// Copyright 2018 The gVisor Authors. // // 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. package kernel import ( "fmt" "runtime/trace" "sort" "gvisor.dev/gvisor/pkg/context" "gvisor.dev/gvisor/pkg/log" "gvisor.dev/gvisor/pkg/usermem" ) const ( // maxStackDebugBytes is the maximum number of user stack bytes that may be // printed by debugDumpStack. maxStackDebugBytes = 1024 // maxCodeDebugBytes is the maximum number of user code bytes that may be // printed by debugDumpCode. maxCodeDebugBytes = 128 ) // Infof logs an formatted info message by calling log.Infof. func (t *Task) Infof(fmt string, v ...interface{}) { if log.IsLogging(log.Info) { log.InfofAtDepth(1, t.logPrefix.Load().(string)+fmt, v...) } } // Warningf logs a warning string by calling log.Warningf. func (t *Task) Warningf(fmt string, v ...interface{}) { if log.IsLogging(log.Warning) { log.WarningfAtDepth(1, t.logPrefix.Load().(string)+fmt, v...) } } // Debugf creates a debug string that includes the task ID. func (t *Task) Debugf(fmt string, v ...interface{}) { if log.IsLogging(log.Debug) { log.DebugfAtDepth(1, t.logPrefix.Load().(string)+fmt, v...) } } // IsLogging returns true iff this level is being logged. func (t *Task) IsLogging(level log.Level) bool { return log.IsLogging(level) } // DebugDumpState logs task state at log level debug. // // Preconditions: The caller must be running on the task goroutine. func (t *Task) DebugDumpState() { t.debugDumpRegisters() t.debugDumpStack() t.debugDumpCode() if mm := t.MemoryManager(); mm != nil { t.Debugf("Mappings:\n%s", mm) } t.Debugf("FDTable:\n%s", t.fdTable) } // debugDumpRegisters logs register state at log level debug. // // Preconditions: The caller must be running on the task goroutine. func (t *Task) debugDumpRegisters() { if !t.IsLogging(log.Debug) { return } regmap, err := t.Arch().RegisterMap() if err != nil { t.Debugf("Registers: %v", err) } else { t.Debugf("Registers:") var regs []string for reg := range regmap { regs = append(regs, reg) } sort.Strings(regs) for _, reg := range regs { t.Debugf("%-8s = %016x", reg, regmap[reg]) } } } // debugDumpStack logs user stack contents at log level debug. // // Preconditions: The caller must be running on the task goroutine. func (t *Task) debugDumpStack() { if !t.IsLogging(log.Debug) { return } m := t.MemoryManager() if m == nil { t.Debugf("Memory manager for task is gone, skipping application stack dump.") return } t.Debugf("Stack:") start := usermem.Addr(t.Arch().Stack()) // Round addr down to a 16-byte boundary. start &= ^usermem.Addr(15) // Print 16 bytes per line, one byte at a time. for offset := uint64(0); offset < maxStackDebugBytes; offset += 16 { addr, ok := start.AddLength(offset) if !ok { break } var data [16]byte n, err := m.CopyIn(t, addr, data[:], usermem.IOOpts{ IgnorePermissions: true, }) // Print as much of the line as we can, even if an error was // encountered. if n > 0 { t.Debugf("%x: % x", addr, data[:n]) } if err != nil { t.Debugf("Error reading stack at address %x: %v", addr+usermem.Addr(n), err) break } } } // debugDumpCode logs user code contents at log level debug. // // Preconditions: The caller must be running on the task goroutine. func (t *Task) debugDumpCode() { if !t.IsLogging(log.Debug) { return } m := t.MemoryManager() if m == nil { t.Debugf("Memory manager for task is gone, skipping application code dump.") return } t.Debugf("Code:") // Print code on both sides of the instruction register. start := usermem.Addr(t.Arch().IP()) - maxCodeDebugBytes/2 // Round addr down to a 16-byte boundary. start &= ^usermem.Addr(15) // Print 16 bytes per line, one byte at a time. for offset := uint64(0); offset < maxCodeDebugBytes; offset += 16 { addr, ok := start.AddLength(offset) if !ok { break } var data [16]byte n, err := m.CopyIn(t, addr, data[:], usermem.IOOpts{ IgnorePermissions: true, }) // Print as much of the line as we can, even if an error was // encountered. if n > 0 { t.Debugf("%x: % x", addr, data[:n]) } if err != nil { t.Debugf("Error reading stack at address %x: %v", addr+usermem.Addr(n), err) break } } } // trace definitions. // // Note that all region names are prefixed by ':' in order to ensure that they // are lexically ordered before all system calls, which use the naked system // call name (e.g. "read") for maximum clarity. const ( traceCategory = "task" runRegion = ":run" blockRegion = ":block" cpuidRegion = ":cpuid" faultRegion = ":fault" ) // updateInfoLocked updates the task's cached log prefix and tracing // information to reflect its current thread ID. // // Preconditions: The task's owning TaskSet.mu must be locked. func (t *Task) updateInfoLocked() { // Use the task's TID in the root PID namespace for logging. tid := t.tg.pidns.owner.Root.tids[t] t.logPrefix.Store(fmt.Sprintf("[% 4d] ", tid)) t.rebuildTraceContext(tid) } // rebuildTraceContext rebuilds the trace context. // // Precondition: the passed tid must be the tid in the root namespace. func (t *Task) rebuildTraceContext(tid ThreadID) { // Re-initialize the trace context. if t.traceTask != nil { t.traceTask.End() } // Note that we define the "task type" to be the dynamic TID. This does // not align perfectly with the documentation for "tasks" in the // tracing package. Tasks may be assumed to be bounded by analysis // tools. However, if we just use a generic "task" type here, then the // "user-defined tasks" page on the tracing dashboard becomes nearly // unusable, as it loads all traces from all tasks. // // We can assume that the number of tasks in the system is not // arbitrarily large (in general it won't be, especially for cases // where we're collecting a brief profile), so using the TID is a // reasonable compromise in this case. t.traceContext, t.traceTask = trace.NewTask(context.Background(), fmt.Sprintf("tid:%d", tid)) } // traceCloneEvent is called when a new task is spawned. // // ntid must be the new task's ThreadID in the root namespace. func (t *Task) traceCloneEvent(ntid ThreadID) { if !trace.IsEnabled() { return } trace.Logf(t.traceContext, traceCategory, "spawn: %d", ntid) } // traceExitEvent is called when a task exits. func (t *Task) traceExitEvent() { if !trace.IsEnabled() { return } trace.Logf(t.traceContext, traceCategory, "exit status: 0x%x", t.exitStatus.Status()) } // traceExecEvent is called when a task calls exec. func (t *Task) traceExecEvent(image *TaskImage) { if !trace.IsEnabled() { return } file := image.MemoryManager.Executable() if file == nil { trace.Logf(t.traceContext, traceCategory, "exec: << unknown >>") return } defer file.DecRef(t) trace.Logf(t.traceContext, traceCategory, "exec: %s", file.PathnameWithDeleted(t)) }