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Kirill Smelkov
linux
Commits
1f8870ed
Commit
1f8870ed
authored
May 27, 2003
by
Miles Bader
Committed by
Arnaldo Carvalho de Melo
May 27, 2003
Browse files
Options
Browse Files
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Email Patches
Plain Diff
[PATCH] Add v850 support for hardware single-step (via ptrace)
parent
7d136361
Changes
2
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Showing
2 changed files
with
310 additions
and
94 deletions
+310
-94
arch/v850/kernel/entry.S
arch/v850/kernel/entry.S
+177
-50
arch/v850/kernel/ptrace.c
arch/v850/kernel/ptrace.c
+133
-44
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arch/v850/kernel/entry.S
View file @
1f8870ed
...
...
@@ -235,25 +235,30 @@
sst.w
syscall_num
,
PTO
+
PT_CUR_SYSCALL
[
ep
]
/*
Save
register
state
not
normally
saved
by
PUSH_STATE
for
TYPE
.
*/
/*
Save
register
state
not
normally
saved
by
PUSH_STATE
for
TYPE
,
to
the
state
-
save
-
frame
on
the
stack
; also copies SP to EP. r19 may be trashed. */
#define SAVE_EXTRA_STATE(type) \
mov
sp
,
ep
; \
type
##
_EXTRA_STATE_SAVER
/*
Restore
register
state
not
normally
restored
by
POP_STATE
for
TYPE
.
*/
/*
Restore
register
state
not
normally
restored
by
POP_STATE
for
TYPE
,
from
the
state
-
save
-
frame
on
the
stack
; also copies SP to EP.
r19
may
be
trashed
.
*/
#define RESTORE_EXTRA_STATE(type) \
mov
sp
,
ep
; \
type
##
_EXTRA_STATE_RESTORER
/*
Save
any
call
-
clobbered
registers
not
normally
saved
by
PUSH_STATE
for
TYPE
.
*/
#define SAVE_EXTRA_STATE_FOR_FUNCALL(type) \
mov
sp
,
ep
; \
type
##
_FUNCALL_EXTRA_STATE_SAVER
/*
Restore
any
call
-
clobbered
registers
not
normally
restored
by
POP_STATE
for
TYPE
.
*/
#define RESTORE_EXTRA_STATE_FOR_FUNCALL(type) \
mov
sp
,
ep
; \
type
##
_FUNCALL_EXTRA_STATE_RESTORER
/*
Save
any
call
-
clobbered
registers
not
normally
saved
by
PUSH_STATE
for
TYPE
,
to
the
state
-
save
-
frame
on
the
stack
.
EP
may
be
trashed
,
but
is
not
guaranteed
to
contain
a
copy
of
SP
(
unlike
after
most
SAVE_
...
macros
)
.
r19
may
be
trashed
.
*/
#define SAVE_EXTRA_STATE_FOR_SCHEDULE(type) \
type
##
_SCHEDULE_EXTRA_STATE_SAVER
/*
Restore
any
call
-
clobbered
registers
not
normally
restored
by
POP_STATE
for
TYPE
,
to
the
state
-
save
-
frame
on
the
stack
.
EP
may
be
trashed
,
but
is
not
guaranteed
to
contain
a
copy
of
SP
(
unlike
after
most
RESTORE_
...
macros
)
.
r19
may
be
trashed
.
*/
#define RESTORE_EXTRA_STATE_FOR_SCHEDULE(type) \
type
##
_SCHEDULE_EXTRA_STATE_RESTORER
/*
These
are
extra_state_saver
/
restorer
values
for
a
user
trap
.
Note
...
...
@@ -264,36 +269,48 @@
caller
of
the
syscall
function
should
have
saved
them
.
*/
#define TRAP_RET reti
/*
Traps
don
't save call-clobbered registers (but do still save arg regs). */
/*
Traps
don
't save call-clobbered registers (but do still save arg regs).
We
preserve
PSw
to
keep
long
-
term
state
,
namely
interrupt
status
(
for
traps
from
kernel
-
mode
),
and
the
single
-
step
flag
(
for
user
traps
)
.
*/
#define TRAP_STATE_SAVER \
SAVE_ARG_REGS
; \
SAVE_PC
(
EIPC
)
SAVE_PC
(
EIPC
)
; \
SAVE_PSW
(
EIPSW
)
/*
When
traps
return
,
they
just
leave
call
-
clobbered
registers
(
except
for
arg
regs
)
with
whatever
value
they
have
from
the
kernel
.
*/
regs
)
with
whatever
value
they
have
from
the
kernel
.
Traps
don
't preserve
the
PSW
,
but
we
zero
EIPSW
to
ensure
it
doesn
't contain anything dangerous
(
in
particular
,
the
single
-
step
flag
)
.
*/
#define TRAP_STATE_RESTORER \
RESTORE_ARG_REGS
; \
RESTORE_PC
(
EIPC
)
RESTORE_PC
(
EIPC
)
; \
RESTORE_PSW
(
EIPSW
)
/*
Save
registers
not
normally
saved
by
traps
.
We
need
to
save
r12
,
even
though
it
's nominally call-clobbered, because it'
s
used
when
restarting
a
system
call
(
the
signal
-
handling
path
uses
SAVE_EXTRA_STATE
,
and
expects
r12
to
be
restored
when
the
trap
returns
)
.
Similarly
,
we
must
save
the
PSW
,
so
that
it
's at least in a known state in the the pt_regs
structure
.
*/
expects
r12
to
be
restored
when
the
trap
returns
)
.
*/
#define TRAP_EXTRA_STATE_SAVER \
SAVE_RVAL_REGS
; \
sst.w
r12
,
PTO
+
PT_GPR
(
12
)[
ep
]
; \
SAVE_CALL_SAVED_REGS
; \
SAVE_PSW
(
EIPSW
)
; \
SAVE_CT_REGS
#define TRAP_EXTRA_STATE_RESTORER \
RESTORE_RVAL_REGS
; \
sld.w
PTO
+
PT_GPR
(
12
)[
ep
],
r12
; \
RESTORE_CALL_SAVED_REGS
; \
RESTORE_PSW
(
EIPSW
)
; \
RESTORE_CT_REGS
#define TRAP_FUNCALL_EXTRA_STATE_SAVER \
/*
Save
registers
prior
to
calling
scheduler
(
just
before
trap
returns
)
.
We
have
to
save
the
return
-
value
registers
to
preserve
the
trap
's return
value
.
Note
that
...
_SCHEDULE_EXTRA_STATE_SAVER
,
unlike
most
...
_SAVER
macros
,
is
required
to
setup
EP
itself
if
EP
is
needed
(
this
is
because
in
many
cases
,
the
macro
is
empty
)
.
*/
#define TRAP_SCHEDULE_EXTRA_STATE_SAVER \
mov
sp
,
ep
; \
SAVE_RVAL_REGS
#define TRAP_FUNCALL_EXTRA_STATE_RESTORER \
/*
Note
that
...
_SCHEDULE_EXTRA_STATE_RESTORER
,
unlike
most
...
_RESTORER
macros
,
is
required
to
setup
EP
itself
if
EP
is
needed
(
this
is
because
in
many
cases
,
the
macro
is
empty
)
.
*/
#define TRAP_SCHEDULE_EXTRA_STATE_RESTORER \
mov
sp
,
ep
; \
RESTORE_RVAL_REGS
/*
Register
saving
/
restoring
for
maskable
interrupts
.
*/
...
...
@@ -391,32 +408,33 @@
ld.w
TI_FLAGS
[
r18
],
r19
; \
andi
_TIF_NEED_RESCHED
,
r19
,
r0
; \
bnz
3
f
; /* Call the scheduler. */ \
andi
_TIF_SIGPENDING
,
r19
,
r0
; \
bnz
4
f
; /* Signals to handle, handle them */ \
5
:
andi
_TIF_SIGPENDING
,
r19
,
r18
; \
ld.w
TASK_PTRACE
[
CURRENT_TASK
],
r19
; /* ptrace flags */ \
or
r18
,
r19
; /* see if either is non-zero */ \
bnz
4
f
; /* if so, handle them */ \
\
/*
Return
to
user
state
.
*/
\
1
:
st.b
r0
,
KM
; /* Now officially in user state. */ \
\
/*
Final
return
.
The
stack
-
pointer
fiddling
is
not
needed
when
returning
\
to
kernel
-
mode
,
but
they
don
't hurt, and this way we can share the \
(
somtimes
rather
lengthy
)
POP_STATE
macro
.
*/
\
(
som
e
times
rather
lengthy
)
POP_STATE
macro
.
*/
\
2
:
POP_STATE
(
type
)
; \
st.w
sp
,
KSP
; /* Save the kernel stack pointer. */ \
ld.w
PT_GPR
(
GPR_SP
)-
PT_SIZE
[
sp
],
sp
; /* Restore stack pointer. */ \
type
##
_RET
; /* Return from the trap/interrupt. */ \
\
/*
Call
the
scheduler
before
returning
from
a
syscall
/
trap
.
*/
\
3
:
SAVE_EXTRA_STATE_FOR_
FUNCALL
(
type
)
; /* Prepare for funcall. */
\
jarl
CSYM
(
schedule
)
,
lp
; /* Call scheduler */ \
3
:
SAVE_EXTRA_STATE_FOR_
SCHEDULE
(
type
)
; /* Prepare to call scheduler. */
\
jarl
call_scheduler
,
lp
; /* Call scheduler */ \
di
; /* The scheduler enables interrupts */\
RESTORE_EXTRA_STATE_FOR_
FUNCALL
(
type
)
; \
RESTORE_EXTRA_STATE_FOR_
SCHEDULE
(
type
)
; \
GET_CURRENT_THREAD
(
r18
)
; \
ld.w
TI_FLAGS
[
r18
],
r19
; \
andi
_TIF_SIGPENDING
,
r19
,
r0
; \
bz
1
b
; /* No signals, return. */ \
/
*
Signals
to
handle
,
fall
through
to
handle
them
.
*/
\
br
5
b
; /* Continue with return path. */ \
\
/*
Handle
a
signal
return
.
*/
\
/*
Handle
a
signal
or
ptraced
process
return
.
\
r18
should
be
non
-
zero
if
there
are
pending
signals
.
*/
\
4
:
/
*
Not
all
registers
are
saved
by
the
normal
trap
/
interrupt
entry
\
points
(
for
instance
,
call
-
saved
registers
(
because
the
normal
\
C
-
compiler
calling
sequence
in
the
kernel
makes
sure
they
're \
...
...
@@ -426,10 +444,7 @@
the
normal
entry
sequence
,
so
that
it
may
be
safely
restored
\
(
in
a
possibly
modified
form
)
after
do_signal
returns
.
*/
\
SAVE_EXTRA_STATE
(
type
)
; /* Save state not saved by entry. */ \
movea
PTO
,
sp
,
r6
; /* Arg 1: struct pt_regs *regs */ \
mov
r0
,
r7
; /* Arg 2: sigset_t *oldset */ \
jarl
CSYM
(
do_signal
),
lp
; /* Handle any signals */ \
di
; /* sig handling enables interrupts */ \
jarl
handle_signal_or_ptrace_return
,
lp
; \
RESTORE_EXTRA_STATE
(
type
)
; /* Restore extra regs. */ \
br
1
b
...
...
@@ -680,20 +695,48 @@ END(irq)
G_ENTRY
(
dbtrap
):
SAVE_STATE
(
DBTRAP
,
r0
,
ENTRY_SP
)//
Save
registers
.
/
*
First
see
if
we
came
from
kernel
mode
; if so, the dbtrap
instruction
has
a
special
meaning
,
to
set
the
DIR
(
`
debug
information
register
') register. This is because the DIR register
can
_only_
be
manipulated
/
read
while
in
`
debug
mode
,
' and debug
mode
is
only
active
while
we
're inside the dbtrap handler. The
exact
functionality
is
:
{
DIR
=
(
DIR
|
r6
)
&
~
r7
; return DIR; }. */
ld.b
PTO
+
PT_KERNEL_MODE
[
sp
],
r19
cmp
r19
,
r0
bz
1
f
stsr
SR_DIR
,
r10
or
r6
,
r10
not
r7
,
r7
and
r7
,
r10
ldsr
r10
,
SR_DIR
stsr
SR_DIR
,
r10
//
Confirm
the
value
we
set
st.w
r10
,
PTO
+
PT_GPR
(
10
)[
sp
]
//
return
it
br
3
f
1
:
ei
//
Enable
interrupts
.
/
*
The
default
signal
type
we
raise
.
*/
mov
SIGTRAP
,
r6
/
*
See
if
it
's a single-step trap. */
stsr
SR_DBPSW
,
r19
andi
0x0800
,
r19
,
r19
bnz
2
f
/
*
Look
to
see
if
the
preceding
instruction
was
is
a
dbtrap
or
not
,
to
decide
which
signal
we
should
use
.
*/
stsr
SR_DBPC
,
r19
//
PC
following
trapping
insn
ld.hu
-
2
[
r19
],
r19
mov
SIGTRAP
,
r6
ori
0xf840
,
r0
,
r20
//
DBTRAP
insn
cmp
r19
,
r20
//
Was
this
trap
caused
by
DBTRAP
?
cmov
ne
,
SIGILL
,
r6
,
r6
//
Choose
signal
appropriately
/
*
Raise
the
desired
signal
.
*/
mov
CURRENT_TASK
,
r7
//
Arg
1
:
task
jarl
CSYM
(
force
_sig
),
lp
//
tail
call
2
:
mov
CURRENT_TASK
,
r7
//
Arg
1
:
task
jarl
CSYM
(
send
_sig
),
lp
//
tail
call
RETURN
(
DBTRAP
)
3
:
RETURN
(
DBTRAP
)
END
(
dbtrap
)
...
...
@@ -734,6 +777,90 @@ L_ENTRY(bad_trap_wrapper):
END
(
bad_trap_wrapper
)
/*
*
Invoke
the
scheduler
,
called
from
the
trap
/
irq
kernel
exit
path
.
*
*
This
basically
just
calls
`
schedule
', but also arranges for extra
*
registers
to
be
saved
for
ptrace
'd processes, so ptrace can modify them.
*/
L_ENTRY
(
call_scheduler
):
ld.w
TASK_PTRACE
[
CURRENT_TASK
],
r19
//
See
if
task
is
ptrace
'd
cmp
r19
,
r0
bnz
1
f
//
...
yes
,
do
special
stuff
jr
CSYM
(
schedule
)
//
...
no
,
just
tail
-
call
scheduler
//
Save
extra
regs
for
ptrace
'd task. We want to save anything
//
that
would
otherwise
only
be
`
implicitly
' saved by the normal
//
compiler
calling
-
convention
.
1
:
mov
sp
,
ep
//
Setup
EP
for
SAVE_CALL_SAVED_REGS
SAVE_CALL_SAVED_REGS
//
Save
call
-
saved
registers
to
stack
mov
lp
,
r20
//
Save
LP
in
a
callee
-
saved
register
jarl
CSYM
(
schedule
),
lp
//
Call
scheduler
mov
r20
,
lp
mov
sp
,
ep
//
We
can
't rely on EP after return
RESTORE_CALL_SAVED_REGS
//
Restore
(
possibly
modified
)
regs
jmp
[
lp
]
//
Return
to
the
return
path
END
(
call_scheduler
)
/*
*
This
is
an
out
-
of
-
line
handler
for
two
special
cases
during
the
kernel
*
trap
/
irq
exit
sequence
:
*
*
(
1
)
If
r18
is
non
-
zero
then
a
signal
needs
to
be
handled
,
which
is
*
done
,
and
then
the
caller
returned
to
.
*
*
(
2
)
If
r18
is
non
-
zero
then
we
're returning to a ptraced process, which
*
has
several
special
cases
--
single
-
stepping
and
trap
tracing
,
both
*
of
which
require
using
the
`
dbret
' instruction to exit the kernel
*
instead
of
the
normal
`
reti
' (this is because the CPU not correctly
*
single
-
step
after
a
reti
)
.
In
this
case
,
of
course
,
this
handler
*
never
returns
to
the
caller
.
*
*
In
either
case
,
all
registers
should
have
been
saved
to
the
current
*
state
-
save
-
frame
on
the
stack
,
except
for
callee
-
saved
registers
.
*
*
[
These
two
different
cases
are
combined
merely
to
avoid
bloating
the
*
macro
-
inlined
code
,
not
because
they
really
make
much
sense
together
!]
*/
L_ENTRY
(
handle_signal_or_ptrace_return
):
cmp
r18
,
r0
//
See
if
handling
a
signal
bz
1
f
//
...
nope
,
go
do
ptrace
return
//
Handle
a
signal
mov
lp
,
r20
//
Save
link
-
pointer
mov
r10
,
r21
//
Save
return
-
values
(
for
trap
)
mov
r11
,
r22
movea
PTO
,
sp
,
r6
//
Arg
1
:
struct
pt_regs
*
regs
mov
r0
,
r7
//
Arg
2
:
sigset_t
*
oldset
jarl
CSYM
(
do_signal
),
lp
//
Handle
the
signal
di
//
sig
handling
enables
interrupts
mov
r20
,
lp
//
Restore
link
-
pointer
mov
r21
,
r10
//
Restore
return
-
values
(
for
trap
)
mov
r22
,
r11
ld.w
TASK_PTRACE
[
CURRENT_TASK
],
r19
//
check
ptrace
flags
too
cmp
r19
,
r0
bnz
1
f
//
...
some
set
,
so
look
more
2
:
jmp
[
lp
]
//
...
none
set
,
so
return
normally
//
ptrace
return
1
:
ld.w
PTO
+
PT_PSW
[
sp
],
r19
//
Look
at
user
-
processes
's flags
andi
0x0800
,
r19
,
r19
//
See
if
single
-
step
flag
is
set
bz
2
b
//
...
nope
,
return
normally
//
Return
as
if
from
a
dbtrap
insn
st.b
r0
,
KM
//
Now
officially
in
user
state
.
POP_STATE
(
DBTRAP
)
//
Restore
regs
st.w
sp
,
KSP
//
Save
the
kernel
stack
pointer
.
ld.w
PT_GPR
(
GPR_SP
)-
PT_SIZE
[
sp
],
sp
//
Restore
user
stack
pointer
.
DBTRAP_RET
//
Return
from
the
trap
/
interrupt
.
END
(
handle_signal_or_ptrace_return
)
/*
*
This
is
where
we
switch
between
two
threads
.
The
arguments
are
:
*
r6
--
pointer
to
the
struct
thread
for
the
`
current
' process
...
...
arch/v850/kernel/ptrace.c
View file @
1f8870ed
/*
* arch/v850/kernel/ptrace.c -- `ptrace' system call
*
* Copyright (C) 2002
NEC
Corporation
* Copyright (C) 2002 Miles Bader <miles@gnu.org>
* Copyright (C) 2002
,03 NEC Electronics
Corporation
* Copyright (C) 2002
,03
Miles Bader <miles@gnu.org>
*
* Derived from arch/mips/kernel/ptrace.c:
*
...
...
@@ -29,6 +29,89 @@
#include <asm/processor.h>
#include <asm/uaccess.h>
/* Returns the address where the register at REG_OFFS in P is stashed away. */
static
v850_reg_t
*
reg_save_addr
(
unsigned
reg_offs
,
struct
task_struct
*
t
)
{
struct
pt_regs
*
regs
;
/* Three basic cases:
(1) A register normally saved before calling the scheduler, is
available in the kernel entry pt_regs structure at the top
of the kernel stack. The kernel trap/irq exit path takes
care to save/restore almost all registers for ptrace'd
processes.
(2) A call-clobbered register, where the process P entered the
kernel via [syscall] trap, is not stored anywhere; that's
OK, because such registers are not expected to be preserved
when the trap returns anyway (so we don't actually bother to
test for this case).
(3) A few registers not used at all by the kernel, and so
normally never saved except by context-switches, are in the
context switch state. */
if
(
reg_offs
==
PT_CTPC
||
reg_offs
==
PT_CTPSW
||
reg_offs
==
PT_CTBP
)
/* Register saved during context switch. */
regs
=
thread_saved_regs
(
t
);
else
/* Register saved during kernel entry (or not available). */
regs
=
task_regs
(
t
);
return
(
v850_reg_t
*
)((
char
*
)
regs
+
reg_offs
);
}
/* Set the bits SET and clear the bits CLEAR in the v850e DIR
(`debug information register'). Returns the new value of DIR. */
static
inline
v850_reg_t
set_dir
(
v850_reg_t
set
,
v850_reg_t
clear
)
{
register
v850_reg_t
rval
asm
(
"r10"
);
register
v850_reg_t
arg0
asm
(
"r6"
)
=
set
;
register
v850_reg_t
arg1
asm
(
"r7"
)
=
clear
;
/* The dbtrap handler has exactly this functionality when called
from kernel mode. 0xf840 is a `dbtrap' insn. */
asm
(
".short 0xf840"
:
"=r"
(
rval
)
:
"r"
(
arg0
),
"r"
(
arg1
));
return
rval
;
}
/* Makes sure hardware single-stepping is (globally) enabled.
Returns true if successful. */
static
inline
int
enable_single_stepping
(
void
)
{
static
int
enabled
=
0
;
/* Remember whether we already did it. */
if
(
!
enabled
)
{
/* Turn on the SE (`single-step enable') bit, 0x100, in the
DIR (`debug information register'). This may fail if a
processor doesn't support it or something. We also try
to clear bit 0x40 (`INI'), which is necessary to use the
debug stuff on the v850e2; on the v850e, clearing 0x40
shouldn't cause any problem. */
v850_reg_t
dir
=
set_dir
(
0x100
,
0x40
);
/* Make sure it really got set. */
if
(
dir
&
0x100
)
enabled
=
1
;
}
return
enabled
;
}
/* Try to set CHILD's single-step flag to VAL. Returns true if successful. */
static
int
set_single_step
(
struct
task_struct
*
t
,
int
val
)
{
v850_reg_t
*
psw_addr
=
reg_save_addr
(
PT_PSW
,
t
);
if
(
val
)
{
/* Make sure single-stepping is enabled. */
if
(
!
enable_single_stepping
())
return
0
;
/* Set T's single-step flag. */
*
psw_addr
|=
0x800
;
}
else
*
psw_addr
&=
~
0x800
;
return
1
;
}
int
sys_ptrace
(
long
request
,
long
pid
,
long
addr
,
long
data
)
{
struct
task_struct
*
child
;
...
...
@@ -36,12 +119,6 @@ int sys_ptrace(long request, long pid, long addr, long data)
lock_kernel
();
#if 0
printk("ptrace(r=%d,pid=%d,addr=%08lx,data=%08lx)\n",
(int) request, (int) pid, (unsigned long) addr,
(unsigned long) data);
#endif
if
(
request
==
PTRACE_TRACEME
)
{
/* are we already being traced? */
if
(
current
->
ptrace
&
PT_PTRACED
)
{
...
...
@@ -81,31 +158,15 @@ int sys_ptrace(long request, long pid, long addr, long data)
goto
out_tsk
;
switch
(
request
)
{
case
PTRACE_PEEKTEXT
:
/* read word at location addr. */
case
PTRACE_PEEKDATA
:{
unsigned
long
tmp
;
int
copied
;
unsigned
long
val
,
copied
;
copied
=
access_process_vm
(
child
,
addr
,
&
tmp
,
sizeof
(
tmp
),
0
);
case
PTRACE_PEEKTEXT
:
/* read word at location addr. */
case
PTRACE_PEEKDATA
:
copied
=
access_process_vm
(
child
,
addr
,
&
val
,
sizeof
(
val
),
0
);
rval
=
-
EIO
;
if
(
copied
!=
sizeof
(
tmp
))
if
(
copied
!=
sizeof
(
val
))
break
;
rval
=
put_user
(
tmp
,(
unsigned
long
*
)
data
);
goto
out
;
}
/* Read the word at location addr in the USER area. */
case
PTRACE_PEEKUSR
:
if
(
addr
>=
0
&&
addr
<
PT_SIZE
&&
(
addr
&
0x3
)
==
0
)
{
struct
pt_regs
*
regs
=
task_regs
(
child
);
unsigned
long
val
=
*
(
unsigned
long
*
)((
char
*
)
regs
+
addr
);
rval
=
put_user
(
val
,
(
unsigned
long
*
)
data
);
}
else
{
rval
=
0
;
rval
=
-
EIO
;
}
rval
=
put_user
(
val
,
(
unsigned
long
*
)
data
);
goto
out
;
case
PTRACE_POKETEXT
:
/* write the word at location addr. */
...
...
@@ -117,27 +178,54 @@ int sys_ptrace(long request, long pid, long addr, long data)
rval
=
-
EIO
;
goto
out
;
/* Read/write the word at location ADDR in the registers. */
case
PTRACE_PEEKUSR
:
case
PTRACE_POKEUSR
:
if
(
addr
>=
0
&&
addr
<
PT_SIZE
&&
(
addr
&
0x3
)
==
0
)
{
struct
pt_regs
*
regs
=
task_regs
(
child
);
unsigned
long
*
loc
=
(
unsigned
long
*
)((
char
*
)
regs
+
addr
);
*
loc
=
data
;
}
else
{
rval
=
0
;
if
(
addr
>=
PT_SIZE
&&
request
==
PTRACE_PEEKUSR
)
{
/* Special requests that don't actually correspond
to offsets in struct pt_regs. */
if
(
addr
==
PT_TEXT_ADDR
)
val
=
child
->
mm
->
start_code
;
else
if
(
addr
==
PT_DATA_ADDR
)
val
=
child
->
mm
->
start_data
;
else
if
(
addr
==
PT_TEXT_LEN
)
val
=
child
->
mm
->
end_code
-
child
->
mm
->
start_code
;
else
rval
=
-
EIO
;
}
}
else
if
(
addr
>=
0
&&
addr
<
PT_SIZE
&&
(
addr
&
0x3
)
==
0
)
{
v850_reg_t
*
reg_addr
=
reg_save_addr
(
addr
,
child
);
if
(
request
==
PTRACE_PEEKUSR
)
val
=
*
reg_addr
;
else
*
reg_addr
=
data
;
}
else
rval
=
-
EIO
;
if
(
rval
==
0
&&
request
==
PTRACE_PEEKUSR
)
rval
=
put_user
(
val
,
(
unsigned
long
*
)
data
);
goto
out
;
case
PTRACE_SYSCALL
:
/* continue and stop at next (return from) syscall */
case
PTRACE_CONT
:
/* rvaltart after signal. */
/* Continue and stop at next (return from) syscall */
case
PTRACE_SYSCALL
:
/* Restart after a signal. */
case
PTRACE_CONT
:
/* Execute a single instruction. */
case
PTRACE_SINGLESTEP
:
rval
=
-
EIO
;
if
((
unsigned
long
)
data
>
_NSIG
)
break
;
/* Turn CHILD's single-step flag on or off. */
if
(
!
set_single_step
(
child
,
request
==
PTRACE_SINGLESTEP
))
break
;
if
(
request
==
PTRACE_SYSCALL
)
set_tsk_thread_flag
(
child
,
TIF_SYSCALL_TRACE
);
else
clear_tsk_thread_flag
(
child
,
TIF_SYSCALL_TRACE
);
child
->
exit_code
=
data
;
wake_up_process
(
child
);
rval
=
0
;
...
...
@@ -157,6 +245,7 @@ int sys_ptrace(long request, long pid, long addr, long data)
break
;
case
PTRACE_DETACH
:
/* detach a process that was attached. */
set_single_step
(
child
,
0
);
/* Clear single-step flag */
rval
=
ptrace_detach
(
child
,
data
);
break
;
...
...
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