fields.type, ident.fields.code, value)){
fprintf(stderr, "Failed to output event on instance %s\n", inst->name);
return 1;
}
}
//send syn event to publish all events
if(libevdev_uinput_write_event(data->output_ev, EV_SYN, SYN_REPORT, 0)){
fprintf(stderr, "Failed to output sync event on instance %s\n", inst->name);
return 1;
}
return 0;
#else
fprintf(stderr, "The evdev backend does not support output on this platform\n");
return 1;
#endif
}
static int evdev_shutdown(size_t n, instance** inst){
evdev_instance_data* data = NULL;
size_t u;
for(u = 0; u < n; u++){
data = (evdev_instance_data*) inst[u]->impl;
if(data->input_fd >= 0){
libevdev_free(data->input_ev);
close(data->input_fd);
}
#ifndef EVDEV_NO_UINPUT
if(data->output_enabled){
libevdev_uinput_destroy(data->output_ev);
}
libevdev_free(data->output_proto);
#endif
data->relative_axes = 0;
free(data->relative_axis);
free(inst[u]->impl);
}
fprintf(stderr, "evdev backend shut down\n");
return 0;
}
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