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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, stepping by the tracing process, or an event in the traced
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.
A traced process may report additional signal stops corresponding to
events in the traced process. These additional signal stops are reported
as SIGTRAP or SIGSTOP signals. The tracing process can use the
PT_LWPINFO request to determine which events are associated with a
SIGTRAP or SIGSTOP signal. Note that multiple events may be associated
with a single signal. For example, events indicated by the PL_FLAG_BORN,
PL_FLAG_FORKED, and PL_FLAG_EXEC flags are also reported as a system call
exit event (PL_FLAG_SCX). The signal stop for a new child process
enabled via PTRACE_FORK will report a SIGSTOP signal. All other
additional signal stops use SIGTRAP.
DETACH AND TERMINATION
Normally, exiting tracing process should wait for all pending debugging
events and then detach from all alive traced processes before exiting
using PT_DETACH request. If tracing process exits without detaching, for
instance due to abnormal termination, the destiny of the traced children
processes is determined by the kern.kill_on_debugger_exit sysctl control.
anyway.
SELECTING THE TARGET
The pid argument of the call specifies the target on which to perform the
requested operation. For operations affecting the global process state,
the process ID is typically passed there. Similarly, for operations
affecting only a thread, the thread ID needs to be passed.
Still, for global operations, the ID of any thread can be used as the
target, and system will perform the request on the process owning that
thread. If a thread operation got the process ID as pid, the system
randomly selects a thread from among the threads owned by the process.
For single-threaded processes there is no difference between specifying
process or thread ID as the target.
DISABLING PTRACE
The ptrace subsystem provides rich facilities to manipulate other
processes state. Sometimes it may be desirable to disallow it either
completely, or limit its scope. The following controls are provided for
this:
security.bsd.allow_ptrace Setting this sysctl to zero makes
ptrace return ENOSYS always as if
the syscall is not implemented by
the kernel.
security.bsd.unprivileged_proc_debug Setting this sysctl to zero
disallows the use of ptrace() by
unprivileged processes.
security.bsd.see_other_uids Setting this sysctl to zero
prevents ptrace() requests from
targeting processes with a real
user identifier different from the
caller's. These requests will fail
with error ESRCH.
security.bsd.see_other_gids Setting this sysctl to zero
disallows ptrace() requests from
processes that have no groups in
common with the target process,
considering their sets of real and
supplementary groups. These
requests will fail with error
ESRCH.
security.bsd.see_jail_proc Setting this sysctl to zero
disallows ptrace() requests from
processes belonging to a different
jail than that of the target
process, even if the requesting
process' jail is an ancestor of the
target process'. These requests
will fail with error ESRCH.
securelevel and init The init(1) process can only be
traced with ptrace if securelevel
is zero.
process only reports a signal stop if the corresponding flag is set in
the tracing event mask. The current set of tracing event flags include:
PTRACE_EXEC Report a stop for a successful invocation of
execve(2). This event is indicated by the
PL_FLAG_EXEC flag in the pl_flags member of struct
ptrace_lwpinfo.
PTRACE_SCE Report a stop on each system call entry. This event
is indicated by the PL_FLAG_SCE flag in the pl_flags
member of struct ptrace_lwpinfo.
PTRACE_SCX Report a stop on each system call exit. This event is
indicated by the PL_FLAG_SCX flag in the pl_flags
member of struct ptrace_lwpinfo.
PTRACE_SYSCALL Report stops for both system call entry and exit.
PTRACE_FORK This event flag controls tracing for new child
processes of a traced process.
When this event flag is enabled, new child processes
will enable tracing and stop before executing their
first instruction. The new child process will include
the PL_FLAG_CHILD flag in the pl_flags member of
struct ptrace_lwpinfo. The traced process will report
a stop that includes the PL_FLAG_FORKED flag. The
process ID of the new child process will also be
present in the pl_child_pid member of struct
ptrace_lwpinfo. If the new child process was created
via vfork(2), the traced process's stop will also
include the PL_FLAG_VFORKED flag. Note that new child
processes will be attached with the default tracing
event mask; they do not inherit the event mask of the
traced process.
When this event flag is not enabled, new child
processes will execute without tracing enabled.
PTRACE_LWP This event flag controls tracing of LWP (kernel
thread) creation and destruction. When this event is
enabled, new LWPs will stop and report an event with
PL_FLAG_BORN set before executing their first
instruction, and exiting LWPs will stop and report an
event with PL_FLAG_EXITED set before completing their
termination.
Note that new processes do not report an event for the
creation of their initial thread, and exiting
processes do not report an event for the termination
of the last thread.
PTRACE_VFORK Report a stop event when a parent process resumes
after a vfork(2).
When a thread in the traced process creates a new
child process via vfork(2), the stop that reports
PL_FLAG_FORKED and PL_FLAG_SCX occurs just after the
child process is created, but before the thread waits
The PTRACE_VFORK flag enables a new stop that
indicates when the new child process stops sharing the
process memory of the parent process. A debugger can
reinsert breakpoints in the parent process and resume
it in response to this event. This event is indicated
by setting the PL_FLAG_VFORK_DONE flag.
The default tracing event mask when attaching to a process via PT_ATTACH,
PT_TRACE_ME, or PTRACE_FORK includes only PTRACE_EXEC events. All other
event flags are disabled.
PTRACE REQUESTS
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 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
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 instruction 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
executed.
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 supplies the value to be written.
PT_IO This request allows reading and writing arbitrary
amounts of data in the traced process's address
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 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_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
otherwise unrelated process and begin tracing it.
It does not need any cooperation from the process
to trace. In this case, pid specifies the process
ID of the process to trace, 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
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_GETREGSET This request reads the registers from the traced
process. The data argument specifies the register
set to read, with the addr argument pointing at a
struct iovec where the iov_base field points to a
register set specific structure to hold the
registers, and the iov_len field holds the length
of the structure.
PT_SETREGSET This request writes to the registers of the traced
process. The data argument specifies the register
set to write to, with the addr argument pointing at
a struct iovec where the iov_base field points to a
register set specific structure to hold the
registers, and the iov_len field holds the length
of the structure. If iov_base is NULL the kernel
will return the expected length of the register set
specific structure in the iov_len field and not
change the target register set.
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 specifies 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:
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 when
PTRACE_FORK is enabled.
PL_FLAG_BORN
This flag is set for the first
event reported from a new LWP when
PTRACE_LWP is enabled. It is
reported along with PL_FLAG_SCX.
PL_FLAG_EXITED
This flag is set for the last event
reported by an exiting LWP when
PTRACE_LWP is enabled. 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
PL_FLAG_VFORK_DONE
Indicates that the thread has
resumed after a child process
created via vfork(2) has stopped
sharing its address space with the
traced process.
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 system call not counting the system
call identifier. Note that for indirect
system calls this field reports the
arguments passed to the indirected system
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
associated 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. Stepping is automatically
disabled when a single step trap is caught.
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.
trace all future system call exits and continue the
process. The addr and data arguments are used the
same as for PT_CONTINUE.
PT_SYSCALL This request will set the PTRACE_SYSCALL event flag
to trace all future system call entries and exits
and continue the process. The addr and data
arguments are used the same as for PT_CONTINUE.
PT_GET_SC_ARGS For the thread which is stopped in either
PL_FLAG_SCE or PL_FLAG_SCX state, that is, on entry
or exit to a syscall, this request fetches the
syscall arguments.
The arguments are copied out into the buffer
pointed to by the addr pointer, sequentially. Each
syscall argument is stored as the machine word.
Kernel copies out as many arguments as the syscall
accepts, see the pl_syscall_narg member of the
struct ptrace_lwpinfo, but not more than the data
bytes in total are copied.
PT_GET_SC_RET Fetch the system call return values on exit from a
syscall. This request is only valid for threads
stopped in a syscall exit (the PL_FLAG_SCX state).
The addr argument specifies a pointer to a struct
ptrace_sc_ret, which is defined as follows:
struct ptrace_sc_ret {
register_t sr_retval[2];
int sr_error;
};
The data argument is set to the size of the
structure.
If the system call completed successfully, sr_error
is set to zero and the return values of the system
call are saved in sr_retval. If the system call
failed to execute, sr_error field is set to a
positive errno(2) value. If the system call
completed in an unusual fashion, sr_error is set to
a negative value:
ERESTART System call will be restarted.
EJUSTRETURN System call completed sucessfully but
did not set a return value (for
example, setcontext(2) and
sigreturn(2)).
PT_FOLLOW_FORK This request controls tracing for new child
processes of a traced process. If data is non-
zero, PTRACE_FORK is set in the traced process's
event tracing mask. If data is zero, PTRACE_FORK
is cleared from the traced process's event tracing
mask.
PT_LWP_EVENTS This request controls tracing of LWP creation and
The size of the integer must be passed in data.
PT_SET_EVENT_MASK This request sets the traced process's event
tracing mask from the integer pointed to by addr.
The size of the integer must be passed in data.
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 tracing 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 unmodified 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 pathname 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.
PT_COREDUMP This request creates a coredump for the stopped
program. The addr argument specifies a pointer to
a struct ptrace_coredump, which is defined as
follows:
struct ptrace_coredump {
int pc_fd;
uint32_t pc_flags;
pc_flags Flags. The following flags are defined:
PC_COMPRESS Request compression of the
dump.
PC_ALL Include non-dumpable entries
into the dump. The dumper
ignores MAP_NOCORE flag of
the process map entry, but
device mappings are not
dumped even with PC_ALL set.
pc_limit Maximum size of the coredump. Specify
zero for no limit.
The size of struct ptrace_coredump must be passed
in data.
PT_SC_REMOTE Request to execute a syscall in the context of the
traced process, in the specified thread. The addr
argument must point to the struct ptrace_sc_remote,
which describes the requested syscall and its
arguments, and receives the result. The size of
struct ptrace_sc_remote must be passed in data.
struct ptrace_sc_remote {
struct ptrace_sc_ret pscr_ret;
u_int pscr_syscall;
u_int pscr_nargs;
u_long *pscr_args;
};
The pscr_syscall contains the syscall number to
execute, the pscr_nargs is the number of supplied
arguments, which are supplied in the pscr_args
array. Result of the execution is returned in the
pscr_ret member. Note that the request and its
result do not affect the returned value from the
currently executed syscall, if any.
PT_COREDUMP and PT_SC_REMOTE usage
The process must be stopped before dumping or initiating a remote system
call. A single thread in the target process is temporarily unsuspended
in the kernel to perform the action. If the ptrace call fails before a
thread is unsuspended, there is no event to waitpid(2) for. If a thread
was unsuspended, it will stop again before the ptrace call returns, and
the process must be waited upon using waitpid(2) to consume the new stop
event. Since it is hard to deduce whether a thread was unsuspended
before an error occurred, it is recommended to unconditionally perform
waitpid(2) with WNOHANG flag after PT_COREDUMP and PT_SC_REMOTE, and
silently accept zero result from it.
For PT_SC_REMOTE, the selected thread must be stopped in the safe place,
which is currently defined as a syscall exit, or a return from kernel to
user mode (basically, a signal handler call place). Kernel returns EBUSY
status if attempt is made to execute remote syscall at unsafe stop.
Note that neither kern.trap_enotcap sysctl setting, nor the corresponding
procctl(2) flag PROC_TRAPCAP_CTL_ENABLE are obeyed during the execution
result in the target process deadlock. In this situation, the only way
out is to kill the target.
ARM MACHINE-SPECIFIC REQUESTS
PT_GETVFPREGS Return the thread's VFP machine state in the buffer
pointed to by addr.
The data argument is ignored.
PT_SETVFPREGS Set the thread's VFP machine state from the buffer
pointed to by addr.
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
layout 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
documentation. 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
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
segmented memory addressing using the %fs segment
register. 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.
PT_GETVSRREGS Return doubleword 1 of the thread's VSX registers
VSR0-VSR31 in the buffer pointed to by addr.
The data argument is ignored.
PT_SETVSRREGS Set doubleword 1 of the thread's VSX registers
VSR0-VSR31 from the buffer pointed to by addr.
The data argument is ignored.
Additionally, other machine-specific requests can exist.
RETURN VALUES
into the kernel, both for historic reasons and for consistency with other
operating systems. It is recommended to assign zero to errno explicitly
for forward compatibility.
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.
a memory allocation failure occurred when
accessing process memory.
[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 6 AT&T UNIX.
FreeBSD 14.0-RELEASE-p11 August 18, 2023 FreeBSD 14.0-RELEASE-p11