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// Copyright 2022 The Gitea Authors. All rights reserved.
// SPDX-License-Identifier: MIT
package process
import (
"fmt"
"io"
"runtime/pprof"
"sort"
"time"
"github.com/google/pprof/profile"
)
// StackEntry is an entry on a stacktrace
type StackEntry struct {
Function string
File string
Line int
}
// Label represents a pprof label assigned to goroutine stack
type Label struct {
Name string
Value string
}
// Stack is a stacktrace relating to a goroutine. (Multiple goroutines may have the same stacktrace)
type Stack struct {
Count int64 // Number of goroutines with this stack trace
Description string
Labels []*Label `json:",omitempty"`
Entry []*StackEntry `json:",omitempty"`
}
// A Process is a combined representation of a Process and a Stacktrace for the goroutines associated with it
type Process struct {
PID IDType
ParentPID IDType
Description string
Start time.Time
Type string
Children []*Process `json:",omitempty"`
Stacks []*Stack `json:",omitempty"`
}
// Processes gets the processes in a thread safe manner
func (pm *Manager) Processes(flat, noSystem bool) ([]*Process, int) {
pm.mutex.Lock()
processCount := len(pm.processMap)
processes := make([]*Process, 0, len(pm.processMap))
if flat {
for _, process := range pm.processMap {
if noSystem && process.Type == SystemProcessType {
continue
}
processes = append(processes, process.toProcess())
}
} else {
// We need our own processMap
processMap := map[IDType]*Process{}
for _, internalProcess := range pm.processMap {
process, ok := processMap[internalProcess.PID]
if !ok {
process = internalProcess.toProcess()
processMap[process.PID] = process
}
// Check its parent
if process.ParentPID == "" {
processes = append(processes, process)
continue
}
internalParentProcess, ok := pm.processMap[internalProcess.ParentPID]
if ok {
parentProcess, ok := processMap[process.ParentPID]
if !ok {
parentProcess = internalParentProcess.toProcess()
processMap[parentProcess.PID] = parentProcess
}
parentProcess.Children = append(parentProcess.Children, process)
continue
}
processes = append(processes, process)
}
}
pm.mutex.Unlock()
if !flat && noSystem {
for i := 0; i < len(processes); i++ {
process := processes[i]
if process.Type != SystemProcessType {
continue
}
processes[len(processes)-1], processes[i] = processes[i], processes[len(processes)-1]
processes = append(processes[:len(processes)-1], process.Children...)
i--
}
}
// Sort by process' start time. Oldest process appears first.
sort.Slice(processes, func(i, j int) bool {
left, right := processes[i], processes[j]
return left.Start.Before(right.Start)
})
return processes, processCount
}
// ProcessStacktraces gets the processes and stacktraces in a thread safe manner
func (pm *Manager) ProcessStacktraces(flat, noSystem bool) ([]*Process, int, int64, error) {
var stacks *profile.Profile
var err error
// We cannot use the pm.ProcessMap here because we will release the mutex ...
processMap := map[IDType]*Process{}
var processCount int
// Lock the manager
pm.mutex.Lock()
processCount = len(pm.processMap)
// Add a defer to unlock in case there is a panic
unlocked := false
defer func() {
if !unlocked {
pm.mutex.Unlock()
}
}()
processes := make([]*Process, 0, len(pm.processMap))
if flat {
for _, internalProcess := range pm.processMap {
process := internalProcess.toProcess()
processMap[process.PID] = process
if noSystem && internalProcess.Type == SystemProcessType {
continue
}
processes = append(processes, process)
}
} else {
for _, internalProcess := range pm.processMap {
process, ok := processMap[internalProcess.PID]
if !ok {
process = internalProcess.toProcess()
processMap[process.PID] = process
}
// Check its parent
if process.ParentPID == "" {
processes = append(processes, process)
continue
}
internalParentProcess, ok := pm.processMap[internalProcess.ParentPID]
if ok {
parentProcess, ok := processMap[process.ParentPID]
if !ok {
parentProcess = internalParentProcess.toProcess()
processMap[parentProcess.PID] = parentProcess
}
parentProcess.Children = append(parentProcess.Children, process)
continue
}
processes = append(processes, process)
}
}
// Now from within the lock we need to get the goroutines.
// Why? If we release the lock then between between filling the above map and getting
// the stacktraces another process could be created which would then look like a dead process below
reader, writer := io.Pipe()
defer reader.Close()
go func() {
err := pprof.Lookup("goroutine").WriteTo(writer, 0)
_ = writer.CloseWithError(err)
}()
stacks, err = profile.Parse(reader)
if err != nil {
return nil, 0, 0, err
}
// Unlock the mutex
pm.mutex.Unlock()
unlocked = true
goroutineCount := int64(0)
// Now walk through the "Sample" slice in the goroutines stack
for _, sample := range stacks.Sample {
// In the "goroutine" pprof profile each sample represents one or more goroutines
// with the same labels and stacktraces.
// We will represent each goroutine by a `Stack`
stack := &Stack{}
// Add the non-process associated labels from the goroutine sample to the Stack
for name, value := range sample.Label {
if name == DescriptionPProfLabel || name == PIDPProfLabel || (!flat && name == PPIDPProfLabel) || name == ProcessTypePProfLabel {
continue
}
// Labels from the "goroutine" pprof profile only have one value.
// This is because the underlying representation is a map[string]string
if len(value) != 1 {
// Unexpected...
return nil, 0, 0, fmt.Errorf("label: %s in goroutine stack with unexpected number of values: %v", name, value)
}
stack.Labels = append(stack.Labels, &Label{Name: name, Value: value[0]})
}
// The number of goroutines that this sample represents is the `stack.Value[0]`
stack.Count = sample.Value[0]
goroutineCount += stack.Count
// Now we want to associate this Stack with a Process.
var process *Process
// Try to get the PID from the goroutine labels
if pidvalue, ok := sample.Label[PIDPProfLabel]; ok && len(pidvalue) == 1 {
pid := IDType(pidvalue[0])
// Now try to get the process from our map
process, ok = processMap[pid]
if !ok && pid != "" {
// This means that no process has been found in the process map - but there was a process PID
// Therefore this goroutine belongs to a dead process and it has escaped control of the process as it
// should have died with the process context cancellation.
// We need to create a dead process holder for this process and label it appropriately
// get the parent PID
ppid := IDType("")
if value, ok := sample.Label[PPIDPProfLabel]; ok && len(value) == 1 {
ppid = IDType(value[0])
}
// format the description
description := "(dead process)"
if value, ok := sample.Label[DescriptionPProfLabel]; ok && len(value) == 1 {
description = value[0] + " " + description
}
// override the type of the process to "code" but add the old type as a label on the first stack
ptype := NoneProcessType
if value, ok := sample.Label[ProcessTypePProfLabel]; ok && len(value) == 1 {
stack.Labels = append(stack.Labels, &Label{Name: ProcessTypePProfLabel, Value: value[0]})
}
process = &Process{
PID: pid,
ParentPID: ppid,
Description: description,
Type: ptype,
}
// Now add the dead process back to the map and tree so we don't go back through this again.
processMap[process.PID] = process
added := false
if process.ParentPID != "" && !flat {
if parent, ok := processMap[process.ParentPID]; ok {
parent.Children = append(parent.Children, process)
added = true
}
}
if !added {
processes = append(processes, process)
}
}
}
if process == nil {
// This means that the sample we're looking has no PID label
var ok bool
process, ok = processMap[""]
if !ok {
// this is the first time we've come acrross an unassociated goroutine so create a "process" to hold them
process = &Process{
Description: "(unassociated)",
Type: NoneProcessType,
}
processMap[process.PID] = process
processes = append(processes, process)
}
}
// The sample.Location represents a stack trace for this goroutine,
// however each Location can represent multiple lines (mostly due to inlining)
// so we need to walk the lines too
for _, location := range sample.Location {
for _, line := range location.Line {
entry := &StackEntry{
Function: line.Function.Name,
File: line.Function.Filename,
Line: int(line.Line),
}
stack.Entry = append(stack.Entry, entry)
}
}
// Now we need a short-descriptive name to call the stack trace if when it is folded and
// assuming the stack trace has some lines we'll choose the bottom of the stack (i.e. the
// initial function that started the stack trace.) The top of the stack is unlikely to
// be very helpful as a lot of the time it will be runtime.select or some other call into
// a std library.
stack.Description = "(unknown)"
if len(stack.Entry) > 0 {
stack.Description = stack.Entry[len(stack.Entry)-1].Function
}
process.Stacks = append(process.Stacks, stack)
}
// restrict to not show system processes
if noSystem {
for i := 0; i < len(processes); i++ {
process := processes[i]
if process.Type != SystemProcessType && process.Type != NoneProcessType {
continue
}
processes[len(processes)-1], processes[i] = processes[i], processes[len(processes)-1]
processes = append(processes[:len(processes)-1], process.Children...)
i--
}
}
// Now finally re-sort the processes. Newest process appears first
after := func(processes []*Process) func(i, j int) bool {
return func(i, j int) bool {
left, right := processes[i], processes[j]
return left.Start.After(right.Start)
}
}
sort.Slice(processes, after(processes))
if !flat {
var sortChildren func(process *Process)
sortChildren = func(process *Process) {
sort.Slice(process.Children, after(process.Children))
for _, child := range process.Children {
sortChildren(child)
}
}
}
return processes, processCount, goroutineCount, err
}
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