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PTRACE(2)		  FreeBSD System Calls Manual		     PTRACE(2)

NAME
     ptrace -- process tracing and debugging

LIBRARY
     Standard C	Library	(libc, -lc)

SYNOPSIS
     #include <sys/types.h>
     #include <sys/ptrace.h>

     int
     ptrace(int	request, pid_t pid, caddr_t addr, int data);

DESCRIPTION
     The ptrace() system call provides tracing and debugging facilities.  It
     allows one	process	(the tracing process) to control another (the traced
     process).	The tracing process must first attach to the traced process,
     and then issue a series of	ptrace() system	calls to control the execution
     of	the process, as	well as	access process memory and register state.  For
     the duration of the tracing session, the traced process will be
     ``re-parented'', with its parent process ID (and resulting	behavior)
     changed to	the tracing process.  It is permissible	for a tracing process
     to	attach to more than one	other process at a time.  When the tracing
     process has completed its work, it	must detach the	traced process;	if a
     tracing process exits without first detaching all processes it has
     attached, those processes will be killed.

     Most of the time, the traced process runs normally, but when it receives
     a signal (see sigaction(2)), it stops.  The tracing process is expected
     to	notice this via	wait(2)	or the delivery	of a SIGCHLD signal, examine
     the state of the stopped process, and cause it to terminate or continue
     as	appropriate.  The signal may be	a normal process signal, generated as
     a result of traced	process	behavior, or use of the	kill(2)	system call;
     alternatively, it may be generated	by the tracing facility	as a result of
     attaching,	system calls, or stepping by the tracing process.  The tracing
     process may choose	to intercept the signal, using it to observe process
     behavior (such as SIGTRAP), or forward the	signal to the process if
     appropriate.  The ptrace()	system call is the mechanism by	which all this
     happens.

     The 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 ptrace() calls are made by the
     tracing process, and the pid argument specifies the process ID of the
     traced process or a corresponding thread ID.  The request argument	can
     be:

     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 par-
		   ent.	 All the other arguments are ignored.  (If the parent
		   process does	not expect to trace the	child, it will proba-
		   bly be rather confused by the results; once the traced
		   process stops, it cannot be made to continue	except via
		   ptrace().)  When a process has used this request and	calls
		   execve(2) or	any of the routines built on it	(such as
		   execv(3)), it will stop before executing the	first instruc-
		   tion	of the new image.  Also, any setuid or setgid bits on
		   the executable being	executed will be ignored.  If the
		   child was created by	vfork(2) system	call or	rfork(2) call
		   with	the RFMEM flag specified, the debugging	events are
		   reported to the parent only after the execve(2) is exe-
		   cuted.

     PT_READ_I,	PT_READ_D
		   These requests read a single	int of data from the traced
		   process's address space.  Traditionally, ptrace() has
		   allowed for machines	with distinct address spaces for
		   instruction and data, which is why there are	two requests:
		   conceptually, PT_READ_I reads from the instruction space
		   and PT_READ_D reads from the	data space.  In	the current
		   FreeBSD implementation, these two requests are completely
		   identical.  The addr	argument specifies the address (in the
		   traced process's 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 ptrace().

     PT_WRITE_I, PT_WRITE_D
		   These requests parallel PT_READ_I and PT_READ_D, except
		   that	they write rather than read.  The data argument	sup-
		   plies the value to be written.

     PT_IO	   This	request	allows reading and writing arbitrary amounts
		   of data in the traced process's address space.  The addr
		   argument specifies a	pointer	to a struct ptrace_io_desc,
		   which is defined as follows:

		   struct ptrace_io_desc {
			   int	   piod_op;	   /* I/O operation */
			   void	   *piod_offs;	   /* child offset */
			   void	   *piod_addr;	   /* parent offset */
			   size_t  piod_len;	   /* request length */
		   };

		   /*
		    * Operations in piod_op.
		    */
		   #define PIOD_READ_D	   1	   /* Read from	D space	*/
		   #define PIOD_WRITE_D	   2	   /* Write to D space */
		   #define PIOD_READ_I	   3	   /* Read from	I space	*/
		   #define PIOD_WRITE_I	   4	   /* Write to I space */

		   The data argument is	ignored.  The actual number of bytes
		   read	or written is stored in	piod_len upon return.

     PT_CONTINUE   The traced process continues	execution.  The	addr argument
		   is an address specifying the	place where execution is to be
		   resumed (a new value	for the	program	counter), or
		   (caddr_t)1 to indicate that execution is to pick up where
		   it left off.	 The data argument provides a signal number to
		   be delivered	to the traced process as it resumes execution,
		   or 0	if no signal is	to be sent.

     PT_STEP	   The traced process is single	stepped	one instruction.  The
		   addr	argument should	be passed (caddr_t)1.  The data	argu-
		   ment	provides a signal number to be delivered to the	traced
		   process as it resumes execution, or 0 if no signal is to be
		   sent.

     PT_KILL	   The traced process terminates, as if	PT_CONTINUE had	been
		   used	with SIGKILL given as the signal to be delivered.

     PT_ATTACH	   This	request	allows a process to gain control of an other-
		   wise	unrelated process and begin tracing it.	 It does not
		   need	any cooperation	from the to-be-traced process.	In
		   this	case, 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.

     PT_DETACH	   This	request	is like	PT_CONTINUE, except that it does not
		   allow specifying an alternate place to continue execution,
		   and after it	succeeds, the traced process is	no longer
		   traced and continues	execution normally.

     PT_GETREGS	   This	request	reads the traced process's machine registers
		   into	the ``struct reg'' (defined in <machine/reg.h>)
		   pointed to by addr.

     PT_SETREGS	   This	request	is the converse	of PT_GETREGS; it loads	the
		   traced process's machine registers from the ``struct	reg''
		   (defined in <machine/reg.h>)	pointed	to by addr.

     PT_GETFPREGS  This	request	reads the traced process's floating-point reg-
		   isters into the ``struct fpreg'' (defined in
		   <machine/reg.h>) pointed to by addr.

     PT_SETFPREGS  This	request	is the converse	of PT_GETFPREGS; it loads the
		   traced process's floating-point registers from the ``struct
		   fpreg'' (defined in <machine/reg.h>)	pointed	to by addr.

     PT_GETDBREGS  This	request	reads the traced process's debug registers
		   into	the ``struct dbreg'' (defined in <machine/reg.h>)
		   pointed to by addr.

     PT_SETDBREGS  This	request	is the converse	of PT_GETDBREGS; it loads the
		   traced process's debug registers from the ``struct dbreg''
		   (defined in <machine/reg.h>)	pointed	to by addr.

     PT_LWPINFO	   This	request	can be used to obtain information about	the
		   kernel thread, also known as	light-weight process, that
		   caused the traced process to	stop.  The addr	argument spec-
		   ifies a pointer to a	struct ptrace_lwpinfo, which is
		   defined as follows:

		   struct ptrace_lwpinfo {
			   lwpid_t pl_lwpid;
			   int	   pl_event;
			   int	   pl_flags;
			   sigset_t pl_sigmask;
			   sigset_t pl_siglist;
			   siginfo_t pl_siginfo;
			   char	   pl_tdname[MAXCOMLEN + 1];
			   pid_t   pl_child_pid;
			   u_int   pl_syscall_code;
			   u_int   pl_syscall_narg;
		   };

		   The data argument is	to be set to the size of the structure
		   known to the	caller.	 This allows the structure to grow
		   without affecting older programs.

		   The fields in the struct ptrace_lwpinfo have	the following
		   meaning:
		   pl_lwpid
			   LWP id of the thread
		   pl_event
			   Event that caused the stop.	Currently defined
			   events are
			   PL_EVENT_NONE
				   No reason given
			   PL_EVENT_SIGNAL
				   Thread stopped due to the pending signal
		   pl_flags
			   Flags that specify additional details about
			   observed stop.  Currently defined flags are:
			   PL_FLAG_SCE
				   The thread stopped due to system call
				   entry, right	after the kernel is entered.
				   The debugger	may examine syscall arguments
				   that	are stored in memory and registers
				   according to	the ABI	of the current
				   process, and	modify them, if	needed.
			   PL_FLAG_SCX
				   The thread is stopped immediately before
				   syscall is returning	to the usermode.  The
				   debugger may	examine	system call return
				   values in the ABI-defined registers and/or
				   memory.
			   PL_FLAG_EXEC
				   When	PL_FLAG_SCX is set, this flag may be
				   additionally	specified to inform that the
				   program being executed by debuggee process
				   has been changed by successful execution of
				   a system call from the execve(2) family.
			   PL_FLAG_SI
				   Indicates that pl_siginfo member of struct
				   ptrace_lwpinfo contains valid information.
			   PL_FLAG_FORKED
				   Indicates that the process is returning
				   from	a call to fork(2) that created a new
				   child process.  The process identifier of
				   the new process is available	in the
				   pl_child_pid	member of struct
				   ptrace_lwpinfo.
			   PL_FLAG_CHILD
				   The flag is set for first event reported
				   from	a new child, which is automatically
				   attached due	to PT_FOLLOW_FORK enabled.
			   PL_FLAG_BORN
				   This	flag is	set for	the first event
				   reported from a new LWP when	LWP events are
				   enabled via PT_LWP_EVENTS.  It is reported
				   along with PL_FLAG_SCX and is always
				   reported if LWP events are enabled.
			   PL_FLAG_EXITED
				   This	flag is	set for	the last event
				   reported by an exiting LWP when LWP events
				   are enabled via PT_LWP_EVENTS.  Note	that
				   this	event is not reported when the last
				   LWP in a process exits.  The	termination of
				   the last thread is reported via a normal
				   process exit	event.
		   pl_sigmask
			   The current signal mask of the LWP
		   pl_siglist
			   The current pending set of signals for the LWP.
			   Note	that signals that are delivered	to the process
			   would not appear on an LWP siglist until the	thread
			   is selected for delivery.
		   pl_siginfo
			   The siginfo that accompanies	the signal pending.
			   Only	valid for PL_EVENT_SIGNAL stop when PL_FLAG_SI
			   is set in pl_flags.
		   pl_tdname
			   The name of the thread.
		   pl_child_pid
			   The process identifier of the new child process.
			   Only	valid for a PL_EVENT_SIGNAL stop when
			   PL_FLAG_FORKED is set in pl_flags.
		   pl_syscall_code
			   The ABI-specific identifier of the current system
			   call.  Note that for	indirect system	calls this
			   field reports the indirected	system call.  Only
			   valid when PL_FLAG_SCE or PL_FLAG_SCX is set	in
			   pl_flags.
		   pl_syscall_narg
			   The number of arguments passed to the current sys-
			   tem call not	counting the system call identifier.
			   Note	that for indirect system calls this field
			   reports the arguments passed	to the indirected sys-
			   tem call.  Only valid when PL_FLAG_SCE or
			   PL_FLAG_SCX is set in pl_flags.

     PT_GETNUMLWPS
		   This	request	returns	the number of kernel threads associ-
		   ated	with the traced	process.

     PT_GETLWPLIST
		   This	request	can be used to get the current thread list.  A
		   pointer to an array of type lwpid_t should be passed	in
		   addr, with the array	size specified by data.	 The return
		   value from ptrace() is the count of array entries filled
		   in.

     PT_SETSTEP	   This	request	will turn on single stepping of	the specified
		   process.

     PT_CLEARSTEP  This	request	will turn off single stepping of the specified
		   process.

     PT_SUSPEND	   This	request	will suspend the specified thread.

     PT_RESUME	   This	request	will resume the	specified thread.

     PT_TO_SCE	   This	request	will trace the specified process on each sys-
		   tem call entry.

     PT_TO_SCX	   This	request	will trace the specified process on each sys-
		   tem call exit.

     PT_SYSCALL	   This	request	will trace the specified process on each sys-
		   tem call entry and exit.

     PT_FOLLOW_FORK
		   This	request	controls tracing for new child processes of a
		   traced process.  If data is non-zero, then new child	pro-
		   cesses will enable tracing and stop before executing	their
		   first instruction.  If data is zero,	then new child pro-
		   cesses will execute without tracing enabled.	 By default,
		   tracing is not enabled for new child	processes.  Child pro-
		   cesses do not inherit this property.	 The traced process
		   will	set the	PL_FLAG_FORKED flag upon exit from a system
		   call	that creates a new process.

     PT_LWP_EVENTS
		   This	request	controls tracing of LWP	creation and destruc-
		   tion.  If data is non-zero, then LWPs will stop to report
		   creation and	destruction events.  If	data is	zero, then LWP
		   creation and	destruction events will	not be reported.  By
		   default, tracing is not enabled for LWP events.  Child pro-
		   cesses do not inherit this property.	 New LWPs will stop to
		   report an event with	PL_FLAG_BORN set before	executing
		   their first instruction.  Exiting LWPs will stop to report
		   an event with PL_FLAG_EXITED	set before completing their
		   termination.

		   Note	that new processes do not report an event for the cre-
		   ation of their initial thread, and exiting processes	do not
		   report an event for the termination of the last thread.

     PT_VM_TIMESTAMP
		   This	request	returns	the generation number or timestamp of
		   the memory map of the traced	process	as the return value
		   from	ptrace().  This	provides a low-cost way	for the	trac-
		   ing process to determine if the VM map changed since	the
		   last	time this request was made.

     PT_VM_ENTRY   This	request	is used	to iterate over	the entries of the VM
		   map of the traced process.  The addr	argument specifies a
		   pointer to a	struct ptrace_vm_entry,	which is defined as
		   follows:

		   struct ptrace_vm_entry {
			   int		   pve_entry;
			   int		   pve_timestamp;
			   u_long	   pve_start;
			   u_long	   pve_end;
			   u_long	   pve_offset;
			   u_int	   pve_prot;
			   u_int	   pve_pathlen;
			   long		   pve_fileid;
			   uint32_t	   pve_fsid;
			   char		   *pve_path;
		   };

		   The first entry is returned by setting pve_entry to zero.
		   Subsequent entries are returned by leaving pve_entry	unmod-
		   ified from the value	returned by previous requests.	The
		   pve_timestamp field can be used to detect changes to	the VM
		   map while iterating over the	entries.  The tracing process
		   can then take appropriate action, such as restarting.  By
		   setting pve_pathlen to a non-zero value on entry, the path-
		   name	of the backing object is returned in the buffer
		   pointed to by pve_path, provided the	entry is backed	by a
		   vnode.  The pve_pathlen field is updated with the actual
		   length of the pathname (including the terminating null
		   character).	The pve_offset field is	the offset within the
		   backing object at which the range starts.  The range	is
		   located in the VM space at pve_start	and extends up to
		   pve_end (inclusive).

		   The data argument is	ignored.

x86 MACHINE-SPECIFIC REQUESTS
     PT_GETXMMREGS	   Copy	the XMM	FPU state into the buffer pointed to
			   by the argument addr.  The buffer has the same lay-
			   out as the 32-bit save buffer for the machine
			   instruction FXSAVE.

			   This	request	is only	valid for i386 programs, both
			   on native 32-bit systems and	on amd64 kernels.  For
			   64-bit amd64	programs, the XMM state	is reported as
			   part	of the FPU state returned by the PT_GETFPREGS
			   request.

			   The data argument is	ignored.

     PT_SETXMMREGS	   Load	the XMM	FPU state for the thread from the
			   buffer pointed to by	the argument addr.  The	buffer
			   has the same	layout as the 32-bit load buffer for
			   the machine instruction FXRSTOR.

			   As with PT_GETXMMREGS, this request is only valid
			   for i386 programs.

			   The data argument is	ignored.

     PT_GETXSTATE_INFO	   Report which	XSAVE FPU extensions are supported by
			   the CPU and allowed in userspace programs.  The
			   addr	argument must point to a variable of type
			   struct ptrace_xstate_info, which contains the
			   information on the request return.  struct
			   ptrace_xstate_info is defined as follows:

			   struct ptrace_xstate_info {
				   uint64_t	   xsave_mask;
				   uint32_t	   xsave_len;
			   };
			   The xsave_mask field	is a bitmask of	the currently
			   enabled extensions.	The meaning of the bits	is
			   defined in the Intel	and AMD	processor documenta-
			   tion.  The xsave_len	field reports the length of
			   the XSAVE area for storing the hardware state for
			   currently enabled extensions	in the format defined
			   by the x86 XSAVE machine instruction.

			   The data argument value must	be equal to the	size
			   of the struct ptrace_xstate_info.

     PT_GETXSTATE	   Return the content of the XSAVE area	for the
			   thread.  The	addr argument points to	the buffer
			   where the content is	copied,	and the	data argument
			   specifies the size of the buffer.  The kernel
			   copies out as much content as allowed by the	buffer
			   size.  The buffer layout is specified by the	layout
			   of the save area for	the XSAVE machine instruction.

     PT_SETXSTATE	   Load	the XSAVE state	for the	thread from the	buffer
			   specified by	the addr pointer.  The buffer size is
			   passed in the data argument.	 The buffer must be at
			   least as large as the struct	savefpu	(defined in
			   x86/fpu.h) to allow the complete x87	FPU and	XMM
			   state load.	It must	not be larger than the XSAVE
			   state length, as reported by	the xsave_len field
			   from	the struct ptrace_xstate_info of the
			   PT_GETXSTATE_INFO request.  Layout of the buffer is
			   identical to	the layout of the load area for	the
			   XRSTOR machine instruction.

     PT_GETFSBASE	   Return the value of the base	used when doing	seg-
			   mented memory addressing using the %fs segment reg-
			   ister.  The addr argument points to an unsigned
			   long	variable where the base	value is stored.

			   The data argument is	ignored.

     PT_GETGSBASE	   Like	the PT_GETFSBASE request, but returns the base
			   for the %gs segment register.

     PT_SETFSBASE	   Set the base	for the	%fs segment register to	the
			   value pointed to by the addr	argument.  addr	must
			   point to the	unsigned long variable containing the
			   new base.

			   The data argument is	ignored.

     PT_SETGSBASE	   Like	the PT_SETFSBASE request, but sets the base
			   for the %gs segment register.

PowerPC	MACHINE-SPECIFIC REQUESTS
     PT_GETVRREGS     Return the thread's ALTIVEC machine state	in the buffer
		      pointed to by addr.

		      The data argument	is ignored.

     PT_SETVRREGS     Set the thread's ALTIVEC machine state from the buffer
		      pointed to by addr.

		      The data argument	is ignored.

     Additionally, other machine-specific requests can exist.

RETURN VALUES
     Some requests can cause ptrace() to return	-1 as a	non-error value; to
     disambiguate, errno can be	set to 0 before	the call and checked after-
     wards.

ERRORS
     The ptrace() system call may fail if:

     [ESRCH]
			+o   No process having the specified process ID exists.

     [EINVAL]
			+o   A process attempted	to use PT_ATTACH on itself.
			+o   The	request	argument was not one of	the legal
			    requests.
			+o   The	signal number (in data)	to PT_CONTINUE was
			    neither 0 nor a legal signal number.
			+o   PT_GETREGS,	PT_SETREGS, PT_GETFPREGS,
			    PT_SETFPREGS, PT_GETDBREGS,	or PT_SETDBREGS	was
			    attempted on a process with	no valid register set.
			    (This is normally true only	of system processes.)
			+o   PT_VM_ENTRY	was given an invalid value for
			    pve_entry.	This can also be caused	by changes to
			    the	VM map of the process.
			+o   The	size (in data) provided	to PT_LWPINFO was less
			    than or equal to zero, or larger than the
			    ptrace_lwpinfo structure known to the kernel.
			+o   The	size (in data) provided	to the x86-specific
			    PT_GETXSTATE_INFO request was not equal to the
			    size of the	struct ptrace_xstate_info.
			+o   The	size (in data) provided	to the x86-specific
			    PT_SETXSTATE request was less than the size	of the
			    x87	plus the XMM save area.
			+o   The	size (in data) provided	to the x86-specific
			    PT_SETXSTATE request was larger than returned in
			    the	xsave_len member of the	struct
			    ptrace_xstate_info from the	PT_GETXSTATE_INFO
			    request.
			+o   The	base value, provided to	the amd64-specific
			    requests PT_SETFSBASE or PT_SETGSBASE, pointed
			    outside of the valid user address space.  This
			    error will not occur in 32-bit programs.

     [EBUSY]
			+o   PT_ATTACH was attempted on a process that was
			    already being traced.
			+o   A request attempted	to manipulate a	process	that
			    was	being traced by	some process other than	the
			    one	making the request.
			+o   A request (other than PT_ATTACH) specified a
			    process that was not stopped.

     [EPERM]
			+o   A request (other than PT_ATTACH) attempted to
			    manipulate a process that was not being traced at
			    all.
			+o   An attempt was made	to use PT_ATTACH on a process
			    in violation of the	requirements listed under
			    PT_ATTACH above.

     [ENOENT]
			+o   PT_VM_ENTRY	previously returned the	last entry of
			    the	memory map.  No	more entries exist.

     [ENAMETOOLONG]
			+o   PT_VM_ENTRY	cannot return the pathname of the
			    backing object because the buffer is not big
			    enough.  pve_pathlen holds the minimum buffer size
			    required on	return.

SEE ALSO
     execve(2),	sigaction(2), wait(2), execv(3), i386_clr_watch(3),
     i386_set_watch(3)

HISTORY
     The ptrace() function appeared in Version 7 AT&T UNIX.

FreeBSD	11.1		       December	29, 2015		  FreeBSD 11.1
NAME | LIBRARY | SYNOPSIS | DESCRIPTION | x86 MACHINE-SPECIFIC REQUESTS | PowerPC MACHINE-SPECIFIC REQUESTS | RETURN VALUES | ERRORS | SEE ALSO | HISTORY

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