package monitor import ( "fmt" "sync" "time" log "github.com/hashicorp/go-hclog" ) // Monitor provides a mechanism to stream logs using go-hclog // InterceptLogger and SinkAdapter. It allows streaming of logs // at a different log level than what is set on the logger. type Monitor interface { // Start returns a channel of log messages which are sent // ever time a log message occurs Start() <-chan []byte // Stop de-registers the sink from the InterceptLogger // and closes the log channels Stop() } // monitor implements the Monitor interface type monitor struct { // protects droppedCount and logCh sync.Mutex sink log.SinkAdapter // logger is the logger we will be monitoring logger log.InterceptLogger // logCh is a buffered chan where we send logs when streaming logCh chan []byte // doneCh coordinates the shutdown of logCh doneCh chan struct{} // droppedCount is the current count of messages // that were dropped from the logCh buffer. // only access under lock droppedCount int bufSize int // droppedDuration is the amount of time we should // wait to check for dropped messages. Defaults // to 3 seconds droppedDuration time.Duration } // New creates a new Monitor. Start must be called in order to actually start // streaming logs func New(buf int, logger log.InterceptLogger, opts *log.LoggerOptions) Monitor { return new(buf, logger, opts) } func new(buf int, logger log.InterceptLogger, opts *log.LoggerOptions) *monitor { sw := &monitor{ logger: logger, logCh: make(chan []byte, buf), doneCh: make(chan struct{}, 1), bufSize: buf, droppedDuration: 3 * time.Second, } opts.Output = sw sink := log.NewSinkAdapter(opts) sw.sink = sink return sw } // Stop stops the monitoring process func (d *monitor) Stop() { close(d.doneCh) } // Start registers a sink on the monitor's logger and starts sending // received log messages over the returned channel. func (d *monitor) Start() <-chan []byte { d.logger.RegisterSink(d.sink) streamCh := make(chan []byte, d.bufSize) // run a go routine that listens for streamed // log messages and sends them to streamCh go func() { defer func() { d.logger.DeregisterSink(d.sink) close(streamCh) }() for { select { case log := <-d.logCh: select { case <-d.doneCh: return case streamCh <- log: } case <-d.doneCh: return } } }() // run a go routine that periodically checks for // dropped messages and makes room on the logCh // to add a dropped message count warning go func() { // loop and check for dropped messages LOOP: for { select { case <-d.doneCh: break LOOP case <-time.After(d.droppedDuration): d.Lock() // Check if there have been any dropped messages. if d.droppedCount > 0 { dropped := fmt.Sprintf("[WARN] Monitor dropped %d logs during monitor request\n", d.droppedCount) select { case <-d.doneCh: break LOOP // Try sending dropped message count to logCh in case // there is room in the buffer now. case d.logCh <- []byte(dropped): default: // Drop a log message to make room for "Monitor dropped.." message select { case <-d.logCh: d.droppedCount++ dropped = fmt.Sprintf("[WARN] Monitor dropped %d logs during monitor request\n", d.droppedCount) default: } d.logCh <- []byte(dropped) } d.droppedCount = 0 } // unlock after handling dropped message d.Unlock() } } }() return streamCh } // Write attempts to send latest log to logCh // it drops the log if channel is unavailable to receive func (d *monitor) Write(p []byte) (n int, err error) { d.Lock() defer d.Unlock() // ensure logCh is still open select { case <-d.doneCh: return default: } bytes := make([]byte, len(p)) copy(bytes, p) select { case d.logCh <- bytes: default: d.droppedCount++ } return }