// Copyright 2016 Google LLC // // 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. // +build linux,go1.7 package main import ( "encoding/json" "flag" "fmt" "io/ioutil" "log" "math/rand" "os" "sync" "time" "cloud.google.com/go/cmd/go-cloud-debug-agent/internal/breakpoints" debuglet "cloud.google.com/go/cmd/go-cloud-debug-agent/internal/controller" "cloud.google.com/go/cmd/go-cloud-debug-agent/internal/debug" "cloud.google.com/go/cmd/go-cloud-debug-agent/internal/debug/local" "cloud.google.com/go/cmd/go-cloud-debug-agent/internal/valuecollector" "cloud.google.com/go/compute/metadata" "golang.org/x/net/context" "golang.org/x/oauth2" "golang.org/x/oauth2/google" cd "google.golang.org/api/clouddebugger/v2" ) var ( appModule = flag.String("appmodule", "", "Optional application module name.") appVersion = flag.String("appversion", "", "Optional application module version name.") sourceContextFile = flag.String("sourcecontext", "", "File containing JSON-encoded source context.") verbose = flag.Bool("v", false, "Output verbose log messages.") projectNumber = flag.String("projectnumber", "", "Project number."+ " If this is not set, it is read from the GCP metadata server.") projectID = flag.String("projectid", "", "Project ID."+ " If this is not set, it is read from the GCP metadata server.") serviceAccountFile = flag.String("serviceaccountfile", "", "File containing JSON service account credentials.") ) const ( maxCapturedStackFrames = 50 maxCapturedVariables = 1000 ) func main() { flag.Usage = usage flag.Parse() args := flag.Args() if len(args) == 0 { // The user needs to supply the name of the executable to run. flag.Usage() return } if *projectNumber == "" { var err error *projectNumber, err = metadata.NumericProjectID() if err != nil { log.Print("Debuglet initialization: ", err) } } if *projectID == "" { var err error *projectID, err = metadata.ProjectID() if err != nil { log.Print("Debuglet initialization: ", err) } } sourceContexts, err := readSourceContextFile(*sourceContextFile) if err != nil { log.Print("Reading source context file: ", err) } var ts oauth2.TokenSource ctx := context.Background() if *serviceAccountFile != "" { if ts, err = serviceAcctTokenSource(ctx, *serviceAccountFile, cd.CloudDebuggerScope); err != nil { log.Fatalf("Error getting credentials from file %s: %v", *serviceAccountFile, err) } } else if ts, err = google.DefaultTokenSource(ctx, cd.CloudDebuggerScope); err != nil { log.Print("Error getting application default credentials for Cloud Debugger:", err) os.Exit(103) } c, err := debuglet.NewController(ctx, debuglet.Options{ ProjectNumber: *projectNumber, ProjectID: *projectID, AppModule: *appModule, AppVersion: *appVersion, SourceContexts: sourceContexts, Verbose: *verbose, TokenSource: ts, }) if err != nil { log.Fatal("Error connecting to Cloud Debugger: ", err) } prog, err := local.New(args[0]) if err != nil { log.Fatal("Error loading program: ", err) } // Load the program, but don't actually start it running yet. if _, err = prog.Run(args[1:]...); err != nil { log.Fatal("Error loading program: ", err) } bs := breakpoints.NewBreakpointStore(prog) // Seed the random number generator. rand.Seed(time.Now().UnixNano()) // Now we want to do two things: run the user's program, and start sending // List requests periodically to the Debuglet Controller to get breakpoints // to set. // // We want to give the Debuglet Controller a chance to give us breakpoints // before we start the program, otherwise we would miss any breakpoint // triggers that occur during program startup -- for example, a breakpoint on // the first line of main. But if the Debuglet Controller is not responding or // is returning errors, we don't want to delay starting the program // indefinitely. // // We pass a channel to breakpointListLoop, which will close it when the first // List call finishes. Then we wait until either the channel is closed or a // 5-second timer has finished before starting the program. ch := make(chan bool) // Start a goroutine that sends List requests to the Debuglet Controller, and // sets any breakpoints it gets back. go breakpointListLoop(ctx, c, bs, ch) // Wait until 5 seconds have passed or breakpointListLoop has closed ch. select { case <-time.After(5 * time.Second): case <-ch: } // Run the debuggee. programLoop(ctx, c, bs, prog) } // usage prints a usage message to stderr and exits. func usage() { me := "a.out" if len(os.Args) >= 1 { me = os.Args[0] } fmt.Fprintf(os.Stderr, "Usage of %s:\n", me) fmt.Fprintf(os.Stderr, "\t%s [flags...] -- args...\n", me) fmt.Fprintf(os.Stderr, "Flags:\n") flag.PrintDefaults() fmt.Fprintf(os.Stderr, "See https://cloud.google.com/tools/cloud-debugger/setting-up-on-compute-engine for more information.\n") os.Exit(2) } // readSourceContextFile reads a JSON-encoded source context from the given file. // It returns a non-empty slice on success. func readSourceContextFile(filename string) ([]*cd.SourceContext, error) { if filename == "" { return nil, nil } scJSON, err := ioutil.ReadFile(filename) if err != nil { return nil, fmt.Errorf("reading file %q: %v", filename, err) } var sc cd.SourceContext if err = json.Unmarshal(scJSON, &sc); err != nil { return nil, fmt.Errorf("parsing file %q: %v", filename, err) } return []*cd.SourceContext{&sc}, nil } // breakpointListLoop repeatedly calls the Debuglet Controller's List RPC, and // passes the results to the BreakpointStore so it can set and unset breakpoints // in the program. // // After the first List call finishes, ch is closed. func breakpointListLoop(ctx context.Context, c *debuglet.Controller, bs *breakpoints.BreakpointStore, first chan bool) { const ( avgTimeBetweenCalls = time.Second errorDelay = 5 * time.Second ) // randomDuration returns a random duration with expected value avg. randomDuration := func(avg time.Duration) time.Duration { return time.Duration(rand.Int63n(int64(2*avg + 1))) } var consecutiveFailures uint for { callStart := time.Now() resp, err := c.List(ctx) if err != nil && err != debuglet.ErrListUnchanged { log.Printf("Debuglet controller server error: %v", err) } if err == nil { bs.ProcessBreakpointList(resp.Breakpoints) } if first != nil { // We've finished one call to List and set any breakpoints we received. close(first) first = nil } // Asynchronously send updates for any breakpoints that caused an error when // the BreakpointStore tried to process them. We don't wait for the update // to finish before the program can exit, as we do for normal updates. errorBps := bs.ErrorBreakpoints() for _, bp := range errorBps { go func(bp *cd.Breakpoint) { if err := c.Update(ctx, bp.Id, bp); err != nil { log.Printf("Failed to send breakpoint update for %s: %s", bp.Id, err) } }(bp) } // Make the next call not too soon after the one we just did. delay := randomDuration(avgTimeBetweenCalls) // If the call returned an error other than ErrListUnchanged, wait longer. if err != nil && err != debuglet.ErrListUnchanged { // Wait twice as long after each consecutive failure, to a maximum of 16x. delay += randomDuration(errorDelay * (1 << consecutiveFailures)) if consecutiveFailures < 4 { consecutiveFailures++ } } else { consecutiveFailures = 0 } // Sleep until we reach time callStart+delay. If we've already passed that // time, time.Sleep will return immediately -- this should be the common // case, since the server will delay responding to List for a while when // there are no changes to report. time.Sleep(callStart.Add(delay).Sub(time.Now())) } } // programLoop runs the program being debugged to completion. When a breakpoint's // conditions are satisfied, it sends an Update RPC to the Debuglet Controller. // The function returns when the program exits and all Update RPCs have finished. func programLoop(ctx context.Context, c *debuglet.Controller, bs *breakpoints.BreakpointStore, prog debug.Program) { var wg sync.WaitGroup for { // Run the program until it hits a breakpoint or exits. status, err := prog.Resume() if err != nil { break } // Get the breakpoints at this address whose conditions were satisfied, // and remove the ones that aren't logpoints. bps := bs.BreakpointsAtPC(status.PC) bps = bpsWithConditionSatisfied(bps, prog) for _, bp := range bps { if bp.Action != "LOG" { bs.RemoveBreakpoint(bp) } } if len(bps) == 0 { continue } // Evaluate expressions and get the stack. vc := valuecollector.NewCollector(prog, maxCapturedVariables) needStackFrames := false for _, bp := range bps { // If evaluating bp's condition didn't return an error, evaluate bp's // expressions, and later get the stack frames. if bp.Status == nil { bp.EvaluatedExpressions = expressionValues(bp.Expressions, prog, vc) needStackFrames = true } } var ( stack []*cd.StackFrame stackFramesStatusMessage *cd.StatusMessage ) if needStackFrames { stack, stackFramesStatusMessage = stackFrames(prog, vc) } // Read variable values from the program. variableTable := vc.ReadValues() // Start a goroutine to send updates to the Debuglet Controller or write // to logs, concurrently with resuming the program. // TODO: retry Update on failure. for _, bp := range bps { wg.Add(1) switch bp.Action { case "LOG": go func(format string, evaluatedExpressions []*cd.Variable) { s := valuecollector.LogString(format, evaluatedExpressions, variableTable) log.Print(s) wg.Done() }(bp.LogMessageFormat, bp.EvaluatedExpressions) bp.Status = nil bp.EvaluatedExpressions = nil default: go func(bp *cd.Breakpoint) { defer wg.Done() bp.IsFinalState = true if bp.Status == nil { // If evaluating bp's condition didn't return an error, include the // stack frames, variable table, and any status message produced when // getting the stack frames. bp.StackFrames = stack bp.VariableTable = variableTable bp.Status = stackFramesStatusMessage } if err := c.Update(ctx, bp.Id, bp); err != nil { log.Printf("Failed to send breakpoint update for %s: %s", bp.Id, err) } }(bp) } } } // Wait for all updates to finish before returning. wg.Wait() } // bpsWithConditionSatisfied returns the breakpoints whose conditions are true // (or that do not have a condition.) func bpsWithConditionSatisfied(bpsIn []*cd.Breakpoint, prog debug.Program) []*cd.Breakpoint { var bpsOut []*cd.Breakpoint for _, bp := range bpsIn { cond, err := condTruth(bp.Condition, prog) if err != nil { bp.Status = errorStatusMessage(err.Error(), refersToBreakpointCondition) // Include bp in the list to be updated when there's an error, so that // the user gets a response. bpsOut = append(bpsOut, bp) } else if cond { bpsOut = append(bpsOut, bp) } } return bpsOut } // condTruth evaluates a condition. func condTruth(condition string, prog debug.Program) (bool, error) { if condition == "" { // A condition wasn't set. return true, nil } val, err := prog.Evaluate(condition) if err != nil { return false, err } if v, ok := val.(bool); !ok { return false, fmt.Errorf("condition expression has type %T, should be bool", val) } else { return v, nil } } // expressionValues evaluates a slice of expressions and returns a []*cd.Variable // containing the results. // If the result of an expression evaluation refers to values from the program's // memory (e.g., the expression evaluates to a slice) a corresponding variable is // added to the value collector, to be read later. func expressionValues(expressions []string, prog debug.Program, vc *valuecollector.Collector) []*cd.Variable { evaluatedExpressions := make([]*cd.Variable, len(expressions)) for i, exp := range expressions { ee := &cd.Variable{Name: exp} evaluatedExpressions[i] = ee if val, err := prog.Evaluate(exp); err != nil { ee.Status = errorStatusMessage(err.Error(), refersToBreakpointExpression) } else { vc.FillValue(val, ee) } } return evaluatedExpressions } // stackFrames returns a stack trace for the program. It passes references to // function parameters and local variables to the value collector, so it can read // their values later. func stackFrames(prog debug.Program, vc *valuecollector.Collector) ([]*cd.StackFrame, *cd.StatusMessage) { frames, err := prog.Frames(maxCapturedStackFrames) if err != nil { return nil, errorStatusMessage("Error getting stack: "+err.Error(), refersToUnspecified) } stackFrames := make([]*cd.StackFrame, len(frames)) for i, f := range frames { frame := &cd.StackFrame{} frame.Function = f.Function for _, v := range f.Params { frame.Arguments = append(frame.Arguments, vc.AddVariable(debug.LocalVar(v))) } for _, v := range f.Vars { frame.Locals = append(frame.Locals, vc.AddVariable(v)) } frame.Location = &cd.SourceLocation{ Path: f.File, Line: int64(f.Line), } stackFrames[i] = frame } return stackFrames, nil } // errorStatusMessage returns a *cd.StatusMessage indicating an error, // with the given message and refersTo field. func errorStatusMessage(msg string, refersTo int) *cd.StatusMessage { return &cd.StatusMessage{ Description: &cd.FormatMessage{Format: "$0", Parameters: []string{msg}}, IsError: true, RefersTo: refersToString[refersTo], } } const ( // RefersTo values for cd.StatusMessage. refersToUnspecified = iota refersToBreakpointCondition refersToBreakpointExpression ) // refersToString contains the strings for each refersTo value. // See the definition of StatusMessage in the v2/clouddebugger package. var refersToString = map[int]string{ refersToUnspecified: "UNSPECIFIED", refersToBreakpointCondition: "BREAKPOINT_CONDITION", refersToBreakpointExpression: "BREAKPOINT_EXPRESSION", } func serviceAcctTokenSource(ctx context.Context, filename string, scope ...string) (oauth2.TokenSource, error) { data, err := ioutil.ReadFile(filename) if err != nil { return nil, fmt.Errorf("cannot read service account file: %v", err) } cfg, err := google.JWTConfigFromJSON(data, scope...) if err != nil { return nil, fmt.Errorf("google.JWTConfigFromJSON: %v", err) } return cfg.TokenSource(ctx), nil }