// Copyright (C) 2018 Vincent Ambo <mail@tazj.in> // // journaldriver 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 3 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, see <http://www.gnu.org/licenses/>. //! This file implements journaldriver, a small application that //! forwards logs from journald (systemd's log facility) to //! Stackdriver Logging. //! //! Log entries are read continously from journald and are forwarded //! to Stackdriver in batches. //! //! Stackdriver Logging has a concept of monitored resources. In the //! simplest case this monitored resource will be the GCE instance on //! which journaldriver is running. //! //! Information about the instance, the project and required security //! credentials are retrieved from Google's metadata instance on GCP. //! //! To run journaldriver on non-GCP machines, users must specify the //! `GOOGLE_APPLICATION_CREDENTIALS`, `GOOGLE_CLOUD_PROJECT` and //! `LOG_NAME` environment variables. #[macro_use] extern crate failure; #[macro_use] extern crate log; #[macro_use] extern crate serde_derive; #[macro_use] extern crate serde_json; #[macro_use] extern crate lazy_static; extern crate chrono; extern crate env_logger; extern crate medallion; extern crate serde; extern crate systemd; extern crate ureq; use chrono::offset::LocalResult; use chrono::prelude::*; use failure::ResultExt; use serde_json::{from_str, Value}; use std::env; use std::fs::{self, File, rename}; use std::io::{self, Read, ErrorKind, Write}; use std::mem; use std::path::PathBuf; use std::process; use std::time::{Duration, Instant}; use systemd::journal::*; #[cfg(test)] mod tests; const LOGGING_SERVICE: &str = "https://logging.googleapis.com/google.logging.v2.LoggingServiceV2"; const ENTRIES_WRITE_URL: &str = "https://logging.googleapis.com/v2/entries:write"; const METADATA_TOKEN_URL: &str = "http://metadata.google.internal/computeMetadata/v1/instance/service-accounts/default/token"; const METADATA_ID_URL: &str = "http://metadata.google.internal/computeMetadata/v1/instance/id"; const METADATA_ZONE_URL: &str = "http://metadata.google.internal/computeMetadata/v1/instance/zone"; const METADATA_PROJECT_URL: &str = "http://metadata.google.internal/computeMetadata/v1/project/project-id"; /// Convenience type alias for results using failure's `Error` type. type Result<T> = std::result::Result<T, failure::Error>; /// Representation of static service account credentials for GCP. #[derive(Debug, Deserialize)] struct Credentials { /// PEM encoded private key private_key: String, /// `kid` of this private key private_key_id: String, /// "email" address of the service account client_email: String, } lazy_static! { /// ID of the GCP project to which to send logs. static ref PROJECT_ID: String = get_project_id(); /// Name of the log to write to (this should only be manually /// configured if not running on GCP): static ref LOG_NAME: String = env::var("LOG_NAME") .unwrap_or("journaldriver".into()); /// Service account credentials (if configured) static ref SERVICE_ACCOUNT_CREDENTIALS: Option<Credentials> = env::var("GOOGLE_APPLICATION_CREDENTIALS").ok() .and_then(|path| File::open(path).ok()) .and_then(|file| serde_json::from_reader(file).ok()); /// Descriptor of the currently monitored instance. Refer to the /// documentation of `determine_monitored_resource` for more /// information. static ref MONITORED_RESOURCE: Value = determine_monitored_resource(); /// Path to the directory in which journaldriver should persist /// its cursor state. static ref CURSOR_DIR: PathBuf = env::var("CURSOR_POSITION_DIR") .unwrap_or("/var/lib/journaldriver".into()) .into(); /// Path to the cursor position file itself. static ref CURSOR_FILE: PathBuf = { let mut path = CURSOR_DIR.clone(); path.push("cursor.pos"); path }; /// Path to the temporary file used for cursor position writes. static ref CURSOR_TMP_FILE: PathBuf = { let mut path = CURSOR_DIR.clone(); path.push("cursor.tmp"); path }; } /// Convenience helper for retrieving values from the metadata server. fn get_metadata(url: &str) -> Result<String> { let response = ureq::get(url) .set("Metadata-Flavor", "Google") .timeout_connect(5000) .timeout_read(5000) .call(); if response.ok() { // Whitespace is trimmed to remove newlines from responses. let body = response.into_string() .context("Failed to decode metadata response")? .trim().to_string(); Ok(body) } else { let status = response.status_line().to_string(); let body = response.into_string() .unwrap_or_else(|e| format!("Metadata body error: {}", e)); bail!("Metadata failure: {} ({})", body, status) } } /// Convenience helper for determining the project ID. fn get_project_id() -> String { env::var("GOOGLE_CLOUD_PROJECT") .map_err(Into::into) .or_else(|_: failure::Error| get_metadata(METADATA_PROJECT_URL)) .expect("Could not determine project ID") } /// Determines the monitored resource descriptor used in Stackdriver /// logs. On GCP this will be set to the instance ID as returned by /// the metadata server. /// /// On non-GCP machines the value is determined by using the /// `GOOGLE_CLOUD_PROJECT` and `LOG_STREAM` environment variables. /// /// [issue #4]: https://github.com/tazjin/journaldriver/issues/4 fn determine_monitored_resource() -> Value { if let Ok(log) = env::var("LOG_STREAM") { // The special value `global` is recognised as a log stream name that // results in a `global`-type resource descriptor. This is useful in // cases where Stackdriver Error Reporting is intended to be used on // a non-GCE instance. See [issue #4][] for details. if log == "global" { return json!({ "type": "global", "labels": { "project_id": PROJECT_ID.as_str(), } }); } json!({ "type": "logging_log", "labels": { "project_id": PROJECT_ID.as_str(), "name": log, } }) } else { let instance_id = get_metadata(METADATA_ID_URL) .expect("Could not determine instance ID"); let zone = get_metadata(METADATA_ZONE_URL) .expect("Could not determine instance zone"); json!({ "type": "gce_instance", "labels": { "project_id": PROJECT_ID.as_str(), "instance_id": instance_id, "zone": zone, } }) } } /// Represents the response returned by the metadata server's token /// endpoint. The token is normally valid for an hour. #[derive(Deserialize)] struct TokenResponse { expires_in: u64, access_token: String, } /// Struct used to store a token together with a sensible /// representation of when it expires. struct Token { token: String, fetched_at: Instant, expires: Duration, } impl Token { /// Does this token need to be renewed? fn is_expired(&self) -> bool { self.fetched_at.elapsed() > self.expires } } /// Retrieves a token from the GCP metadata service. Retrieving these /// tokens requires no additional authentication. fn get_metadata_token() -> Result<Token> { let body = get_metadata(METADATA_TOKEN_URL)?; let token: TokenResponse = from_str(&body)?; debug!("Fetched new token from metadata service"); Ok(Token { fetched_at: Instant::now(), expires: Duration::from_secs(token.expires_in / 2), token: token.access_token, }) } /// Signs a token using static client credentials configured for a /// service account. This service account must have been given the /// `Log Writer` role in Google Cloud IAM. /// /// The process for creating and signing these tokens is described /// here: /// /// https://developers.google.com/identity/protocols/OAuth2ServiceAccount#jwt-auth fn sign_service_account_token(credentials: &Credentials) -> Result<Token> { use medallion::{Algorithm, Header, Payload}; let iat = Utc::now(); let exp = iat.checked_add_signed(chrono::Duration::seconds(3600)) .ok_or_else(|| format_err!("Failed to calculate token expiry"))?; let header = Header { alg: Algorithm::RS256, headers: Some(json!({ "kid": credentials.private_key_id, })), }; let payload: Payload<()> = Payload { iss: Some(credentials.client_email.clone()), sub: Some(credentials.client_email.clone()), aud: Some(LOGGING_SERVICE.to_string()), iat: Some(iat.timestamp() as u64), exp: Some(exp.timestamp() as u64), ..Default::default() }; let token = medallion::Token::new(header, payload) .sign(credentials.private_key.as_bytes()) .context("Signing service account token failed")?; debug!("Signed new service account token"); Ok(Token { token, fetched_at: Instant::now(), expires: Duration::from_secs(3000), }) } /// Retrieve the authentication token either by using static client /// credentials, or by talking to the metadata server. /// /// Which behaviour is used is controlled by the environment variable /// `GOOGLE_APPLICATION_CREDENTIALS`, which should be configured to /// point at a JSON private key file if service account authentication /// is to be used. fn get_token() -> Result<Token> { if let Some(credentials) = SERVICE_ACCOUNT_CREDENTIALS.as_ref() { sign_service_account_token(credentials) } else { get_metadata_token() } } /// This structure represents the different types of payloads /// supported by journaldriver. /// /// Currently log entries can either contain plain text messages or /// structured payloads in JSON-format. #[derive(Debug, Serialize, PartialEq)] #[serde(untagged)] enum Payload { TextPayload { #[serde(rename = "textPayload")] text_payload: String, }, JsonPayload { #[serde(rename = "jsonPayload")] json_payload: Value, }, } /// Attempt to parse a log message as JSON and return it as a /// structured payload. If parsing fails, return the entry in plain /// text format. fn message_to_payload(message: Option<String>) -> Payload { match message { None => Payload::TextPayload { text_payload: "empty log entry".into() }, Some(text_payload) => { // Attempt to deserialize the text payload as a generic // JSON value. if let Ok(json_payload) = serde_json::from_str::<Value>(&text_payload) { // If JSON-parsing succeeded on the payload, check // whether we parsed an object (Stackdriver does not // expect other types of JSON payload) and return it // in that case. if json_payload.is_object() { return Payload::JsonPayload { json_payload } } } Payload::TextPayload { text_payload } } } } /// Attempt to parse journald's microsecond timestamps into a UTC /// timestamp. /// /// Parse errors are dismissed and returned as empty options: There /// simply aren't any useful fallback mechanisms other than defaulting /// to ingestion time for journaldriver's use-case. fn parse_microseconds(input: String) -> Option<DateTime<Utc>> { if input.len() != 16 { return None; } let seconds: i64 = (&input[..10]).parse().ok()?; let micros: u32 = (&input[10..]).parse().ok()?; match Utc.timestamp_opt(seconds, micros * 1000) { LocalResult::Single(time) => Some(time), _ => None, } } /// Converts a journald log message priority to a /// Stackdriver-compatible severity number. /// /// Both Stackdriver and journald specify equivalent /// severities/priorities. Conveniently, the names are the same. /// Inconveniently, the numbers are not. /// /// For more information on the journald priorities, consult these /// man-pages: /// /// * systemd.journal-fields(7) (section 'PRIORITY') /// * sd-daemon(3) /// * systemd.exec(5) (section 'SyslogLevelPrefix') /// /// Note that priorities can be logged by applications via the prefix /// concept described in these man pages, without interfering with /// structured JSON-payloads. /// /// For more information on the Stackdriver severity levels, please /// consult Google's documentation: /// /// https://cloud.google.com/logging/docs/reference/v2/rest/v2/LogEntry#LogSeverity /// /// Any unknown priority values result in no severity being set. fn priority_to_severity(priority: String) -> Option<u32> { match priority.as_ref() { "0" => Some(800), // emerg "1" => Some(700), // alert "2" => Some(600), // crit "3" => Some(500), // err "4" => Some(400), // warning "5" => Some(300), // notice "6" => Some(200), // info "7" => Some(100), // debug _ => None, } } /// This structure represents a log entry in the format expected by /// the Stackdriver API. #[derive(Debug, Serialize)] #[serde(rename_all = "camelCase")] struct LogEntry { labels: Value, #[serde(skip_serializing_if = "Option::is_none")] timestamp: Option<DateTime<Utc>>, #[serde(flatten)] payload: Payload, // https://cloud.google.com/logging/docs/reference/v2/rest/v2/LogEntry#LogSeverity #[serde(skip_serializing_if = "Option::is_none")] severity: Option<u32>, } impl From<JournalRecord> for LogEntry { // Converts from the fields contained in a journald record to the // representation required by Stackdriver Logging. // // The fields are documented in systemd.journal-fields(7). fn from(mut record: JournalRecord) -> LogEntry { // The message field is technically just a convention, but // journald seems to default to it when ingesting unit // output. let payload = message_to_payload(record.remove("MESSAGE")); // Presumably this is always set, but who can be sure // about anything in this world. let hostname = record.remove("_HOSTNAME"); // The unit is seemingly missing on kernel entries, but // present on all others. let unit = record.remove("_SYSTEMD_UNIT"); // The source timestamp (if present) is specified in // microseconds since epoch. // // If it is not present or can not be parsed, journaldriver // will not send a timestamp for the log entry and it will // default to the ingestion time. let timestamp = record .remove("_SOURCE_REALTIME_TIMESTAMP") .and_then(parse_microseconds); // Journald uses syslogd's concept of priority. No idea if this is // always present, but it's optional in the Stackdriver API, so we just // omit it if we can't find or parse it. let severity = record .remove("PRIORITY") .and_then(priority_to_severity); LogEntry { payload, timestamp, labels: json!({ "host": hostname, "unit": unit.unwrap_or_else(|| "syslog".into()), }), severity, } } } /// Attempt to read from the journal. If no new entry is present, /// await the next one up to the specified timeout. fn receive_next_record(timeout: Duration, journal: &mut Journal) -> Result<Option<JournalRecord>> { let next_record = journal.next_record()?; if next_record.is_some() { return Ok(next_record); } Ok(journal.await_next_record(Some(timeout))?) } /// This function starts a double-looped, blocking receiver. It will /// buffer messages for half a second before flushing them to /// Stackdriver. fn receiver_loop(mut journal: Journal) -> Result<()> { let mut token = get_token()?; let mut buf: Vec<LogEntry> = Vec::new(); let iteration = Duration::from_millis(500); loop { trace!("Beginning outer iteration"); let now = Instant::now(); loop { if now.elapsed() > iteration { break; } if let Ok(Some(entry)) = receive_next_record(iteration, &mut journal) { trace!("Received a new entry"); buf.push(entry.into()); } } if !buf.is_empty() { let to_flush = mem::replace(&mut buf, Vec::new()); flush(&mut token, to_flush, journal.cursor()?)?; } trace!("Done outer iteration"); } } /// Writes the current cursor into `/var/journaldriver/cursor.pos`. To /// avoid issues with journaldriver being terminated while the cursor /// is still being written, this will first write the cursor into a /// temporary file and then move it. fn persist_cursor(cursor: String) -> Result<()> { // This code exists to aid in tracking down if there are other // causes of issue #2 than what has already been taken care of. // // One theory is that journald (or the Rust library to interface // with it) may occasionally return empty cursor strings. If this // is ever the case, we would like to know about it. if cursor.is_empty() { error!("Received empty journald cursor position, refusing to persist!"); error!("Please report this message at https://github.com/tazjin/journaldriver/issues/2"); return Ok(()) } let mut file = File::create(&*CURSOR_TMP_FILE) .context("Failed to create cursor file")?; write!(file, "{}", cursor).context("Failed to write cursor file")?; rename(&*CURSOR_TMP_FILE, &*CURSOR_FILE) .context("Failed to move cursor file") .map_err(Into::into) } /// Flushes all drained records to Stackdriver. Any Stackdriver /// message can at most contain 1000 log entries which means they are /// chunked up here. /// /// In some cases large payloads seem to cause errors in Stackdriver - /// the chunks are therefore made smaller here. /// /// If flushing is successful the last cursor position will be /// persisted to disk. fn flush(token: &mut Token, entries: Vec<LogEntry>, cursor: String) -> Result<()> { if token.is_expired() { debug!("Refreshing Google metadata access token"); let new_token = get_token()?; mem::replace(token, new_token); } for chunk in entries.chunks(750) { let request = prepare_request(chunk); if let Err(write_error) = write_entries(token, request) { error!("Failed to write {} entries: {}", chunk.len(), write_error) } else { debug!("Wrote {} entries to Stackdriver", chunk.len()) } } persist_cursor(cursor) } /// Convert a slice of log entries into the format expected by /// Stackdriver. This format is documented here: /// /// https://cloud.google.com/logging/docs/reference/v2/rest/v2/entries/write fn prepare_request(entries: &[LogEntry]) -> Value { json!({ "logName": format!("projects/{}/logs/{}", PROJECT_ID.as_str(), LOG_NAME.as_str()), "resource": &*MONITORED_RESOURCE, "entries": entries, "partialSuccess": true }) } /// Perform the log entry insertion in Stackdriver Logging. fn write_entries(token: &Token, request: Value) -> Result<()> { let response = ureq::post(ENTRIES_WRITE_URL) .set("Authorization", format!("Bearer {}", token.token).as_str()) // The timeout values are set relatively high, not because of // an expectation of Stackdriver being slow but just to // eventually hit an error case in case of network troubles. // Presumably no request in a functioning environment will // ever hit these limits. .timeout_connect(2000) .timeout_read(5000) .send_json(request); if response.ok() { Ok(()) } else { let status = response.status_line().to_string(); let body = response.into_string() .unwrap_or_else(|_| "no response body".into()); bail!("Write failure: {} ({})", body, status) } } /// Attempt to read the initial cursor position from the configured /// file. If there is no initial cursor position set, read from the /// tail of the log. /// /// The only "acceptable" error when reading the cursor position is /// the cursor position file not existing, other errors are fatal /// because they indicate a misconfiguration of journaldriver. fn initial_cursor() -> Result<JournalSeek> { let read_result: io::Result<String> = (|| { let mut contents = String::new(); let mut file = File::open(&*CURSOR_FILE)?; file.read_to_string(&mut contents)?; Ok(contents.trim().into()) })(); match read_result { Ok(cursor) => Ok(JournalSeek::Cursor { cursor }), Err(ref err) if err.kind() == ErrorKind::NotFound => { info!("No previous cursor position, reading from journal tail"); Ok(JournalSeek::Tail) }, Err(err) => { (Err(err).context("Could not read cursor position"))? } } } fn main () { env_logger::init(); // The directory in which cursor positions are persisted should // have been created: if !CURSOR_DIR.exists() { error!("Cursor directory at '{:?}' does not exist", *CURSOR_DIR); process::exit(1); } let cursor_position_dir = CURSOR_FILE.parent() .expect("Invalid cursor position file path"); fs::create_dir_all(cursor_position_dir) .expect("Could not create directory to store cursor position in"); let mut journal = Journal::open(JournalFiles::All, false, true) .expect("Failed to open systemd journal"); let seek_position = initial_cursor() .expect("Failed to determine initial cursor position"); match journal.seek(seek_position) { Ok(cursor) => info!("Opened journal at cursor '{}'", cursor), Err(err) => { error!("Failed to set initial journal position: {}", err); process::exit(1) } } receiver_loop(journal).expect("log receiver encountered an unexpected error"); }