// 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/.
//! IPC Implementation, Rust part
usecrate::private::MetricId; use once_cell::sync::Lazy; use serde::{Deserialize, Serialize}; use std::collections::HashMap; #[cfg(not(feature = "with_gecko"))] use std::sync::atomic::AtomicBool; use std::sync::atomic::{AtomicUsize, Ordering}; use std::sync::Mutex; #[cfg(feature = "with_gecko")] use {std::convert::TryInto, std::sync::atomic::AtomicU32, xpcom::interfaces::nsIXULRuntime};
usesuper::metrics::__glean_metric_maps;
type EventRecord = (u64, HashMap<String, String>);
/// Global singleton: pending IPC payload. static PAYLOAD: Lazy<Mutex<IPCPayload>> = Lazy::new(|| Mutex::new(IPCPayload::default())); /// Global singleton: number of times the IPC payload was accessed. static PAYLOAD_ACCESS_COUNT: AtomicUsize = AtomicUsize::new(0);
// The maximum size of an IPC message in Firefox Desktop is 256MB. // (See IPC::Channel::kMaximumMessageSize) // In `IPCPayload` the largest size can be attained in the fewest accesses via events. // Each event could be its own u64 id, u64 timestamp, and HashMap of ten i32 to ten 100-byte strings. // That's 1056B = 8 + 8 + 10(4 + 100) // In 256MB we can fit 254200 or so of these, not counting overhead. // Let's take a conservative estimate of 100000 to // 0) Account for overhead // 1) Not be greedy // 2) Allow time for the dispatch to main thread which will actually perform the flush // "Why the -1?" Because fetch_add returns the value before the addition. // bug 1936851 - Perhaps due to longer and more event extras, or object and text metrics, // we're hitting the size limit before hitting the watermark. // Change the watermark from 100k - 1 to 90k - 1. const PAYLOAD_ACCESS_WATERMARK: usize = 90000 - 1;
pubfn with_ipc_payload<F, R>(f: F) -> R where
F: FnOnce(&mut IPCPayload) -> R,
{ if PAYLOAD_ACCESS_COUNT.fetch_add(1, Ordering::SeqCst) > PAYLOAD_ACCESS_WATERMARK { // We reset this before the actual flush to keep all the logic together. // Otherwise the count reset would need to happen down in take_buf(). // This may overcount (resulting in undersized payloads) which is okay.
PAYLOAD_ACCESS_COUNT.store(0, Ordering::SeqCst);
handle_payload_filling();
} letmut payload = PAYLOAD.lock().unwrap();
f(&mut payload)
}
/// Do we need IPC? /// /// Thread-safe. #[cfg(feature = "with_gecko")] static PROCESS_TYPE: Lazy<AtomicU32> = Lazy::new(|| { extern"C" { fn FOG_GetProcessType() -> i32;
} // SAFETY NOTE: Safe because it returns a primitive by value. let process_type = unsafe { FOG_GetProcessType() }; // It's impossible for i32 to overflow u32, but maybe someone got clever // and introduced a negative process type constant. Default to parent. let process_type = process_type
.try_into()
.unwrap_or(nsIXULRuntime::PROCESS_TYPE_DEFAULT); // We don't have process-specific init locations outside of the main // process, so we introduce this side-effect to a global static init. // This is the absolute first time we decide which process type we're // treating this process as, so this is the earliest we can do this.
register_process_shutdown(process_type);
AtomicU32::new(process_type)
});
/// The first time we're used in a process, /// we'll need to start thinking about cleanup. /// /// Please only call once per process. /// Multiple calls may register multiple handlers. #[cfg(feature = "with_gecko")] fn register_process_shutdown(process_type: u32) { match process_type {
nsIXULRuntime::PROCESS_TYPE_DEFAULT => { // Parent process shutdown is handled by the FOG XPCOM Singleton.
}
nsIXULRuntime::PROCESS_TYPE_CONTENT => { // Content child shutdown is in C++ for access to RunOnShutdown(). extern"C" { fn FOG_RegisterContentChildShutdown();
} unsafe {
FOG_RegisterContentChildShutdown();
};
}
nsIXULRuntime::PROCESS_TYPE_GMPLUGIN => { // GMP process shutdown is handled in GMPChild::ActorDestroy.
}
nsIXULRuntime::PROCESS_TYPE_GPU => { // GPU process shutdown is handled in GPUParent::ActorDestroy.
}
nsIXULRuntime::PROCESS_TYPE_RDD => { // RDD process shutdown is handled in RDDParent::ActorDestroy.
}
nsIXULRuntime::PROCESS_TYPE_SOCKET => { // Socket process shutdown is handled in SocketProcessChild::ActorDestroy.
}
nsIXULRuntime::PROCESS_TYPE_UTILITY => { // Utility process shutdown is handled in UtilityProcessChild::ActorDestroy.
}
_ => { // We don't yet support other process types.
log::error!("Process type {} tried to use FOG, but isn't supported! (Process type constants are in nsIXULRuntime.rs)", process_type);
}
}
}
/// An RAII that, on drop, restores the value used to determine whether FOG /// needs IPC. Used in tests. /// ```rust,ignore /// #[test] /// fn test_need_ipc_raii() { /// assert!(false == ipc::need_ipc()); /// { /// let _raii = ipc::test_set_need_ipc(true); /// assert!(ipc::need_ipc()); /// } /// assert!(false == ipc::need_ipc()); /// } /// ``` #[cfg(not(feature = "with_gecko"))] pubstruct TestNeedIpcRAII {
prev_value: bool,
}
#[cfg(not(feature = "with_gecko"))] impl Drop for TestNeedIpcRAII { fn drop(&mutself) {
TEST_NEED_IPC.store(self.prev_value, Ordering::Relaxed);
}
}
/// Test-only API for telling FOG to use IPC mechanisms even if the test has /// only the one process. See TestNeedIpcRAII for an example. #[cfg(not(feature = "with_gecko"))] pubfn test_set_need_ipc(need_ipc: bool) -> TestNeedIpcRAII {
TestNeedIpcRAII {
prev_value: TEST_NEED_IPC.swap(need_ipc, Ordering::Relaxed),
}
}
#[cfg(not(feature = "with_gecko"))] fn handle_payload_filling() { // Space intentionally left blank. // Without Gecko IPC to drain the buffer, there's nothing we can do.
}
#[cfg(feature = "with_gecko")] fn handle_payload_filling() { extern"C" { fn FOG_IPCPayloadFull();
} // SAFETY NOTE: Safe because it doesn't take or return values. unsafe { FOG_IPCPayloadFull() };
}
#[cfg(not(feature = "with_gecko"))] pubfn is_in_automation() -> bool { // Without Gecko IPC to drain the buffer, there's nothing we can do. false
}
#[cfg(feature = "with_gecko")] pubfn is_in_automation() -> bool { extern"C" { fn FOG_IPCIsInAutomation() -> bool;
} // SAFETY NOTE: Safe because it returns a primitive by value. unsafe { FOG_IPCIsInAutomation() }
}
// Reason: We instrument the error counts, // but don't need more detailed error information at the moment. #[allow(clippy::result_unit_err)] pubfn replay_from_buf(buf: &[u8]) -> Result<(), ()> { // TODO: Instrument failures to find metrics by id. let ipc_payload: IPCPayload = bincode::deserialize(buf).map_err(|_| ())?; for (id, value) in ipc_payload.booleans.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::BOOLEAN_MAP
.read()
.expect("Read lock for dynamic boolean map was poisoned"); iflet Some(metric) = map.get(&id) {
metric.set(value);
}
} elseiflet Some(metric) = __glean_metric_maps::BOOLEAN_MAP.get(&id) {
metric.set(value);
}
} for (id, labeled_bools) in ipc_payload.labeled_booleans.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::LABELED_BOOLEAN_MAP
.read()
.expect("Read lock for dynamic labeled boolean map was poisoned"); iflet Some(metric) = map.get(&id) { for (label, value) in labeled_bools.into_iter() {
metric.get(&label).set(value);
}
}
} else { for (label, value) in labeled_bools.into_iter() {
__glean_metric_maps::labeled_boolean_get(*id, &label).set(value);
}
}
} for (id, value) in ipc_payload.counters.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::COUNTER_MAP
.read()
.expect("Read lock for dynamic counter map was poisoned"); iflet Some(metric) = map.get(&id) {
metric.add(value);
}
} elseiflet Some(metric) = __glean_metric_maps::COUNTER_MAP.get(&id) {
metric.add(value);
}
} for (id, samples) in ipc_payload.custom_samples.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::CUSTOM_DISTRIBUTION_MAP
.read()
.expect("Read lock for dynamic custom distribution map was poisoned"); iflet Some(metric) = map.get(&id) {
metric.accumulate_samples_signed(samples);
}
} elseiflet Some(metric) = __glean_metric_maps::CUSTOM_DISTRIBUTION_MAP.get(&id) {
metric.accumulate_samples_signed(samples);
}
} for (id, labeled_custom_samples) in ipc_payload.labeled_custom_samples.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::LABELED_CUSTOM_DISTRIBUTION_MAP
.read()
.expect("Read lock for dynamic labeled custom distribution map was poisoned"); iflet Some(metric) = map.get(&id) { for (label, samples) in labeled_custom_samples.into_iter() {
metric.get(&label).accumulate_samples_signed(samples);
}
}
} else { for (label, samples) in labeled_custom_samples.into_iter() {
__glean_metric_maps::labeled_custom_distribution_get(*id, &label)
.accumulate_samples_signed(samples);
}
}
} for (id, value) in ipc_payload.denominators.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::DENOMINATOR_MAP
.read()
.expect("Read lock for dynamic denominator map was poisoned"); iflet Some(metric) = map.get(&id) {
metric.add(value);
}
} elseiflet Some(metric) = __glean_metric_maps::DENOMINATOR_MAP.get(&id) {
metric.add(value);
}
} for (id, records) in ipc_payload.events.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::EVENT_MAP
.read()
.expect("Read lock for dynamic event map was poisoned"); iflet Some(metric) = map.get(&id) { for (timestamp, extra) in records.into_iter() {
metric.record_with_time(timestamp, extra);
}
}
} else { for (timestamp, extra) in records.into_iter() { let _ = __glean_metric_maps::record_event_by_id_with_time(id, timestamp, extra);
}
}
} for (id, labeled_counts) in ipc_payload.labeled_counters.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::LABELED_COUNTER_MAP
.read()
.expect("Read lock for dynamic labeled counter map was poisoned"); iflet Some(metric) = map.get(&id) { for (label, count) in labeled_counts.into_iter() {
metric.get(&label).add(count);
}
}
} else { for (label, count) in labeled_counts.into_iter() {
__glean_metric_maps::labeled_counter_get(*id, &label).add(count);
}
}
} for (id, samples) in ipc_payload.memory_samples.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::MEMORY_DISTRIBUTION_MAP
.read()
.expect("Read lock for dynamic memory dist map was poisoned"); iflet Some(metric) = map.get(&id) {
metric.accumulate_samples(samples);
}
} elseiflet Some(metric) = __glean_metric_maps::MEMORY_DISTRIBUTION_MAP.get(&id) {
samples
.into_iter()
.for_each(|sample| metric.accumulate(sample));
}
} for (id, labeled_memory_samples) in ipc_payload.labeled_memory_samples.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::LABELED_MEMORY_DISTRIBUTION_MAP
.read()
.expect("Read lock for dynamic labeled memory distribution map was poisoned"); iflet Some(metric) = map.get(&id) { for (label, samples) in labeled_memory_samples.into_iter() {
metric.get(&label).accumulate_samples(samples);
}
}
} else { for (label, samples) in labeled_memory_samples.into_iter() {
__glean_metric_maps::labeled_memory_distribution_get(*id, &label)
.accumulate_samples(samples);
}
}
} for (id, value) in ipc_payload.numerators.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::NUMERATOR_MAP
.read()
.expect("Read lock for dynamic numerator map was poisoned"); iflet Some(metric) = map.get(&id) {
metric.add_to_numerator(value);
}
} elseiflet Some(metric) = __glean_metric_maps::NUMERATOR_MAP.get(&id) {
metric.add_to_numerator(value);
}
} for (id, (n, d)) in ipc_payload.rates.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::RATE_MAP
.read()
.expect("Read lock for dynamic rate map was poisoned"); iflet Some(metric) = map.get(&id) {
metric.add_to_numerator(n);
metric.add_to_denominator(d);
}
} elseiflet Some(metric) = __glean_metric_maps::RATE_MAP.get(&id) {
metric.add_to_numerator(n);
metric.add_to_denominator(d);
}
} for (id, strings) in ipc_payload.string_lists.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::STRING_LIST_MAP
.read()
.expect("Read lock for dynamic string list map was poisoned"); iflet Some(metric) = map.get(&id) {
strings.iter().for_each(|s| metric.add(s));
}
} elseiflet Some(metric) = __glean_metric_maps::STRING_LIST_MAP.get(&id) {
strings.iter().for_each(|s| metric.add(s));
}
} for (id, samples) in ipc_payload.timing_samples.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::TIMING_DISTRIBUTION_MAP
.read()
.expect("Read lock for dynamic timing distribution map was poisoned"); iflet Some(metric) = map.get(&id) {
metric.accumulate_raw_samples_nanos(samples);
}
} elseiflet Some(metric) = __glean_metric_maps::TIMING_DISTRIBUTION_MAP.get(&id) {
metric.accumulate_raw_samples_nanos(samples);
}
} for (id, labeled_timing_samples) in ipc_payload.labeled_timing_samples.into_iter() { if id.is_dynamic() { let map = crate::factory::__jog_metric_maps::LABELED_TIMING_DISTRIBUTION_MAP
.read()
.expect("Read lock for dynamic labeled timing distribution map was poisoned"); iflet Some(metric) = map.get(&id) { for (label, samples) in labeled_timing_samples.into_iter() {
metric.get(&label).accumulate_raw_samples_nanos(samples);
}
}
} else { for (label, samples) in labeled_timing_samples.into_iter() {
__glean_metric_maps::labeled_timing_distribution_get(*id, &label)
.accumulate_raw_samples_nanos(samples);
}
}
}
Ok(())
}
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