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nexedi
linux
Commits
82d007ae
Commit
82d007ae
authored
Oct 05, 2003
by
Russell King
Browse files
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parents
d1054d95
d24e45f8
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5 changed files
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282 additions
and
265 deletions
+282
-265
arch/arm/lib/lib1funcs.S
arch/arm/lib/lib1funcs.S
+260
-257
arch/arm/mach-pxa/irq.c
arch/arm/mach-pxa/irq.c
+13
-3
arch/arm/mach-pxa/lubbock.c
arch/arm/mach-pxa/lubbock.c
+2
-1
include/asm-arm/arch-pxa/irqs.h
include/asm-arm/arch-pxa/irqs.h
+5
-3
include/asm-arm/arch-pxa/lubbock.h
include/asm-arm/arch-pxa/lubbock.h
+2
-1
No files found.
arch/arm/lib/lib1funcs.S
View file @
82d007ae
@
libgcc1
routines
for
ARM
cpu
.
@
Division
routines
,
written
by
Richard
Earnshaw
,
(
rearnsha
@
armltd
.
co
.
uk
)
/*
*
linux
/
arch
/
arm
/
lib
/
lib1funcs
.
S
:
Optimized
ARM
division
routines
*
*
Author
:
Nicolas
Pitre
<
nico
@
cam
.
org
>
*
-
contributed
to
gcc
-
3
.4
on
Sep
30
,
2003
*
-
adapted
for
the
Linux
kernel
on
Oct
2
,
2003
*/
/*
Copyright
(
C
)
1995
,
1996
,
1998
Free
Software
Foundation
,
Inc
.
/*
Copyright
1995
,
1996
,
1998
,
1999
,
2000
,
2003
Free
Software
Foundation
,
Inc
.
This
file
is
free
software
; you can redistribute it and/or modify it
under
the
terms
of
the
GNU
General
Public
License
as
published
by
the
...
...
@@ -10,11 +15,12 @@ later version.
In
addition
to
the
permissions
in
the
GNU
General
Public
License
,
the
Free
Software
Foundation
gives
you
unlimited
permission
to
link
the
compiled
version
of
this
file
with
other
programs
,
and
to
distribute
those
programs
without
any
restriction
coming
from
the
use
of
this
file
.
(
The
General
Public
License
restrictions
do
apply
in
other
respects
; for example, they cover modification of the file, and
distribution
when
not
linked
into
another
program
.
)
compiled
version
of
this
file
into
combinations
with
other
programs
,
and
to
distribute
those
combinations
without
any
restriction
coming
from
the
use
of
this
file
.
(
The
General
Public
License
restrictions
do
apply
in
other
respects
; for example, they cover modification of
the
file
,
and
distribution
when
not
linked
into
a
combine
executable
.)
This
file
is
distributed
in
the
hope
that
it
will
be
useful
,
but
WITHOUT
ANY
WARRANTY
; without even the implied warranty of
...
...
@@ -26,286 +32,283 @@ along with this program; see the file COPYING. If not, write to
the
Free
Software
Foundation
,
59
Temple
Place
-
Suite
330
,
Boston
,
MA
02111
-
1307
,
USA
.
*/
/*
As
a
special
exception
,
if
you
link
this
library
with
other
files
,
some
of
which
are
compiled
with
GCC
,
to
produce
an
executable
,
this
library
does
not
by
itself
cause
the
resulting
executable
to
be
covered
by
the
GNU
General
Public
License
.
This
exception
does
not
however
invalidate
any
other
reasons
why
the
executable
file
might
be
covered
by
the
GNU
General
Public
License
.
*/
/*
This
code
is
derived
from
gcc
2
.95.3
*
29
/
07
/
01
Adapted
for
linux
*
27
/
03
/
03
Ian
Molton
Clean
up
CONFIG_CPU
*/
#include <linux/linkage.h>
#include <asm/assembler.h>
#include <asm/hardware.h>
#define RET mov
#define RETc(x) mov##x
#define RETCOND
dividend
.
req
r0
divisor
.
req
r1
result
.
req
r2
overdone
.
req
r2
curbit
.
req
r3
.
macro
ARM_DIV_BODY
dividend
,
divisor
,
result
,
curbit
#if __LINUX_ARM_ARCH__ >= 5
clz
\
curbit
,
\
divisor
clz
\
result
,
\
dividend
sub
\
result
,
\
curbit
,
\
result
mov
\
curbit
,
#
1
mov
\
divisor
,
\
divisor
,
lsl
\
result
mov
\
curbit
,
\
curbit
,
lsl
\
result
mov
\
result
,
#
0
#else
@
Initially
shift
the
divisor
left
3
bits
if
possible
,
@
set
curbit
accordingly
.
This
allows
for
curbit
to
be
located
@
at
the
left
end
of
each
4
bit
nibbles
in
the
division
loop
@
to
save
one
loop
in
most
cases
.
tst
\
divisor
,
#
0xe0000000
moveq
\
divisor
,
\
divisor
,
lsl
#
3
moveq
\
curbit
,
#
8
movne
\
curbit
,
#
1
ENTRY
(
__udivsi3
)
cmp
divisor
,
#
0
beq
Ldiv0
mov
curbit
,
#
1
mov
result
,
#
0
cmp
dividend
,
divisor
bcc
Lgot_result_udivsi3
1
:
@
Unless
the
divisor
is
very
big
,
shift
it
up
in
multiples
of
@
four
bits
,
since
this
is
the
amount
of
unwinding
in
the
main
@
division
loop
.
Continue
shifting
until
the
divisor
is
@
larger
than
the
dividend
.
cmp
divisor
,
#
0x10000000
cmp
cc
divisor
,
dividend
mov
cc
divisor
,
divisor
,
lsl
#
4
mov
cc
curbit
,
curbit
,
lsl
#
4
b
cc
1
b
1
:
cmp
\
divisor
,
#
0x10000000
cmp
lo
\
divisor
,
\
dividend
mov
lo
\
divisor
,
\
divisor
,
lsl
#
4
mov
lo
\
curbit
,
\
curbit
,
lsl
#
4
b
lo
1
b
2
:
@
For
very
big
divisors
,
we
must
shift
it
a
bit
at
a
time
,
or
@
we
will
be
in
danger
of
overflowing
.
cmp
divisor
,
#
0x80000000
cmpcc
divisor
,
dividend
movcc
divisor
,
divisor
,
lsl
#
1
movcc
curbit
,
curbit
,
lsl
#
1
bcc
2
b
3
:
@
Test
for
possible
subtractions
,
and
note
which
bits
@
are
done
in
the
result
.
On
the
final
pass
,
this
may
subtract
@
too
much
from
the
dividend
,
but
the
result
will
be
ok
,
since
the
@
"bit"
will
have
been
shifted
out
at
the
bottom
.
cmp
dividend
,
divisor
subcs
dividend
,
dividend
,
divisor
orrcs
result
,
result
,
curbit
cmp
dividend
,
divisor
,
lsr
#
1
subcs
dividend
,
dividend
,
divisor
,
lsr
#
1
orrcs
result
,
result
,
curbit
,
lsr
#
1
cmp
dividend
,
divisor
,
lsr
#
2
subcs
dividend
,
dividend
,
divisor
,
lsr
#
2
orrcs
result
,
result
,
curbit
,
lsr
#
2
cmp
dividend
,
divisor
,
lsr
#
3
subcs
dividend
,
dividend
,
divisor
,
lsr
#
3
orrcs
result
,
result
,
curbit
,
lsr
#
3
cmp
dividend
,
#
0
@
Early
termination
?
movnes
curbit
,
curbit
,
lsr
#
4
@
No
,
any
more
bits
to
do
?
movne
divisor
,
divisor
,
lsr
#
4
bne
3
b
Lgot_result_udivsi3
:
mov
r0
,
result
RET
pc
,
lr
1
:
cmp
\
divisor
,
#
0x80000000
cmplo
\
divisor
,
\
dividend
movlo
\
divisor
,
\
divisor
,
lsl
#
1
movlo
\
curbit
,
\
curbit
,
lsl
#
1
blo
1
b
Ldiv0
:
str
lr
,
[
sp
,
#-
4
]!
bl
__div0
mov
r0
,
#
0
@
about
as
wrong
as
it
could
be
ldmia
sp
!,
{
pc
}
RETCOND
mov
\
result
,
#
0
/*
__umodsi3
-----------------------
*/
#endif
@
Division
loop
1
:
cmp
\
dividend
,
\
divisor
subhs
\
dividend
,
\
dividend
,
\
divisor
orrhs
\
result
,
\
result
,
\
curbit
cmp
\
dividend
,
\
divisor
,
lsr
#
1
subhs
\
dividend
,
\
dividend
,
\
divisor
,
lsr
#
1
orrhs
\
result
,
\
result
,
\
curbit
,
lsr
#
1
cmp
\
dividend
,
\
divisor
,
lsr
#
2
subhs
\
dividend
,
\
dividend
,
\
divisor
,
lsr
#
2
orrhs
\
result
,
\
result
,
\
curbit
,
lsr
#
2
cmp
\
dividend
,
\
divisor
,
lsr
#
3
subhs
\
dividend
,
\
dividend
,
\
divisor
,
lsr
#
3
orrhs
\
result
,
\
result
,
\
curbit
,
lsr
#
3
cmp
\
dividend
,
#
0
@
Early
termination
?
movnes
\
curbit
,
\
curbit
,
lsr
#
4
@
No
,
any
more
bits
to
do
?
movne
\
divisor
,
\
divisor
,
lsr
#
4
bne
1
b
.
endm
.
macro
ARM_DIV2_ORDER
divisor
,
order
#if __LINUX_ARM_ARCH__ >= 5
clz
\
order
,
\
divisor
rsb
\
order
,
\
order
,
#
31
#else
cmp
\
divisor
,
#(
1
<<
16
)
movhs
\
divisor
,
\
divisor
,
lsr
#
16
movhs
\
order
,
#
16
movlo
\
order
,
#
0
cmp
\
divisor
,
#(
1
<<
8
)
movhs
\
divisor
,
\
divisor
,
lsr
#
8
addhs
\
order
,
\
order
,
#
8
cmp
\
divisor
,
#(
1
<<
4
)
movhs
\
divisor
,
\
divisor
,
lsr
#
4
addhs
\
order
,
\
order
,
#
4
cmp
\
divisor
,
#(
1
<<
2
)
addhi
\
order
,
\
order
,
#
3
addls
\
order
,
\
order
,
\
divisor
,
lsr
#
1
#endif
.
endm
.
macro
ARM_MOD_BODY
dividend
,
divisor
,
order
,
spare
#if __LINUX_ARM_ARCH__ >= 5
clz
\
order
,
\
divisor
clz
\
spare
,
\
dividend
sub
\
order
,
\
order
,
\
spare
mov
\
divisor
,
\
divisor
,
lsl
\
order
#else
mov
\
order
,
#
0
ENTRY
(
__umodsi3
)
cmp
divisor
,
#
0
beq
Ldiv0
mov
curbit
,
#
1
cmp
dividend
,
divisor
RETc
(
cc
)
pc
,
lr
1
:
@
Unless
the
divisor
is
very
big
,
shift
it
up
in
multiples
of
@
four
bits
,
since
this
is
the
amount
of
unwinding
in
the
main
@
division
loop
.
Continue
shifting
until
the
divisor
is
@
larger
than
the
dividend
.
cmp
divisor
,
#
0x10000000
cmp
cc
divisor
,
dividend
mov
cc
divisor
,
divisor
,
lsl
#
4
movcc
curbit
,
curbit
,
lsl
#
4
b
cc
1
b
1
:
cmp
\
divisor
,
#
0x10000000
cmp
lo
\
divisor
,
\
dividend
mov
lo
\
divisor
,
\
divisor
,
lsl
#
4
addlo
\
order
,
\
order
,
#
4
b
lo
1
b
2
:
@
For
very
big
divisors
,
we
must
shift
it
a
bit
at
a
time
,
or
@
we
will
be
in
danger
of
overflowing
.
cmp
divisor
,
#
0x80000000
cmpcc
divisor
,
dividend
movcc
divisor
,
divisor
,
lsl
#
1
movcc
curbit
,
curbit
,
lsl
#
1
bcc
2
b
3
:
@
Test
for
possible
subtractions
.
On
the
final
pass
,
this
may
@
subtract
too
much
from
the
dividend
,
so
keep
track
of
which
@
subtractions
are
done
,
we
can
fix
them
up
afterwards
...
mov
overdone
,
#
0
cmp
dividend
,
divisor
subcs
dividend
,
dividend
,
divisor
cmp
dividend
,
divisor
,
lsr
#
1
subcs
dividend
,
dividend
,
divisor
,
lsr
#
1
orrcs
overdone
,
overdone
,
curbit
,
ror
#
1
cmp
dividend
,
divisor
,
lsr
#
2
subcs
dividend
,
dividend
,
divisor
,
lsr
#
2
orrcs
overdone
,
overdone
,
curbit
,
ror
#
2
cmp
dividend
,
divisor
,
lsr
#
3
subcs
dividend
,
dividend
,
divisor
,
lsr
#
3
orrcs
overdone
,
overdone
,
curbit
,
ror
#
3
mov
ip
,
curbit
cmp
dividend
,
#
0
@
Early
termination
?
movnes
curbit
,
curbit
,
lsr
#
4
@
No
,
any
more
bits
to
do
?
movne
divisor
,
divisor
,
lsr
#
4
bne
3
b
@
Any
subtractions
that
we
should
not
have
done
will
be
recorded
in
@
the
top
three
bits
of
"overdone"
.
Exactly
which
were
not
needed
@
are
governed
by
the
position
of
the
bit
,
stored
in
ip
.
@
If
we
terminated
early
,
because
dividend
became
zero
,
@
then
none
of
the
below
will
match
,
since
the
bit
in
ip
will
not
be
@
in
the
bottom
nibble
.
ands
overdone
,
overdone
,
#
0xe0000000
RETc
(
eq
)
pc
,
lr
@
No
fixups
needed
tst
overdone
,
ip
,
ror
#
3
addne
dividend
,
dividend
,
divisor
,
lsr
#
3
tst
overdone
,
ip
,
ror
#
2
addne
dividend
,
dividend
,
divisor
,
lsr
#
2
tst
overdone
,
ip
,
ror
#
1
addne
dividend
,
dividend
,
divisor
,
lsr
#
1
RET
pc
,
lr
1
:
cmp
\
divisor
,
#
0x80000000
cmplo
\
divisor
,
\
dividend
movlo
\
divisor
,
\
divisor
,
lsl
#
1
addlo
\
order
,
\
order
,
#
1
blo
1
b
#endif
@
Perform
all
needed
substractions
to
keep
only
the
reminder
.
@
Do
comparisons
in
batch
of
4
first
.
subs
\
order
,
\
order
,
#
3
@
yes
,
3
is
intended
here
blt
2
f
1
:
cmp
\
dividend
,
\
divisor
subhs
\
dividend
,
\
dividend
,
\
divisor
cmp
\
dividend
,
\
divisor
,
lsr
#
1
subhs
\
dividend
,
\
dividend
,
\
divisor
,
lsr
#
1
cmp
\
dividend
,
\
divisor
,
lsr
#
2
subhs
\
dividend
,
\
dividend
,
\
divisor
,
lsr
#
2
cmp
\
dividend
,
\
divisor
,
lsr
#
3
subhs
\
dividend
,
\
dividend
,
\
divisor
,
lsr
#
3
cmp
\
dividend
,
#
1
mov
\
divisor
,
\
divisor
,
lsr
#
4
subges
\
order
,
\
order
,
#
4
bge
1
b
tst
\
order
,
#
3
teqne
\
dividend
,
#
0
beq
5
f
@
Either
1
,
2
or
3
comparison
/
substractions
are
left
.
2
:
cmn
\
order
,
#
2
blt
4
f
beq
3
f
cmp
\
dividend
,
\
divisor
subhs
\
dividend
,
\
dividend
,
\
divisor
mov
\
divisor
,
\
divisor
,
lsr
#
1
3
:
cmp
\
dividend
,
\
divisor
subhs
\
dividend
,
\
dividend
,
\
divisor
mov
\
divisor
,
\
divisor
,
lsr
#
1
4
:
cmp
\
dividend
,
\
divisor
subhs
\
dividend
,
\
dividend
,
\
divisor
5
:
.
endm
ENTRY
(
__udivsi3
)
subs
r2
,
r1
,
#
1
moveq
pc
,
lr
bcc
Ldiv0
cmp
r0
,
r1
bls
11
f
tst
r1
,
r2
beq
12
f
ARM_DIV_BODY
r0
,
r1
,
r2
,
r3
mov
r0
,
r2
mov
pc
,
lr
11
:
moveq
r0
,
#
1
movne
r0
,
#
0
mov
pc
,
lr
12
:
ARM_DIV2_ORDER
r1
,
r2
mov
r0
,
r0
,
lsr
r2
mov
pc
,
lr
ENTRY
(
__umodsi3
)
subs
r2
,
r1
,
#
1
@
compare
divisor
with
1
bcc
Ldiv0
cmpne
r0
,
r1
@
compare
dividend
with
divisor
moveq
r0
,
#
0
tsthi
r1
,
r2
@
see
if
divisor
is
power
of
2
andeq
r0
,
r0
,
r2
movls
pc
,
lr
ARM_MOD_BODY
r0
,
r1
,
r2
,
r3
mov
pc
,
lr
ENTRY
(
__divsi3
)
eor
ip
,
dividend
,
divisor
@
Save
the
sign
of
the
result
.
mov
curbit
,
#
1
mov
result
,
#
0
cmp
divisor
,
#
0
rsbmi
divisor
,
divisor
,
#
0
@
Loops
below
use
unsigned
.
cmp
r1
,
#
0
eor
ip
,
r0
,
r1
@
save
the
sign
of
the
result
.
beq
Ldiv0
cmp
dividend
,
#
0
rsbmi
dividend
,
dividend
,
#
0
cmp
dividend
,
divisor
bcc
Lgot_result_divsi3
rsbmi
r1
,
r1
,
#
0
@
loops
below
use
unsigned
.
subs
r2
,
r1
,
#
1
@
division
by
1
or
-
1
?
beq
10
f
movs
r3
,
r0
rsbmi
r3
,
r0
,
#
0
@
positive
dividend
value
cmp
r3
,
r1
bls
11
f
tst
r1
,
r2
@
divisor
is
power
of
2
?
beq
12
f
1
:
@
Unless
the
divisor
is
very
big
,
shift
it
up
in
multiples
of
@
four
bits
,
since
this
is
the
amount
of
unwinding
in
the
main
@
division
loop
.
Continue
shifting
until
the
divisor
is
@
larger
than
the
dividend
.
cmp
divisor
,
#
0x10000000
cmpcc
divisor
,
dividend
movcc
divisor
,
divisor
,
lsl
#
4
movcc
curbit
,
curbit
,
lsl
#
4
bcc
1
b
ARM_DIV_BODY
r3
,
r1
,
r0
,
r2
2
:
@
For
very
big
divisors
,
we
must
shift
it
a
bit
at
a
time
,
or
@
we
will
be
in
danger
of
overflowing
.
cmp
divisor
,
#
0x80000000
cmpcc
divisor
,
dividend
movcc
divisor
,
divisor
,
lsl
#
1
movcc
curbit
,
curbit
,
lsl
#
1
bcc
2
b
3
:
@
Test
for
possible
subtractions
,
and
note
which
bits
@
are
done
in
the
result
.
On
the
final
pass
,
this
may
subtract
@
too
much
from
the
dividend
,
but
the
result
will
be
ok
,
since
the
@
"bit"
will
have
been
shifted
out
at
the
bottom
.
cmp
dividend
,
divisor
subcs
dividend
,
dividend
,
divisor
orrcs
result
,
result
,
curbit
cmp
dividend
,
divisor
,
lsr
#
1
subcs
dividend
,
dividend
,
divisor
,
lsr
#
1
orrcs
result
,
result
,
curbit
,
lsr
#
1
cmp
dividend
,
divisor
,
lsr
#
2
subcs
dividend
,
dividend
,
divisor
,
lsr
#
2
orrcs
result
,
result
,
curbit
,
lsr
#
2
cmp
dividend
,
divisor
,
lsr
#
3
subcs
dividend
,
dividend
,
divisor
,
lsr
#
3
orrcs
result
,
result
,
curbit
,
lsr
#
3
cmp
dividend
,
#
0
@
Early
termination
?
movnes
curbit
,
curbit
,
lsr
#
4
@
No
,
any
more
bits
to
do
?
movne
divisor
,
divisor
,
lsr
#
4
bne
3
b
Lgot_result_divsi3
:
mov
r0
,
result
cmp
ip
,
#
0
rsbmi
r0
,
r0
,
#
0
RET
pc
,
lr
mov
pc
,
lr
10
:
teq
ip
,
r0
@
same
sign
?
rsbmi
r0
,
r0
,
#
0
mov
pc
,
lr
11
:
movlo
r0
,
#
0
moveq
r0
,
ip
,
asr
#
31
orreq
r0
,
r0
,
#
1
mov
pc
,
lr
12
:
ARM_DIV2_ORDER
r1
,
r2
cmp
ip
,
#
0
mov
r0
,
r3
,
lsr
r2
rsbmi
r0
,
r0
,
#
0
mov
pc
,
lr
ENTRY
(
__modsi3
)
mov
curbit
,
#
1
cmp
divisor
,
#
0
rsbmi
divisor
,
divisor
,
#
0
@
Loops
below
use
unsigned
.
cmp
r1
,
#
0
beq
Ldiv0
@
Need
to
save
the
sign
of
the
dividend
,
unfortunately
,
we
need
@
ip
later
on
; this is faster than pushing lr and using that.
str
dividend
,
[
sp
,
#-
4
]!
cmp
dividend
,
#
0
rsbmi
dividend
,
dividend
,
#
0
cmp
dividend
,
divisor
bcc
Lgot_result_modsi3
1
:
@
Unless
the
divisor
is
very
big
,
shift
it
up
in
multiples
of
@
four
bits
,
since
this
is
the
amount
of
unwinding
in
the
main
@
division
loop
.
Continue
shifting
until
the
divisor
is
@
larger
than
the
dividend
.
cmp
divisor
,
#
0x10000000
cmpcc
divisor
,
dividend
movcc
divisor
,
divisor
,
lsl
#
4
movcc
curbit
,
curbit
,
lsl
#
4
bcc
1
b
rsbmi
r1
,
r1
,
#
0
@
loops
below
use
unsigned
.
movs
ip
,
r0
@
preserve
sign
of
dividend
rsbmi
r0
,
r0
,
#
0
@
if
negative
make
positive
subs
r2
,
r1
,
#
1
@
compare
divisor
with
1
cmpne
r0
,
r1
@
compare
dividend
with
divisor
moveq
r0
,
#
0
tsthi
r1
,
r2
@
see
if
divisor
is
power
of
2
andeq
r0
,
r0
,
r2
bls
10
f
ARM_MOD_BODY
r0
,
r1
,
r2
,
r3
10
:
cmp
ip
,
#
0
rsbmi
r0
,
r0
,
#
0
mov
pc
,
lr
Ldiv0
:
str
lr
,
[
sp
,
#-
4
]!
bl
__div0
mov
r0
,
#
0
@
About
as
wrong
as
it
could
be
.
ldr
pc
,
[
sp
],
#
4
2
:
@
For
very
big
divisors
,
we
must
shift
it
a
bit
at
a
time
,
or
@
we
will
be
in
danger
of
overflowing
.
cmp
divisor
,
#
0x80000000
cmpcc
divisor
,
dividend
movcc
divisor
,
divisor
,
lsl
#
1
movcc
curbit
,
curbit
,
lsl
#
1
bcc
2
b
3
:
@
Test
for
possible
subtractions
.
On
the
final
pass
,
this
may
@
subtract
too
much
from
the
dividend
,
so
keep
track
of
which
@
subtractions
are
done
,
we
can
fix
them
up
afterwards
...
mov
overdone
,
#
0
cmp
dividend
,
divisor
subcs
dividend
,
dividend
,
divisor
cmp
dividend
,
divisor
,
lsr
#
1
subcs
dividend
,
dividend
,
divisor
,
lsr
#
1
orrcs
overdone
,
overdone
,
curbit
,
ror
#
1
cmp
dividend
,
divisor
,
lsr
#
2
subcs
dividend
,
dividend
,
divisor
,
lsr
#
2
orrcs
overdone
,
overdone
,
curbit
,
ror
#
2
cmp
dividend
,
divisor
,
lsr
#
3
subcs
dividend
,
dividend
,
divisor
,
lsr
#
3
orrcs
overdone
,
overdone
,
curbit
,
ror
#
3
mov
ip
,
curbit
cmp
dividend
,
#
0
@
Early
termination
?
movnes
curbit
,
curbit
,
lsr
#
4
@
No
,
any
more
bits
to
do
?
movne
divisor
,
divisor
,
lsr
#
4
bne
3
b
@
Any
subtractions
that
we
should
not
have
done
will
be
recorded
in
@
the
top
three
bits
of
"overdone"
.
Exactly
which
were
not
needed
@
are
governed
by
the
position
of
the
bit
,
stored
in
ip
.
@
If
we
terminated
early
,
because
dividend
became
zero
,
@
then
none
of
the
below
will
match
,
since
the
bit
in
ip
will
not
be
@
in
the
bottom
nibble
.
ands
overdone
,
overdone
,
#
0xe0000000
beq
Lgot_result_modsi3
tst
overdone
,
ip
,
ror
#
3
addne
dividend
,
dividend
,
divisor
,
lsr
#
3
tst
overdone
,
ip
,
ror
#
2
addne
dividend
,
dividend
,
divisor
,
lsr
#
2
tst
overdone
,
ip
,
ror
#
1
addne
dividend
,
dividend
,
divisor
,
lsr
#
1
Lgot_result_modsi3
:
ldr
ip
,
[
sp
],
#
4
cmp
ip
,
#
0
rsbmi
dividend
,
dividend
,
#
0
RET
pc
,
lr
arch/arm/mach-pxa/irq.c
View file @
82d007ae
...
...
@@ -58,7 +58,19 @@ static int pxa_gpio_irq_type(unsigned int irq, unsigned int type)
{
int
gpio
,
idx
;
gpio
=
irq
-
((
irq
>=
IRQ_GPIO
(
2
))
?
IRQ_GPIO
(
2
)
+
2
:
IRQ_GPIO
(
0
));
gpio
=
IRQ_TO_GPIO
(
irq
);
idx
=
gpio
>>
5
;
if
(
type
==
IRQT_PROBE
)
{
/* Don't mess with enabled GPIOs using preconfigured edges or
GPIOs set to alternate function during probe */
if
((
GPIO_IRQ_rising_edge
[
idx
]
|
GPIO_IRQ_falling_edge
[
idx
])
&
GPIO_bit
(
gpio
))
return
0
;
if
(
GAFR
(
gpio
)
&
(
0x3
<<
(((
gpio
)
&
0xf
)
*
2
)))
return
0
;
type
=
__IRQT_RISEDGE
|
__IRQT_FALEDGE
;
}
printk
(
KERN_DEBUG
"IRQ%d (GPIO%d): "
,
irq
,
gpio
);
...
...
@@ -78,10 +90,8 @@ static int pxa_gpio_irq_type(unsigned int irq, unsigned int type)
printk
(
"edges
\n
"
);
idx
=
gpio
>>
5
;
GRER
(
gpio
)
=
GPIO_IRQ_rising_edge
[
idx
]
&
GPIO_IRQ_mask
[
idx
];
GFER
(
gpio
)
=
GPIO_IRQ_falling_edge
[
idx
]
&
GPIO_IRQ_mask
[
idx
];
return
0
;
}
...
...
arch/arm/mach-pxa/lubbock.c
View file @
82d007ae
...
...
@@ -78,7 +78,7 @@ static void __init lubbock_init_irq(void)
pxa_init_irq
();
/* setup extra lubbock irqs */
for
(
irq
=
LUBBOCK_IRQ
(
0
);
irq
<=
LUBBOCK_
IRQ
(
5
)
;
irq
++
)
{
for
(
irq
=
LUBBOCK_IRQ
(
0
);
irq
<=
LUBBOCK_
LAST_IRQ
;
irq
++
)
{
set_irq_chip
(
irq
,
&
lubbock_irq_chip
);
set_irq_handler
(
irq
,
do_level_IRQ
);
set_irq_flags
(
irq
,
IRQF_VALID
|
IRQF_PROBE
);
...
...
@@ -124,6 +124,7 @@ static struct map_desc lubbock_io_desc[] __initdata = {
{
0xf0000000
,
0x08000000
,
0x00100000
,
MT_DEVICE
},
/* CPLD */
{
0xf1000000
,
0x0c000000
,
0x00100000
,
MT_DEVICE
},
/* LAN91C96 IO */
{
0xf1100000
,
0x0e000000
,
0x00100000
,
MT_DEVICE
},
/* LAN91C96 Attr */
{
0xf4000000
,
0x10000000
,
0x00800000
,
MT_DEVICE
},
/* SA1111 */
};
static
void
__init
lubbock_map_io
(
void
)
...
...
include/asm-arm/arch-pxa/irqs.h
View file @
82d007ae
...
...
@@ -47,7 +47,7 @@
#define IRQ_TO_GPIO_2_80(i) \
((i) - PXA_IRQ(32) + 2)
#define IRQ_TO_GPIO(i) ((i) - (((i) > IRQ_GPIO1) ? IRQ_GPIO(2) : IRQ_GPIO(0)))
#define IRQ_TO_GPIO(i) ((i) - (((i) > IRQ_GPIO1) ? IRQ_GPIO(2)
- 2
: IRQ_GPIO(0)))
/*
* The next 16 interrupts are for board specific purposes. Since
...
...
@@ -131,8 +131,10 @@
#define LUBBOCK_IRQ(x) (IRQ_BOARD_START + (x))
#define LUBBOCK_SD_IRQ LUBBOCK_IRQ(0)
#define LUBBOCK_SA1111_IRQ LUBBOCK_IRQ(1)
#define LUBBOCK_USB_IRQ LUBBOCK_IRQ(2)
#define LUBBOCK_USB_IRQ LUBBOCK_IRQ(2)
/* usb connect */
#define LUBBOCK_ETH_IRQ LUBBOCK_IRQ(3)
#define LUBBOCK_UCB1400_IRQ LUBBOCK_IRQ(4)
#define LUBBOCK_BB_IRQ LUBBOCK_IRQ(5)
#define LUBBOCK_USB_DISC_IRQ LUBBOCK_IRQ(6)
/* usb disconnect */
#define LUBBOCK_LAST_IRQ LUBBOCK_IRQ(6)
include/asm-arm/arch-pxa/lubbock.h
View file @
82d007ae
...
...
@@ -12,7 +12,8 @@
#define LUBBOCK_FPGA_PHYS PXA_CS2_PHYS
#define LUBBOCK_FPGA_VIRT (0xf0000000)
/* phys 0x08000000 */
#define LUBBOCK_ETH_BASE (0xf1000000)
/* phys 0x0c000000 */
#define LUBBOCK_ETH_PHYS PXA_CS3_PHYS
#define LUBBOCK_ETH_VIRT (0xf1000000)
#define LUB_P2V(x) ((x) - LUBBOCK_FPGA_PHYS + LUBBOCK_FPGA_VIRT)
#define LUB_V2P(x) ((x) - LUBBOCK_FPGA_VIRT + LUBBOCK_FPGA_PHYS)
...
...
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