proc

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Published: May 24, 2020 License: MIT Imports: 40 Imported by: 0

Documentation

Overview

Package proc is a low-level package that provides methods to manipulate the process we are debugging.

proc implements all core functionality including: * creating / attaching to a process * process manipulation (step, next, continue, halt) * methods to explore the memory of the process

Index

Constants

View Source
const (
	// UnrecoveredPanic is the name given to the unrecovered panic breakpoint.
	UnrecoveredPanic = "unrecovered-panic"

	// FatalThrow is the name given to the breakpoint triggered when the target
	// process dies because of a fatal runtime error.
	FatalThrow = "runtime-fatal-throw"
)
View Source
const (
	// GNUFlavour will display GNU assembly syntax.
	GNUFlavour = AssemblyFlavour(iota)
	// IntelFlavour will display Intel assembly syntax.
	IntelFlavour
	// GoFlavour will display Go assembly syntax.
	GoFlavour
)
View Source
const (
	IMAGE_FILE_MACHINE_UNKNOWN   = 0x0
	IMAGE_FILE_MACHINE_AM33      = 0x1d3
	IMAGE_FILE_MACHINE_AMD64     = 0x8664
	IMAGE_FILE_MACHINE_ARM       = 0x1c0
	IMAGE_FILE_MACHINE_ARMNT     = 0x1c4
	IMAGE_FILE_MACHINE_ARM64     = 0xaa64
	IMAGE_FILE_MACHINE_EBC       = 0xebc
	IMAGE_FILE_MACHINE_I386      = 0x14c
	IMAGE_FILE_MACHINE_IA64      = 0x200
	IMAGE_FILE_MACHINE_M32R      = 0x9041
	IMAGE_FILE_MACHINE_MIPS16    = 0x266
	IMAGE_FILE_MACHINE_MIPSFPU   = 0x366
	IMAGE_FILE_MACHINE_MIPSFPU16 = 0x466
	IMAGE_FILE_MACHINE_POWERPC   = 0x1f0
	IMAGE_FILE_MACHINE_POWERPCFP = 0x1f1
	IMAGE_FILE_MACHINE_R4000     = 0x166
	IMAGE_FILE_MACHINE_SH3       = 0x1a2
	IMAGE_FILE_MACHINE_SH3DSP    = 0x1a3
	IMAGE_FILE_MACHINE_SH4       = 0x1a6
	IMAGE_FILE_MACHINE_SH5       = 0x1a8
	IMAGE_FILE_MACHINE_THUMB     = 0x1c2
	IMAGE_FILE_MACHINE_WCEMIPSV2 = 0x169
)
View Source
const (
	// FloatIsNormal means the value is a normal float.
	FloatIsNormal floatSpecial = iota
	// FloatIsNaN means the float is a special NaN value.
	FloatIsNaN
	// FloatIsPosInf means the float is a special positive inifitiy value.
	FloatIsPosInf
	// FloatIsNegInf means the float is a special negative infinity value.
	FloatIsNegInf
)
View Source
const (
	// VariableEscaped is set for local variables that escaped to the heap
	//
	// The compiler performs escape analysis on local variables, the variables
	// that may outlive the stack frame are allocated on the heap instead and
	// only the address is recorded on the stack. These variables will be
	// marked with this flag.
	VariableEscaped variableFlags = (1 << iota)
	// VariableShadowed is set for local variables that are shadowed by a
	// variable with the same name in another scope
	VariableShadowed
	// VariableConstant means this variable is a constant value
	VariableConstant
	// VariableArgument means this variable is a function argument
	VariableArgument
	// VariableReturnArgument means this variable is a function return value
	VariableReturnArgument
	// VariableFakeAddress means the address of this variable is either fake
	// (i.e. the variable is partially or completely stored in a CPU register
	// and doesn't have a real address) or possibly no longer availabe (because
	// the variable is the return value of a function call and allocated on a
	// frame that no longer exists)
	VariableFakeAddress
)
View Source
const (
	Gidle           uint64 = iota // 0
	Grunnable                     // 1 runnable and on a run queue
	Grunning                      // 2
	Gsyscall                      // 3
	Gwaiting                      // 4
	GmoribundUnused               // 5 currently unused, but hardcoded in gdb scripts
	Gdead                         // 6
	Genqueue                      // 7 Only the Gscanenqueue is used.
	Gcopystack                    // 8 in this state when newstack is moving the stack
)

G status, from: src/runtime/runtime2.go

View Source
const STT_FUNC = 2

STT_FUNC is a code object, see /usr/include/elf.h for a full definition.

Variables

View Source
var (
	// ErrCouldNotDetermineRelocation is an error returned when Delve could not determine the base address of a
	// position independant executable.
	ErrCouldNotDetermineRelocation = errors.New("could not determine the base address of a PIE")

	// ErrNoDebugInfoFound is returned when Delve cannot open the debug_info
	// section or find an external debug info file.
	ErrNoDebugInfoFound = errors.New("could not open debug info")
)
View Source
var (
	// ErrNotRecorded is returned when an action is requested that is
	// only possible on recorded (traced) programs.
	ErrNotRecorded = errors.New("not a recording")

	// ErrNoRuntimeAllG is returned when the runtime.allg list could
	// not be found.
	ErrNoRuntimeAllG = errors.New("could not find goroutine array")

	// ErrProcessDetached indicates that we detached from the target process.
	ErrProcessDetached = errors.New("detached from the process")
)
View Source
var ErrUnknownRegister = errors.New("unknown register")

ErrUnknownRegister is returned when the value of an unknown register is requested.

View Source
var ErrUnreadableG = errors.New("could not read G struct")

PEMachineString map pe machine to name, See $GOROOT/src/debug/pe/pe.go for detail

Functions

func DisableAsyncPreemptEnv

func DisableAsyncPreemptEnv() []string

DisableAsyncPreemptEnv returns a process environment (like os.Environ) where asyncpreemptoff is set to 1.

func EvalExpressionWithCalls

func EvalExpressionWithCalls(t *Target, g *G, expr string, retLoadCfg LoadConfig, checkEscape bool) error

EvalExpressionWithCalls is like EvalExpression but allows function calls in 'expr'. Because this can only be done in the current goroutine, unlike EvalExpression, EvalExpressionWithCalls is not a method of EvalScope.

func FindDeferReturnCalls

func FindDeferReturnCalls(text []AsmInstruction) []uint64

func FindFileLocation

func FindFileLocation(p Process, fileName string, lineno int) ([]uint64, error)

FindFileLocation returns the PC for a given file:line. Assumes that `file` is normalized to lower case and '/' on Windows.

func FindFunctionLocation

func FindFunctionLocation(p Process, funcName string, lineOffset int) ([]uint64, error)

FindFunctionLocation finds address of a function's line If lineOffset is passed FindFunctionLocation will return the address of that line

func FirstPCAfterPrologue

func FirstPCAfterPrologue(p Process, fn *Function, sameline bool) (uint64, error)

FirstPCAfterPrologue returns the address of the first instruction after the prologue for function fn. If sameline is set FirstPCAfterPrologue will always return an address associated with the same line as fn.Entry.

Types

type Ancestor

type Ancestor struct {
	ID         int64 // Goroutine ID
	Unreadable error
	// contains filtered or unexported fields
}

func Ancestors

func Ancestors(p Process, g *G, n int) ([]Ancestor, error)

Ancestors returns the list of ancestors for g.

func (*Ancestor) Stack

func (a *Ancestor) Stack(n int) ([]Stackframe, error)

Stack returns the stack trace of ancestor 'a' as saved by the runtime.

type Arch

type Arch struct {
	Name string // architecture name

	// RegistersToDwarfRegisters maps hardware registers to DWARF registers.
	RegistersToDwarfRegisters func(uint64, Registers) op.DwarfRegisters

	// DwarfRegisterToString returns the name and value representation of the given register.
	DwarfRegisterToString func(int, *op.DwarfRegister) (string, bool, string)
	// contains filtered or unexported fields
}

Arch represents a CPU architecture.

func AMD64Arch

func AMD64Arch(goos string) *Arch

AMD64Arch returns an initialized AMD64 struct.

func ARM64Arch

func ARM64Arch(goos string) *Arch

ARM64Arch returns an initialized ARM64 struct.

func I386Arch

func I386Arch(goos string) *Arch

I386Arch returns an initialized I386Arch struct.

func (*Arch) BreakInstrMovesPC

func (a *Arch) BreakInstrMovesPC() bool

BreakInstrMovesPC is true if hitting the breakpoint instruction advances the instruction counter by the size of the breakpoint instruction.

func (*Arch) BreakpointInstruction

func (a *Arch) BreakpointInstruction() []byte

BreakpointInstruction is the instruction that will trigger a breakpoint trap for the given architecture.

func (*Arch) BreakpointSize

func (a *Arch) BreakpointSize() int

BreakpointSize is the size of the breakpoint instruction for the given architecture.

func (*Arch) DerefTLS

func (a *Arch) DerefTLS() bool

DerefTLS is true if the G struct stored in the TLS section is a pointer and the address must be dereferenced to find to actual G struct.

func (*Arch) MaxInstructionLength

func (a *Arch) MaxInstructionLength() int

MaxInstructionLength is the maximum size in bytes of an instruction.

func (*Arch) Prologues

func (a *Arch) Prologues() []opcodeSeq

Prologues returns a list of stack split prologues that are inserted at function entry.

func (*Arch) PtrSize

func (a *Arch) PtrSize() int

PtrSize returns the size of a pointer for the architecture.

type AsmInstruction

type AsmInstruction struct {
	Loc        Location
	DestLoc    *Location
	Bytes      []byte
	Breakpoint bool
	AtPC       bool

	Size int
	Kind AsmInstructionKind

	Inst archInst
}

AsmInstruction represents one assembly instruction.

func Disassemble

func Disassemble(mem MemoryReadWriter, regs Registers, breakpoints *BreakpointMap, bi *BinaryInfo, startAddr, endAddr uint64) ([]AsmInstruction, error)

Disassemble disassembles target memory between startAddr and endAddr, marking the current instruction being executed in goroutine g. If currentGoroutine is set and thread is stopped at a CALL instruction Disassemble will evaluate the argument of the CALL instruction using the thread's registers. Be aware that the Bytes field of each returned instruction is a slice of a larger array of size startAddr - endAddr.

func (*AsmInstruction) IsCall

func (instr *AsmInstruction) IsCall() bool

IsCall is true if instr is a call instruction.

func (*AsmInstruction) IsJmp

func (instr *AsmInstruction) IsJmp() bool

IsJmp is true if instr is an unconditional jump instruction.

func (*AsmInstruction) IsRet

func (instr *AsmInstruction) IsRet() bool

IsRet is true if instr is a return instruction.

func (*AsmInstruction) Text

func (inst *AsmInstruction) Text(flavour AssemblyFlavour, bi *BinaryInfo) string

Text will return the assembly instructions in human readable format according to the flavour specified.

type AsmInstructionKind

type AsmInstructionKind uint8
const (
	OtherInstruction AsmInstructionKind = iota
	CallInstruction
	RetInstruction
	JmpInstruction
)

type AssemblyFlavour

type AssemblyFlavour int

AssemblyFlavour is the assembly syntax to display.

type BinaryInfo

type BinaryInfo struct {
	// Architecture of this binary.
	Arch *Arch

	// GOOS operating system this binary is executing on.
	GOOS string

	// Functions is a list of all DW_TAG_subprogram entries in debug_info, sorted by entry point
	Functions []Function
	// Sources is a list of all source files found in debug_line.
	Sources []string
	// LookupFunc maps function names to a description of the function.
	LookupFunc map[string]*Function

	// SymNames maps addr to a description *elf.Symbol of this addr.
	SymNames map[uint64]*elf.Symbol

	// Images is a list of loaded shared libraries (also known as
	// shared objects on linux or DLLs on windows).
	Images []*Image

	ElfDynamicSection ElfDynamicSection

	// PackageMap maps package names to package paths, needed to lookup types inside DWARF info.
	// On Go1.12 this mapping is determined by using the last element of a package path, for example:
	//   github.com/deyuhua/delve
	// will map to 'delve' because it ends in '/delve'.
	// Starting with Go1.13 debug_info will contain a special attribute
	// (godwarf.AttrGoPackageName) containing the canonical package name for
	// each package.
	// If multiple packages have the same name the map entry will have more
	// than one item in the slice.
	PackageMap map[string][]string
	// contains filtered or unexported fields
}

BinaryInfo holds information on the binaries being executed (this includes both the executable and also any loaded libraries).

func NewBinaryInfo

func NewBinaryInfo(goos, goarch string) *BinaryInfo

NewBinaryInfo returns an initialized but unloaded BinaryInfo struct.

func (*BinaryInfo) AddImage

func (bi *BinaryInfo) AddImage(path string, addr uint64) error

AddImage adds the specified image to bi, loading data asynchronously. Addr is the relocated entry point for the executable and staticBase (i.e. the relocation offset) for all other images. The first image added must be the executable file.

func (*BinaryInfo) AllPCsForFileLines

func (bi *BinaryInfo) AllPCsForFileLines(filename string, linenos []int) map[int][]uint64

AllPCsForFileLines returns a map providing all PC addresses for filename and each line in linenos

func (*BinaryInfo) Close

func (bi *BinaryInfo) Close() error

Close closes all internal readers.

func (*BinaryInfo) GStructOffset

func (bi *BinaryInfo) GStructOffset() uint64

GStructOffset returns the offset of the G struct in thread local storage.

func (*BinaryInfo) LastModified

func (bi *BinaryInfo) LastModified() time.Time

LastModified returns the last modified time of the binary.

func (*BinaryInfo) LineToPC

func (bi *BinaryInfo) LineToPC(filename string, lineno int) (pcs []uint64, err error)

LineToPC converts a file:line into a list of matching memory addresses, corresponding to the first instruction matching the specified file:line in the containing function and all its inlined calls.

func (*BinaryInfo) ListPackagesBuildInfo

func (bi *BinaryInfo) ListPackagesBuildInfo(includeFiles bool) []*PackageBuildInfo

ListPackagesBuildInfo returns the list of packages used by the program along with the directory where each package was compiled and optionally the list of files constituting the package.

func (*BinaryInfo) LoadBinaryInfo

func (bi *BinaryInfo) LoadBinaryInfo(path string, entryPoint uint64, debugInfoDirs []string) error

LoadBinaryInfo will load and store the information from the binary at 'path'.

func (*BinaryInfo) LoadImageFromData

func (bi *BinaryInfo) LoadImageFromData(dwdata *dwarf.Data, debugFrameBytes, debugLineBytes, debugLocBytes []byte)

LoadImageFromData creates a new Image, using the specified data, and adds it to bi. This is used for debugging BinaryInfo, you should use LoadBinary instead.

func (*BinaryInfo) Location

func (bi *BinaryInfo) Location(entry godwarf.Entry, attr dwarf.Attr, pc uint64, regs op.DwarfRegisters) (int64, []op.Piece, *locationExpr, error)

Location returns the location described by attribute attr of entry. This will either be an int64 address or a slice of Pieces for locations that don't correspond to a single memory address (registers, composite locations).

func (*BinaryInfo) LocationCovers

func (bi *BinaryInfo) LocationCovers(entry *dwarf.Entry, attr dwarf.Attr) ([][2]uint64, error)

LocationCovers returns the list of PC addresses that is covered by the location attribute 'attr' of entry 'entry'.

func (*BinaryInfo) PCToFunc

func (bi *BinaryInfo) PCToFunc(pc uint64) *Function

PCToFunc returns the concrete function containing the given PC address. If the PC address belongs to an inlined call it will return the containing function.

func (*BinaryInfo) PCToImage

func (bi *BinaryInfo) PCToImage(pc uint64) *Image

PCToImage returns the image containing the given PC address.

func (*BinaryInfo) PCToInlineFunc

func (bi *BinaryInfo) PCToInlineFunc(pc uint64) *Function

PCToInlineFunc returns the function containing the given PC address. If the PC address belongs to an inlined call it will return the inlined function.

func (*BinaryInfo) PCToLine

func (bi *BinaryInfo) PCToLine(pc uint64) (string, int, *Function)

PCToLine converts an instruction address to a file/line/function.

func (*BinaryInfo) Producer

func (bi *BinaryInfo) Producer() string

Producer returns the value of DW_AT_producer.

func (*BinaryInfo) Types

func (bi *BinaryInfo) Types() ([]string, error)

Types returns list of types present in the debugged program.

type Breakpoint

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
	LogicalID    int    // ID of the logical breakpoint that owns this physical breakpoint

	// 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
	TraceReturn   bool
	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 ensures 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
	// contains filtered or unexported fields
}

Breakpoint represents a physical breakpoint. Stores information on the break point including the byte of data that originally was stored at that address.

func (*Breakpoint) CheckCondition

func (bp *Breakpoint) CheckCondition(thread Thread) BreakpointState

CheckCondition evaluates bp's condition on thread.

func (*Breakpoint) IsInternal

func (bp *Breakpoint) IsInternal() bool

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 (*Breakpoint) IsUser

func (bp *Breakpoint) IsUser() bool

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 (*Breakpoint) String

func (bp *Breakpoint) String() string

type BreakpointExistsError

type BreakpointExistsError struct {
	File string
	Line int
	Addr uint64
}

BreakpointExistsError is returned when trying to set a breakpoint at an address that already has a breakpoint set for it.

func (BreakpointExistsError) Error

func (bpe BreakpointExistsError) Error() string

type BreakpointKind

type BreakpointKind uint16

BreakpointKind determines the behavior of delve when the breakpoint is reached.

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
)

type BreakpointManipulation

type BreakpointManipulation interface {
	Breakpoints() *BreakpointMap
	SetBreakpoint(addr uint64, kind BreakpointKind, cond ast.Expr) (*Breakpoint, error)
	ClearBreakpoint(addr uint64) (*Breakpoint, error)
	ClearInternalBreakpoints() error
}

BreakpointManipulation is an interface for managing breakpoints.

type BreakpointMap

type BreakpointMap struct {
	M map[uint64]*Breakpoint
	// contains filtered or unexported fields
}

BreakpointMap represents an (address, breakpoint) map.

func NewBreakpointMap

func NewBreakpointMap() BreakpointMap

NewBreakpointMap creates a new BreakpointMap.

func (*BreakpointMap) Clear

func (bpmap *BreakpointMap) Clear(addr uint64, clearBreakpoint clearBreakpointFn) (*Breakpoint, error)

Clear clears the breakpoint at addr. Do not call this function call proc.Process.ClearBreakpoint instead.

func (*BreakpointMap) ClearInternalBreakpoints

func (bpmap *BreakpointMap) ClearInternalBreakpoints(clearBreakpoint clearBreakpointFn) error

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 (*BreakpointMap) HasInternalBreakpoints

func (bpmap *BreakpointMap) HasInternalBreakpoints() bool

HasInternalBreakpoints returns true if bpmap has at least one internal breakpoint set.

func (*BreakpointMap) ResetBreakpointIDCounter

func (bpmap *BreakpointMap) ResetBreakpointIDCounter()

ResetBreakpointIDCounter resets the breakpoint ID counter of bpmap.

func (*BreakpointMap) Set

func (bpmap *BreakpointMap) Set(addr uint64, kind BreakpointKind, cond ast.Expr, writeBreakpoint WriteBreakpointFn) (*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 (*BreakpointMap) SetWithID

func (bpmap *BreakpointMap) SetWithID(id int, addr uint64, writeBreakpoint WriteBreakpointFn) (*Breakpoint, error)

SetWithID creates a breakpoint at addr, with the specified logical ID.

type BreakpointState

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
}

BreakpointState describes the state of a breakpoint in a thread.

func (*BreakpointState) Clear

func (bpstate *BreakpointState) Clear()

Clear zeros the struct.

func (*BreakpointState) String

func (bpstate *BreakpointState) String() string

type Checkpoint

type Checkpoint struct {
	ID    int
	When  string
	Where string
}

Checkpoint is a checkpoint

type CommonThread

type CommonThread struct {
	// contains filtered or unexported fields
}

CommonThread contains fields used by this package, common to all implementations of the Thread interface.

func (*CommonThread) ReturnValues

func (t *CommonThread) ReturnValues(cfg LoadConfig) []*Variable

ReturnValues reads the return values from the function executing on this thread using the provided LoadConfig.

type CpuArch

type CpuArch interface {
	String() string
}

CpuArch is a stringer interface representing CPU architectures.

type Defer

type Defer struct {
	DeferredPC uint64 // Value of field _defer.fn.fn, the deferred function
	DeferPC    uint64 // PC address of instruction that added this defer
	SP         uint64 // Value of SP register when this function was deferred (this field gets adjusted when the stack is moved to match the new stack space)

	Unreadable error
	// contains filtered or unexported fields
}

Defer represents one deferred call

func (*Defer) EvalScope

func (d *Defer) EvalScope(thread Thread) (*EvalScope, error)

EvalScope returns an EvalScope relative to the argument frame of this deferred call. The argument frame of a deferred call is stored in memory immediately after the deferred header.

func (*Defer) Next

func (d *Defer) Next() *Defer

Next returns the next defer in the linked list

type Direction

type Direction int8

Direction is the direction of execution for the target process.

const (
	// Forward direction executes the target normally.
	Forward Direction = 0
	// Backward direction executes the target in reverse.
	Backward Direction = 1
)

type ElfDynamicSection

type ElfDynamicSection struct {
	Addr uint64 // relocated address of where the .dynamic section is mapped in memory
	Size uint64 // size of the .dynamic section of the executable
}

ElfDynamicSection describes the .dynamic section of an ELF executable.

type ErrCouldNotFindLine

type ErrCouldNotFindLine struct {
	// contains filtered or unexported fields
}

func (*ErrCouldNotFindLine) Error

func (err *ErrCouldNotFindLine) Error() string

type ErrFunctionNotFound

type ErrFunctionNotFound struct {
	FuncName string
}

ErrFunctionNotFound is returned when failing to find the function named 'FuncName' within the binary.

func (*ErrFunctionNotFound) Error

func (err *ErrFunctionNotFound) Error() string

type ErrNoBuildIDNote

type ErrNoBuildIDNote struct{}

ErrNoBuildIDNote is used in openSeparateDebugInfo to signal there's no build-id note on the binary, so LoadBinaryInfoElf will return the error message coming from elfFile.DWARF() instead.

func (*ErrNoBuildIDNote) Error

func (e *ErrNoBuildIDNote) Error() string

type ErrNoGoroutine

type ErrNoGoroutine struct {
	// contains filtered or unexported fields
}

ErrNoGoroutine returned when a G could not be found for a specific thread.

func (ErrNoGoroutine) Error

func (ng ErrNoGoroutine) Error() string

type ErrNoSourceForPC

type ErrNoSourceForPC struct {
	// contains filtered or unexported fields
}

ErrNoSourceForPC is returned when the given address does not correspond with a source file location.

func (*ErrNoSourceForPC) Error

func (err *ErrNoSourceForPC) Error() string

type ErrProcessExited

type ErrProcessExited struct {
	Pid    int
	Status int
}

ErrProcessExited indicates that the process has exited and contains both process id and exit status.

func (ErrProcessExited) Error

func (pe ErrProcessExited) Error() string

type ErrThreadBlocked

type ErrThreadBlocked struct{}

ErrThreadBlocked is returned when the thread is blocked in the scheduler.

func (ErrThreadBlocked) Error

func (tbe ErrThreadBlocked) Error() string

type ErrUnsupportedArch

type ErrUnsupportedArch struct {
	// contains filtered or unexported fields
}

ErrUnsupportedArch is returned when attempting to debug a binary compiled for an unsupported architecture.

func (*ErrUnsupportedArch) Error

func (e *ErrUnsupportedArch) Error() string

type EvalScope

type EvalScope struct {
	Location
	Regs op.DwarfRegisters
	Mem  MemoryReadWriter // Target's memory

	BinInfo *BinaryInfo
	// contains filtered or unexported fields
}

EvalScope is the scope for variable evaluation. Contains the thread, current location (PC), and canonical frame address.

func ConvertEvalScope

func ConvertEvalScope(dbp *Target, gid, frame, deferCall int) (*EvalScope, error)

ConvertEvalScope returns a new EvalScope in the context of the specified goroutine ID and stack frame. If deferCall is > 0 the eval scope will be relative to the specified deferred call.

func FrameToScope

func FrameToScope(bi *BinaryInfo, thread MemoryReadWriter, g *G, frames ...Stackframe) *EvalScope

FrameToScope returns a new EvalScope for frames[0]. If frames has at least two elements all memory between frames[0].Regs.SP() and frames[1].Regs.CFA will be cached. Otherwise all memory between frames[0].Regs.SP() and frames[0].Regs.CFA will be cached.

func GoroutineScope

func GoroutineScope(thread Thread) (*EvalScope, error)

GoroutineScope returns an EvalScope for the goroutine running on the given thread.

func ThreadScope

func ThreadScope(thread Thread) (*EvalScope, error)

ThreadScope returns an EvalScope for the given thread.

func (*EvalScope) DwarfReader

func (scope *EvalScope) DwarfReader() *reader.Reader

DwarfReader returns the DwarfReader containing the Dwarf information for the target process.

func (*EvalScope) EvalExpression

func (scope *EvalScope) EvalExpression(expr string, cfg LoadConfig) (*Variable, error)

EvalExpression returns the value of the given expression.

func (*EvalScope) EvalVariable

func (scope *EvalScope) EvalVariable(name string, cfg LoadConfig) (*Variable, error)

EvalVariable returns the value of the given expression (backwards compatibility).

func (*EvalScope) FunctionArguments

func (scope *EvalScope) FunctionArguments(cfg LoadConfig) ([]*Variable, error)

FunctionArguments returns the name, value, and type of all current function arguments.

func (*EvalScope) LocalVariables

func (scope *EvalScope) LocalVariables(cfg LoadConfig) ([]*Variable, error)

LocalVariables returns all local variables from the current function scope.

func (*EvalScope) Locals

func (scope *EvalScope) Locals() ([]*Variable, error)

Locals fetches all variables of a specific type in the current function scope.

func (*EvalScope) PackageVariables

func (scope *EvalScope) PackageVariables(cfg LoadConfig) ([]*Variable, error)

PackageVariables returns the name, value, and type of all package variables in the application.

func (*EvalScope) PtrSize

func (scope *EvalScope) PtrSize() int

PtrSize returns the size of a pointer.

func (*EvalScope) SetVariable

func (scope *EvalScope) SetVariable(name, value string) error

SetVariable sets the value of the named variable

type Function

type Function struct {
	Name       string
	Entry, End uint64 // same as DW_AT_lowpc and DW_AT_highpc

	// InlinedCalls lists all inlined calls to this function
	InlinedCalls []InlinedCall
	// contains filtered or unexported fields
}

Function describes a function in the target program.

func (*Function) BaseName

func (fn *Function) BaseName() string

BaseName returns the symbol name without the package or receiver name. Borrowed from $GOROOT/debug/gosym/symtab.go

func (*Function) Optimized

func (fn *Function) Optimized() bool

Optimized returns true if the function was optimized by the compiler.

func (*Function) PackageName

func (fn *Function) PackageName() string

PackageName returns the package part of the symbol name, or the empty string if there is none. Borrowed from $GOROOT/debug/gosym/symtab.go

func (*Function) PrologueEndPC

func (fn *Function) PrologueEndPC() uint64

PrologueEndPC returns the PC just after the function prologue

func (*Function) ReceiverName

func (fn *Function) ReceiverName() string

ReceiverName returns the receiver type name of this symbol, or the empty string if there is none. Borrowed from $GOROOT/debug/gosym/symtab.go

type G

type G struct {
	ID      int    // Goroutine ID
	PC      uint64 // PC of goroutine when it was parked.
	SP      uint64 // SP of goroutine when it was parked.
	BP      uint64 // BP of goroutine when it was parked (go >= 1.7).
	LR      uint64 // LR of goroutine when it was parked.
	GoPC    uint64 // PC of 'go' statement that created this goroutine.
	StartPC uint64 // PC of the first function run on this goroutine.
	Status  uint64

	SystemStack bool // SystemStack is true if this goroutine is currently executing on a system stack.

	// Information on goroutine location
	CurrentLoc Location

	// Thread that this goroutine is currently allocated to
	Thread Thread

	Unreadable error // could not read the G struct
	// contains filtered or unexported fields
}

G represents a runtime G (goroutine) structure (at least the fields that Delve is interested in).

func FindGoroutine

func FindGoroutine(dbp *Target, gid int) (*G, error)

FindGoroutine returns a G struct representing the goroutine specified by `gid`.

func GetG

func GetG(thread Thread) (*G, error)

GetG returns information on the G (goroutine) that is executing on this thread.

The G structure for a thread is stored in thread local storage. Here we simply calculate the address and read and parse the G struct.

We cannot simply use the allg linked list in order to find the M that represents the given OS thread and follow its G pointer because on Darwin mach ports are not universal, so our port for this thread would not map to the `id` attribute of the M structure. Also, when linked against libc, Go prefers the libc version of clone as opposed to the runtime version. This has the consequence of not setting M.id for any thread, regardless of OS.

In order to get around all this craziness, we read the address of the G structure for the current thread from the thread local storage area.

func GoroutinesInfo

func GoroutinesInfo(dbp *Target, start, count int) ([]*G, int, error)

GoroutinesInfo searches for goroutines starting at index 'start', and returns an array of up to 'count' (or all found elements, if 'count' is 0) G structures representing the information Delve care about from the internal runtime G structure. GoroutinesInfo also returns the next index to be used as 'start' argument while scanning for all available goroutines, or -1 if there was an error or if the index already reached the last possible value.

func (*G) Defer

func (g *G) Defer() *Defer

Defer returns the top-most defer of the goroutine.

func (*G) Go

func (g *G) Go() Location

Go returns the location of the 'go' statement that spawned this goroutine.

func (*G) Labels

func (g *G) Labels() map[string]string

func (*G) Stacktrace

func (g *G) Stacktrace(depth int, opts StacktraceOptions) ([]Stackframe, error)

Stacktrace returns the stack trace for a goroutine. Note the locations in the array are return addresses not call addresses.

func (*G) StartLoc

func (g *G) StartLoc() Location

StartLoc returns the starting location of the goroutine.

func (*G) UserCurrent

func (g *G) UserCurrent() Location

UserCurrent returns the location the users code is at, or was at before entering a runtime function.

type Image

type Image struct {
	Path       string
	StaticBase uint64
	// contains filtered or unexported fields
}

Image represents a loaded library file (shared object on linux, DLL on windows).

func (*Image) Close

func (image *Image) Close() error

func (*Image) DwarfReader

func (so *Image) DwarfReader() *reader.Reader

DwarfReader returns a reader for the dwarf data

func (*Image) LoadError

func (image *Image) LoadError() error

LoadError returns any error incurred while loading this image.

func (*Image) Type

func (image *Image) Type(offset dwarf.Offset) (godwarf.Type, error)

Type returns the Dwarf type entry at `offset`.

type Info

type Info interface {
	Pid() int
	// ResumeNotify specifies a channel that will be closed the next time
	// ContinueOnce finishes resuming the target.
	ResumeNotify(chan<- struct{})
	// Valid returns true if this Process can be used. When it returns false it
	// also returns an error describing why the Process is invalid (either
	// ErrProcessExited or ErrProcessDetached).
	Valid() (bool, error)
	BinInfo() *BinaryInfo
	EntryPoint() (uint64, error)

	ThreadInfo
}

Info is an interface that provides general information on the target.

type InlinedCall

type InlinedCall struct {
	LowPC, HighPC uint64 // Address range of the generated inlined instructions
	// contains filtered or unexported fields
}

InlinedCall represents a concrete inlined call to a function.

type InvalidAddressError

type InvalidAddressError struct {
	Address uint64
}

InvalidAddressError represents the result of attempting to set a breakpoint at an invalid address.

func (InvalidAddressError) Error

func (iae InvalidAddressError) Error() string

type IsNilErr

type IsNilErr struct {
	// contains filtered or unexported fields
}

IsNilErr is returned when a variable is nil.

func (*IsNilErr) Error

func (err *IsNilErr) Error() string

type LoadConfig

type LoadConfig struct {
	// FollowPointers requests pointers to be automatically dereferenced.
	FollowPointers bool
	// MaxVariableRecurse is how far to recurse when evaluating nested types.
	MaxVariableRecurse int
	// MaxStringLen is the maximum number of bytes read from a string
	MaxStringLen int
	// MaxArrayValues is the maximum number of elements read from an array, a slice or a map.
	MaxArrayValues int
	// MaxStructFields is the maximum number of fields read from a struct, -1 will read all fields.
	MaxStructFields int

	// MaxMapBuckets is the maximum number of map buckets to read before giving up.
	// A value of 0 will read as many buckets as necessary until the entire map
	// is read or MaxArrayValues is reached.
	//
	// Loading a map is an operation that issues O(num_buckets) operations.
	// Normally the number of buckets is proportional to the number of elements
	// in the map, since the runtime tries to keep the load factor of maps
	// between 40% and 80%.
	//
	// It is possible, however, to create very sparse maps either by:
	// a) adding lots of entries to a map and then deleting most of them, or
	// b) using the make(mapType, N) expression with a very large N
	//
	// When this happens delve will have to scan many empty buckets to find the
	// few entries in the map.
	// MaxMapBuckets can be set to avoid annoying slowdowns␣while reading
	// very sparse maps.
	//
	// Since there is no good way for a user of delve to specify the value of
	// MaxMapBuckets, this field is not actually exposed through the API.
	// Instead (*EvalScope).LocalVariables and  (*EvalScope).FunctionArguments
	// set this field automatically to MaxArrayValues * maxMapBucketsFactor.
	// Every other invocation uses the default value of 0, obtaining the old behavior.
	// In practice this means that debuggers using the ListLocalVars or
	// ListFunctionArgs API will not experience a massive slowdown when a very
	// sparse map is in scope, but evaluating a single variable will still work
	// correctly, even if the variable in question is a very sparse map.
	MaxMapBuckets int
}

LoadConfig controls how variables are loaded from the targets memory.

type Location

type Location struct {
	PC   uint64
	File string
	Line int
	Fn   *Function
}

Location represents the location of a thread. Holds information on the current instruction address, the source file:line, and the function.

type MemoryReadWriter

type MemoryReadWriter interface {
	MemoryReader
	WriteMemory(addr uintptr, data []byte) (written int, err error)
}

MemoryReadWriter is an interface for reading or writing to the targets memory. This allows us to read from the actual target memory or possibly a cache.

func DereferenceMemory

func DereferenceMemory(mem MemoryReadWriter) MemoryReadWriter

DereferenceMemory returns a MemoryReadWriter that can read and write the memory pointed to by pointers in this memory. Normally mem and mem.Dereference are the same object, they are different only if this MemoryReadWriter is used to access memory outside of the normal address space of the inferior process (such as data contained in registers, or composite memory).

type MemoryReader

type MemoryReader interface {
	// ReadMemory is just like io.ReaderAt.ReadAt.
	ReadMemory(buf []byte, addr uintptr) (n int, err error)
}

MemoryReader is like io.ReaderAt, but the offset is a uintptr so that it can address all of 64-bit memory. Redundant with memoryReadWriter but more easily suited to working with the standard io package.

type NewTargetConfig

type NewTargetConfig struct {
	Path                string            // path of the main executable
	DebugInfoDirs       []string          // Directories to search for split debug info
	WriteBreakpoint     WriteBreakpointFn // Function to write a breakpoint to the target process
	DisableAsyncPreempt bool              // Go 1.14 asynchronous preemption should be disabled
	StopReason          StopReason        // Initial stop reason
}

NewTargetConfig contains the configuration for a new Target object,

type NoBreakpointError

type NoBreakpointError struct {
	Addr uint64
}

NoBreakpointError is returned when trying to clear a breakpoint that does not exist.

func (NoBreakpointError) Error

func (nbp NoBreakpointError) Error() string

type NullAddrError

type NullAddrError struct{}

NullAddrError is an error for a null address.

func (NullAddrError) Error

func (n NullAddrError) Error() string

type PEMachine

type PEMachine uint16

func (PEMachine) String

func (m PEMachine) String() string

type PackageBuildInfo

type PackageBuildInfo struct {
	ImportPath    string
	DirectoryPath string
	Files         map[string]struct{}
}

type Process

Process represents the target of the debugger. This target could be a system process, core file, etc.

Implementations of Process are not required to be thread safe and users of Process should not assume they are. There is one exception to this rule: it is safe to call RequestManualStop concurrently with ContinueOnce.

type ProcessInternal

type ProcessInternal interface {
	SetCurrentThread(Thread)
	// Restart restarts the recording from the specified position, or from the
	// last checkpoint if pos == "".
	// If pos starts with 'c' it's a checkpoint ID, otherwise it's an event
	// number.
	Restart(pos string) error
	Detach(bool) error
	ContinueOnce() (trapthread Thread, stopReason StopReason, err error)
}

ProcessInternal holds a set of methods that are not meant to be called by anyone except for an instance of `proc.Target`. These methods are not safe to use by themselves and should never be called directly outside of the `proc` package. This is temporary and in support of an ongoing refactor.

type ProcessManipulation

type ProcessManipulation interface {
	RequestManualStop() error
	// CheckAndClearManualStopRequest returns true the first time it's called
	// after a call to RequestManualStop.
	CheckAndClearManualStopRequest() bool
}

ProcessManipulation is an interface for changing the execution state of a process.

type RecordingManipulation

type RecordingManipulation interface {
	// Recorded returns true if the current process is a recording and the path
	// to the trace directory.
	Recorded() (recorded bool, tracedir string)
	// Direction changes execution direction.
	ChangeDirection(Direction) error
	// GetDirection returns the current direction of execution.
	GetDirection() Direction
	// When returns current recording position.
	When() (string, error)
	// Checkpoint sets a checkpoint at the current position.
	Checkpoint(where string) (id int, err error)
	// Checkpoints returns the list of currently set checkpoint.
	Checkpoints() ([]Checkpoint, error)
	// ClearCheckpoint removes a checkpoint.
	ClearCheckpoint(id int) error
}

RecordingManipulation is an interface for manipulating process recordings.

type Register

type Register struct {
	Name string
	Reg  *op.DwarfRegister
}

Register represents a CPU register.

func AppendBytesRegister

func AppendBytesRegister(regs []Register, name string, value []byte) []Register

AppendBytesRegister will create a new Register struct with the name and value specified and append it to the `regs` slice.

func AppendUint64Register

func AppendUint64Register(regs []Register, name string, value uint64) []Register

AppendUint64Register will create a new Register struct with the name and value specified and append it to the `regs` slice.

type Registers

type Registers interface {
	PC() uint64
	SP() uint64
	BP() uint64
	TLS() uint64
	// GAddr returns the address of the G variable if it is known, 0 and false otherwise
	GAddr() (uint64, bool)
	Get(int) (uint64, error)
	Slice(floatingPoint bool) ([]Register, error)
	// Copy returns a copy of the registers that is guaranteed not to change
	// when the registers of the associated thread change.
	Copy() (Registers, error)
}

Registers is an interface for a generic register type. The interface encapsulates the generic values / actions we need independent of arch. The concrete register types will be different depending on OS/Arch.

type Stackframe

type Stackframe struct {
	Current, Call Location

	// Frame registers.
	Regs op.DwarfRegisters

	// Return address for this stack frame (as read from the stack frame itself).
	Ret uint64

	// Err is set if an error occurred during stacktrace
	Err error
	// SystemStack is true if this frame belongs to a system stack.
	SystemStack bool
	// Inlined is true if this frame is actually an inlined call.
	Inlined bool
	// Bottom is true if this is the bottom of the stack
	Bottom bool

	// TopmostDefer is the defer that would be at the top of the stack when a
	// panic unwind would get to this call frame, in other words it's the first
	// deferred function that will  be called if the runtime unwinds past this
	// call frame.
	TopmostDefer *Defer

	// Defers is the list of functions deferred by this stack frame (so far).
	Defers []*Defer
	// contains filtered or unexported fields
}

Stackframe represents a frame in a system stack.

Each stack frame has two locations Current and Call.

For the topmost stackframe Current and Call are the same location.

For stackframes after the first Current is the location corresponding to the return address and Call is the location of the CALL instruction that was last executed on the frame. Note however that Call.PC is always equal to Current.PC, because finding the correct value for Call.PC would require disassembling each function in the stacktrace.

For synthetic stackframes generated for inlined function calls Current.Fn is the function containing the inlining and Call.Fn in the inlined function.

func ThreadStacktrace

func ThreadStacktrace(thread Thread, depth int) ([]Stackframe, error)

ThreadStacktrace returns the stack trace for thread. Note the locations in the array are return addresses not call addresses.

func (*Stackframe) FrameOffset

func (frame *Stackframe) FrameOffset() int64

FrameOffset returns the address of the stack frame, absolute for system stack frames or as an offset from stackhi for goroutine stacks (a negative value).

func (*Stackframe) FramePointerOffset

func (frame *Stackframe) FramePointerOffset() int64

FramePointerOffset returns the value of the frame pointer, absolute for system stack frames or as an offset from stackhi for goroutine stacks (a negative value).

type StacktraceOptions

type StacktraceOptions uint16
const (
	// StacktraceReadDefers requests a stacktrace decorated with deferred calls
	// for each frame.
	StacktraceReadDefers StacktraceOptions = 1 << iota

	// StacktraceSimple requests a stacktrace where no stack switches will be
	// attempted.
	StacktraceSimple

	// StacktraceG requests a stacktrace starting with the register
	// values saved in the runtime.g structure.
	StacktraceG
)

type StopReason

type StopReason uint8

StopReason describes the reason why the target process is stopped. A process could be stopped for multiple simultaneous reasons, in which case only one will be reported.

const (
	StopUnknown             StopReason = iota
	StopLaunched                       // The process was just launched
	StopAttached                       // The debugger stopped the process after attaching
	StopExited                         // The target process terminated
	StopBreakpoint                     // The target process hit one or more software breakpoints
	StopHardcodedBreakpoint            // The target process hit a hardcoded breakpoint (for example runtime.Breakpoint())
	StopManual                         // A manual stop was requested
	StopNextFinished                   // The next/step/stepout command terminated
	StopCallReturned                   // An injected call completed
)

type Target

type Target struct {
	Process

	// StopReason describes the reason why the target process is stopped.
	// A process could be stopped for multiple simultaneous reasons, in which
	// case only one will be reported.
	StopReason StopReason
	// contains filtered or unexported fields
}

Target represents the process being debugged.

func NewTarget

func NewTarget(p Process, cfg NewTargetConfig) (*Target, error)

NewTarget returns an initialized Target object.

func (*Target) ClearAllGCache

func (t *Target) ClearAllGCache()

ClearAllGCache clears the internal Goroutine cache. This should be called anytime the target process executes instructions.

func (*Target) Continue

func (dbp *Target) Continue() error

Continue continues execution of the debugged process. It will continue until it hits a breakpoint or is otherwise stopped.

func (*Target) Detach

func (t *Target) Detach(kill bool) error

Detach will detach the target from the underylying process. This means the debugger will no longer receive events from the process we were previously debugging. If kill is true then the process will be killed when we detach.

func (*Target) Next

func (dbp *Target) Next() (err error)

Next continues execution until the next source line.

func (*Target) Restart

func (t *Target) Restart(from string) error

Restart will start the process over from the location specified by the "from" locspec. This is only useful for recorded targets. Restarting of a normal process happens at a higher level (debugger.Restart).

func (*Target) SelectedGoroutine

func (t *Target) SelectedGoroutine() *G

SelectedGoroutine returns the currently selected goroutine.

func (*Target) Step

func (dbp *Target) Step() (err error)

Step will continue until another source line is reached. Will step into functions.

func (*Target) StepInstruction

func (dbp *Target) StepInstruction() (err error)

StepInstruction will continue the current thread for exactly one instruction. This method affects only the thread associated with the selected goroutine. All other threads will remain stopped.

func (*Target) StepOut

func (dbp *Target) StepOut() error

StepOut will continue until the current goroutine exits the function currently being executed or a deferred function is executed

func (*Target) SupportsFunctionCalls

func (t *Target) SupportsFunctionCalls() bool

SupportsFunctionCalls returns whether or not the backend supports calling functions during a debug session. Currently only non-recorded processes running on AMD64 support function calls.

func (*Target) SwitchGoroutine

func (p *Target) SwitchGoroutine(g *G) error

SwitchGoroutine will change the selected and active goroutine.

func (*Target) SwitchThread

func (p *Target) SwitchThread(tid int) error

SwitchThread will change the selected and active thread.

type Thread

type Thread interface {
	MemoryReadWriter
	Location() (*Location, error)
	// Breakpoint will return the breakpoint that this thread is stopped at or
	// nil if the thread is not stopped at any breakpoint.
	Breakpoint() *BreakpointState
	ThreadID() int

	// Registers returns the CPU registers of this thread. The contents of the
	// variable returned may or may not change to reflect the new CPU status
	// when the thread is resumed or the registers are changed by calling
	// SetPC/SetSP/etc.
	// To insure that the the returned variable won't change call the Copy
	// method of Registers.
	Registers() (Registers, error)

	// RestoreRegisters restores saved registers
	RestoreRegisters(Registers) error
	BinInfo() *BinaryInfo
	StepInstruction() error
	// Blocked returns true if the thread is blocked
	Blocked() bool
	// SetCurrentBreakpoint updates the current breakpoint of this thread, if adjustPC is true also checks for breakpoints that were just hit (this should only be passed true after a thread resume)
	SetCurrentBreakpoint(adjustPC bool) error
	// Common returns the CommonThread structure for this thread
	Common() *CommonThread

	SetPC(uint64) error
	SetSP(uint64) error
	SetDX(uint64) error
}

Thread represents a thread.

type ThreadInfo

type ThreadInfo interface {
	FindThread(threadID int) (Thread, bool)
	ThreadList() []Thread
	CurrentThread() Thread
}

ThreadInfo is an interface for getting information on active threads in the process.

type Variable

type Variable struct {
	Addr      uintptr
	OnlyAddr  bool
	Name      string
	DwarfType godwarf.Type
	RealType  godwarf.Type
	Kind      reflect.Kind

	Value        constant.Value
	FloatSpecial floatSpecial

	Len int64
	Cap int64

	Flags variableFlags

	// Base address of arrays, Base address of the backing array for slices (0 for nil slices)
	// Base address of the backing byte array for strings
	// address of the struct backing chan and map variables
	// address of the function entry point for function variables (0 for nil function pointers)
	Base uintptr

	Children []Variable

	Unreadable error

	LocationExpr *locationExpr // location expression
	DeclLine     int64         // line number of this variable's declaration
	// contains filtered or unexported fields
}

Variable represents a variable. It contains the address, name, type and other information parsed from both the Dwarf information and the memory of the debugged process. If OnlyAddr is true, the variables value has not been loaded.

func (*Variable) ConstDescr

func (v *Variable) ConstDescr() string

ConstDescr describes the value of v using constants.

func (*Variable) TypeString

func (v *Variable) TypeString() string

TypeString returns the string representation of the type of this variable.

type WriteBreakpointFn

type WriteBreakpointFn func(addr uint64) (file string, line int, fn *Function, originalData []byte, err error)

WriteBreakpointFn is a type that represents a function to be used for writting breakpoings into the target.

Directories

Path Synopsis
This package contains functions and data structures used by both the linux implementation of the native backend and the core backend to deal with structures used by the linux kernel.
This package contains functions and data structures used by both the linux implementation of the native backend and the core backend to deal with structures used by the linux kernel.

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