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Kirill Smelkov
linux
Commits
58cef2ea
Commit
58cef2ea
authored
Apr 02, 2002
by
David Mosberger
Browse files
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arch/ia64/lib/copy_page_mck.S:
Tweak for better performance when data is in L2 or L3 cache.
parent
8b39f58f
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58cef2ea
...
@@ -17,28 +17,28 @@
...
@@ -17,28 +17,28 @@
*
cycle
*
cycle
*
*
*
Principle
of
operation
:
*
Principle
of
operation
:
*
First
,
note
that
L1
has
a
line
-
size
of
64
bytes
and
L2
a
line
-
size
of
128
bytes
.
*
To
avoid
secondary
misses
in
L2
,
we
prefetch
both
source
and
destination
with
a
line
-
size
*
of
128
bytes
.
When
both
of
these
lines
are
in
the
L2
and
the
first
half
of
the
*
source
line
is
in
L1
,
we
start
copying
the
remaining
words
.
The
second
half
of
the
*
source
line
is
prefetched
in
an
earlier
iteration
,
so
that
by
the
time
we
start
*
accessing
it
,
it
's also present in the L1.
*
*
We
use
a
software
-
pipelined
loop
to
control
the
overall
operation
.
The
pipeline
*
We
use
a
software
-
pipelined
loop
to
control
the
overall
operation
.
The
pipeline
*
has
2
*
PREFETCH_DIST
+
2
stages
.
The
first
PREFETCH_DIST
stages
are
used
for
prefetching
*
has
2
*
PREFETCH_DIST
+
K
stages
.
The
first
PREFETCH_DIST
stages
are
used
for
prefetching
*
source
cache
-
lines
.
The
second
PREFETCH_DIST
stages
are
used
for
prefetching
destination
*
source
cache
-
lines
.
The
second
PREFETCH_DIST
stages
are
used
for
prefetching
destination
*
cache
-
lines
,
the
two
last
stages
are
used
to
copy
the
cache
-
line
words
not
copied
by
*
cache
-
lines
,
the
last
K
stages
are
used
to
copy
the
cache
-
line
words
not
copied
by
*
the
prefetches
.
The
four
relevant
points
in
the
pipelined
are
called
A
,
B
,
C
,
D
:
*
the
prefetches
.
The
four
relevant
points
in
the
pipelined
are
called
A
,
B
,
C
,
D
:
*
p
[
A
]
is
TRUE
if
a
source
-
line
should
be
prefetched
,
p
[
B
]
is
TRUE
if
a
destination
-
line
*
p
[
A
]
is
TRUE
if
a
source
-
line
should
be
prefetched
,
p
[
B
]
is
TRUE
if
a
destination
-
line
*
should
be
prefetched
,
p
[
C
]
is
TRUE
if
at
least
one
more
cacheline
needs
to
be
copied
,
*
should
be
prefetched
,
p
[
C
]
is
TRUE
if
the
second
half
of
an
L2
line
should
be
brought
*
and
p
[
D
]
is
TRUE
if
a
cachline
needs
to
be
copied
.
*
into
L1D
and
p
[
D
]
is
TRUE
if
a
cacheline
needs
to
be
copied
.
*
*
Note
that
L1
has
a
line
-
size
of
64
bytes
and
L2
a
line
-
size
of
128
bytes
.
To
avoid
*
secondary
misses
in
L2
,
we
prefetch
both
source
and
destination
with
a
line
-
size
*
of
128
bytes
.
When
both
of
these
lines
are
in
the
L2
and
the
first
half
of
the
*
source
line
is
in
L1
,
we
start
copying
the
remaining
words
.
The
second
half
of
the
*
source
line
is
prefetched
in
the
previous
iteration
,
so
that
by
the
time
we
start
*
accessing
it
,
it
's also present in the L1.
*
*
*
This
all
sounds
very
complicated
,
but
thanks
to
the
modulo
-
scheduled
loop
support
,
*
This
all
sounds
very
complicated
,
but
thanks
to
the
modulo
-
scheduled
loop
support
,
*
the
resulting
code
is
very
regular
and
quite
easy
to
follow
(
once
you
get
the
idea
)
.
*
the
resulting
code
is
very
regular
and
quite
easy
to
follow
(
once
you
get
the
idea
)
.
*
*
*
As
a
secondary
optimization
,
the
first
2
*
PREFETCH_DIST
iterations
are
implemented
*
As
a
secondary
optimization
,
the
first
2
*
PREFETCH_DIST
iterations
are
implemented
*
as
the
separate
.
prefetch_loop
.
Logically
,
this
loop
performs
exactly
like
the
*
as
the
separate
.
prefetch_loop
.
Logically
,
this
loop
performs
exactly
like
the
*
main
-
loop
(
.
line_copy
),
but
has
all
know
-
to
-
be
-
predicated
-
off
instructions
removed
,
*
main
-
loop
(
.
line_copy
),
but
has
all
know
n
-
to
-
be
-
predicated
-
off
instructions
removed
,
*
so
that
each
loop
iteration
is
faster
(
again
,
good
for
cached
case
)
.
*
so
that
each
loop
iteration
is
faster
(
again
,
good
for
cached
case
)
.
*
*
*
When
reading
the
code
,
it
helps
to
keep
the
following
picture
in
mind
:
*
When
reading
the
code
,
it
helps
to
keep
the
following
picture
in
mind
:
...
@@ -49,13 +49,13 @@
...
@@ -49,13 +49,13 @@
*
| t2 |
t3
| |
*
| t2 |
t3
| |
*
| t4 |
t5
| |
*
| t4 |
t5
| |
*
| t6 |
t7
| |
128
bytes
*
| t6 |
t7
| |
128
bytes
*
| n
8
|
t9
| |
(
L2
cache
line
)
*
| n
[y]
|
t9
| |
(
L2
cache
line
)
*
| t10 |
t11
| |
*
| t10 |
t11
| |
*
| t12 |
t13
| |
*
| t12 |
t13
| |
*
| t14 |
t15
|
v
*
| t14 |
t15
|
v
*
+------+------+---
*
+------+------+---
*
*
*
Here
,
v
[
x
]
is
copied
by
the
(
memory
)
prefetch
.
n
8
is
loaded
in
the
previous
iteration
*
Here
,
v
[
x
]
is
copied
by
the
(
memory
)
prefetch
.
n
[
y
]
is
loaded
at
p
[
C
]
*
to
fetch
the
second
-
half
of
the
L2
cache
line
into
L1
,
and
the
tX
words
are
copied
in
*
to
fetch
the
second
-
half
of
the
L2
cache
line
into
L1
,
and
the
tX
words
are
copied
in
*
an
order
that
avoids
bank
conflicts
.
*
an
order
that
avoids
bank
conflicts
.
*/
*/
...
@@ -79,22 +79,21 @@
...
@@ -79,22 +79,21 @@
#define t5 t1 // alias!
#define t5 t1 // alias!
#define t6 t2 // alias!
#define t6 t2 // alias!
#define t7 t3 // alias!
#define t7 t3 // alias!
#define n8 r21
#define t9 t5 // alias!
#define t9 t5 // alias!
#define t10 t4 // alias!
#define t10 t4 // alias!
#define t11 t7 // alias!
#define t11 t7 // alias!
#define t12 t6 // alias!
#define t12 t6 // alias!
#define t14 t10 // alias!
#define t14 t10 // alias!
#define t13 r2
2
#define t13 r2
1
#define t15 r2
3
#define t15 r2
2
#define saved_lc r2
4
#define saved_lc r2
3
#define saved_pr r2
5
#define saved_pr r2
4
#define A 0
#define A 0
#define B (PREFETCH_DIST)
#define B (PREFETCH_DIST)
#define C (B + PREFETCH_DIST)
#define C (B + PREFETCH_DIST)
#define D (C +
1
)
#define D (C +
3
)
#define N (D + 1)
#define N (D + 1)
#define Nrot ((N + 7) & ~7)
#define Nrot ((N + 7) & ~7)
...
@@ -102,7 +101,7 @@ GLOBAL_ENTRY(copy_page)
...
@@ -102,7 +101,7 @@ GLOBAL_ENTRY(copy_page)
.
prologue
.
prologue
alloc
r8
=
ar
.
pfs
,
2
,
Nrot
-
2
,
0
,
Nrot
alloc
r8
=
ar
.
pfs
,
2
,
Nrot
-
2
,
0
,
Nrot
.
rotr
v
[
2
*
PREFETCH_DIST
]
.
rotr
v
[
2
*
PREFETCH_DIST
]
,
n
[
D
-
C
+
1
]
.
rotp
p
[
N
]
.
rotp
p
[
N
]
.
save
ar
.
lc
,
saved_lc
.
save
ar
.
lc
,
saved_lc
...
@@ -124,6 +123,9 @@ GLOBAL_ENTRY(copy_page)
...
@@ -124,6 +123,9 @@ GLOBAL_ENTRY(copy_page)
add
src1
=
3
*
8
,
in1
//
first
t3
src
add
src1
=
3
*
8
,
in1
//
first
t3
src
add
dst0
=
8
,
in0
//
first
t1
dst
add
dst0
=
8
,
in0
//
first
t1
dst
add
dst1
=
3
*
8
,
in0
//
first
t3
dst
add
dst1
=
3
*
8
,
in0
//
first
t3
dst
nop.m
0
nop.m
0
nop.i
0
;;
;;
//
same
as
.
line_copy
loop
,
but
with
all
predicated
-
off
instructions
removed
:
//
same
as
.
line_copy
loop
,
but
with
all
predicated
-
off
instructions
removed
:
.
prefetch_loop
:
.
prefetch_loop
:
...
@@ -135,15 +137,14 @@ GLOBAL_ENTRY(copy_page)
...
@@ -135,15 +137,14 @@ GLOBAL_ENTRY(copy_page)
mov
ar
.
lc
=
(
PAGE_SIZE
/
128
)
-
(
2
*
PREFETCH_DIST
)
-
1
mov
ar
.
lc
=
(
PAGE_SIZE
/
128
)
-
(
2
*
PREFETCH_DIST
)
-
1
mov
ar
.
ec
=
N
//
#
of
stages
in
pipeline
mov
ar
.
ec
=
N
//
#
of
stages
in
pipeline
;;
;;
.
align
32
.
line_copy
:
.
line_copy
:
(
p
[
D
])
ld8
t2
=
[
src0
],
3
*
8
//
M0
(
p
[
D
])
ld8
t2
=
[
src0
],
3
*
8
//
M0
(
p
[
D
])
ld8
t4
=
[
src1
],
3
*
8
//
M1
(
p
[
D
])
ld8
t4
=
[
src1
],
3
*
8
//
M1
(
p
[
B
])
st8
[
dst_pre_mem
]
=
v
[
B
],
128
//
M2
prefetch
dst
from
memory
(
p
[
B
])
st8
[
dst_pre_mem
]
=
v
[
B
],
128
//
M2
prefetch
dst
from
memory
(
p
[
D
])
st8
[
dst_pre_l2
]
=
n
8
,
128
//
M3
prefetch
dst
from
L2
(
p
[
D
])
st8
[
dst_pre_l2
]
=
n
[
D
-
C
]
,
128
//
M3
prefetch
dst
from
L2
;;
;;
(
p
[
A
])
ld8
v
[
A
]
=
[
src_pre_mem
],
128
//
M0
prefetch
src
from
memory
(
p
[
A
])
ld8
v
[
A
]
=
[
src_pre_mem
],
128
//
M0
prefetch
src
from
memory
(
p
[
C
])
ld8
n
8
=
[
src_pre_l2
],
128
//
M1
prefetch
src
from
L2
(
p
[
C
])
ld8
n
[
0
]
=
[
src_pre_l2
],
128
//
M1
prefetch
src
from
L2
(
p
[
D
])
st8
[
dst0
]
=
t1
,
8
//
M2
(
p
[
D
])
st8
[
dst0
]
=
t1
,
8
//
M2
(
p
[
D
])
st8
[
dst1
]
=
t3
,
8
//
M3
(
p
[
D
])
st8
[
dst1
]
=
t3
,
8
//
M3
;;
;;
...
@@ -172,8 +173,8 @@ GLOBAL_ENTRY(copy_page)
...
@@ -172,8 +173,8 @@ GLOBAL_ENTRY(copy_page)
(
p
[
D
])
st8
[
dst0
]
=
t12
,
8
(
p
[
D
])
st8
[
dst0
]
=
t12
,
8
(
p
[
D
])
st8
[
dst1
]
=
t14
,
8
(
p
[
D
])
st8
[
dst1
]
=
t14
,
8
;;
;;
(
p
[
C
])
ld8
t1
=
[
src0
],
8
(
p
[
D
-
1
])
ld8
t1
=
[
src0
],
8
(
p
[
C
])
ld8
t3
=
[
src1
],
8
(
p
[
D
-
1
])
ld8
t3
=
[
src1
],
8
(
p
[
D
])
st8
[
dst0
]
=
t13
,
4
*
8
(
p
[
D
])
st8
[
dst0
]
=
t13
,
4
*
8
(
p
[
D
])
st8
[
dst1
]
=
t15
,
4
*
8
(
p
[
D
])
st8
[
dst1
]
=
t15
,
4
*
8
br.ctop.sptk
.
line_copy
br.ctop.sptk
.
line_copy
...
...
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