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bee/vendor/github.com/derekparker/delve/service/debugger/debugger.go

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2017-03-19 22:45:54 +00:00
package debugger
import (
"debug/gosym"
"errors"
"fmt"
"go/parser"
"log"
"path/filepath"
"regexp"
"runtime"
"strings"
"sync"
"time"
"github.com/derekparker/delve/pkg/proc"
"github.com/derekparker/delve/pkg/target"
"github.com/derekparker/delve/service/api"
)
// Debugger service.
//
// Debugger provides a higher level of
// abstraction over proc.Process.
// It handles converting from internal types to
// the types expected by clients. It also handles
// functionality needed by clients, but not needed in
// lower lever packages such as proc.
type Debugger struct {
config *Config
// TODO(DO NOT MERGE WITHOUT) rename to targetMutex
processMutex sync.Mutex
target target.Interface
}
// Config provides the configuration to start a Debugger.
//
// Only one of ProcessArgs or AttachPid should be specified. If ProcessArgs is
// provided, a new process will be launched. Otherwise, the debugger will try
// to attach to an existing process with AttachPid.
type Config struct {
// ProcessArgs are the arguments to launch a new process.
ProcessArgs []string
// WorkingDir is working directory of the new process. This field is used
// only when launching a new process.
WorkingDir string
// AttachPid is the PID of an existing process to which the debugger should
// attach.
AttachPid int
}
// New creates a new Debugger.
func New(config *Config) (*Debugger, error) {
d := &Debugger{
config: config,
}
// Create the process by either attaching or launching.
if d.config.AttachPid > 0 {
log.Printf("attaching to pid %d", d.config.AttachPid)
p, err := proc.Attach(d.config.AttachPid)
if err != nil {
return nil, attachErrorMessage(d.config.AttachPid, err)
}
d.target = p
} else {
log.Printf("launching process with args: %v", d.config.ProcessArgs)
p, err := proc.Launch(d.config.ProcessArgs, d.config.WorkingDir)
if err != nil {
if err != proc.NotExecutableErr && err != proc.UnsupportedArchErr {
err = fmt.Errorf("could not launch process: %s", err)
}
return nil, err
}
d.target = p
}
return d, nil
}
// ProcessPid returns the PID of the process
// the debugger is debugging.
func (d *Debugger) ProcessPid() int {
return d.target.Pid()
}
// LastModified returns the time that the process' executable was last
// modified.
func (d *Debugger) LastModified() time.Time {
return d.target.LastModified()
}
// Detach detaches from the target process.
// If `kill` is true we will kill the process after
// detaching.
func (d *Debugger) Detach(kill bool) error {
d.processMutex.Lock()
defer d.processMutex.Unlock()
return d.detach(kill)
}
func (d *Debugger) detach(kill bool) error {
if d.config.AttachPid != 0 {
return d.target.Detach(kill)
}
return d.target.Kill()
}
// Restart will restart the target process, first killing
// and then exec'ing it again.
func (d *Debugger) Restart() ([]api.DiscardedBreakpoint, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
if !d.target.Exited() {
if d.target.Running() {
d.target.Halt()
}
// Ensure the process is in a PTRACE_STOP.
if err := stopProcess(d.ProcessPid()); err != nil {
return nil, err
}
if err := d.detach(true); err != nil {
return nil, err
}
}
p, err := proc.Launch(d.config.ProcessArgs, d.config.WorkingDir)
if err != nil {
return nil, fmt.Errorf("could not launch process: %s", err)
}
discarded := []api.DiscardedBreakpoint{}
for _, oldBp := range d.breakpoints() {
if oldBp.ID < 0 {
continue
}
if len(oldBp.File) > 0 {
oldBp.Addr, err = p.FindFileLocation(oldBp.File, oldBp.Line)
if err != nil {
discarded = append(discarded, api.DiscardedBreakpoint{oldBp, err.Error()})
continue
}
}
newBp, err := p.SetBreakpoint(oldBp.Addr, proc.UserBreakpoint, nil)
if err != nil {
return nil, err
}
if err := copyBreakpointInfo(newBp, oldBp); err != nil {
return nil, err
}
}
d.target = p
return discarded, nil
}
// State returns the current state of the debugger.
func (d *Debugger) State() (*api.DebuggerState, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
return d.state()
}
func (d *Debugger) state() (*api.DebuggerState, error) {
if d.target.Exited() {
return nil, proc.ProcessExitedError{Pid: d.ProcessPid()}
}
var (
state *api.DebuggerState
goroutine *api.Goroutine
)
if d.target.SelectedGoroutine() != nil {
goroutine = api.ConvertGoroutine(d.target.SelectedGoroutine())
}
state = &api.DebuggerState{
SelectedGoroutine: goroutine,
Exited: d.target.Exited(),
}
for i := range d.target.Threads() {
th := api.ConvertThread(d.target.Threads()[i])
state.Threads = append(state.Threads, th)
if i == d.target.CurrentThread().ID {
state.CurrentThread = th
}
}
for _, bp := range d.target.Breakpoints() {
if bp.Internal() {
state.NextInProgress = true
break
}
}
return state, nil
}
// CreateBreakpoint creates a breakpoint.
func (d *Debugger) CreateBreakpoint(requestedBp *api.Breakpoint) (*api.Breakpoint, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
var (
createdBp *api.Breakpoint
addr uint64
err error
)
if requestedBp.Name != "" {
if err = api.ValidBreakpointName(requestedBp.Name); err != nil {
return nil, err
}
if d.findBreakpointByName(requestedBp.Name) != nil {
return nil, errors.New("breakpoint name already exists")
}
}
switch {
case len(requestedBp.File) > 0:
fileName := requestedBp.File
if runtime.GOOS == "windows" {
// Accept fileName which is case-insensitive and slash-insensitive match
fileNameNormalized := strings.ToLower(filepath.ToSlash(fileName))
for symFile := range d.target.Sources() {
if fileNameNormalized == strings.ToLower(filepath.ToSlash(symFile)) {
fileName = symFile
break
}
}
}
addr, err = d.target.FindFileLocation(fileName, requestedBp.Line)
case len(requestedBp.FunctionName) > 0:
if requestedBp.Line >= 0 {
addr, err = d.target.FindFunctionLocation(requestedBp.FunctionName, false, requestedBp.Line)
} else {
addr, err = d.target.FindFunctionLocation(requestedBp.FunctionName, true, 0)
}
default:
addr = requestedBp.Addr
}
if err != nil {
return nil, err
}
bp, err := d.target.SetBreakpoint(addr, proc.UserBreakpoint, nil)
if err != nil {
return nil, err
}
if err := copyBreakpointInfo(bp, requestedBp); err != nil {
if _, err1 := d.target.ClearBreakpoint(bp.Addr); err1 != nil {
err = fmt.Errorf("error while creating breakpoint: %v, additionally the breakpoint could not be properly rolled back: %v", err, err1)
}
return nil, err
}
createdBp = api.ConvertBreakpoint(bp)
log.Printf("created breakpoint: %#v", createdBp)
return createdBp, nil
}
func (d *Debugger) AmendBreakpoint(amend *api.Breakpoint) error {
d.processMutex.Lock()
defer d.processMutex.Unlock()
original := d.findBreakpoint(amend.ID)
if original == nil {
return fmt.Errorf("no breakpoint with ID %d", amend.ID)
}
if err := api.ValidBreakpointName(amend.Name); err != nil {
return err
}
return copyBreakpointInfo(original, amend)
}
func (d *Debugger) CancelNext() error {
return d.target.ClearInternalBreakpoints()
}
func copyBreakpointInfo(bp *proc.Breakpoint, requested *api.Breakpoint) (err error) {
bp.Name = requested.Name
bp.Tracepoint = requested.Tracepoint
bp.Goroutine = requested.Goroutine
bp.Stacktrace = requested.Stacktrace
bp.Variables = requested.Variables
bp.LoadArgs = api.LoadConfigToProc(requested.LoadArgs)
bp.LoadLocals = api.LoadConfigToProc(requested.LoadLocals)
bp.Cond = nil
if requested.Cond != "" {
bp.Cond, err = parser.ParseExpr(requested.Cond)
}
return err
}
// ClearBreakpoint clears a breakpoint.
func (d *Debugger) ClearBreakpoint(requestedBp *api.Breakpoint) (*api.Breakpoint, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
var clearedBp *api.Breakpoint
bp, err := d.target.ClearBreakpoint(requestedBp.Addr)
if err != nil {
return nil, fmt.Errorf("Can't clear breakpoint @%x: %s", requestedBp.Addr, err)
}
clearedBp = api.ConvertBreakpoint(bp)
log.Printf("cleared breakpoint: %#v", clearedBp)
return clearedBp, err
}
// Breakpoints returns the list of current breakpoints.
func (d *Debugger) Breakpoints() []*api.Breakpoint {
d.processMutex.Lock()
defer d.processMutex.Unlock()
return d.breakpoints()
}
func (d *Debugger) breakpoints() []*api.Breakpoint {
bps := []*api.Breakpoint{}
for _, bp := range d.target.Breakpoints() {
if bp.Internal() {
continue
}
bps = append(bps, api.ConvertBreakpoint(bp))
}
return bps
}
// FindBreakpoint returns the breakpoint specified by 'id'.
func (d *Debugger) FindBreakpoint(id int) *api.Breakpoint {
d.processMutex.Lock()
defer d.processMutex.Unlock()
bp := d.findBreakpoint(id)
if bp == nil {
return nil
}
return api.ConvertBreakpoint(bp)
}
func (d *Debugger) findBreakpoint(id int) *proc.Breakpoint {
for _, bp := range d.target.Breakpoints() {
if bp.ID == id {
return bp
}
}
return nil
}
// FindBreakpointByName returns the breakpoint specified by 'name'
func (d *Debugger) FindBreakpointByName(name string) *api.Breakpoint {
d.processMutex.Lock()
defer d.processMutex.Unlock()
return d.findBreakpointByName(name)
}
func (d *Debugger) findBreakpointByName(name string) *api.Breakpoint {
for _, bp := range d.breakpoints() {
if bp.Name == name {
return bp
}
}
return nil
}
// Threads returns the threads of the target process.
func (d *Debugger) Threads() ([]*api.Thread, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
if d.target.Exited() {
return nil, &proc.ProcessExitedError{}
}
threads := []*api.Thread{}
for _, th := range d.target.Threads() {
threads = append(threads, api.ConvertThread(th))
}
return threads, nil
}
// FindThread returns the thread for the given 'id'.
func (d *Debugger) FindThread(id int) (*api.Thread, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
if d.target.Exited() {
return nil, &proc.ProcessExitedError{}
}
for _, th := range d.target.Threads() {
if th.ID == id {
return api.ConvertThread(th), nil
}
}
return nil, nil
}
// Command handles commands which control the debugger lifecycle
func (d *Debugger) Command(command *api.DebuggerCommand) (*api.DebuggerState, error) {
var err error
if command.Name == api.Halt {
// RequestManualStop does not invoke any ptrace syscalls, so it's safe to
// access the process directly.
log.Print("halting")
err = d.target.RequestManualStop()
}
d.processMutex.Lock()
defer d.processMutex.Unlock()
switch command.Name {
case api.Continue:
log.Print("continuing")
err = d.target.Continue()
if err != nil {
if exitedErr, exited := err.(proc.ProcessExitedError); exited {
state := &api.DebuggerState{}
state.Exited = true
state.ExitStatus = exitedErr.Status
state.Err = errors.New(exitedErr.Error())
return state, nil
}
return nil, err
}
state, stateErr := d.state()
if stateErr != nil {
return state, stateErr
}
err = d.collectBreakpointInformation(state)
return state, err
case api.Next:
log.Print("nexting")
err = d.target.Next()
case api.Step:
log.Print("stepping")
err = d.target.Step()
case api.StepInstruction:
log.Print("single stepping")
err = d.target.StepInstruction()
case api.StepOut:
log.Print("step out")
err = d.target.StepOut()
case api.SwitchThread:
log.Printf("switching to thread %d", command.ThreadID)
err = d.target.SwitchThread(command.ThreadID)
case api.SwitchGoroutine:
log.Printf("switching to goroutine %d", command.GoroutineID)
err = d.target.SwitchGoroutine(command.GoroutineID)
case api.Halt:
// RequestManualStop already called
}
if err != nil {
return nil, err
}
return d.state()
}
func (d *Debugger) collectBreakpointInformation(state *api.DebuggerState) error {
if state == nil {
return nil
}
for i := range state.Threads {
if state.Threads[i].Breakpoint == nil {
continue
}
bp := state.Threads[i].Breakpoint
bpi := &api.BreakpointInfo{}
state.Threads[i].BreakpointInfo = bpi
if bp.Goroutine {
g, err := d.target.CurrentThread().GetG()
if err != nil {
return err
}
bpi.Goroutine = api.ConvertGoroutine(g)
}
if bp.Stacktrace > 0 {
rawlocs, err := d.target.CurrentThread().Stacktrace(bp.Stacktrace)
if err != nil {
return err
}
bpi.Stacktrace, err = d.convertStacktrace(rawlocs, nil)
if err != nil {
return err
}
}
s, err := d.target.Threads()[state.Threads[i].ID].Scope()
if err != nil {
return err
}
if len(bp.Variables) > 0 {
bpi.Variables = make([]api.Variable, len(bp.Variables))
}
for i := range bp.Variables {
v, err := s.EvalVariable(bp.Variables[i], proc.LoadConfig{true, 1, 64, 64, -1})
if err != nil {
return err
}
bpi.Variables[i] = *api.ConvertVar(v)
}
if bp.LoadArgs != nil {
if vars, err := s.FunctionArguments(*api.LoadConfigToProc(bp.LoadArgs)); err == nil {
bpi.Arguments = convertVars(vars)
}
}
if bp.LoadLocals != nil {
if locals, err := s.LocalVariables(*api.LoadConfigToProc(bp.LoadLocals)); err == nil {
bpi.Locals = convertVars(locals)
}
}
}
return nil
}
// Sources returns a list of the source files for target binary.
func (d *Debugger) Sources(filter string) ([]string, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
regex, err := regexp.Compile(filter)
if err != nil {
return nil, fmt.Errorf("invalid filter argument: %s", err.Error())
}
files := []string{}
for f := range d.target.Sources() {
if regex.Match([]byte(f)) {
files = append(files, f)
}
}
return files, nil
}
// Functions returns a list of functions in the target process.
func (d *Debugger) Functions(filter string) ([]string, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
return regexFilterFuncs(filter, d.target.Funcs())
}
func (d *Debugger) Types(filter string) ([]string, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
regex, err := regexp.Compile(filter)
if err != nil {
return nil, fmt.Errorf("invalid filter argument: %s", err.Error())
}
types, err := d.target.Types()
if err != nil {
return nil, err
}
r := make([]string, 0, len(types))
for _, typ := range types {
if regex.Match([]byte(typ)) {
r = append(r, typ)
}
}
return r, nil
}
func regexFilterFuncs(filter string, allFuncs []gosym.Func) ([]string, error) {
regex, err := regexp.Compile(filter)
if err != nil {
return nil, fmt.Errorf("invalid filter argument: %s", err.Error())
}
funcs := []string{}
for _, f := range allFuncs {
if f.Sym != nil && regex.Match([]byte(f.Name)) {
funcs = append(funcs, f.Name)
}
}
return funcs, nil
}
// PackageVariables returns a list of package variables for the thread,
// optionally regexp filtered using regexp described in 'filter'.
func (d *Debugger) PackageVariables(threadID int, filter string, cfg proc.LoadConfig) ([]api.Variable, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
regex, err := regexp.Compile(filter)
if err != nil {
return nil, fmt.Errorf("invalid filter argument: %s", err.Error())
}
vars := []api.Variable{}
thread, found := d.target.Threads()[threadID]
if !found {
return nil, fmt.Errorf("couldn't find thread %d", threadID)
}
scope, err := thread.Scope()
if err != nil {
return nil, err
}
pv, err := scope.PackageVariables(cfg)
if err != nil {
return nil, err
}
for _, v := range pv {
if regex.Match([]byte(v.Name)) {
vars = append(vars, *api.ConvertVar(v))
}
}
return vars, err
}
// Registers returns string representation of the CPU registers.
func (d *Debugger) Registers(threadID int, floatingPoint bool) (api.Registers, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
thread, found := d.target.Threads()[threadID]
if !found {
return nil, fmt.Errorf("couldn't find thread %d", threadID)
}
regs, err := thread.Registers(floatingPoint)
if err != nil {
return nil, err
}
return api.ConvertRegisters(regs.Slice()), err
}
func convertVars(pv []*proc.Variable) []api.Variable {
vars := make([]api.Variable, 0, len(pv))
for _, v := range pv {
vars = append(vars, *api.ConvertVar(v))
}
return vars
}
// LocalVariables returns a list of the local variables.
func (d *Debugger) LocalVariables(scope api.EvalScope, cfg proc.LoadConfig) ([]api.Variable, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
s, err := d.target.ConvertEvalScope(scope.GoroutineID, scope.Frame)
if err != nil {
return nil, err
}
pv, err := s.LocalVariables(cfg)
if err != nil {
return nil, err
}
return convertVars(pv), err
}
// FunctionArguments returns the arguments to the current function.
func (d *Debugger) FunctionArguments(scope api.EvalScope, cfg proc.LoadConfig) ([]api.Variable, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
s, err := d.target.ConvertEvalScope(scope.GoroutineID, scope.Frame)
if err != nil {
return nil, err
}
pv, err := s.FunctionArguments(cfg)
if err != nil {
return nil, err
}
return convertVars(pv), nil
}
// EvalVariableInScope will attempt to evaluate the variable represented by 'symbol'
// in the scope provided.
func (d *Debugger) EvalVariableInScope(scope api.EvalScope, symbol string, cfg proc.LoadConfig) (*api.Variable, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
s, err := d.target.ConvertEvalScope(scope.GoroutineID, scope.Frame)
if err != nil {
return nil, err
}
v, err := s.EvalVariable(symbol, cfg)
if err != nil {
return nil, err
}
return api.ConvertVar(v), err
}
// SetVariableInScope will set the value of the variable represented by
// 'symbol' to the value given, in the given scope.
func (d *Debugger) SetVariableInScope(scope api.EvalScope, symbol, value string) error {
d.processMutex.Lock()
defer d.processMutex.Unlock()
s, err := d.target.ConvertEvalScope(scope.GoroutineID, scope.Frame)
if err != nil {
return err
}
return s.SetVariable(symbol, value)
}
// Goroutines will return a list of goroutines in the target process.
func (d *Debugger) Goroutines() ([]*api.Goroutine, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
goroutines := []*api.Goroutine{}
gs, err := d.target.GoroutinesInfo()
if err != nil {
return nil, err
}
for _, g := range gs {
goroutines = append(goroutines, api.ConvertGoroutine(g))
}
return goroutines, err
}
// Stacktrace returns a list of Stackframes for the given goroutine. The
// length of the returned list will be min(stack_len, depth).
// If 'full' is true, then local vars, function args, etc will be returned as well.
func (d *Debugger) Stacktrace(goroutineID, depth int, cfg *proc.LoadConfig) ([]api.Stackframe, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
var rawlocs []proc.Stackframe
g, err := d.target.FindGoroutine(goroutineID)
if err != nil {
return nil, err
}
if g == nil {
rawlocs, err = d.target.CurrentThread().Stacktrace(depth)
} else {
rawlocs, err = g.Stacktrace(depth)
}
if err != nil {
return nil, err
}
return d.convertStacktrace(rawlocs, cfg)
}
func (d *Debugger) convertStacktrace(rawlocs []proc.Stackframe, cfg *proc.LoadConfig) ([]api.Stackframe, error) {
locations := make([]api.Stackframe, 0, len(rawlocs))
for i := range rawlocs {
frame := api.Stackframe{Location: api.ConvertLocation(rawlocs[i].Call)}
if cfg != nil && rawlocs[i].Current.Fn != nil {
var err error
scope := rawlocs[i].Scope(d.target.CurrentThread())
locals, err := scope.LocalVariables(*cfg)
if err != nil {
return nil, err
}
arguments, err := scope.FunctionArguments(*cfg)
if err != nil {
return nil, err
}
frame.Locals = convertVars(locals)
frame.Arguments = convertVars(arguments)
}
locations = append(locations, frame)
}
return locations, nil
}
// FindLocation will find the location specified by 'locStr'.
func (d *Debugger) FindLocation(scope api.EvalScope, locStr string) ([]api.Location, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
loc, err := parseLocationSpec(locStr)
if err != nil {
return nil, err
}
s, _ := d.target.ConvertEvalScope(scope.GoroutineID, scope.Frame)
locs, err := loc.Find(d, s, locStr)
for i := range locs {
file, line, fn := d.target.PCToLine(locs[i].PC)
locs[i].File = file
locs[i].Line = line
locs[i].Function = api.ConvertFunction(fn)
}
return locs, err
}
// Disassembles code between startPC and endPC
// if endPC == 0 it will find the function containing startPC and disassemble the whole function
func (d *Debugger) Disassemble(scope api.EvalScope, startPC, endPC uint64, flavour api.AssemblyFlavour) (api.AsmInstructions, error) {
d.processMutex.Lock()
defer d.processMutex.Unlock()
if endPC == 0 {
_, _, fn := d.target.PCToLine(startPC)
if fn == nil {
return nil, fmt.Errorf("Address 0x%x does not belong to any function", startPC)
}
startPC = fn.Entry
endPC = fn.End
}
currentGoroutine := true
thread := d.target.CurrentThread()
if s, err := d.target.ConvertEvalScope(scope.GoroutineID, scope.Frame); err == nil {
thread = s.Thread
if scope.GoroutineID != -1 {
g, _ := s.Thread.GetG()
if g == nil || g.ID != scope.GoroutineID {
currentGoroutine = false
}
}
}
insts, err := thread.Disassemble(startPC, endPC, currentGoroutine)
if err != nil {
return nil, err
}
disass := make(api.AsmInstructions, len(insts))
for i := range insts {
disass[i] = api.ConvertAsmInstruction(insts[i], insts[i].Text(proc.AssemblyFlavour(flavour)))
}
return disass, nil
}