blob: edf34f7842b76a953c84da4d2ab81d22dcc6bb07 [file] [log] [blame]
/*
* Copyright (C) 2011-2017 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include <dirent.h>
#include <errno.h>
#include <fcntl.h>
#include <inttypes.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/epoll.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <sys/un.h>
#include <time.h>
#include <unistd.h>
#include <functional>
#include <android-base/file.h>
#include <android-base/macros.h>
#include <linux/netlink.h>
#include <sys/socket.h>
#include <cutils/android_get_control_file.h>
#include <cutils/klog.h>
#include <cutils/misc.h>
#include <cutils/properties.h>
#include <cutils/uevent.h>
#include <sys/reboot.h>
#ifdef CHARGER_ENABLE_SUSPEND
#include <suspend/autosuspend.h>
#endif
#include "AnimationParser.h"
#include "healthd_draw.h"
#include <health2/Health.h>
#include <healthd/healthd.h>
using namespace android;
// main healthd loop
extern int healthd_main(void);
char* locale;
#ifndef max
#define max(a, b) ((a) > (b) ? (a) : (b))
#endif
#ifndef min
#define min(a, b) ((a) < (b) ? (a) : (b))
#endif
#define ARRAY_SIZE(x) (sizeof(x) / sizeof((x)[0]))
#define MSEC_PER_SEC (1000LL)
#define NSEC_PER_MSEC (1000000LL)
#define BATTERY_UNKNOWN_TIME (2 * MSEC_PER_SEC)
#define POWER_ON_KEY_TIME (2 * MSEC_PER_SEC)
#define UNPLUGGED_SHUTDOWN_TIME (10 * MSEC_PER_SEC)
#define UNPLUGGED_DISPLAY_TIME (3 * MSEC_PER_SEC)
#define MAX_BATT_LEVEL_WAIT_TIME (3 * MSEC_PER_SEC)
#define UNPLUGGED_SHUTDOWN_TIME_PROP "ro.product.charger.unplugged_shutdown_time"
#define LAST_KMSG_MAX_SZ (32 * 1024)
#define LOGE(x...) KLOG_ERROR("charger", x);
#define LOGW(x...) KLOG_WARNING("charger", x);
#define LOGV(x...) KLOG_DEBUG("charger", x);
// Resources in /product/etc/res overrides resources in /res.
// If the device is using the Generic System Image (GSI), resources may exist in
// both paths.
static constexpr const char* product_animation_desc_path =
"/product/etc/res/values/charger/animation.txt";
static constexpr const char* product_animation_root = "/product/etc/res/images/";
static constexpr const char* animation_desc_path = "/res/values/charger/animation.txt";
struct key_state {
bool pending;
bool down;
int64_t timestamp;
};
struct charger {
bool have_battery_state;
bool charger_connected;
bool screen_blanked;
int64_t next_screen_transition;
int64_t next_key_check;
int64_t next_pwr_check;
int64_t wait_batt_level_timestamp;
key_state keys[KEY_MAX + 1];
animation* batt_anim;
GRSurface* surf_unknown;
int boot_min_cap;
};
static const animation BASE_ANIMATION = {
.text_clock =
{
.pos_x = 0,
.pos_y = 0,
.color_r = 255,
.color_g = 255,
.color_b = 255,
.color_a = 255,
.font = nullptr,
},
.text_percent =
{
.pos_x = 0,
.pos_y = 0,
.color_r = 255,
.color_g = 255,
.color_b = 255,
.color_a = 255,
},
.run = false,
.frames = nullptr,
.cur_frame = 0,
.num_frames = 0,
.first_frame_repeats = 2,
.cur_cycle = 0,
.num_cycles = 3,
.cur_level = 0,
.cur_status = BATTERY_STATUS_UNKNOWN,
};
static animation::frame default_animation_frames[] = {
{
.disp_time = 750,
.min_level = 0,
.max_level = 19,
.surface = NULL,
},
{
.disp_time = 750,
.min_level = 0,
.max_level = 39,
.surface = NULL,
},
{
.disp_time = 750,
.min_level = 0,
.max_level = 59,
.surface = NULL,
},
{
.disp_time = 750,
.min_level = 0,
.max_level = 79,
.surface = NULL,
},
{
.disp_time = 750,
.min_level = 80,
.max_level = 95,
.surface = NULL,
},
{
.disp_time = 750,
.min_level = 0,
.max_level = 100,
.surface = NULL,
},
};
static animation battery_animation = BASE_ANIMATION;
static charger charger_state;
static healthd_config* healthd_config;
static android::BatteryProperties* batt_prop;
static std::unique_ptr<HealthdDraw> healthd_draw;
/* current time in milliseconds */
static int64_t curr_time_ms() {
timespec tm;
clock_gettime(CLOCK_MONOTONIC, &tm);
return tm.tv_sec * MSEC_PER_SEC + (tm.tv_nsec / NSEC_PER_MSEC);
}
#define MAX_KLOG_WRITE_BUF_SZ 256
static void dump_last_kmsg(void) {
std::string buf;
char* ptr;
size_t len;
LOGW("\n");
LOGW("*************** LAST KMSG ***************\n");
LOGW("\n");
const char* kmsg[] = {
// clang-format off
"/sys/fs/pstore/console-ramoops-0",
"/sys/fs/pstore/console-ramoops",
"/proc/last_kmsg",
// clang-format on
};
for (size_t i = 0; i < arraysize(kmsg) && buf.empty(); ++i) {
auto fd = android_get_control_file(kmsg[i]);
if (fd >= 0) {
android::base::ReadFdToString(fd, &buf);
} else {
android::base::ReadFileToString(kmsg[i], &buf);
}
}
if (buf.empty()) {
LOGW("last_kmsg not found. Cold reset?\n");
goto out;
}
len = min(buf.size(), LAST_KMSG_MAX_SZ);
ptr = &buf[buf.size() - len];
while (len > 0) {
size_t cnt = min(len, MAX_KLOG_WRITE_BUF_SZ);
char yoink;
char* nl;
nl = (char*)memrchr(ptr, '\n', cnt - 1);
if (nl) cnt = nl - ptr + 1;
yoink = ptr[cnt];
ptr[cnt] = '\0';
klog_write(6, "<4>%s", ptr);
ptr[cnt] = yoink;
len -= cnt;
ptr += cnt;
}
out:
LOGW("\n");
LOGW("************* END LAST KMSG *************\n");
LOGW("\n");
}
#ifdef CHARGER_ENABLE_SUSPEND
static int request_suspend(bool enable) {
if (enable)
return autosuspend_enable();
else
return autosuspend_disable();
}
#else
static int request_suspend(bool /*enable*/) {
return 0;
}
#endif
static void kick_animation(animation* anim) {
anim->run = true;
}
static void reset_animation(animation* anim) {
anim->cur_cycle = 0;
anim->cur_frame = 0;
anim->run = false;
}
static void update_screen_state(charger* charger, int64_t now) {
animation* batt_anim = charger->batt_anim;
int disp_time;
if (!batt_anim->run || now < charger->next_screen_transition) return;
// If battery level is not ready, keep checking in the defined time
if (batt_prop == nullptr ||
(batt_prop->batteryLevel == 0 && batt_prop->batteryStatus == BATTERY_STATUS_UNKNOWN)) {
if (charger->wait_batt_level_timestamp == 0) {
// Set max delay time and skip drawing screen
charger->wait_batt_level_timestamp = now + MAX_BATT_LEVEL_WAIT_TIME;
LOGV("[%" PRId64 "] wait for battery capacity ready\n", now);
return;
} else if (now <= charger->wait_batt_level_timestamp) {
// Do nothing, keep waiting
return;
}
// If timeout and battery level is still not ready, draw unknown battery
}
if (healthd_draw == nullptr) {
if (healthd_config && healthd_config->screen_on) {
if (!healthd_config->screen_on(batt_prop)) {
LOGV("[%" PRId64 "] leave screen off\n", now);
batt_anim->run = false;
charger->next_screen_transition = -1;
if (charger->charger_connected) request_suspend(true);
return;
}
}
healthd_draw.reset(new HealthdDraw(batt_anim));
#ifndef CHARGER_DISABLE_INIT_BLANK
healthd_draw->blank_screen(true);
charger->screen_blanked = true;
#endif
}
/* animation is over, blank screen and leave */
if (batt_anim->num_cycles > 0 && batt_anim->cur_cycle == batt_anim->num_cycles) {
reset_animation(batt_anim);
charger->next_screen_transition = -1;
healthd_draw->blank_screen(true);
charger->screen_blanked = true;
LOGV("[%" PRId64 "] animation done\n", now);
if (charger->charger_connected) request_suspend(true);
return;
}
disp_time = batt_anim->frames[batt_anim->cur_frame].disp_time;
if (charger->screen_blanked) {
healthd_draw->blank_screen(false);
charger->screen_blanked = false;
}
/* animation starting, set up the animation */
if (batt_anim->cur_frame == 0) {
LOGV("[%" PRId64 "] animation starting\n", now);
if (batt_prop) {
batt_anim->cur_level = batt_prop->batteryLevel;
batt_anim->cur_status = batt_prop->batteryStatus;
if (batt_prop->batteryLevel >= 0 && batt_anim->num_frames != 0) {
/* find first frame given current battery level */
for (int i = 0; i < batt_anim->num_frames; i++) {
if (batt_anim->cur_level >= batt_anim->frames[i].min_level &&
batt_anim->cur_level <= batt_anim->frames[i].max_level) {
batt_anim->cur_frame = i;
break;
}
}
if (charger->charger_connected) {
// repeat the first frame first_frame_repeats times
disp_time = batt_anim->frames[batt_anim->cur_frame].disp_time *
batt_anim->first_frame_repeats;
} else {
disp_time = UNPLUGGED_DISPLAY_TIME / batt_anim->num_cycles;
}
LOGV("cur_frame=%d disp_time=%d\n", batt_anim->cur_frame, disp_time);
}
}
}
/* draw the new frame (@ cur_frame) */
healthd_draw->redraw_screen(charger->batt_anim, charger->surf_unknown);
/* if we don't have anim frames, we only have one image, so just bump
* the cycle counter and exit
*/
if (batt_anim->num_frames == 0 || batt_anim->cur_level < 0) {
LOGW("[%" PRId64 "] animation missing or unknown battery status\n", now);
charger->next_screen_transition = now + BATTERY_UNKNOWN_TIME;
batt_anim->cur_cycle++;
return;
}
/* schedule next screen transition */
charger->next_screen_transition = curr_time_ms() + disp_time;
/* advance frame cntr to the next valid frame only if we are charging
* if necessary, advance cycle cntr, and reset frame cntr
*/
if (charger->charger_connected) {
batt_anim->cur_frame++;
while (batt_anim->cur_frame < batt_anim->num_frames &&
(batt_anim->cur_level < batt_anim->frames[batt_anim->cur_frame].min_level ||
batt_anim->cur_level > batt_anim->frames[batt_anim->cur_frame].max_level)) {
batt_anim->cur_frame++;
}
if (batt_anim->cur_frame >= batt_anim->num_frames) {
batt_anim->cur_cycle++;
batt_anim->cur_frame = 0;
/* don't reset the cycle counter, since we use that as a signal
* in a test above to check if animation is over
*/
}
} else {
/* Stop animating if we're not charging.
* If we stop it immediately instead of going through this loop, then
* the animation would stop somewhere in the middle.
*/
batt_anim->cur_frame = 0;
batt_anim->cur_cycle++;
}
}
static int set_key_callback(charger* charger, int code, int value) {
int64_t now = curr_time_ms();
int down = !!value;
if (code > KEY_MAX) return -1;
/* ignore events that don't modify our state */
if (charger->keys[code].down == down) return 0;
/* only record the down even timestamp, as the amount
* of time the key spent not being pressed is not useful */
if (down) charger->keys[code].timestamp = now;
charger->keys[code].down = down;
charger->keys[code].pending = true;
if (down) {
LOGV("[%" PRId64 "] key[%d] down\n", now, code);
} else {
int64_t duration = now - charger->keys[code].timestamp;
int64_t secs = duration / 1000;
int64_t msecs = duration - secs * 1000;
LOGV("[%" PRId64 "] key[%d] up (was down for %" PRId64 ".%" PRId64 "sec)\n", now, code,
secs, msecs);
}
return 0;
}
static void update_input_state(charger* charger, input_event* ev) {
if (ev->type != EV_KEY) return;
set_key_callback(charger, ev->code, ev->value);
}
static void set_next_key_check(charger* charger, key_state* key, int64_t timeout) {
int64_t then = key->timestamp + timeout;
if (charger->next_key_check == -1 || then < charger->next_key_check)
charger->next_key_check = then;
}
static void process_key(charger* charger, int code, int64_t now) {
key_state* key = &charger->keys[code];
if (code == KEY_POWER) {
if (key->down) {
int64_t reboot_timeout = key->timestamp + POWER_ON_KEY_TIME;
if (now >= reboot_timeout) {
/* We do not currently support booting from charger mode on
all devices. Check the property and continue booting or reboot
accordingly. */
if (property_get_bool("ro.enable_boot_charger_mode", false)) {
LOGW("[%" PRId64 "] booting from charger mode\n", now);
property_set("sys.boot_from_charger_mode", "1");
} else {
if (charger->batt_anim->cur_level >= charger->boot_min_cap) {
LOGW("[%" PRId64 "] rebooting\n", now);
reboot(RB_AUTOBOOT);
} else {
LOGV("[%" PRId64
"] ignore power-button press, battery level "
"less than minimum\n",
now);
}
}
} else {
/* if the key is pressed but timeout hasn't expired,
* make sure we wake up at the right-ish time to check
*/
set_next_key_check(charger, key, POWER_ON_KEY_TIME);
/* Turn on the display and kick animation on power-key press
* rather than on key release
*/
kick_animation(charger->batt_anim);
request_suspend(false);
}
} else {
/* if the power key got released, force screen state cycle */
if (key->pending) {
kick_animation(charger->batt_anim);
request_suspend(false);
}
}
}
key->pending = false;
}
static void handle_input_state(charger* charger, int64_t now) {
process_key(charger, KEY_POWER, now);
if (charger->next_key_check != -1 && now > charger->next_key_check)
charger->next_key_check = -1;
}
static void handle_power_supply_state(charger* charger, int64_t now) {
int timer_shutdown = UNPLUGGED_SHUTDOWN_TIME;
if (!charger->have_battery_state) return;
if (!charger->charger_connected) {
request_suspend(false);
if (charger->next_pwr_check == -1) {
/* Last cycle would have stopped at the extreme top of battery-icon
* Need to show the correct level corresponding to capacity.
*
* Reset next_screen_transition to update screen immediately.
* Reset & kick animation to show complete animation cycles
* when charger disconnected.
*/
timer_shutdown =
property_get_int32(UNPLUGGED_SHUTDOWN_TIME_PROP, UNPLUGGED_SHUTDOWN_TIME);
charger->next_screen_transition = now - 1;
reset_animation(charger->batt_anim);
kick_animation(charger->batt_anim);
charger->next_pwr_check = now + timer_shutdown;
LOGW("[%" PRId64 "] device unplugged: shutting down in %" PRId64 " (@ %" PRId64 ")\n",
now, (int64_t)timer_shutdown, charger->next_pwr_check);
} else if (now >= charger->next_pwr_check) {
LOGW("[%" PRId64 "] shutting down\n", now);
reboot(RB_POWER_OFF);
} else {
/* otherwise we already have a shutdown timer scheduled */
}
} else {
/* online supply present, reset shutdown timer if set */
if (charger->next_pwr_check != -1) {
/* Reset next_screen_transition to update screen immediately.
* Reset & kick animation to show complete animation cycles
* when charger connected again.
*/
request_suspend(false);
charger->next_screen_transition = now - 1;
reset_animation(charger->batt_anim);
kick_animation(charger->batt_anim);
LOGW("[%" PRId64 "] device plugged in: shutdown cancelled\n", now);
}
charger->next_pwr_check = -1;
}
}
void healthd_mode_charger_heartbeat() {
charger* charger = &charger_state;
int64_t now = curr_time_ms();
handle_input_state(charger, now);
handle_power_supply_state(charger, now);
/* do screen update last in case any of the above want to start
* screen transitions (animations, etc)
*/
update_screen_state(charger, now);
}
void healthd_mode_charger_battery_update(android::BatteryProperties* props) {
charger* charger = &charger_state;
charger->charger_connected =
props->chargerAcOnline || props->chargerUsbOnline || props->chargerWirelessOnline;
if (!charger->have_battery_state) {
charger->have_battery_state = true;
charger->next_screen_transition = curr_time_ms() - 1;
request_suspend(false);
reset_animation(charger->batt_anim);
kick_animation(charger->batt_anim);
}
batt_prop = props;
}
int healthd_mode_charger_preparetowait(void) {
charger* charger = &charger_state;
int64_t now = curr_time_ms();
int64_t next_event = INT64_MAX;
int64_t timeout;
LOGV("[%" PRId64 "] next screen: %" PRId64 " next key: %" PRId64 " next pwr: %" PRId64 "\n",
now, charger->next_screen_transition, charger->next_key_check, charger->next_pwr_check);
if (charger->next_screen_transition != -1) next_event = charger->next_screen_transition;
if (charger->next_key_check != -1 && charger->next_key_check < next_event)
next_event = charger->next_key_check;
if (charger->next_pwr_check != -1 && charger->next_pwr_check < next_event)
next_event = charger->next_pwr_check;
if (next_event != -1 && next_event != INT64_MAX)
timeout = max(0, next_event - now);
else
timeout = -1;
return (int)timeout;
}
static int input_callback(charger* charger, int fd, unsigned int epevents) {
input_event ev;
int ret;
ret = ev_get_input(fd, epevents, &ev);
if (ret) return -1;
update_input_state(charger, &ev);
return 0;
}
static void charger_event_handler(uint32_t /*epevents*/) {
int ret;
ret = ev_wait(-1);
if (!ret) ev_dispatch();
}
animation* init_animation() {
bool parse_success;
std::string content;
if (base::ReadFileToString(product_animation_desc_path, &content)) {
parse_success = parse_animation_desc(content, &battery_animation);
battery_animation.set_resource_root(product_animation_root);
} else if (base::ReadFileToString(animation_desc_path, &content)) {
parse_success = parse_animation_desc(content, &battery_animation);
} else {
LOGW("Could not open animation description at %s\n", animation_desc_path);
parse_success = false;
}
if (!parse_success) {
LOGW("Could not parse animation description. Using default animation.\n");
battery_animation = BASE_ANIMATION;
battery_animation.animation_file.assign("charger/battery_scale");
battery_animation.frames = default_animation_frames;
battery_animation.num_frames = ARRAY_SIZE(default_animation_frames);
}
if (battery_animation.fail_file.empty()) {
battery_animation.fail_file.assign("charger/battery_fail");
}
LOGV("Animation Description:\n");
LOGV(" animation: %d %d '%s' (%d)\n", battery_animation.num_cycles,
battery_animation.first_frame_repeats, battery_animation.animation_file.c_str(),
battery_animation.num_frames);
LOGV(" fail_file: '%s'\n", battery_animation.fail_file.c_str());
LOGV(" clock: %d %d %d %d %d %d '%s'\n", battery_animation.text_clock.pos_x,
battery_animation.text_clock.pos_y, battery_animation.text_clock.color_r,
battery_animation.text_clock.color_g, battery_animation.text_clock.color_b,
battery_animation.text_clock.color_a, battery_animation.text_clock.font_file.c_str());
LOGV(" percent: %d %d %d %d %d %d '%s'\n", battery_animation.text_percent.pos_x,
battery_animation.text_percent.pos_y, battery_animation.text_percent.color_r,
battery_animation.text_percent.color_g, battery_animation.text_percent.color_b,
battery_animation.text_percent.color_a, battery_animation.text_percent.font_file.c_str());
for (int i = 0; i < battery_animation.num_frames; i++) {
LOGV(" frame %.2d: %d %d %d\n", i, battery_animation.frames[i].disp_time,
battery_animation.frames[i].min_level, battery_animation.frames[i].max_level);
}
return &battery_animation;
}
void healthd_mode_charger_init(struct healthd_config* config) {
using android::hardware::health::V2_0::implementation::Health;
int ret;
charger* charger = &charger_state;
int i;
int epollfd;
dump_last_kmsg();
LOGW("--------------- STARTING CHARGER MODE ---------------\n");
ret = ev_init(std::bind(&input_callback, charger, std::placeholders::_1, std::placeholders::_2));
if (!ret) {
epollfd = ev_get_epollfd();
healthd_register_event(epollfd, charger_event_handler, EVENT_WAKEUP_FD);
}
animation* anim = init_animation();
charger->batt_anim = anim;
ret = res_create_display_surface(anim->fail_file.c_str(), &charger->surf_unknown);
if (ret < 0) {
LOGE("Cannot load custom battery_fail image. Reverting to built in: %d\n", ret);
ret = res_create_display_surface("charger/battery_fail", &charger->surf_unknown);
if (ret < 0) {
LOGE("Cannot load built in battery_fail image\n");
charger->surf_unknown = NULL;
}
}
GRSurface** scale_frames;
int scale_count;
int scale_fps; // Not in use (charger/battery_scale doesn't have FPS text
// chunk). We are using hard-coded frame.disp_time instead.
ret = res_create_multi_display_surface(anim->animation_file.c_str(), &scale_count, &scale_fps,
&scale_frames);
if (ret < 0) {
LOGE("Cannot load battery_scale image\n");
anim->num_frames = 0;
anim->num_cycles = 1;
} else if (scale_count != anim->num_frames) {
LOGE("battery_scale image has unexpected frame count (%d, expected %d)\n", scale_count,
anim->num_frames);
anim->num_frames = 0;
anim->num_cycles = 1;
} else {
for (i = 0; i < anim->num_frames; i++) {
anim->frames[i].surface = scale_frames[i];
}
}
ev_sync_key_state(
std::bind(&set_key_callback, charger, std::placeholders::_1, std::placeholders::_2));
charger->next_screen_transition = -1;
charger->next_key_check = -1;
charger->next_pwr_check = -1;
charger->wait_batt_level_timestamp = 0;
// Initialize Health implementation (which initializes the internal BatteryMonitor).
Health::initInstance(config);
healthd_config = config;
charger->boot_min_cap = config->boot_min_cap;
}
static struct healthd_mode_ops charger_ops = {
.init = healthd_mode_charger_init,
.preparetowait = healthd_mode_charger_preparetowait,
.heartbeat = healthd_mode_charger_heartbeat,
.battery_update = healthd_mode_charger_battery_update,
};
int healthd_charger_main(int argc, char** argv) {
int ch;
healthd_mode_ops = &charger_ops;
while ((ch = getopt(argc, argv, "cr")) != -1) {
switch (ch) {
case 'c':
// -c is now a noop
break;
case 'r':
// -r is now a noop
break;
case '?':
default:
LOGE("Unrecognized charger option: %c\n", optopt);
exit(1);
}
}
return healthd_main();
}