NetBSD/lib/libc/sys/ptrace.2

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.\" $NetBSD: ptrace.2,v 1.13 2000/09/27 22:31:43 nathanw Exp $
.\"
.\" This file is in the public domain.
.Dd November 7, 1994
.Dt PTRACE 2
.Os
.Sh NAME
.Nm ptrace
.Nd process tracing and debugging
.Sh LIBRARY
.Lb libc
.Sh SYNOPSIS
.Fd #include <sys/types.h>
.Fd #include <sys/ptrace.h>
.Ft int
.Fn ptrace "int request" "pid_t pid" "caddr_t addr" "int data"
.Sh DESCRIPTION
.Fn ptrace
provides tracing and debugging facilities. It allows one process (the
.Em tracing
process) to control another (the
.Em traced
process). Most of the time, the traced process runs normally, but when
it receives a signal
.Po
see
.Xr sigaction 2
.Pc ,
it stops. The tracing process is expected to notice this via
.Xr wait 2
or the delivery of a
.Dv SIGCHLD
signal, examine the state of the stopped process, and cause it to
terminate or continue as appropriate.
.Fn ptrace
is the mechanism by which all this happens.
.Pp
The
.Fa request
argument specifies what operation is being performed; the meaning of
the rest of the arguments depends on the operation, but except for one
special case noted below, all
.Fn ptrace
calls are made by the tracing process, and the
.Fa pid
argument specifies the process ID of the traced process.
.Fa request
can be:
.Bl -tag -width 12n
.It Dv PT_TRACE_ME
This request is the only one used by the traced process; it declares
that the process expects to be traced by its parent. All the other
arguments are ignored. (If the parent process does not expect to trace
the child, it will probably be rather confused by the results; once the
traced process stops, it cannot be made to continue except via
.Eo \&
.Fn ptrace
.Ec \&.)
When a process has used this request and calls
.Xr execve 2
or any of the routines built on it
.Po
such as
.Xr execv 3
.Pc ,
it will stop before executing the first instruction of the new image.
Also, any setuid or setgid bits on the executable being executed will
be ignored.
.It Dv PT_READ_I , Dv PT_READ_D
These requests read a single
.Li int
of data from the traced process' address space. Traditionally,
.Fn ptrace
has allowed for machines with distinct address spaces for instruction
and data, which is why there are two requests: conceptually,
.Dv PT_READ_I
reads from the instruction space and
.Dv PT_READ_D
reads from the data space. In the current
.Nx
implementation, these
two requests are completely identical. The
.Fa addr
argument specifies the address (in the traced process' virtual address
space) at which the read is to be done. This address does not have to
meet any alignment constraints. The value read is returned as the
return value from
.Eo \&
.Fn ptrace
.Ec .
.It Dv PT_WRITE_I , Dv PT_WRITE_D
These requests parallel
.Dv PT_READ_I
and
.Dv PT_READ_D ,
except that they write rather than read. The
.Fa data
argument supplies the value to be written.
.\" .It Dv PT_READ_U
.\" This request reads an
.\" .Li int
.\" from the traced process' user structure. The
.\" .Fa addr
.\" argument specifies the location of the int relative to the base of the
.\" user structure; it will usually be an integer value cast to
.\" .Li caddr_t
.\" either explicitly or via the presence of a prototype for
.\" .Eo \&
.\" .Fn ptrace
.\" .Ec .
.\" Unlike
.\" .Dv PT_READ_I
.\" and
.\" .Dv PT_READ_D ,
.\" .Fa addr
.\" must be aligned on an
.\" .Li int
.\" boundary. The value read is returned as the return value from
.\" .Eo \&
.\" .Fn ptrace
.\" .Ec .
.\" .It Dv PT_WRITE_U
.\" This request writes an
.\" .Li int
.\" into the traced process' user structure.
.\" .Fa addr
.\" specifies the offset, just as for
.\" .Dv PT_READ_U ,
.\" and
.\" .Fa data
.\" specifies the value to be written, just as for
.\" .Dv PT_WRITE_I
.\" and
.\" .Dv PT_WRITE_D .
.It Dv PT_CONTINUE
The traced process continues execution.
.Fa addr
is an address specifying the place where execution is to be resumed (a
new value for the program counter), or
.Li (caddr_t)1
to indicate that execution is to pick up where it left off.
.Fa data
provides a signal number to be delivered to the traced process as it
resumes execution, or 0 if no signal is to be sent.
.It Dv PT_KILL
The traced process terminates, as if
.Dv PT_CONTINUE
had been used with
.Dv SIGKILL
given as the signal to be delivered.
.It Dv PT_ATTACH
This request allows a process to gain control of an otherwise unrelated
process and begin tracing it. It does not need any cooperation from
the to-be-traced process. In this case,
.Fa pid
specifies the process ID of the to-be-traced process, and the other two
arguments are ignored. This request requires that the target process
must have the same real UID as the tracing process, and that it must
not be executing a setuid or setgid executable. (If the tracing
process is running as root, these restrictions do not apply.) The
tracing process will see the newly-traced process stop and may then
control it as if it had been traced all along.
.Pp
Three other restrictions apply to all tracing processes, even those
running as root. First, no process may trace a system process.
Second, no process may trace the process running
.Xr init 8 .
Third, if a process has its root directory set with
.Xr chroot 2 ,
it may not trace another process unless that process's root directory
is at or below the tracing process's root.
.It Dv PT_DETACH
This request is like PT_CONTINUE, except that after it
succeeds, the traced process is no longer traced and continues
execution normally.
.El
.Pp
Additionally, the following requests exist but are
not avaliable on all machine architectures. The file
.Aq Pa machine/ptrace.h
lists which requests exist on a given machine.
.Bl -tag -width 12n
.It Dv PT_STEP
Execution continues as in request PT_CONTINUE; however
as soon as possible after execution of at least one
instruction, execution stops again.
.It Dv PT_GETREGS
This request reads the traced process' machine registers into the
.Dq Li "struct reg"
(defined in
.Aq Pa machine/reg.h )
pointed to by
.Fa addr .
.It Dv PT_SETREGS
This request is the converse of
.Dv PT_GETREGS ;
it loads the traced process' machine registers from the
.Dq Li "struct reg"
(defined in
.Aq Pa machine/reg.h )
pointed to by
.Fa addr .
.It Dv PT_GETFPREGS
This request reads the traced process' floating-point registers into
the
.Dq Li "struct fpreg"
(defined in
.Aq Pa machine/reg.h )
pointed to by
.Fa addr .
.It Dv PT_SETFPREGS
This request is the converse of
.Dv PT_GETFPREGS ;
it loads the traced process' floating-point registers from the
.Dq Li "struct fpreg"
(defined in
.Aq Pa machine/reg.h )
pointed to by
.Fa addr .
.\" .It Dv PT_SYSCALL
.\" This request is like
.\" .Dv PT_CONTINUE
.\" except that the process will stop next time it executes any system
.\" call. Information about the system call can be examined with
.\" .Dv PT_READ_U
.\" and potentially modified with
.\" .Dv PT_WRITE_U
.\" through the
.\" .Li u_kproc.kp_proc.p_md
.\" element of the user structure (see below). If the process is continued
.\" with another
.\" .Dv PT_SYSCALL
.\" request, it will stop again on exit from the syscall, at which point
.\" the return values can be examined and potentially changed. The
.\" .Li u_kproc.kp_proc.p_md
.\" element is of type
.\" .Dq Li "struct mdproc" ,
.\" which should be declared by including
.\" .Aq Pa sys/param.h ,
.\" .Aq Pa sys/user.h ,
.\" and
.\" .Aq Pa machine/proc.h ,
.\" and contains the following fields (among others):
.\" .Bl -item -compact -offset indent
.\" .It
.\" .Li syscall_num
.\" .It
.\" .Li syscall_nargs
.\" .It
.\" .Li syscall_args[8]
.\" .It
.\" .Li syscall_err
.\" .It
.\" .Li syscall_rv[2]
.\" .El
.\" When a process stops on entry to a syscall,
.\" .Li syscall_num
.\" holds the number of the syscall,
.\" .Li syscall_nargs
.\" holds the number of arguments it expects, and
.\" .Li syscall_args
.\" holds the arguments themselves. (Only the first
.\" .Li syscall_nargs
.\" elements of
.\" .Li syscall_args
.\" are guaranteed to be useful.) When a process stops on exit from a
.\" syscall,
.\" .Li syscall_num
.\" is
.\" .Eo \&
.\" .Li -1
.\" .Ec ,
.\" .Li syscall_err
.\" holds the error number
.\" .Po
.\" see
.\" .Xr errno 2
.\" .Pc ,
.\" or 0 if no error occurred, and
.\" .Li syscall_rv
.\" holds the return values. (If the syscall returns only one value, only
.\" .Li syscall_rv[0]
.\" is useful.) The tracing process can modify any of these with
.\" .Dv PT_WRITE_U ;
.\" only some modifications are useful.
.\" .Pp
.\" On entry to a syscall,
.\" .Li syscall_num
.\" can be changed, and the syscall actually performed will correspond to
.\" the new number (it is the responsibility of the tracing process to fill
.\" in
.\" .Li syscall_args
.\" appropriately for the new call, but there is no need to modify
.\" .Eo \&
.\" .Li syscall_nargs
.\" .Ec ).
.\" If the new syscall number is 0, no syscall is actually performed;
.\" instead,
.\" .Li syscall_err
.\" and
.\" .Li syscall_rv
.\" are passed back to the traced process directly (and therefore should be
.\" filled in). If the syscall number is otherwise out of range, a dummy
.\" syscall which simply produces an
.\" .Er ENOSYS
.\" error is effectively performed.
.\" .Pp
.\" On exit from a syscall, only
.\" .Li syscall_err
.\" and
.\" .Li syscall_rv
.\" can usefully be changed; they are set to the values returned by the
.\" syscall and will be passed back to the traced process by the normal
.\" syscall return mechanism.
.El
.Sh ERRORS
Some requests can cause
.Fn ptrace
to return
.Li -1
as a non-error value; to disambiguate,
.Va errno
can be set to 0 before the call and checked afterwards. The possible
errors are:
.Bl -tag -width 4n
.It Bq Er ESRCH
No process having the specified process ID exists.
.It Bq Er EINVAL
.Bl -bullet -compact
.It
A process attempted to use
.Dv PT_ATTACH
on itself.
.It
The
.Fa request
was not a legal request on this machine architecture.
.\" .It
.\" The
.\" .Fa addr
.\" to
.\" .Dv PT_READ_U
.\" or
.\" .Dv PT_WRITE_U
.\" was not
.\" .Li int Ns \&-aligned.
.It
The signal number (in
.Fa data )
to
.Dv PT_CONTINUE
.\" or
.\" .Dv PT_SYSCALL
was neither 0 nor a legal signal number.
.It
.Dv PT_GETREGS ,
.Dv PT_SETREGS ,
.Dv PT_GETFPREGS ,
or
.Dv PT_SETFPREGS
was attempted on a process with no valid register set. (This is
normally true only of system processes.)
.El
.It Bq Er EBUSY
.Bl -bullet -compact
.It
.Dv PT_ATTACH
was attempted on a process that was already being traced.
.It
A request attempted to manipulate a process that was being traced by
some process other than the one making the request.
.It
A request (other than
.Dv PT_ATTACH )
specified a process that wasn't stopped.
.El
.It Bq Er EPERM
.Bl -bullet -compact
.It
A request (other than
.Dv PT_ATTACH )
attempted to manipulate a process that wasn't being traced at all.
.It
An attempt was made to use
.Dv PT_ATTACH
on a process in violation of the requirements listed under
.Dv PT_ATTACH
above.
.El
1999-03-09 06:58:14 +03:00
.El
.Sh SEE ALSO
.Xr sigaction 2 ,
.Xr signal 7
.Sh BUGS
On the SPARC, the PC is set to the provided PC value for
.Dv PT_CONTINUE
and similar calls, but the NPC is set willy-nilly to 4 greater than the
PC value. Using
.Dv PT_GETREGS
and
.Dv PT_SETREGS
to modify the PC, passing
.Li (caddr_t)1
to
.Eo \&
.Fn ptrace
.Ec ,
should be able to sidestep this.
.\" .Pp
.\" When using
.\" .Dv PT_SYSCALL ,
.\" there is no easy way to tell whether the traced process stopped because
.\" it made a syscall or because a signal was sent at a moment that it just
.\" happened to have valid-looking garbage in its
.\" .Dq Li "struct mdproc" .