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bee/vendor/github.com/derekparker/delve/pkg/proc/breakpoints.go

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2018-10-13 13:45:53 +00:00
package proc
import (
"errors"
"fmt"
"go/ast"
"go/constant"
"reflect"
)
// Breakpoint represents a breakpoint. Stores information on the break
// point including the byte of data that originally was stored at that
// address.
type Breakpoint struct {
// File & line information for printing.
FunctionName string
File string
Line int
Addr uint64 // Address breakpoint is set for.
OriginalData []byte // If software breakpoint, the data we replace with breakpoint instruction.
Name string // User defined name of the breakpoint
ID int // Monotonically increasing ID.
// Kind describes whether this is an internal breakpoint (for next'ing or
// stepping).
// A single breakpoint can be both a UserBreakpoint and some kind of
// internal breakpoint, but it can not be two different kinds of internal
// breakpoint.
Kind BreakpointKind
// Breakpoint information
Tracepoint bool // Tracepoint flag
Goroutine bool // Retrieve goroutine information
Stacktrace int // Number of stack frames to retrieve
Variables []string // Variables to evaluate
LoadArgs *LoadConfig
LoadLocals *LoadConfig
HitCount map[int]uint64 // Number of times a breakpoint has been reached in a certain goroutine
TotalHitCount uint64 // Number of times a breakpoint has been reached
// DeferReturns: when kind == NextDeferBreakpoint this breakpoint
// will also check if the caller is runtime.gopanic or if the return
// address is in the DeferReturns array.
// Next uses NextDeferBreakpoints for the breakpoint it sets on the
// deferred function, DeferReturns is populated with the
// addresses of calls to runtime.deferreturn in the current
// function. This insures that the breakpoint on the deferred
// function only triggers on panic or on the defer call to
// the function, not when the function is called directly
DeferReturns []uint64
// Cond: if not nil the breakpoint will be triggered only if evaluating Cond returns true
Cond ast.Expr
// internalCond is the same as Cond but used for the condition of internal breakpoints
internalCond ast.Expr
// ReturnInfo describes how to collect return variables when this
// breakpoint is hit as a return breakpoint.
returnInfo *returnBreakpointInfo
}
// BreakpointKind determines the behavior of delve when the
// breakpoint is reached.
type BreakpointKind uint16
const (
// UserBreakpoint is a user set breakpoint
UserBreakpoint BreakpointKind = (1 << iota)
// NextBreakpoint is a breakpoint set by Next, Continue
// will stop on it and delete it
NextBreakpoint
// NextDeferBreakpoint is a breakpoint set by Next on the
// first deferred function. In addition to checking their condition
// breakpoints of this kind will also check that the function has been
// called by runtime.gopanic or through runtime.deferreturn.
NextDeferBreakpoint
// StepBreakpoint is a breakpoint set by Step on a CALL instruction,
// Continue will set a new breakpoint (of NextBreakpoint kind) on the
// destination of CALL, delete this breakpoint and then continue again
StepBreakpoint
)
func (bp *Breakpoint) String() string {
return fmt.Sprintf("Breakpoint %d at %#v %s:%d (%d)", bp.ID, bp.Addr, bp.File, bp.Line, bp.TotalHitCount)
}
// BreakpointExistsError is returned when trying to set a breakpoint at
// an address that already has a breakpoint set for it.
type BreakpointExistsError struct {
File string
Line int
Addr uint64
}
func (bpe BreakpointExistsError) Error() string {
return fmt.Sprintf("Breakpoint exists at %s:%d at %x", bpe.File, bpe.Line, bpe.Addr)
}
// InvalidAddressError represents the result of
// attempting to set a breakpoint at an invalid address.
type InvalidAddressError struct {
Address uint64
}
func (iae InvalidAddressError) Error() string {
return fmt.Sprintf("Invalid address %#v\n", iae.Address)
}
type returnBreakpointInfo struct {
retFrameCond ast.Expr
fn *Function
frameOffset int64
spOffset int64
}
// CheckCondition evaluates bp's condition on thread.
func (bp *Breakpoint) CheckCondition(thread Thread) BreakpointState {
bpstate := BreakpointState{Breakpoint: bp, Active: false, Internal: false, CondError: nil}
if bp.Cond == nil && bp.internalCond == nil {
bpstate.Active = true
bpstate.Internal = bp.IsInternal()
return bpstate
}
nextDeferOk := true
if bp.Kind&NextDeferBreakpoint != 0 {
frames, err := ThreadStacktrace(thread, 2)
if err == nil {
ispanic := len(frames) >= 3 && frames[2].Current.Fn != nil && frames[2].Current.Fn.Name == "runtime.gopanic"
isdeferreturn := false
if len(frames) >= 1 {
for _, pc := range bp.DeferReturns {
if frames[0].Ret == pc {
isdeferreturn = true
break
}
}
}
nextDeferOk = ispanic || isdeferreturn
}
}
if bp.IsInternal() {
// Check internalCondition if this is also an internal breakpoint
bpstate.Active, bpstate.CondError = evalBreakpointCondition(thread, bp.internalCond)
bpstate.Active = bpstate.Active && nextDeferOk
if bpstate.Active || bpstate.CondError != nil {
bpstate.Internal = true
return bpstate
}
}
if bp.IsUser() {
// Check normal condition if this is also a user breakpoint
bpstate.Active, bpstate.CondError = evalBreakpointCondition(thread, bp.Cond)
}
return bpstate
}
// IsInternal returns true if bp is an internal breakpoint.
// User-set breakpoints can overlap with internal breakpoints, in that case
// both IsUser and IsInternal will be true.
func (bp *Breakpoint) IsInternal() bool {
return bp.Kind != UserBreakpoint
}
// IsUser returns true if bp is a user-set breakpoint.
// User-set breakpoints can overlap with internal breakpoints, in that case
// both IsUser and IsInternal will be true.
func (bp *Breakpoint) IsUser() bool {
return bp.Kind&UserBreakpoint != 0
}
func evalBreakpointCondition(thread Thread, cond ast.Expr) (bool, error) {
if cond == nil {
return true, nil
}
scope, err := GoroutineScope(thread)
if err != nil {
return true, err
}
v, err := scope.evalAST(cond)
if err != nil {
return true, fmt.Errorf("error evaluating expression: %v", err)
}
if v.Kind != reflect.Bool {
return true, errors.New("condition expression not boolean")
}
v.loadValue(loadFullValue)
if v.Unreadable != nil {
return true, fmt.Errorf("condition expression unreadable: %v", v.Unreadable)
}
return constant.BoolVal(v.Value), nil
}
// NoBreakpointError is returned when trying to
// clear a breakpoint that does not exist.
type NoBreakpointError struct {
Addr uint64
}
func (nbp NoBreakpointError) Error() string {
return fmt.Sprintf("no breakpoint at %#v", nbp.Addr)
}
// BreakpointMap represents an (address, breakpoint) map.
type BreakpointMap struct {
M map[uint64]*Breakpoint
breakpointIDCounter int
internalBreakpointIDCounter int
}
// NewBreakpointMap creates a new BreakpointMap.
func NewBreakpointMap() BreakpointMap {
return BreakpointMap{
M: make(map[uint64]*Breakpoint),
}
}
// ResetBreakpointIDCounter resets the breakpoint ID counter of bpmap.
func (bpmap *BreakpointMap) ResetBreakpointIDCounter() {
bpmap.breakpointIDCounter = 0
}
type writeBreakpointFn func(addr uint64) (file string, line int, fn *Function, originalData []byte, err error)
type clearBreakpointFn func(*Breakpoint) error
// Set creates a breakpoint at addr calling writeBreakpoint. Do not call this
// function, call proc.Process.SetBreakpoint instead, this function exists
// to implement proc.Process.SetBreakpoint.
func (bpmap *BreakpointMap) Set(addr uint64, kind BreakpointKind, cond ast.Expr, writeBreakpoint writeBreakpointFn) (*Breakpoint, error) {
if bp, ok := bpmap.M[addr]; ok {
// We can overlap one internal breakpoint with one user breakpoint, we
// need to support this otherwise a conditional breakpoint can mask a
// breakpoint set by next or step.
if (kind != UserBreakpoint && bp.Kind != UserBreakpoint) || (kind == UserBreakpoint && bp.IsUser()) {
return bp, BreakpointExistsError{bp.File, bp.Line, bp.Addr}
}
bp.Kind |= kind
if kind != UserBreakpoint {
bp.internalCond = cond
} else {
bp.Cond = cond
}
return bp, nil
}
f, l, fn, originalData, err := writeBreakpoint(addr)
if err != nil {
return nil, err
}
newBreakpoint := &Breakpoint{
FunctionName: fn.Name,
File: f,
Line: l,
Addr: addr,
Kind: kind,
OriginalData: originalData,
HitCount: map[int]uint64{},
}
if kind != UserBreakpoint {
bpmap.internalBreakpointIDCounter++
newBreakpoint.ID = bpmap.internalBreakpointIDCounter
newBreakpoint.internalCond = cond
} else {
bpmap.breakpointIDCounter++
newBreakpoint.ID = bpmap.breakpointIDCounter
newBreakpoint.Cond = cond
}
bpmap.M[addr] = newBreakpoint
return newBreakpoint, nil
}
// SetWithID creates a breakpoint at addr, with the specified ID.
func (bpmap *BreakpointMap) SetWithID(id int, addr uint64, writeBreakpoint writeBreakpointFn) (*Breakpoint, error) {
bp, err := bpmap.Set(addr, UserBreakpoint, nil, writeBreakpoint)
if err == nil {
bp.ID = id
bpmap.breakpointIDCounter--
}
return bp, err
}
// Clear clears the breakpoint at addr.
// Do not call this function call proc.Process.ClearBreakpoint instead.
func (bpmap *BreakpointMap) Clear(addr uint64, clearBreakpoint clearBreakpointFn) (*Breakpoint, error) {
bp, ok := bpmap.M[addr]
if !ok {
return nil, NoBreakpointError{Addr: addr}
}
bp.Kind &= ^UserBreakpoint
bp.Cond = nil
if bp.Kind != 0 {
return bp, nil
}
if err := clearBreakpoint(bp); err != nil {
return nil, err
}
delete(bpmap.M, addr)
return bp, nil
}
// ClearInternalBreakpoints removes all internal breakpoints from the map,
// calling clearBreakpoint on each one.
// Do not call this function, call proc.Process.ClearInternalBreakpoints
// instead, this function is used to implement that.
func (bpmap *BreakpointMap) ClearInternalBreakpoints(clearBreakpoint clearBreakpointFn) error {
for addr, bp := range bpmap.M {
bp.Kind = bp.Kind & UserBreakpoint
bp.internalCond = nil
bp.returnInfo = nil
if bp.Kind != 0 {
continue
}
if err := clearBreakpoint(bp); err != nil {
return err
}
delete(bpmap.M, addr)
}
return nil
}
// HasInternalBreakpoints returns true if bpmap has at least one internal
// breakpoint set.
func (bpmap *BreakpointMap) HasInternalBreakpoints() bool {
for _, bp := range bpmap.M {
if bp.IsInternal() {
return true
}
}
return false
}
// BreakpointState describes the state of a breakpoint in a thread.
type BreakpointState struct {
*Breakpoint
// Active is true if the breakpoint condition was met.
Active bool
// Internal is true if the breakpoint was matched as an internal
// breakpoint.
Internal bool
// CondError contains any error encountered while evaluating the
// breakpoint's condition.
CondError error
}
// Clear zeros the struct.
func (bpstate *BreakpointState) Clear() {
bpstate.Breakpoint = nil
bpstate.Active = false
bpstate.Internal = false
bpstate.CondError = nil
}
func (bpstate *BreakpointState) String() string {
s := bpstate.Breakpoint.String()
if bpstate.Active {
s += " active"
}
if bpstate.Internal {
s += " internal"
}
return s
}
func configureReturnBreakpoint(bi *BinaryInfo, bp *Breakpoint, topframe *Stackframe, retFrameCond ast.Expr) {
if topframe.Current.Fn == nil {
return
}
bp.returnInfo = &returnBreakpointInfo{
retFrameCond: retFrameCond,
fn: topframe.Current.Fn,
frameOffset: topframe.FrameOffset(),
spOffset: topframe.FrameOffset() - int64(bi.Arch.PtrSize()), // must be the value that SP had at the entry point of the function
}
}
func (rbpi *returnBreakpointInfo) Collect(thread Thread) []*Variable {
if rbpi == nil {
return nil
}
g, err := GetG(thread)
if err != nil {
return returnInfoError("could not get g", err, thread)
}
scope, err := GoroutineScope(thread)
if err != nil {
return returnInfoError("could not get scope", err, thread)
}
v, err := scope.evalAST(rbpi.retFrameCond)
if err != nil || v.Unreadable != nil || v.Kind != reflect.Bool {
// This condition was evaluated as part of the breakpoint condition
// evaluation, if the errors happen they will be reported as part of the
// condition errors.
return nil
}
if !constant.BoolVal(v.Value) {
// Breakpoint not hit as a return breakpoint.
return nil
}
oldFrameOffset := rbpi.frameOffset + int64(g.stackhi)
oldSP := uint64(rbpi.spOffset + int64(g.stackhi))
err = fakeFunctionEntryScope(scope, rbpi.fn, oldFrameOffset, oldSP)
if err != nil {
return returnInfoError("could not read function entry", err, thread)
}
vars, err := scope.Locals()
if err != nil {
return returnInfoError("could not evaluate return variables", err, thread)
}
vars = filterVariables(vars, func(v *Variable) bool {
return (v.Flags & VariableReturnArgument) != 0
})
// Go saves the return variables in the opposite order that the user
// specifies them so here we reverse the slice to make it easier to
// understand.
for i := 0; i < len(vars)/2; i++ {
vars[i], vars[len(vars)-i-1] = vars[len(vars)-i-1], vars[i]
}
return vars
}
func returnInfoError(descr string, err error, mem MemoryReadWriter) []*Variable {
v := newConstant(constant.MakeString(fmt.Sprintf("%s: %v", descr, err.Error())), mem)
v.Name = "return value read error"
return []*Variable{v}
}