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/*
* Copyright (C) 2010 by Joachim Breitner <mail@joachim-breitner.de>
*
* Based on battstat-hal.c:
* Copyright (C) 2005 by Ryan Lortie <desrt@desrt.ca>
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
* $Id$
*/
#include <config.h>
#ifdef HAVE_UPOWER
#include <upower.h>
#include <math.h>
#include "battstat-upower.h"
static UpClient *upc;
static void (*status_updated_callback) (void);
/* status_updated_callback() can not be called directly because at the time of
* the device-remove signal, the device is not actually removed from the list
* of devices known to the up_client object (see libupower-glib/up-client.c in
* upower). Waiting for the next idle timer works around this issue and has has
* the additionaly benefit of possibly running status_updated_callback only
* once when several events happen very soon after each other.
*/
static gboolean status_update_scheduled;
static gboolean
update_status_idle (gpointer junk)
{
if (status_updated_callback)
status_updated_callback ();
return status_update_scheduled = FALSE;
}
static void
schedule_status_callback (void)
{
if (status_update_scheduled)
return;
status_update_scheduled = TRUE;
g_idle_add (update_status_idle, NULL);
}
static void
device_cb (UpClient *client, UpDevice *device, gpointer user_data) {
schedule_status_callback();
}
static void
device_removed_cb (UpClient *client, const gchar *object_path, gpointer user_data) {
schedule_status_callback();
}
/* ---- public functions ---- */
char *
battstat_upower_initialise (void (*callback) (void))
{
status_updated_callback = callback;
if( upc != NULL )
return g_strdup( "Already initialised!" );
if( (upc = up_client_new() ) == NULL )
goto error_out;
GPtrArray *devices;
devices = up_client_get_devices2 (upc);
if (!devices) {
goto error_shutdownclient;
}
g_ptr_array_unref(devices);
g_signal_connect_after( upc, "device-added", G_CALLBACK (device_cb), NULL );
g_signal_connect_after( upc, "device-removed", G_CALLBACK (device_removed_cb), NULL );
return NULL;
error_shutdownclient:
g_object_unref( upc );
upc = NULL;
error_out:
return g_strdup ("Can not initialize upower");
}
void
battstat_upower_cleanup( void )
{
if( upc == NULL )
return;
g_object_unref( upc );
upc = NULL;
}
#include "battstat.h"
/* This function currently exists to allow the multiple batteries supported
* by the upower backend to appear as a single composite battery device (since
* at the current time this is all that battstat supports).
*
* This entire function is filled with logic to make multiple batteries
* appear as one "composite" battery. Comments included as appropriate.
*
* For more information about some of the assumptions made in the following
* code please see the following mailing list post and the resulting thread:
*
* http://lists.freedesktop.org/archives/hal/2005-July/002841.html
*/
void
battstat_upower_get_battery_info( BatteryStatus *status )
{
GPtrArray *devices = up_client_get_devices2 (upc);
/* The calculation to get overall percentage power remaining is as follows:
*
* Sum( Current charges ) / Sum( Full Capacities )
*
* We can't just take an average of all of the percentages since this
* doesn't deal with the case that one battery might have a larger
* capacity than the other.
*
* In order to do this calculation, we need to keep a running total of
* current charge and full capacities.
*/
double current_charge_total = 0, full_capacity_total = 0;
/* Record the time remaining as reported by upower. This is used in the event
* that the system has exactly one battery (since, then, upower is capable
* of providing an accurate time remaining report and we should trust it.)
*/
gint64 remaining_time = 0;
/* The total (dis)charge rate of the system is the sum of the rates of
* the individual batteries.
*/
double rate_total = 0;
/* We need to know if we should report the composite battery as present
* at all. The logic is that if at least one actual battery is installed
* then the composite battery will be reported to exist.
*/
int present = 0;
/* We need to know if we are on AC power or not. Eventually, we can look
* at the AC adaptor upower devices to determine that. For now, we assume that
* if any battery is discharging then we must not be on AC power. Else, by
* default, we must be on AC.
*/
int on_ac_power = 1;
/* Finally, we consider the composite battery to be "charging" if at least
* one of the actual batteries in the system is charging.
*/
int charging = 0;
/* For each physical battery bay... */
int i;
for( i = 0; i < devices->len; i++ )
{
UpDevice *upd = g_ptr_array_index( devices, i );
int type, state;
double current_charge, full_capacity, rate;
gint64 time_to_full, time_to_empty;
g_object_get( upd,
"kind", &type,
"state", &state,
"energy", ¤t_charge,
"energy-full", &full_capacity,
"energy-rate", &rate,
"time-to-full", &time_to_full,
"time-to-empty", &time_to_empty,
NULL );
/* Only count batteries here */
if (type != UP_DEVICE_KIND_BATTERY)
continue;
/* At least one battery present -> composite battery is present. */
present++;
/* At least one battery charging -> composite battery is charging. */
if( state == UP_DEVICE_STATE_CHARGING )
charging = 1;
/* At least one battery is discharging -> we're not on AC. */
if( state == UP_DEVICE_STATE_DISCHARGING )
on_ac_power = 0;
/* Sum the totals for current charge, design capacity, (dis)charge rate. */
current_charge_total += current_charge;
full_capacity_total += full_capacity;
rate_total += rate;
/* Record remaining time too, incase this is the only battery. */
remaining_time = (state == UP_DEVICE_STATE_DISCHARGING ? time_to_empty : time_to_full);
}
if( !present || full_capacity_total <= 0 || (charging && !on_ac_power) )
{
/* Either no battery is present or something has gone horribly wrong.
* In either case we must return that the composite battery is not
* present.
*/
status->present = FALSE;
status->percent = 0;
status->minutes = -1;
status->on_ac_power = TRUE;
status->charging = FALSE;
g_ptr_array_unref( devices );
return;
}
/* Else, our composite battery is present. */
status->present = TRUE;
/* As per above, overall charge is:
*
* Sum( Current charges ) / Sum( Full Capacities )
*/
status->percent = ( current_charge_total / full_capacity_total ) * 100.0 + 0.5;
if( present == 1 )
{
/* In the case of exactly one battery, report the time remaining figure
* from upower directly since it might have come from an authorative source
* (ie: the PMU or APM subsystem).
*
* upower gives remaining time in seconds with a 0 to mean that the
* remaining time is unknown. Battstat uses minutes and -1 for
* unknown time remaining.
*/
if( remaining_time == 0 )
status->minutes = -1;
else
status->minutes = (remaining_time + 30) / 60;
}
/* Rest of cases to deal with multiple battery systems... */
else if( !on_ac_power && rate_total != 0 )
{
/* Then we're discharging. Calculate time remaining until at zero. */
double remaining;
remaining = current_charge_total;
remaining /= rate_total;
status->minutes = (int) floor( remaining * 60.0 + 0.5 );
}
else if( charging && rate_total != 0 )
{
/* Calculate time remaining until charged. For systems with more than
* one battery, this code is very approximate. The assumption is that if
* one battery reaches full charge before the other that the other will
* start charging faster due to the increase in available power (similar
* to how a laptop will charge faster if you're not using it).
*/
double remaining;
remaining = full_capacity_total - current_charge_total;
if( remaining < 0 )
remaining = 0;
remaining /= rate_total;
status->minutes = (int) floor( remaining * 60.0 + 0.5 );
}
else
{
/* On AC power and not charging -or- rate is unknown. */
status->minutes = -1;
}
/* These are simple and well-explained above. */
status->charging = charging;
status->on_ac_power = on_ac_power;
g_ptr_array_unref( devices );
}
void
error_dialog( const char *fmt , ...)
{
va_list ap;
va_start(ap, fmt);
char str[1000];
vsprintf(str, fmt, ap);
va_end(ap);
GtkWidget *dialog;
dialog = gtk_message_dialog_new( NULL, 0, GTK_MESSAGE_ERROR,
GTK_BUTTONS_OK, "%s", str);
g_signal_connect_swapped( G_OBJECT (dialog), "response",
G_CALLBACK (gtk_widget_destroy),
G_OBJECT (dialog) );
gtk_widget_show_all( dialog );
}
#endif /* HAVE_UPOWER */
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