// This Source Code Form is subject to the terms of the Mozilla Public // License, v. 2.0. If a copy of the MPL was not distributed with this // file, You can obtain one at https://mozilla.org/MPL/2.0/.
use std::cmp::Ordering; use std::collections::HashMap; use std::fs; use std::fs::{create_dir_all, File, OpenOptions}; use std::io::BufRead; use std::io::BufReader; use std::io::Write; use std::path::{Path, PathBuf}; use std::sync::{Mutex, RwLock};
use chrono::{DateTime, FixedOffset, Utc};
use serde::{Deserialize, Serialize}; use serde_json::{json, Value as JsonValue};
/// Represents the recorded data for a single event. #[derive(Debug, Clone, Deserialize, Serialize, PartialEq, Eq)] #[cfg_attr(test, derive(Default))] pubstruct RecordedEvent { /// The timestamp of when the event was recorded. /// /// This allows to order events from a single process run. pub timestamp: u64,
/// The event's category. /// /// This is defined by users in the metrics file. pub category: String,
/// The event's name. /// /// This is defined by users in the metrics file. pub name: String,
/// A map of all extra data values. /// /// The set of allowed extra keys is defined by users in the metrics file. #[serde(skip_serializing_if = "Option::is_none")] pub extra: Option<HashMap<String, String>>,
}
/// Represents the stored data for a single event. #[derive(Debug, Clone, Deserialize, Serialize, PartialEq, Eq)] struct StoredEvent { #[serde(flatten)]
event: RecordedEvent,
/// The monotonically-increasing execution counter. /// /// Included to allow sending of events across Glean restarts (bug 1716725). /// Is i32 because it is stored in a CounterMetric. #[serde(default)] #[serde(skip_serializing_if = "Option::is_none")] pub execution_counter: Option<i32>,
}
/// This struct handles the in-memory and on-disk storage logic for events. /// /// So that the data survives shutting down of the application, events are stored /// in an append-only file on disk, in addition to the store in memory. Each line /// of this file records a single event in JSON, exactly as it will be sent in the /// ping. There is one file per store. /// /// When restarting the application, these on-disk files are checked, and if any are /// found, they are loaded, and a `glean.restarted` event is added before any /// further events are collected. This is because the timestamps for these events /// may have come from a previous boot of the device, and therefore will not be /// compatible with any newly-collected events. /// /// Normalizing all these timestamps happens on serialization for submission (see /// `serialize_as_json`) where the client time between restarts is calculated using /// data stored in the `glean.startup.date` extra of the `glean.restarted` event, plus /// the `execution_counter` stored in events on disk. /// /// Neither `execution_counter` nor `glean.startup.date` is submitted in pings. /// The `glean.restarted` event is, though. /// (See [bug 1716725](https://bugzilla.mozilla.org/show_bug.cgi?id=1716725).) #[derive(Debug)] pubstruct EventDatabase { /// Path to directory of on-disk event files pub path: PathBuf, /// The in-memory list of events
event_stores: RwLock<HashMap<String, Vec<StoredEvent>>>, /// A lock to be held when doing operations on the filesystem
file_lock: Mutex<()>,
}
impl EventDatabase { /// Creates a new event database. /// /// # Arguments /// /// * `data_path` - The directory to store events in. A new directory /// * `events` - will be created inside of this directory. pubfn new(data_path: &Path) -> Result<Self> { let path = data_path.join("events");
create_dir_all(&path)?;
/// Initializes events storage after Glean is fully initialized and ready to send pings. /// /// This must be called once on application startup, e.g. from /// [Glean.initialize], but after we are ready to send pings, since this /// could potentially collect and send the "events" ping. /// /// If there are any events queued on disk, it loads them into memory so /// that the memory and disk representations are in sync. /// /// If event records for the "events" ping are present, they are assembled into /// an "events" ping which is submitted immediately with reason "startup". /// /// If event records for custom pings are present, we increment the custom pings' /// stores' `execution_counter` and record a `glean.restarted` /// event with the current client clock in its `glean.startup.date` extra. /// /// # Arguments /// /// * `glean` - The Glean instance. /// * `trim_data_to_registered_pings` - Whether we should trim the event storage of /// any events not belonging to pings previously registered via `register_ping_type`. /// /// # Returns /// /// Whether the "events" ping was submitted. pubfn flush_pending_events_on_startup(
&self,
glean: &Glean,
trim_data_to_registered_pings: bool,
) -> bool { matchself.load_events_from_disk(glean, trim_data_to_registered_pings) {
Ok(_) => { let stores_with_events: Vec<String> = { self.event_stores
.read()
.unwrap()
.keys()
.map(|x| x.to_owned())
.collect() // safe unwrap, only error case is poisoning
}; // We do not want to be holding the event stores lock when // submitting a ping or recording new events. let has_events_events = stores_with_events.contains(&"events".to_owned()); let glean_restarted_stores = if has_events_events {
stores_with_events
.into_iter()
.filter(|store| store != "events")
.collect()
} else {
stores_with_events
}; if !glean_restarted_stores.is_empty() { for store_name in glean_restarted_stores.iter() {
CounterMetric::new(CommonMetricData {
name: "execution_counter".into(),
category: store_name.into(),
send_in_pings: vec![INTERNAL_STORAGE.into()],
lifetime: Lifetime::Ping,
..Default::default()
})
.add_sync(glean, 1);
} let glean_restarted = CommonMetricData {
name: "restarted".into(),
category: "glean".into(),
send_in_pings: glean_restarted_stores,
lifetime: Lifetime::Ping,
..Default::default()
}; let startup = get_iso_time_string(glean.start_time(), TimeUnit::Minute); letmut extra: HashMap<String, String> =
[("glean.startup.date".into(), startup)].into(); if glean.with_timestamps() { let now = Utc::now(); let precise_timestamp = now.timestamp_millis() as u64;
extra.insert("glean_timestamp".to_string(), precise_timestamp.to_string());
} self.record(
glean,
&glean_restarted.into(), crate::get_timestamp_ms(),
Some(extra),
);
}
has_events_events && glean.submit_ping_by_name("events", Some("startup"))
}
Err(err) => {
log::warn!("Error loading events from disk: {}", err); false
}
}
}
fn load_events_from_disk(
&self,
glean: &Glean,
trim_data_to_registered_pings: bool,
) -> Result<()> { // NOTE: The order of locks here is important. // In other code parts we might acquire the `file_lock` when we already have acquired // a lock on `event_stores`. // This is a potential lock-order-inversion. letmut db = self.event_stores.write().unwrap(); // safe unwrap, only error case is poisoning let _lock = self.file_lock.lock().unwrap(); // safe unwrap, only error case is poisoning
for entry in fs::read_dir(&self.path)? { let entry = entry?; if entry.file_type()?.is_file() { let store_name = entry.file_name().into_string()?;
log::info!("Loading events for {}", store_name); if trim_data_to_registered_pings && glean.get_ping_by_name(&store_name).is_none() {
log::warn!("Trimming {}'s events", store_name); iflet Err(err) = fs::remove_file(entry.path()) { match err.kind() {
std::io::ErrorKind::NotFound => { // silently drop this error, the file was already non-existing
}
_ => log::warn!("Error trimming events file '{}': {}", store_name, err),
}
} continue;
} let file = BufReader::new(File::open(entry.path())?);
db.insert(
store_name,
file.lines()
.map_while(Result::ok)
.filter_map(|line| serde_json::from_str::<StoredEvent>(&line).ok())
.collect(),
);
}
}
Ok(())
}
/// Records an event in the desired stores. /// /// # Arguments /// /// * `glean` - The Glean instance. /// * `meta` - The metadata about the event metric. Used to get the category, /// name and stores for the metric. /// * `timestamp` - The timestamp of the event, in milliseconds. Must use a /// monotonically increasing timer (this value is obtained on the /// platform-specific side). /// * `extra` - Extra data values, mapping strings to strings. /// /// ## Returns /// /// `true` if a ping was submitted and should be uploaded. /// `false` otherwise. pubfn record(
&self,
glean: &Glean,
meta: &CommonMetricDataInternal,
timestamp: u64,
extra: Option<HashMap<String, String>>,
) -> bool { // If upload is disabled we don't want to record. if !glean.is_upload_enabled() { returnfalse;
}
letmut submit_max_capacity_event_ping = false;
{ letmut db = self.event_stores.write().unwrap(); // safe unwrap, only error case is poisoning for store_name in meta.inner.send_in_pings.iter() { if !glean.is_ping_enabled(store_name) { continue;
}
let store = db.entry(store_name.to_string()).or_default(); let execution_counter = CounterMetric::new(CommonMetricData {
name: "execution_counter".into(),
category: store_name.into(),
send_in_pings: vec![INTERNAL_STORAGE.into()],
lifetime: Lifetime::Ping,
..Default::default()
})
.get_value(glean, INTERNAL_STORAGE); // Create StoredEvent object, and its JSON form for serialization on disk. let event = StoredEvent {
event: RecordedEvent {
timestamp,
category: meta.inner.category.to_string(),
name: meta.inner.name.to_string(),
extra: extra.clone(),
},
execution_counter,
}; let event_json = serde_json::to_string(&event).unwrap(); // safe unwrap, event can always be serialized
store.push(event); self.write_event_to_disk(store_name, &event_json); if store_name == "events" && store.len() == glean.get_max_events() {
submit_max_capacity_event_ping = true;
}
}
} if submit_max_capacity_event_ping {
glean.submit_ping_by_name("events", Some("max_capacity")); true
} else { false
}
}
/// Writes an event to a single store on disk. /// /// # Arguments /// /// * `store_name` - The name of the store. /// * `event_json` - The event content, as a single-line JSON-encoded string. fn write_event_to_disk(&self, store_name: &str, event_json: &str) { let _lock = self.file_lock.lock().unwrap(); // safe unwrap, only error case is poisoning iflet Err(err) = OpenOptions::new()
.create(true)
.append(true)
.open(self.path.join(store_name))
.and_then(|mut file| writeln!(file, "{}", event_json))
{
log::warn!("IO error writing event to store '{}': {}", store_name, err);
}
}
/// Normalizes the store in-place. /// /// A store may be in any order and contain any number of `glean.restarted` events, /// whose values must be taken into account, along with `execution_counter` values, /// to come up with the correct events with correct `timestamp` values, /// on which we then sort. /// /// 1. Sort by `execution_counter` and `timestamp`, /// breaking ties so that `glean.restarted` comes first. /// 2. Remove all initial and final `glean.restarted` events /// 3. For each group of events that share a `execution_counter`, /// i. calculate the initial `glean.restarted` event's `timestamp`s to be /// clamp(glean.startup.date - ping_info.start_time, biggest_timestamp_of_previous_group + 1) /// ii. normalize each non-`glean-restarted` event's `timestamp` /// relative to the `glean.restarted` event's uncalculated `timestamp` /// 4. Remove `execution_counter` and `glean.startup.date` extra keys /// 5. Sort by `timestamp` /// /// In the event that something goes awry, this will record an invalid_state on /// glean.restarted if it is due to internal inconsistencies, or invalid_value /// on client clock weirdness. /// /// # Arguments /// /// * `glean` - Used to report errors /// * `store_name` - The name of the store we're normalizing. /// * `store` - The store we're to normalize. /// * `glean_start_time` - Used if the glean.startup.date or ping_info.start_time aren't available. Passed as a parameter to ease unit-testing. fn normalize_store(
&self,
glean: &Glean,
store_name: &str,
store: &mut Vec<StoredEvent>,
glean_start_time: DateTime<FixedOffset>,
) { let is_glean_restarted =
|event: &RecordedEvent| event.category == "glean" && event.name == "restarted"; let glean_restarted_meta = |store_name: &str| CommonMetricData {
name: "restarted".into(),
category: "glean".into(),
send_in_pings: vec![store_name.into()],
lifetime: Lifetime::Ping,
..Default::default()
}; // Step 1
store.sort_by(|a, b| {
a.execution_counter
.cmp(&b.execution_counter)
.then_with(|| a.event.timestamp.cmp(&b.event.timestamp))
.then_with(|| { if is_glean_restarted(&a.event) {
Ordering::Less
} else {
Ordering::Greater
}
})
}); // Step 2 // Find the index of the first and final non-`glean.restarted` events. // Remove events before the first and after the final. let final_event = match store
.iter()
.rposition(|event| !is_glean_restarted(&event.event))
{
Some(idx) => idx + 1,
_ => 0,
};
store.drain(final_event..); let first_event = store
.iter()
.position(|event| !is_glean_restarted(&event.event))
.unwrap_or(store.len());
store.drain(..first_event); if store.is_empty() { // There was nothing but `glean.restarted` events. Job's done! return;
} // Step 3 // It is allowed that there might not be any `glean.restarted` event, nor // `execution_counter` extra values. (This should always be the case for the // "events" ping, for instance). // Other inconsistencies are evidence of errors, and so are logged. letmut cur_ec = 0; // The offset within a group of events with the same `execution_counter`. letmut intra_group_offset = store[0].event.timestamp; // The offset between this group and ping_info.start_date. letmut inter_group_offset = 0; letmut highest_ts = 0; for event in store.iter_mut() { let execution_counter = event.execution_counter.take().unwrap_or(0); if is_glean_restarted(&event.event) { // We've entered the next "event group". // We need a new epoch based on glean.startup.date - ping_info.start_date
cur_ec = execution_counter; let glean_startup_date = event
.event
.extra
.as_mut()
.and_then(|extra| {
extra.remove("glean.startup.date").and_then(|date_str| {
DateTime::parse_from_str(&date_str, TimeUnit::Minute.format_pattern())
.map_err(|_| {
record_error(
glean,
&glean_restarted_meta(store_name).into(),
ErrorType::InvalidState,
format!("Unparseable glean.startup.date '{}'", date_str),
None,
);
})
.ok()
})
})
.unwrap_or(glean_start_time); if event
.event
.extra
.as_ref()
.is_some_and(|extra| extra.is_empty())
{ // Small optimization to save us sending empty dicts.
event.event.extra = None;
} let ping_start = DatetimeMetric::new(
CommonMetricData {
name: format!("{}#start", store_name),
category: "".into(),
send_in_pings: vec![INTERNAL_STORAGE.into()],
lifetime: Lifetime::User,
..Default::default()
},
TimeUnit::Minute,
); let ping_start = ping_start
.get_value(glean, INTERNAL_STORAGE)
.unwrap_or(glean_start_time); let time_from_ping_start_to_glean_restarted =
(glean_startup_date - ping_start).num_milliseconds();
intra_group_offset = event.event.timestamp;
inter_group_offset =
u64::try_from(time_from_ping_start_to_glean_restarted).unwrap_or(0); if inter_group_offset < highest_ts {
record_error(
glean,
&glean_restarted_meta(store_name).into(),
ErrorType::InvalidValue,
format!("Time between restart and ping start {} indicates client clock weirdness.", time_from_ping_start_to_glean_restarted),
None,
); // The client's clock went backwards enough that this event group's // glean.restarted looks like it happened _before_ the final event of the previous group. // Or, it went ahead enough to overflow u64. // Adjust things so this group starts 1ms after the previous one.
inter_group_offset = highest_ts + 1;
}
} elseif cur_ec == 0 { // bug 1811872 - cur_ec might need initialization.
cur_ec = execution_counter;
}
event.event.timestamp = event.event.timestamp - intra_group_offset + inter_group_offset; if execution_counter != cur_ec {
record_error(
glean,
&glean_restarted_meta(store_name).into(),
ErrorType::InvalidState,
format!( "Inconsistent execution counter {} (expected {})",
execution_counter, cur_ec
),
None,
); // Let's fix cur_ec up and hope this isn't a sign something big is broken.
cur_ec = execution_counter;
} if highest_ts > event.event.timestamp { // Even though we sorted everything, something in the // execution_counter or glean.startup.date math went awry.
record_error(
glean,
&glean_restarted_meta(store_name).into(),
ErrorType::InvalidState,
format!( "Inconsistent previous highest timestamp {} (expected <= {})",
highest_ts, event.event.timestamp
),
None,
); // Let the highest_ts regress to event.timestamp to hope this minimizes weirdness.
}
highest_ts = event.event.timestamp
}
}
/// Gets a snapshot of the stored event data as a JsonValue. /// /// # Arguments /// /// * `glean` - the Glean instance. /// * `store_name` - The name of the desired store. /// * `clear_store` - Whether to clear the store after snapshotting. /// /// # Returns /// /// A array of events, JSON encoded, if any. Otherwise `None`. pubfn snapshot_as_json(
&self,
glean: &Glean,
store_name: &str,
clear_store: bool,
) -> Option<JsonValue> { let result = { letmut db = self.event_stores.write().unwrap(); // safe unwrap, only error case is poisoning
db.get_mut(&store_name.to_string()).and_then(|store| { if !store.is_empty() { // Normalization happens in-place, so if we're not clearing, // operate on a clone. letmut clone; let store = if clear_store {
store
} else {
clone = store.clone();
&mut clone
}; // We may need to normalize event timestamps across multiple restarts. self.normalize_store(glean, store_name, store, glean.start_time());
Some(json!(store))
} else {
log::warn!("Unexpectly got empty event store for '{}'", store_name);
None
}
})
};
if clear_store { self.event_stores
.write()
.unwrap() // safe unwrap, only error case is poisoning
.remove(&store_name.to_string());
let _lock = self.file_lock.lock().unwrap(); // safe unwrap, only error case is poisoning iflet Err(err) = fs::remove_file(self.path.join(store_name)) { match err.kind() {
std::io::ErrorKind::NotFound => { // silently drop this error, the file was already non-existing
}
_ => log::warn!("Error removing events queue file '{}': {}", store_name, err),
}
}
}
result
}
/// Clears all stored events, both in memory and on-disk. pubfn clear_all(&self) -> Result<()> { // safe unwrap, only error case is poisoning self.event_stores.write().unwrap().clear();
// safe unwrap, only error case is poisoning let _lock = self.file_lock.lock().unwrap();
std::fs::remove_dir_all(&self.path)?;
create_dir_all(&self.path)?;
Ok(())
}
/// **Test-only API (exported for FFI purposes).** /// /// Gets the vector of currently stored events for the given event metric in /// the given store. /// /// This doesn't clear the stored value. pubfn test_get_value<'a>(
&'a self,
meta: &'a CommonMetricDataInternal,
store_name: &str,
) -> Option<Vec<RecordedEvent>> {
record_coverage(&meta.base_identifier());
let value: Vec<RecordedEvent> = self
.event_stores
.read()
.unwrap() // safe unwrap, only error case is poisoning
.get(&store_name.to_string())
.into_iter()
.flatten()
.map(|stored_event| stored_event.event.clone())
.filter(|event| event.name == meta.inner.name && event.category == meta.inner.category)
.collect(); if !value.is_empty() {
Some(value)
} else {
None
}
}
}
#[cfg(test)] mod test { usesuper::*; usecrate::test_get_num_recorded_errors; usecrate::tests::new_glean; use chrono::{TimeZone, Timelike};
#[test] fn handle_truncated_events_on_disk() { let (glean, t) = new_glean(None);
{ let db = EventDatabase::new(t.path()).unwrap();
db.write_event_to_disk("events", "{\"timestamp\": 500");
db.write_event_to_disk("events", "{\"timestamp\"");
db.write_event_to_disk( "events", "{\"timestamp\": 501, \"category\": \"ui\", \"name\": \"click\"}",
);
}
{ let db = EventDatabase::new(t.path()).unwrap();
db.load_events_from_disk(&glean, false).unwrap(); let events = &db.event_stores.read().unwrap()["events"];
assert_eq!(1, events.len());
}
}
letmut data = HashMap::new();
data.insert("a key".to_string(), "a value".to_string()); let event_data = RecordedEvent {
timestamp: 2,
category: "cat".to_string(),
name: "name".to_string(),
extra: Some(data),
};
let event_empty_json = ::serde_json::to_string_pretty(&event_empty).unwrap(); let event_data_json = ::serde_json::to_string_pretty(&event_data).unwrap();
#[test] fn doesnt_record_when_upload_is_disabled() { let (mut glean, dir) = new_glean(None); let db = EventDatabase::new(dir.path()).unwrap();
let test_storage = "store1"; let test_category = "category"; let test_name = "name"; let test_timestamp = 2; let test_meta = CommonMetricDataInternal::new(test_category, test_name, test_storage); let event_data = RecordedEvent {
timestamp: test_timestamp,
category: test_category.to_string(),
name: test_name.to_string(),
extra: None,
};
// Upload is not yet disabled, // so let's check that everything is getting recorded as expected.
db.record(&glean, &test_meta, 2, None);
{ let event_stores = db.event_stores.read().unwrap();
assert_eq!(
&StoredEvent {
event: event_data,
execution_counter: None
},
&event_stores.get(test_storage).unwrap()[0]
);
assert_eq!(event_stores.get(test_storage).unwrap().len(), 1);
}
glean.set_upload_enabled(false);
// Now that upload is disabled, let's check nothing is recorded.
db.record(&glean, &test_meta, 2, None);
{ let event_stores = db.event_stores.read().unwrap();
assert_eq!(event_stores.get(test_storage).unwrap().len(), 1);
}
}
#[test] fn normalize_store_of_glean_restarted() { // Make sure stores empty of anything but glean.restarted events normalize without issue. let (glean, _dir) = new_glean(None);
let store_name = "store-name"; let glean_restarted = StoredEvent {
event: RecordedEvent {
timestamp: 2,
category: "glean".into(),
name: "restarted".into(),
extra: None,
},
execution_counter: None,
}; letmut store = vec![glean_restarted.clone()]; let glean_start_time = glean.start_time();
#[test] fn normalize_store_of_glean_restarted_on_both_ends() { // Make sure stores with non-glean.restarted events don't get drained too far. let (glean, _dir) = new_glean(None);
#[test] fn normalize_store_single_run_timestamp_math() { // With a single run of events (no non-initial or non-terminal `glean.restarted`), // ensure the timestamp math works. // (( works = Initial event gets to be 0, subsequent events get normalized to that 0 )) let (glean, _dir) = new_glean(None);
#[test] fn normalize_store_multi_run_timestamp_math() { // With multiple runs of events (separated by `glean.restarted`), // ensure the timestamp math works. // (( works = Initial event gets to be 0, subsequent events get normalized to that 0. // Subsequent runs figure it out via glean.restarted.date and ping_info.start_time )) let (glean, _dir) = new_glean(None);
// Let's check the first three. for (timestamp, event) in timestamps[..timestamps.len() - 1].iter().zip(store.clone()) {
assert_eq!(
StoredEvent {
event: RecordedEvent {
timestamp: timestamp - timestamps[0],
..not_glean_restarted.event.clone()
},
execution_counter: None,
},
event
);
} // The fourth should be a glean.restarted and have a realtime-based timestamp. let hour_in_millis = 3600000;
assert_eq!(
store[3],
StoredEvent {
event: RecordedEvent {
timestamp: hour_in_millis,
..glean_restarted.event
},
execution_counter: None,
}
); // The fifth should have a timestamp based on the new origin.
assert_eq!(
store[4],
StoredEvent {
event: RecordedEvent {
timestamp: hour_in_millis + timestamps[3] - restarted_ts,
..not_glean_restarted.event
},
execution_counter: None,
}
);
}
#[test] fn normalize_store_multi_run_client_clocks() { // With multiple runs of events (separated by `glean.restarted`), // ensure the timestamp math works. Even when the client clock goes backwards. let (glean, _dir) = new_glean(None);
// Let's check the first two. for (timestamp, event) in timestamps[..timestamps.len() - 2].iter().zip(store.clone()) {
assert_eq!(
StoredEvent {
event: RecordedEvent {
timestamp: timestamp - timestamps[0],
..not_glean_restarted.event.clone()
},
execution_counter: None,
},
event
);
} // The third should be a glean.restarted. Its timestamp should be // one larger than the largest timestamp seen so far (because that's // how we ensure monotonic timestamps when client clocks go backwards).
assert_eq!(
store[2],
StoredEvent {
event: RecordedEvent {
timestamp: store[1].event.timestamp + 1,
..glean_restarted.event
},
execution_counter: None,
}
); // The fifth should have a timestamp based on the new origin.
assert_eq!(
store[3],
StoredEvent {
event: RecordedEvent {
timestamp: timestamps[2] - restarted_ts + store[2].event.timestamp,
..not_glean_restarted.event
},
execution_counter: None,
}
); // And we should have an InvalidValue on glean.restarted to show for it.
assert_eq!(
Ok(1),
test_get_num_recorded_errors(
&glean,
&CommonMetricData {
name: "restarted".into(),
category: "glean".into(),
send_in_pings: vec![store_name.into()],
lifetime: Lifetime::Ping,
..Default::default()
}
.into(),
ErrorType::InvalidValue
)
);
}
#[test] fn normalize_store_non_zero_ec() { // After the first run, execution_counter will likely be non-zero. // Ensure normalizing a store that begins with non-zero ec works. let (glean, _dir) = new_glean(None);
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