src/pkg/debug/proc/proc.go - go - Git at Google

 // Copyright 2009 The Go Authors.  All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 // Package ptrace provides a platform-independent interface for
 // tracing and controlling running processes.  It supports
 // multi-threaded processes and provides typical low-level debugging
 // controls such as breakpoints, single stepping, and manipulating
 // memory and registers.
 package proc

 // TODO(rsc): Have to import everything that proc_linux.go
 // and proc_darwin.go do, because deps.bash only looks at
 // this file.
 import (
 	_ "container/vector";
 	_ "fmt";
 	_ "io";
 	"os";
 	_ "runtime";
 	"strconv";
 	_ "strings";
 	_ "sync";
 	_ "syscall";
 )

 type Word uint64

 // A Cause explains why a thread is stopped.
 type Cause interface {
 	String() string;
 }

 // Regs is a set of named machine registers, including a program
 // counter, link register, and stack pointer.
 //
 // TODO(austin) There's quite a proliferation of methods here.  We
 // could make a Reg interface with Get and Set and make this just PC,
 // Link, SP, Names, and Reg.  We could also put Index in Reg and that
 // makes it easy to get the index of things like the PC (currently
 // there's just no way to know that).  This would also let us include
 // other per-register information like how to print it.
 type Regs interface {
 	// PC returns the value of the program counter.
 	PC() Word;

 	// SetPC sets the program counter to val.
 	SetPC(val Word) os.Error;

 	// Link returns the link register, if any.
 	Link() Word;

 	// SetLink sets the link register to val.
 	SetLink(val Word) os.Error;

 	// SP returns the value of the stack pointer.
 	SP() Word;

 	// SetSP sets the stack pointer register to val.
 	SetSP(val Word) os.Error;

 	// Names returns the names of all of the registers.
 	Names() []string;

 	// Get returns the value of a register, where i corresponds to
 	// the index of the register's name in the array returned by
 	// Names.
 	Get(i int) Word;

 	// Set sets the value of a register.
 	Set(i int, val Word) os.Error;
 }

 // Thread is a thread in the process being traced.
 type Thread interface {
 	// Step steps this thread by a single instruction.  The thread
 	// must be stopped.  If the thread is currently stopped on a
 	// breakpoint, this will step over the breakpoint.
 	//
 	// XXX What if it's stopped because of a signal?
 	Step() os.Error;

 	// Stopped returns the reason that this thread is stopped.  It
 	// is an error is the thread not stopped.
 	Stopped() (Cause, os.Error);

 	// Regs retrieves the current register values from this
 	// thread.  The thread must be stopped.
 	Regs() (Regs, os.Error);

 	// Peek reads len(out) bytes from the address addr in this
 	// thread into out.  The thread must be stopped.  It returns
 	// the number of bytes successfully read.  If an error occurs,
 	// such as attempting to read unmapped memory, this count
 	// could be short and an error will be returned.  If this does
 	// encounter unmapped memory, it will read up to the byte
 	// preceding the unmapped area.
 	Peek(addr Word, out []byte) (int, os.Error);

 	// Poke writes b to the address addr in this thread.  The
 	// thread must be stopped.  It returns the number of bytes
 	// successfully written.  If an error occurs, such as
 	// attempting to write to unmapped memory, this count could be
 	// short and an error will be returned.  If this does
 	// encounter unmapped memory, it will write up to the byte
 	// preceding the unmapped area.
 	Poke(addr Word, b []byte) (int, os.Error);
 }

 // Process is a process being traced.  It consists of a set of
 // threads.  A process can be running, stopped, or terminated.  The
 // process's state extends to all of its threads.
 type Process interface {
 	// Threads returns an array of all threads in this process.
 	Threads() []Thread;

 	// AddBreakpoint creates a new breakpoint at program counter
 	// pc.  Breakpoints can only be created when the process is
 	// stopped.  It is an error if a breakpoint already exists at
 	// pc.
 	AddBreakpoint(pc Word) os.Error;

 	// RemoveBreakpoint removes the breakpoint at the program
 	// counter pc.  It is an error if no breakpoint exists at pc.
 	RemoveBreakpoint(pc Word) os.Error;

 	// Stop stops all running threads in this process before
 	// returning.
 	Stop() os.Error;

 	// Continue resumes execution of all threads in this process.
 	// Any thread that is stopped on a breakpoint will be stepped
 	// over that breakpoint.  Any thread that is stopped because
 	// of a signal (other than SIGSTOP or SIGTRAP) will receive
 	// the pending signal.
 	Continue() os.Error;

 	// WaitStop waits until all threads in process p are stopped
 	// as a result of some thread hitting a breakpoint, receiving
 	// a signal, creating a new thread, or exiting.
 	WaitStop() os.Error;

 	// Detach detaches from this process.  All stopped threads
 	// will be resumed.
 	Detach() os.Error;
 }

 // Stopped is a stop cause used for threads that are stopped either by
 // user request (e.g., from the Stop method or after single stepping),
 // or that are stopped because some other thread caused the program to
 // stop.
 type Stopped struct{}

 func (c Stopped) String() string	{ return "stopped" }

 // Breakpoint is a stop cause resulting from a thread reaching a set
 // breakpoint.
 type Breakpoint Word

 // PC returns the program counter that the program is stopped at.
 func (c Breakpoint) PC() Word	{ return Word(c) }

 func (c Breakpoint) String() string {
 	return "breakpoint at 0x" + strconv.Uitob64(uint64(c.PC()), 16)
 }

 // Signal is a stop cause resulting from a thread receiving a signal.
 // When the process is continued, the signal will be delivered.
 type Signal string

 // Signal returns the signal being delivered to the thread.
 func (c Signal) Name() string	{ return string(c) }

 func (c Signal) String() string	{ return c.Name() }

 // ThreadCreate is a stop cause returned from an existing thread when
 // it creates a new thread.  The new thread exists in a primordial
 // form at this point and will begin executing in earnest when the
 // process is continued.
 type ThreadCreate struct {
 	thread Thread;
 }

 func (c *ThreadCreate) NewThread() Thread	{ return c.thread }

 func (c *ThreadCreate) String() string	{ return "thread create" }

 // ThreadExit is a stop cause resulting from a thread exiting.  When
 // this cause first arises, the thread will still be in the list of
 // process threads and its registers and memory will still be
 // accessible.
 type ThreadExit struct {
 	exitStatus	int;
 	signal		string;
 }

 // Exited returns true if the thread exited normally.
 func (c *ThreadExit) Exited() bool	{ return c.exitStatus != -1 }

 // ExitStatus returns the exit status of the thread if it exited
 // normally or -1 otherwise.
 func (c *ThreadExit) ExitStatus() int	{ return c.exitStatus }

 // Signaled returns true if the thread was terminated by a signal.
 func (c *ThreadExit) Signaled() bool	{ return c.exitStatus == -1 }

 // StopSignal returns the signal that terminated the thread, or "" if
 // it was not terminated by a signal.
 func (c *ThreadExit) StopSignal() string	{ return c.signal }

 func (c *ThreadExit) String() string {
 	res := "thread exited ";
 	switch {
 	case c.Exited():
 		res += "with status " + strconv.Itoa(c.ExitStatus())
 	case c.Signaled():
 		res += "from signal " + c.StopSignal()
 	default:
 		res += "from unknown cause"
 	}
 	return res;
 }
	// Copyright 2009 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	// Package ptrace provides a platform-independent interface for
	// tracing and controlling running processes. It supports
	// multi-threaded processes and provides typical low-level debugging
	// controls such as breakpoints, single stepping, and manipulating
	// memory and registers.
	package proc

	// TODO(rsc): Have to import everything that proc_linux.go
	// and proc_darwin.go do, because deps.bash only looks at
	// this file.
	import (
	_ "container/vector";
	_ "fmt";
	_ "io";
	"os";
	_ "runtime";
	"strconv";
	_ "strings";
	_ "sync";
	_ "syscall";
	)

	type Word uint64

	// A Cause explains why a thread is stopped.
	type Cause interface {
	String() string;
	}

	// Regs is a set of named machine registers, including a program
	// counter, link register, and stack pointer.
	//
	// TODO(austin) There's quite a proliferation of methods here. We
	// could make a Reg interface with Get and Set and make this just PC,
	// Link, SP, Names, and Reg. We could also put Index in Reg and that
	// makes it easy to get the index of things like the PC (currently
	// there's just no way to know that). This would also let us include
	// other per-register information like how to print it.
	type Regs interface {
	// PC returns the value of the program counter.
	PC() Word;

	// SetPC sets the program counter to val.
	SetPC(val Word) os.Error;

	// Link returns the link register, if any.
	Link() Word;

	// SetLink sets the link register to val.
	SetLink(val Word) os.Error;

	// SP returns the value of the stack pointer.
	SP() Word;

	// SetSP sets the stack pointer register to val.
	SetSP(val Word) os.Error;

	// Names returns the names of all of the registers.
	Names() []string;

	// Get returns the value of a register, where i corresponds to
	// the index of the register's name in the array returned by
	// Names.
	Get(i int) Word;

	// Set sets the value of a register.
	Set(i int, val Word) os.Error;
	}

	// Thread is a thread in the process being traced.
	type Thread interface {
	// Step steps this thread by a single instruction. The thread
	// must be stopped. If the thread is currently stopped on a
	// breakpoint, this will step over the breakpoint.
	//
	// XXX What if it's stopped because of a signal?
	Step() os.Error;

	// Stopped returns the reason that this thread is stopped. It
	// is an error is the thread not stopped.
	Stopped() (Cause, os.Error);

	// Regs retrieves the current register values from this
	// thread. The thread must be stopped.
	Regs() (Regs, os.Error);

	// Peek reads len(out) bytes from the address addr in this
	// thread into out. The thread must be stopped. It returns
	// the number of bytes successfully read. If an error occurs,
	// such as attempting to read unmapped memory, this count
	// could be short and an error will be returned. If this does
	// encounter unmapped memory, it will read up to the byte
	// preceding the unmapped area.
	Peek(addr Word, out []byte) (int, os.Error);

	// Poke writes b to the address addr in this thread. The
	// thread must be stopped. It returns the number of bytes
	// successfully written. If an error occurs, such as
	// attempting to write to unmapped memory, this count could be
	// short and an error will be returned. If this does
	// encounter unmapped memory, it will write up to the byte
	// preceding the unmapped area.
	Poke(addr Word, b []byte) (int, os.Error);
	}

	// Process is a process being traced. It consists of a set of
	// threads. A process can be running, stopped, or terminated. The
	// process's state extends to all of its threads.
	type Process interface {
	// Threads returns an array of all threads in this process.
	Threads() []Thread;

	// AddBreakpoint creates a new breakpoint at program counter
	// pc. Breakpoints can only be created when the process is
	// stopped. It is an error if a breakpoint already exists at
	// pc.
	AddBreakpoint(pc Word) os.Error;

	// RemoveBreakpoint removes the breakpoint at the program
	// counter pc. It is an error if no breakpoint exists at pc.
	RemoveBreakpoint(pc Word) os.Error;

	// Stop stops all running threads in this process before
	// returning.
	Stop() os.Error;

	// Continue resumes execution of all threads in this process.
	// Any thread that is stopped on a breakpoint will be stepped
	// over that breakpoint. Any thread that is stopped because
	// of a signal (other than SIGSTOP or SIGTRAP) will receive
	// the pending signal.
	Continue() os.Error;

	// WaitStop waits until all threads in process p are stopped
	// as a result of some thread hitting a breakpoint, receiving
	// a signal, creating a new thread, or exiting.
	WaitStop() os.Error;

	// Detach detaches from this process. All stopped threads
	// will be resumed.
	Detach() os.Error;
	}

	// Stopped is a stop cause used for threads that are stopped either by
	// user request (e.g., from the Stop method or after single stepping),
	// or that are stopped because some other thread caused the program to
	// stop.
	type Stopped struct{}

	func (c Stopped) String() string { return "stopped" }

	// Breakpoint is a stop cause resulting from a thread reaching a set
	// breakpoint.
	type Breakpoint Word

	// PC returns the program counter that the program is stopped at.
	func (c Breakpoint) PC() Word { return Word(c) }

	func (c Breakpoint) String() string {
	return "breakpoint at 0x" + strconv.Uitob64(uint64(c.PC()), 16)
	}

	// Signal is a stop cause resulting from a thread receiving a signal.
	// When the process is continued, the signal will be delivered.
	type Signal string

	// Signal returns the signal being delivered to the thread.
	func (c Signal) Name() string { return string(c) }

	func (c Signal) String() string { return c.Name() }

	// ThreadCreate is a stop cause returned from an existing thread when
	// it creates a new thread. The new thread exists in a primordial
	// form at this point and will begin executing in earnest when the
	// process is continued.
	type ThreadCreate struct {
	thread Thread;
	}

	func (c *ThreadCreate) NewThread() Thread { return c.thread }

	func (c *ThreadCreate) String() string { return "thread create" }

	// ThreadExit is a stop cause resulting from a thread exiting. When
	// this cause first arises, the thread will still be in the list of
	// process threads and its registers and memory will still be
	// accessible.
	type ThreadExit struct {
	exitStatus int;
	signal string;
	}

	// Exited returns true if the thread exited normally.
	func (c *ThreadExit) Exited() bool { return c.exitStatus != -1 }

	// ExitStatus returns the exit status of the thread if it exited
	// normally or -1 otherwise.
	func (c *ThreadExit) ExitStatus() int { return c.exitStatus }

	// Signaled returns true if the thread was terminated by a signal.
	func (c *ThreadExit) Signaled() bool { return c.exitStatus == -1 }

	// StopSignal returns the signal that terminated the thread, or "" if
	// it was not terminated by a signal.
	func (c *ThreadExit) StopSignal() string { return c.signal }

	func (c *ThreadExit) String() string {
	res := "thread exited ";
	switch {
	case c.Exited():
	res += "with status " + strconv.Itoa(c.ExitStatus())
	case c.Signaled():
	res += "from signal " + c.StopSignal()
	default:
	res += "from unknown cause"
	}
	return res;
	}