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Kirill Smelkov
linux
Commits
f07b8ab2
Commit
f07b8ab2
authored
Sep 30, 2003
by
Linus Torvalds
Browse files
Options
Browse Files
Download
Plain Diff
Merge
bk://linux-dj.bkbits.net/cpufreq
into home.osdl.org:/home/torvalds/v2.5/linux
parents
8b0eeec2
7cdf272f
Changes
6
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6 changed files
with
1204 additions
and
25 deletions
+1204
-25
Documentation/cpu-freq/user-guide.txt
Documentation/cpu-freq/user-guide.txt
+2
-0
arch/i386/kernel/cpu/cpufreq/Kconfig
arch/i386/kernel/cpu/cpufreq/Kconfig
+10
-0
arch/i386/kernel/cpu/cpufreq/Makefile
arch/i386/kernel/cpu/cpufreq/Makefile
+1
-0
arch/i386/kernel/cpu/cpufreq/longhaul.c
arch/i386/kernel/cpu/cpufreq/longhaul.c
+45
-25
arch/i386/kernel/cpu/cpufreq/powernow-k8.c
arch/i386/kernel/cpu/cpufreq/powernow-k8.c
+1020
-0
arch/i386/kernel/cpu/cpufreq/powernow-k8.h
arch/i386/kernel/cpu/cpufreq/powernow-k8.h
+126
-0
No files found.
Documentation/cpu-freq/user-guide.txt
View file @
f07b8ab2
...
@@ -57,6 +57,8 @@ AMD mobile K6-2+
...
@@ -57,6 +57,8 @@ AMD mobile K6-2+
AMD mobile K6-3+
AMD mobile K6-3+
AMD mobile Duron
AMD mobile Duron
AMD mobile Athlon
AMD mobile Athlon
AMD Opteron
AMD Athlon 64
Cyrix Media GXm
Cyrix Media GXm
Intel mobile PIII and Intel mobile PIII-M on certain chipsets
Intel mobile PIII and Intel mobile PIII-M on certain chipsets
Intel Pentium 4, Intel Xeon
Intel Pentium 4, Intel Xeon
...
...
arch/i386/kernel/cpu/cpufreq/Kconfig
View file @
f07b8ab2
...
@@ -88,6 +88,16 @@ config X86_POWERNOW_K7
...
@@ -88,6 +88,16 @@ config X86_POWERNOW_K7
If in doubt, say N.
If in doubt, say N.
config X86_POWERNOW_K8
tristate "AMD Opteron/Athlon64 PowerNow!"
depends on CPU_FREQ_TABLE
help
This adds the CPUFreq driver for mobile AMD Opteron/Athlon64 processors.
For details, take a look at linux/Documentation/cpu-freq.
If in doubt, say N.
config X86_GX_SUSPMOD
config X86_GX_SUSPMOD
tristate "Cyrix MediaGX/NatSemi Geode Suspend Modulation"
tristate "Cyrix MediaGX/NatSemi Geode Suspend Modulation"
depends on CPU_FREQ
depends on CPU_FREQ
...
...
arch/i386/kernel/cpu/cpufreq/Makefile
View file @
f07b8ab2
obj-$(CONFIG_X86_POWERNOW_K6)
+=
powernow-k6.o
obj-$(CONFIG_X86_POWERNOW_K6)
+=
powernow-k6.o
obj-$(CONFIG_X86_POWERNOW_K7)
+=
powernow-k7.o
obj-$(CONFIG_X86_POWERNOW_K7)
+=
powernow-k7.o
obj-$(CONFIG_X86_POWERNOW_K8)
+=
powernow-k8.o
obj-$(CONFIG_X86_LONGHAUL)
+=
longhaul.o
obj-$(CONFIG_X86_LONGHAUL)
+=
longhaul.o
obj-$(CONFIG_X86_P4_CLOCKMOD)
+=
p4-clockmod.o
obj-$(CONFIG_X86_P4_CLOCKMOD)
+=
p4-clockmod.o
obj-$(CONFIG_ELAN_CPUFREQ)
+=
elanfreq.o
obj-$(CONFIG_ELAN_CPUFREQ)
+=
elanfreq.o
...
...
arch/i386/kernel/cpu/cpufreq/longhaul.c
View file @
f07b8ab2
...
@@ -70,21 +70,6 @@ static unsigned int calc_speed (int mult, int fsb)
...
@@ -70,21 +70,6 @@ static unsigned int calc_speed (int mult, int fsb)
}
}
static
unsigned
int
longhaul_get_cpu_fsb
(
void
)
{
unsigned
long
lo
,
hi
;
unsigned
int
eblcr_fsb_table
[]
=
{
66
,
133
,
100
,
-
1
};
unsigned
int
invalue
=
0
;
if
(
fsb
==
0
)
{
rdmsr
(
MSR_IA32_EBL_CR_POWERON
,
lo
,
hi
);
invalue
=
(
lo
&
(
1
<<
18
|
1
<<
19
))
>>
18
;
fsb
=
eblcr_fsb_table
[
invalue
];
}
return
fsb
;
}
static
int
longhaul_get_cpu_mult
(
void
)
static
int
longhaul_get_cpu_mult
(
void
)
{
{
unsigned
long
invalue
=
0
,
lo
,
hi
;
unsigned
long
invalue
=
0
,
lo
,
hi
;
...
@@ -168,7 +153,7 @@ static void longhaul_setstate (unsigned int clock_ratio_index)
...
@@ -168,7 +153,7 @@ static void longhaul_setstate (unsigned int clock_ratio_index)
break
;
break
;
/*
/*
* Longhaul v3. (Ezra-T [C5M], Nehemia
g
[C5N])
* Longhaul v3. (Ezra-T [C5M], Nehemia
h
[C5N])
* This can also do voltage scaling, but see above.
* This can also do voltage scaling, but see above.
* Ezra-T was alleged to do FSB scaling too, but it never worked in practice.
* Ezra-T was alleged to do FSB scaling too, but it never worked in practice.
*/
*/
...
@@ -193,6 +178,39 @@ static void longhaul_setstate (unsigned int clock_ratio_index)
...
@@ -193,6 +178,39 @@ static void longhaul_setstate (unsigned int clock_ratio_index)
cpufreq_notify_transition
(
&
freqs
,
CPUFREQ_POSTCHANGE
);
cpufreq_notify_transition
(
&
freqs
,
CPUFREQ_POSTCHANGE
);
}
}
/*
* Centaur decided to make life a little more tricky.
* Only longhaul v1 is allowed to read EBLCR BSEL[0:1].
* Samuel2 and above have to try and guess what the FSB is.
* We do this by assuming we booted at maximum multiplier, and interpolate
* between that value multiplied by possible FSBs and cpu_mhz which
* was calculated at boot time. Really ugly, but no other way to do this.
*/
static
int
_guess
(
int
guess
,
int
maxmult
)
{
int
target
;
target
=
((
maxmult
/
10
)
*
guess
);
if
(
maxmult
%
10
!=
0
)
target
+=
(
guess
/
2
);
target
&=
~
0xf
;
return
target
;
}
static
int
guess_fsb
(
int
maxmult
)
{
int
speed
=
(
cpu_khz
/
1000
)
&
~
0xf
;
int
i
;
int
speeds
[
3
]
=
{
66
,
100
,
133
};
for
(
i
=
0
;
i
<
3
;
i
++
)
{
if
(
_guess
(
speeds
[
i
],
maxmult
)
==
speed
)
return
speeds
[
i
];
}
return
0
;
}
static
int
__init
longhaul_get_ranges
(
void
)
static
int
__init
longhaul_get_ranges
(
void
)
{
{
...
@@ -203,8 +221,8 @@ static int __init longhaul_get_ranges (void)
...
@@ -203,8 +221,8 @@ static int __init longhaul_get_ranges (void)
-
1
,
110
,
120
,
-
1
,
135
,
115
,
125
,
105
,
130
,
150
,
160
,
140
,
-
1
,
155
,
-
1
,
145
};
-
1
,
110
,
120
,
-
1
,
135
,
115
,
125
,
105
,
130
,
150
,
160
,
140
,
-
1
,
155
,
-
1
,
145
};
unsigned
int
j
,
k
=
0
;
unsigned
int
j
,
k
=
0
;
union
msr_longhaul
longhaul
;
union
msr_longhaul
longhaul
;
unsigned
long
lo
,
hi
;
fsb
=
longhaul_get_cpu_fsb
()
;
unsigned
int
eblcr_fsb_table
[]
=
{
66
,
133
,
100
,
-
1
}
;
switch
(
longhaul_version
)
{
switch
(
longhaul_version
)
{
case
1
:
case
1
:
...
@@ -212,6 +230,9 @@ static int __init longhaul_get_ranges (void)
...
@@ -212,6 +230,9 @@ static int __init longhaul_get_ranges (void)
Assume min=3.0x & max = whatever we booted at. */
Assume min=3.0x & max = whatever we booted at. */
minmult
=
30
;
minmult
=
30
;
maxmult
=
longhaul_get_cpu_mult
();
maxmult
=
longhaul_get_cpu_mult
();
rdmsr
(
MSR_IA32_EBL_CR_POWERON
,
lo
,
hi
);
invalue
=
(
lo
&
(
1
<<
18
|
1
<<
19
))
>>
18
;
fsb
=
eblcr_fsb_table
[
invalue
];
break
;
break
;
case
2
...
3
:
case
2
...
3
:
...
@@ -222,14 +243,13 @@ static int __init longhaul_get_ranges (void)
...
@@ -222,14 +243,13 @@ static int __init longhaul_get_ranges (void)
invalue
+=
16
;
invalue
+=
16
;
maxmult
=
multipliers
[
invalue
];
maxmult
=
multipliers
[
invalue
];
#if 0
invalue
=
longhaul
.
bits
.
MinMHzBR
;
invalue
=
longhaul
.
bits
.
MinMHzBR
;
if (longhaul.bits.MinMHzBR4
);
if
(
longhaul
.
bits
.
MinMHzBR4
==
1
)
invalue += 16
;
minmult
=
30
;
minmult = multipliers[invalue];
else
#else
minmult
=
multipliers
[
invalue
];
minmult
=
30
;
/* as per spec */
#endif
fsb
=
guess_fsb
(
maxmult
);
break
;
break
;
}
}
...
...
arch/i386/kernel/cpu/cpufreq/powernow-k8.c
0 → 100644
View file @
f07b8ab2
/*
* (c) 2003 Advanced Micro Devices, Inc.
* Your use of this code is subject to the terms and conditions of the
* GNU general public license version 2. See "../../../COPYING" or
* http://www.gnu.org/licenses/gpl.html
*
* Support : paul.devriendt@amd.com
*
* Based on the powernow-k7.c module written by Dave Jones.
* (C) 2003 Dave Jones <davej@codemonkey.ork.uk> on behalf of SuSE Labs
* Licensed under the terms of the GNU GPL License version 2.
* Based upon datasheets & sample CPUs kindly provided by AMD.
*
* Processor information obtained from Chapter 9 (Power and Thermal Management)
* of the "BIOS and Kernel Developer's Guide for the AMD Athlon 64 and AMD
* Opteron Processors", revision 3.03, available for download from www.amd.com
*
*/
#include <linux/kernel.h>
#include <linux/smp.h>
#include <linux/module.h>
#include <linux/init.h>
#include <linux/cpufreq.h>
#include <linux/slab.h>
#include <linux/string.h>
#include <asm/msr.h>
#include <asm/io.h>
#include <asm/delay.h>
#define PFX "powernow-k8: "
#define BFX PFX "BIOS error: "
#define VERSION "version 1.00.08 - September 26, 2003"
#include "powernow-k8.h"
#ifdef CONFIG_PREEMPT
#warning this driver has not been tested on a preempt system
#endif
static
u32
vstable
;
/* voltage stabalization time, from PSB, units 20 us */
static
u32
plllock
;
/* pll lock time, from PSB, units 1 us */
static
u32
numps
;
/* number of p-states, from PSB */
static
u32
rvo
;
/* ramp voltage offset, from PSB */
static
u32
irt
;
/* isochronous relief time, from PSB */
static
u32
vidmvs
;
/* usable value calculated from mvs, from PSB */
struct
pst_s
*
ppst
;
/* array of p states, valid for this part */
static
u32
currvid
;
/* keep track of the current fid / vid */
static
u32
currfid
;
/*
The PSB table supplied by BIOS allows for the definition of the number of
p-states that can be used when running on a/c, and the number of p-states
that can be used when running on battery. This allows laptop manufacturers
to force the system to save power when running from battery. The relationship
is :
1 <= number_of_battery_p_states <= maximum_number_of_p_states
This driver does NOT have the support in it to detect transitions from
a/c power to battery power, and thus trigger the transition to a lower
p-state if required. This is because I need ACPI and the 2.6 kernel to do
this, and this is a 2.4 kernel driver. Check back for a new improved driver
for the 2.6 kernel soon.
This code therefore assumes it is on battery at all times, and thus
restricts performance to number_of_battery_p_states. For desktops,
number_of_battery_p_states == maximum_number_of_pstates,
so this is not actually a restriction.
*/
static
u32
batps
;
/* limit on the number of p states when on battery */
/* - set by BIOS in the PSB/PST */
static
struct
cpufreq_driver
cpufreq_amd64_driver
=
{
.
verify
=
drv_verify
,
.
target
=
drv_target
,
.
init
=
drv_cpu_init
,
.
name
=
"cpufreq-amd64"
,
.
owner
=
THIS_MODULE
,
};
#define SEARCH_UP 1
#define SEARCH_DOWN 0
/* Return a frequency in MHz, given an input fid */
u32
find_freq_from_fid
(
u32
fid
)
{
return
800
+
(
fid
*
100
);
}
/* Return a fid matching an input frequency in MHz */
u32
find_fid_from_freq
(
u32
freq
)
{
return
(
freq
-
800
)
/
100
;
}
/* Return the vco fid for an input fid */
static
u32
convert_fid_to_vco_fid
(
u32
fid
)
{
if
(
fid
<
HI_FID_TABLE_BOTTOM
)
{
return
8
+
(
2
*
fid
);
}
else
{
return
fid
;
}
}
/* Sort the fid/vid frequency table into ascending order by fid. The spec */
/* implies that it will be sorted by BIOS, but, it only implies it, and I */
/* prefer not to trust when I can check. */
/* Yes, it is a simple bubble sort, but the PST is really small, so the */
/* choice of algorithm is pretty irrelevant. */
static
inline
void
sort_pst
(
struct
pst_s
*
ppst
,
u32
numpstates
)
{
u32
i
;
u8
tempfid
;
u8
tempvid
;
int
swaps
=
1
;
while
(
swaps
)
{
swaps
=
0
;
for
(
i
=
0
;
i
<
(
numpstates
-
1
);
i
++
)
{
if
(
ppst
[
i
].
fid
>
ppst
[
i
+
1
].
fid
)
{
swaps
=
1
;
tempfid
=
ppst
[
i
].
fid
;
tempvid
=
ppst
[
i
].
vid
;
ppst
[
i
].
fid
=
ppst
[
i
+
1
].
fid
;
ppst
[
i
].
vid
=
ppst
[
i
+
1
].
vid
;
ppst
[
i
+
1
].
fid
=
tempfid
;
ppst
[
i
+
1
].
vid
=
tempvid
;
}
}
}
return
;
}
/* Return 1 if the pending bit is set. Unless we are actually just told the */
/* processor to transition a state, seeing this bit set is really bad news. */
static
inline
int
pending_bit_stuck
(
void
)
{
u32
lo
;
u32
hi
;
rdmsr
(
MSR_FIDVID_STATUS
,
lo
,
hi
);
return
lo
&
MSR_S_LO_CHANGE_PENDING
?
1
:
0
;
}
/* Update the global current fid / vid values from the status msr. Returns 1 */
/* on error. */
static
int
query_current_values_with_pending_wait
(
void
)
{
u32
lo
;
u32
hi
;
u32
i
=
0
;
lo
=
MSR_S_LO_CHANGE_PENDING
;
while
(
lo
&
MSR_S_LO_CHANGE_PENDING
)
{
if
(
i
++
>
0x1000000
)
{
printk
(
KERN_ERR
PFX
"detected change pending stuck
\n
"
);
return
1
;
}
rdmsr
(
MSR_FIDVID_STATUS
,
lo
,
hi
);
}
currvid
=
hi
&
MSR_S_HI_CURRENT_VID
;
currfid
=
lo
&
MSR_S_LO_CURRENT_FID
;
return
0
;
}
/* the isochronous relief time */
static
inline
void
count_off_irt
(
void
)
{
udelay
((
1
<<
irt
)
*
10
);
return
;
}
/* the voltage stabalization time */
static
inline
void
count_off_vst
(
void
)
{
udelay
(
vstable
*
VST_UNITS_20US
);
return
;
}
/* write the new fid value along with the other control fields to the msr */
static
int
write_new_fid
(
u32
fid
)
{
u32
lo
;
u32
savevid
=
currvid
;
if
((
fid
&
INVALID_FID_MASK
)
||
(
currvid
&
INVALID_VID_MASK
))
{
printk
(
KERN_ERR
PFX
"internal error - overflow on fid write
\n
"
);
return
1
;
}
lo
=
fid
|
(
currvid
<<
MSR_C_LO_VID_SHIFT
)
|
MSR_C_LO_INIT_FID_VID
;
dprintk
(
KERN_DEBUG
PFX
"writing fid %x, lo %x, hi %x
\n
"
,
fid
,
lo
,
plllock
*
PLL_LOCK_CONVERSION
);
wrmsr
(
MSR_FIDVID_CTL
,
lo
,
plllock
*
PLL_LOCK_CONVERSION
);
if
(
query_current_values_with_pending_wait
())
return
1
;
count_off_irt
();
if
(
savevid
!=
currvid
)
{
printk
(
KERN_ERR
PFX
"vid changed on fid transition, save %x, currvid %x
\n
"
,
savevid
,
currvid
);
return
1
;
}
if
(
fid
!=
currfid
)
{
printk
(
KERN_ERR
PFX
"fid transition failed, fid %x, currfid %x
\n
"
,
fid
,
currfid
);
return
1
;
}
return
0
;
}
/* Write a new vid to the hardware */
static
int
write_new_vid
(
u32
vid
)
{
u32
lo
;
u32
savefid
=
currfid
;
if
((
currfid
&
INVALID_FID_MASK
)
||
(
vid
&
INVALID_VID_MASK
))
{
printk
(
KERN_ERR
PFX
"internal error - overflow on vid write
\n
"
);
return
1
;
}
lo
=
currfid
|
(
vid
<<
MSR_C_LO_VID_SHIFT
)
|
MSR_C_LO_INIT_FID_VID
;
dprintk
(
KERN_DEBUG
PFX
"writing vid %x, lo %x, hi %x
\n
"
,
vid
,
lo
,
STOP_GRANT_5NS
);
wrmsr
(
MSR_FIDVID_CTL
,
lo
,
STOP_GRANT_5NS
);
if
(
query_current_values_with_pending_wait
())
{
return
1
;
}
if
(
savefid
!=
currfid
)
{
printk
(
KERN_ERR
PFX
"fid changed on vid transition, save %x currfid %x
\n
"
,
savefid
,
currfid
);
return
1
;
}
if
(
vid
!=
currvid
)
{
printk
(
KERN_ERR
PFX
"vid transition failed, vid %x, currvid %x
\n
"
,
vid
,
currvid
);
return
1
;
}
return
0
;
}
/* Reduce the vid by the max of step or reqvid. */
/* Decreasing vid codes represent increasing voltages : */
/* vid of 0 is 1.550V, vid of 0x1e is 0.800V, vid of 0x1f is off. */
static
int
decrease_vid_code_by_step
(
u32
reqvid
,
u32
step
)
{
if
((
currvid
-
reqvid
)
>
step
)
reqvid
=
currvid
-
step
;
if
(
write_new_vid
(
reqvid
))
return
1
;
count_off_vst
();
return
0
;
}
/* Change the fid and vid, by the 3 phases. */
static
inline
int
transition_fid_vid
(
u32
reqfid
,
u32
reqvid
)
{
if
(
core_voltage_pre_transition
(
reqvid
))
return
1
;
if
(
core_frequency_transition
(
reqfid
))
return
1
;
if
(
core_voltage_post_transition
(
reqvid
))
return
1
;
if
(
query_current_values_with_pending_wait
())
return
1
;
if
((
reqfid
!=
currfid
)
||
(
reqvid
!=
currvid
))
{
printk
(
KERN_ERR
PFX
"failed: req 0x%x 0x%x, curr 0x%x 0x%x
\n
"
,
reqfid
,
reqvid
,
currfid
,
currvid
);
return
1
;
}
dprintk
(
KERN_INFO
PFX
"transitioned: new fid 0x%x, vid 0x%x
\n
"
,
currfid
,
currvid
);
return
0
;
}
/* Phase 1 - core voltage transition ... setup appropriate voltage for the */
/* fid transition. */
static
inline
int
core_voltage_pre_transition
(
u32
reqvid
)
{
u32
rvosteps
=
rvo
;
u32
savefid
=
currfid
;
dprintk
(
KERN_DEBUG
PFX
"ph1: start, currfid 0x%x, currvid 0x%x, reqvid 0x%x, rvo %x
\n
"
,
currfid
,
currvid
,
reqvid
,
rvo
);
while
(
currvid
>
reqvid
)
{
dprintk
(
KERN_DEBUG
PFX
"ph1: curr 0x%x, requesting vid 0x%x
\n
"
,
currvid
,
reqvid
);
if
(
decrease_vid_code_by_step
(
reqvid
,
vidmvs
))
return
1
;
}
while
(
rvosteps
>
0
)
{
if
(
currvid
==
0
)
{
rvosteps
=
0
;
}
else
{
dprintk
(
KERN_DEBUG
PFX
"ph1: changing vid for rvo, requesting 0x%x
\n
"
,
currvid
-
1
);
if
(
decrease_vid_code_by_step
(
currvid
-
1
,
1
))
return
1
;
rvosteps
--
;
}
}
if
(
query_current_values_with_pending_wait
())
return
1
;
if
(
savefid
!=
currfid
)
{
printk
(
KERN_ERR
PFX
"ph1 err, currfid changed 0x%x
\n
"
,
currfid
);
return
1
;
}
dprintk
(
KERN_DEBUG
PFX
"ph1 complete, currfid 0x%x, currvid 0x%x
\n
"
,
currfid
,
currvid
);
return
0
;
}
/* Phase 2 - core frequency transition */
static
inline
int
core_frequency_transition
(
u32
reqfid
)
{
u32
vcoreqfid
;
u32
vcocurrfid
;
u32
vcofiddiff
;
u32
savevid
=
currvid
;
if
((
reqfid
<
HI_FID_TABLE_BOTTOM
)
&&
(
currfid
<
HI_FID_TABLE_BOTTOM
))
{
printk
(
KERN_ERR
PFX
"ph2 illegal lo-lo transition 0x%x 0x%x
\n
"
,
reqfid
,
currfid
);
return
1
;
}
if
(
currfid
==
reqfid
)
{
printk
(
KERN_ERR
PFX
"ph2 null fid transition 0x%x
\n
"
,
currfid
);
return
0
;
}
dprintk
(
KERN_DEBUG
PFX
"ph2 starting, currfid 0x%x, currvid 0x%x, reqfid 0x%x
\n
"
,
currfid
,
currvid
,
reqfid
);
vcoreqfid
=
convert_fid_to_vco_fid
(
reqfid
);
vcocurrfid
=
convert_fid_to_vco_fid
(
currfid
);
vcofiddiff
=
vcocurrfid
>
vcoreqfid
?
vcocurrfid
-
vcoreqfid
:
vcoreqfid
-
vcocurrfid
;
while
(
vcofiddiff
>
2
)
{
if
(
reqfid
>
currfid
)
{
if
(
currfid
>
LO_FID_TABLE_TOP
)
{
if
(
write_new_fid
(
currfid
+
2
))
{
return
1
;
}
}
else
{
if
(
write_new_fid
(
2
+
convert_fid_to_vco_fid
(
currfid
)))
{
return
1
;
}
}
}
else
{
if
(
write_new_fid
(
currfid
-
2
))
return
1
;
}
vcocurrfid
=
convert_fid_to_vco_fid
(
currfid
);
vcofiddiff
=
vcocurrfid
>
vcoreqfid
?
vcocurrfid
-
vcoreqfid
:
vcoreqfid
-
vcocurrfid
;
}
if
(
write_new_fid
(
reqfid
))
return
1
;
if
(
query_current_values_with_pending_wait
())
return
1
;
if
(
currfid
!=
reqfid
)
{
printk
(
KERN_ERR
PFX
"ph2 mismatch, failed fid transition, curr %x, req %x
\n
"
,
currfid
,
reqfid
);
return
1
;
}
if
(
savevid
!=
currvid
)
{
printk
(
KERN_ERR
PFX
"ph2 vid changed, save %x, curr %x
\n
"
,
savevid
,
currvid
);
return
1
;
}
dprintk
(
KERN_DEBUG
PFX
"ph2 complete, currfid 0x%x, currvid 0x%x
\n
"
,
currfid
,
currvid
);
return
0
;
}
/* Phase 3 - core voltage transition flow ... jump to the final vid. */
static
inline
int
core_voltage_post_transition
(
u32
reqvid
)
{
u32
savefid
=
currfid
;
u32
savereqvid
=
reqvid
;
dprintk
(
KERN_DEBUG
PFX
"ph3 starting, currfid 0x%x, currvid 0x%x
\n
"
,
currfid
,
currvid
);
if
(
reqvid
!=
currvid
)
{
if
(
write_new_vid
(
reqvid
))
return
1
;
if
(
savefid
!=
currfid
)
{
printk
(
KERN_ERR
PFX
"ph3: bad fid change, save %x, curr %x
\n
"
,
savefid
,
currfid
);
return
1
;
}
if
(
currvid
!=
reqvid
)
{
printk
(
KERN_ERR
PFX
"ph3: failed vid transition
\n
, req %x, curr %x"
,
reqvid
,
currvid
);
return
1
;
}
}
if
(
query_current_values_with_pending_wait
())
return
1
;
if
(
savereqvid
!=
currvid
)
{
dprintk
(
KERN_ERR
PFX
"ph3 failed, currvid 0x%x
\n
"
,
currvid
);
return
1
;
}
if
(
savefid
!=
currfid
)
{
dprintk
(
KERN_ERR
PFX
"ph3 failed, currfid changed 0x%x
\n
"
,
currfid
);
return
1
;
}
dprintk
(
KERN_DEBUG
PFX
"ph3 complete, currfid 0x%x, currvid 0x%x
\n
"
,
currfid
,
currvid
);
return
0
;
}
static
inline
int
check_supported_cpu
(
void
)
{
struct
cpuinfo_x86
*
c
=
cpu_data
;
u32
eax
,
ebx
,
ecx
,
edx
;
if
(
num_online_cpus
()
!=
1
)
{
printk
(
KERN_INFO
PFX
"multiprocessor systems not supported
\n
"
);
return
0
;
}
if
(
c
->
x86_vendor
!=
X86_VENDOR_AMD
)
{
printk
(
KERN_INFO
PFX
"Not an AMD processor
\n
"
);
return
0
;
}
eax
=
cpuid_eax
(
CPUID_PROCESSOR_SIGNATURE
);
if
((
eax
&
CPUID_XFAM_MOD
)
==
ATHLON64_XFAM_MOD
)
{
dprintk
(
KERN_DEBUG
PFX
"AMD Althon 64 Processor found
\n
"
);
if
((
eax
&
CPUID_F1_STEP
)
<
ATHLON64_REV_C0
)
{
printk
(
KERN_INFO
PFX
"Revision C0 or better "
"AMD Athlon 64 processor required
\n
"
);
return
0
;
}
}
else
if
((
eax
&
CPUID_XFAM_MOD
)
==
OPTERON_XFAM_MOD
)
{
dprintk
(
KERN_DEBUG
PFX
"AMD Opteron Processor found
\n
"
);
}
else
{
printk
(
KERN_INFO
PFX
"AMD Athlon 64 or AMD Opteron processor required
\n
"
);
return
0
;
}
eax
=
cpuid_eax
(
CPUID_GET_MAX_CAPABILITIES
);
if
(
eax
<
CPUID_FREQ_VOLT_CAPABILITIES
)
{
printk
(
KERN_INFO
PFX
"No frequency change capabilities detected
\n
"
);
return
0
;
}
cpuid
(
CPUID_FREQ_VOLT_CAPABILITIES
,
&
eax
,
&
ebx
,
&
ecx
,
&
edx
);
if
((
edx
&
P_STATE_TRANSITION_CAPABLE
)
!=
P_STATE_TRANSITION_CAPABLE
)
{
printk
(
KERN_INFO
PFX
"Power state transitions not supported
\n
"
);
return
0
;
}
printk
(
KERN_INFO
PFX
"Found AMD Athlon 64 / Opteron processor "
"supporting p-state transitions
\n
"
);
return
1
;
}
/* Find and validate the PSB/PST table in BIOS. */
static
inline
int
find_psb_table
(
void
)
{
struct
psb_s
*
psb
;
struct
pst_s
*
pst
;
unsigned
i
,
j
;
u32
lastfid
;
u32
mvs
;
u8
maxvid
;
for
(
i
=
0xc0000
;
i
<
0xffff0
;
i
+=
0x10
)
{
/* Scan BIOS looking for the signature. */
/* It can not be at ffff0 - it is too big. */
psb
=
phys_to_virt
(
i
);
if
(
memcmp
(
psb
,
PSB_ID_STRING
,
PSB_ID_STRING_LEN
)
!=
0
)
continue
;
dprintk
(
KERN_DEBUG
PFX
"found PSB header at 0x%p
\n
"
,
psb
);
dprintk
(
KERN_DEBUG
PFX
"table vers: 0x%x
\n
"
,
psb
->
tableversion
);
if
(
psb
->
tableversion
!=
PSB_VERSION_1_4
)
{
printk
(
KERN_INFO
BFX
"PSB table is not v1.4
\n
"
);
return
-
ENODEV
;
}
dprintk
(
KERN_DEBUG
PFX
"flags: 0x%x
\n
"
,
psb
->
flags1
);
if
(
psb
->
flags1
)
{
printk
(
KERN_ERR
BFX
"unknown flags
\n
"
);
return
-
ENODEV
;
}
vstable
=
psb
->
voltagestabilizationtime
;
printk
(
KERN_INFO
PFX
"voltage stable time: %d (units 20us)
\n
"
,
vstable
);
dprintk
(
KERN_DEBUG
PFX
"flags2: 0x%x
\n
"
,
psb
->
flags2
);
rvo
=
psb
->
flags2
&
3
;
irt
=
((
psb
->
flags2
)
>>
2
)
&
3
;
mvs
=
((
psb
->
flags2
)
>>
4
)
&
3
;
vidmvs
=
1
<<
mvs
;
batps
=
((
psb
->
flags2
)
>>
6
)
&
3
;
printk
(
KERN_INFO
PFX
"p states on battery: %d "
,
batps
);
switch
(
batps
)
{
case
0
:
printk
(
"- all available
\n
"
);
break
;
case
1
:
printk
(
"- only the minimum
\n
"
);
break
;
case
2
:
printk
(
"- only the 2 lowest
\n
"
);
break
;
case
3
:
printk
(
"- only the 3 lowest
\n
"
);
break
;
}
printk
(
KERN_INFO
PFX
"ramp voltage offset: %d
\n
"
,
rvo
);
printk
(
KERN_INFO
PFX
"isochronous relief time: %d
\n
"
,
irt
);
printk
(
KERN_INFO
PFX
"maximum voltage step: %d
\n
"
,
mvs
);
dprintk
(
KERN_DEBUG
PFX
"numpst: 0x%x
\n
"
,
psb
->
numpst
);
if
(
psb
->
numpst
!=
1
)
{
printk
(
KERN_ERR
BFX
"numpst must be 1
\n
"
);
return
-
ENODEV
;
}
dprintk
(
KERN_DEBUG
PFX
"cpuid: 0x%x
\n
"
,
psb
->
cpuid
);
plllock
=
psb
->
plllocktime
;
printk
(
KERN_INFO
PFX
"pll lock time: 0x%x
\n
"
,
plllock
);
maxvid
=
psb
->
maxvid
;
printk
(
KERN_INFO
PFX
"maxfid: 0x%x
\n
"
,
psb
->
maxfid
);
printk
(
KERN_INFO
PFX
"maxvid: 0x%x
\n
"
,
maxvid
);
numps
=
psb
->
numpstates
;
printk
(
KERN_INFO
PFX
"numpstates: 0x%x
\n
"
,
numps
);
if
(
numps
<
2
)
{
printk
(
KERN_ERR
BFX
"no p states to transition
\n
"
);
return
-
ENODEV
;
}
if
(
batps
==
0
)
{
batps
=
numps
;
}
else
if
(
batps
>
numps
)
{
printk
(
KERN_ERR
BFX
"batterypstates > numpstates
\n
"
);
batps
=
numps
;
}
else
{
printk
(
KERN_ERR
PFX
"Restricting operation to %d p-states
\n
"
,
batps
);
printk
(
KERN_ERR
PFX
"Check for an updated driver to access all "
"%d p-states
\n
"
,
numps
);
}
if
((
numps
<=
1
)
||
(
batps
<=
1
))
{
printk
(
KERN_ERR
PFX
"only 1 p-state to transition
\n
"
);
return
-
ENODEV
;
}
ppst
=
kmalloc
(
sizeof
(
struct
pst_s
)
*
numps
,
GFP_KERNEL
);
if
(
!
ppst
)
{
printk
(
KERN_ERR
PFX
"ppst memory alloc failure
\n
"
);
return
-
ENOMEM
;
}
pst
=
(
struct
pst_s
*
)
(
psb
+
1
);
for
(
j
=
0
;
j
<
numps
;
j
++
)
{
ppst
[
j
].
fid
=
pst
[
j
].
fid
;
ppst
[
j
].
vid
=
pst
[
j
].
vid
;
printk
(
KERN_INFO
PFX
" %d : fid 0x%x, vid 0x%x
\n
"
,
j
,
ppst
[
j
].
fid
,
ppst
[
j
].
vid
);
}
sort_pst
(
ppst
,
numps
);
lastfid
=
ppst
[
0
].
fid
;
if
(
lastfid
>
LO_FID_TABLE_TOP
)
printk
(
KERN_INFO
BFX
"first fid not in lo freq tbl
\n
"
);
if
((
lastfid
>
MAX_FID
)
||
(
lastfid
&
1
)
||
(
ppst
[
0
].
vid
>
LEAST_VID
))
{
printk
(
KERN_ERR
BFX
"first fid/vid bad (0x%x - 0x%x)
\n
"
,
lastfid
,
ppst
[
0
].
vid
);
kfree
(
ppst
);
return
-
ENODEV
;
}
for
(
j
=
1
;
j
<
numps
;
j
++
)
{
if
((
lastfid
>=
ppst
[
j
].
fid
)
||
(
ppst
[
j
].
fid
&
1
)
||
(
ppst
[
j
].
fid
<
HI_FID_TABLE_BOTTOM
)
||
(
ppst
[
j
].
fid
>
MAX_FID
)
||
(
ppst
[
j
].
vid
>
LEAST_VID
))
{
printk
(
KERN_ERR
BFX
"invalid fid/vid in pst(%x %x)
\n
"
,
ppst
[
j
].
fid
,
ppst
[
j
].
vid
);
kfree
(
ppst
);
return
-
ENODEV
;
}
lastfid
=
ppst
[
j
].
fid
;
}
for
(
j
=
0
;
j
<
numps
;
j
++
)
{
if
(
ppst
[
j
].
vid
<
rvo
)
{
/* vid+rvo >= 0 */
printk
(
KERN_ERR
BFX
"0 vid exceeded with pstate %d
\n
"
,
j
);
return
-
ENODEV
;
}
if
(
ppst
[
j
].
vid
<
maxvid
+
rvo
)
{
/* vid+rvo >= maxvid */
printk
(
KERN_ERR
BFX
"maxvid exceeded with pstate %d
\n
"
,
j
);
return
-
ENODEV
;
}
}
if
(
query_current_values_with_pending_wait
())
{
kfree
(
ppst
);
return
-
EIO
;
}
printk
(
KERN_INFO
PFX
"currfid 0x%x, currvid 0x%x
\n
"
,
currfid
,
currvid
);
for
(
j
=
0
;
j
<
numps
;
j
++
)
if
((
ppst
[
j
].
fid
==
currfid
)
&&
(
ppst
[
j
].
vid
==
currvid
))
return
(
0
);
printk
(
KERN_ERR
BFX
"currfid/vid do not match PST, ignoring
\n
"
);
return
0
;
}
printk
(
KERN_ERR
BFX
"no PSB
\n
"
);
return
-
ENODEV
;
}
/* Converts a frequency (that might not necessarily be a multiple of 200) */
/* to a fid. */
u32
find_closest_fid
(
u32
freq
,
int
searchup
)
{
if
(
searchup
==
SEARCH_UP
)
freq
+=
MIN_FREQ_RESOLUTION
-
1
;
freq
=
(
freq
/
MIN_FREQ_RESOLUTION
)
*
MIN_FREQ_RESOLUTION
;
if
(
freq
<
MIN_FREQ
)
freq
=
MIN_FREQ
;
else
if
(
freq
>
MAX_FREQ
)
freq
=
MAX_FREQ
;
return
find_fid_from_freq
(
freq
);
}
static
int
find_match
(
u32
*
ptargfreq
,
u32
*
pmin
,
u32
*
pmax
,
int
searchup
,
u32
*
pfid
,
u32
*
pvid
)
{
u32
availpstates
=
batps
;
u32
targfid
=
find_closest_fid
(
*
ptargfreq
,
searchup
);
u32
minfid
=
find_closest_fid
(
*
pmin
,
SEARCH_DOWN
);
u32
maxfid
=
find_closest_fid
(
*
pmax
,
SEARCH_UP
);
u32
minidx
=
0
;
u32
maxidx
=
availpstates
-
1
;
u32
targidx
=
0xffffffff
;
int
i
;
dprintk
(
KERN_DEBUG
PFX
"find match: freq %d MHz, min %d, max %d
\n
"
,
*
ptargfreq
,
*
pmin
,
*
pmax
);
/* Restrict values to the frequency choices in the PST */
if
(
minfid
<
ppst
[
0
].
fid
)
minfid
=
ppst
[
0
].
fid
;
if
(
maxfid
>
ppst
[
maxidx
].
fid
)
maxfid
=
ppst
[
maxidx
].
fid
;
/* Find appropriate PST index for the minimim fid */
for
(
i
=
0
;
i
<
(
int
)
availpstates
;
i
++
)
{
if
(
minfid
>=
ppst
[
i
].
fid
)
minidx
=
i
;
}
/* Find appropriate PST index for the maximum fid */
for
(
i
=
availpstates
-
1
;
i
>=
0
;
i
--
)
{
if
(
maxfid
<=
ppst
[
i
].
fid
)
maxidx
=
i
;
}
if
(
minidx
>
maxidx
)
maxidx
=
minidx
;
/* Frequency ids are now constrained by limits matching PST entries */
minfid
=
ppst
[
minidx
].
fid
;
maxfid
=
ppst
[
maxidx
].
fid
;
/* Limit the target frequency to these limits */
if
(
targfid
<
minfid
)
targfid
=
minfid
;
else
if
(
targfid
>
maxfid
)
targfid
=
maxfid
;
/* Find the best target index into the PST, contrained by the range */
if
(
searchup
==
SEARCH_UP
)
{
for
(
i
=
maxidx
;
i
>=
(
int
)
minidx
;
i
--
)
{
if
(
targfid
<=
ppst
[
i
].
fid
)
targidx
=
i
;
}
}
else
{
for
(
i
=
minidx
;
i
<=
(
int
)
maxidx
;
i
++
)
{
if
(
targfid
>=
ppst
[
i
].
fid
)
targidx
=
i
;
}
}
if
(
targidx
==
0xffffffff
)
{
printk
(
KERN_ERR
PFX
"could not find target
\n
"
);
return
1
;
}
*
pmin
=
find_freq_from_fid
(
minfid
);
*
pmax
=
find_freq_from_fid
(
maxfid
);
*
ptargfreq
=
find_freq_from_fid
(
ppst
[
targidx
].
fid
);
if
(
pfid
)
*
pfid
=
ppst
[
targidx
].
fid
;
if
(
pvid
)
*
pvid
=
ppst
[
targidx
].
vid
;
return
0
;
}
/* Take a frequency, and issue the fid/vid transition command */
static
inline
int
transition_frequency
(
u32
*
preq
,
u32
*
pmin
,
u32
*
pmax
,
u32
searchup
)
{
u32
fid
;
u32
vid
;
int
res
;
struct
cpufreq_freqs
freqs
;
if
(
find_match
(
preq
,
pmin
,
pmax
,
searchup
,
&
fid
,
&
vid
))
return
1
;
dprintk
(
KERN_DEBUG
PFX
"table matched fid 0x%x, giving vid 0x%x
\n
"
,
fid
,
vid
);
if
(
query_current_values_with_pending_wait
())
return
1
;
if
((
currvid
==
vid
)
&&
(
currfid
==
fid
))
{
dprintk
(
KERN_DEBUG
PFX
"target matches current values (fid 0x%x, vid 0x%x)
\n
"
,
fid
,
vid
);
return
0
;
}
if
((
fid
<
HI_FID_TABLE_BOTTOM
)
&&
(
currfid
<
HI_FID_TABLE_BOTTOM
))
{
printk
(
KERN_ERR
PFX
"ignoring illegal change in lo freq table-%x to %x
\n
"
,
currfid
,
fid
);
return
1
;
}
dprintk
(
KERN_DEBUG
PFX
"changing to fid 0x%x, vid 0x%x
\n
"
,
fid
,
vid
);
freqs
.
cpu
=
0
;
/* only true because SMP not supported */
freqs
.
old
=
find_freq_from_fid
(
currfid
);
freqs
.
new
=
find_freq_from_fid
(
fid
);
cpufreq_notify_transition
(
&
freqs
,
CPUFREQ_PRECHANGE
);
res
=
transition_fid_vid
(
fid
,
vid
);
freqs
.
new
=
find_freq_from_fid
(
currfid
);
cpufreq_notify_transition
(
&
freqs
,
CPUFREQ_POSTCHANGE
);
return
res
;
}
/* Driver entry point to switch to the target frequency */
static
int
drv_target
(
struct
cpufreq_policy
*
pol
,
unsigned
targfreq
,
unsigned
relation
)
{
u32
checkfid
=
currfid
;
u32
checkvid
=
currvid
;
u32
reqfreq
=
targfreq
/
1000
;
u32
minfreq
=
pol
->
min
/
1000
;
u32
maxfreq
=
pol
->
max
/
1000
;
if
(
ppst
==
0
)
{
printk
(
KERN_ERR
PFX
"targ: ppst 0
\n
"
);
return
-
ENODEV
;
}
if
(
pending_bit_stuck
())
{
printk
(
KERN_ERR
PFX
"drv targ fail: change pending bit set
\n
"
);
return
-
EIO
;
}
dprintk
(
KERN_DEBUG
PFX
"targ: %d kHz, min %d, max %d, relation %d
\n
"
,
targfreq
,
pol
->
min
,
pol
->
max
,
relation
);
if
(
query_current_values_with_pending_wait
())
return
-
EIO
;
dprintk
(
KERN_DEBUG
PFX
"targ: curr fid 0x%x, vid 0x%x
\n
"
,
currfid
,
currvid
);
if
((
checkvid
!=
currvid
)
||
(
checkfid
!=
currfid
))
{
printk
(
KERN_ERR
PFX
"error - out of sync, fid 0x%x 0x%x, vid 0x%x 0x%x
\n
"
,
checkfid
,
currfid
,
checkvid
,
currvid
);
}
if
(
transition_frequency
(
&
reqfreq
,
&
minfreq
,
&
maxfreq
,
relation
==
CPUFREQ_RELATION_H
?
SEARCH_UP
:
SEARCH_DOWN
))
{
printk
(
KERN_ERR
PFX
"transition frequency failed
\n
"
);
return
1
;
}
pol
->
cur
=
1000
*
find_freq_from_fid
(
currfid
);
return
0
;
}
/* Driver entry point to verify the policy and range of frequencies */
static
int
drv_verify
(
struct
cpufreq_policy
*
pol
)
{
u32
min
=
pol
->
min
/
1000
;
u32
max
=
pol
->
max
/
1000
;
u32
targ
=
min
;
int
res
;
if
(
ppst
==
0
)
{
printk
(
KERN_ERR
PFX
"verify - ppst 0
\n
"
);
return
-
ENODEV
;
}
if
(
pending_bit_stuck
())
{
printk
(
KERN_ERR
PFX
"failing verify, change pending bit set
\n
"
);
return
-
EIO
;
}
dprintk
(
KERN_DEBUG
PFX
"ver: cpu%d, min %d, max %d, cur %d, pol %d
\n
"
,
pol
->
cpu
,
pol
->
min
,
pol
->
max
,
pol
->
cur
,
pol
->
policy
);
if
(
pol
->
cpu
!=
0
)
{
printk
(
KERN_ERR
PFX
"verify - cpu not 0
\n
"
);
return
-
ENODEV
;
}
res
=
find_match
(
&
targ
,
&
min
,
&
max
,
pol
->
policy
==
CPUFREQ_POLICY_POWERSAVE
?
SEARCH_DOWN
:
SEARCH_UP
,
0
,
0
);
if
(
!
res
)
{
pol
->
min
=
min
*
1000
;
pol
->
max
=
max
*
1000
;
}
return
res
;
}
/* per CPU init entry point to the driver */
static
int
__init
drv_cpu_init
(
struct
cpufreq_policy
*
pol
)
{
if
(
pol
->
cpu
!=
0
)
{
printk
(
KERN_ERR
PFX
"init not cpu 0
\n
"
);
return
-
ENODEV
;
}
pol
->
policy
=
CPUFREQ_POLICY_PERFORMANCE
;
/* boot as fast as we can */
/* Take a crude guess here. */
pol
->
cpuinfo
.
transition_latency
=
((
rvo
+
8
)
*
vstable
*
VST_UNITS_20US
)
+
(
3
*
(
1
<<
irt
)
*
10
);
if
(
query_current_values_with_pending_wait
())
return
-
EIO
;
pol
->
cur
=
1000
*
find_freq_from_fid
(
currfid
);
dprintk
(
KERN_DEBUG
PFX
"policy current frequency %d kHz
\n
"
,
pol
->
cur
);
/* min/max the cpu is capable of */
pol
->
cpuinfo
.
min_freq
=
1000
*
find_freq_from_fid
(
ppst
[
0
].
fid
);
pol
->
cpuinfo
.
max_freq
=
1000
*
find_freq_from_fid
(
ppst
[
numps
-
1
].
fid
);
pol
->
min
=
1000
*
find_freq_from_fid
(
ppst
[
0
].
fid
);
pol
->
max
=
1000
*
find_freq_from_fid
(
ppst
[
batps
-
1
].
fid
);
printk
(
KERN_INFO
PFX
"cpu_init done, current fid 0x%x, vid 0x%x
\n
"
,
currfid
,
currvid
);
return
0
;
}
/* driver entry point for init */
static
int
__init
drv_init
(
void
)
{
int
rc
;
printk
(
KERN_INFO
PFX
VERSION
"
\n
"
);
if
(
check_supported_cpu
()
==
0
)
return
-
ENODEV
;
rc
=
find_psb_table
();
if
(
rc
)
return
rc
;
if
(
pending_bit_stuck
())
{
printk
(
KERN_ERR
PFX
"drv_init fail, change pending bit set
\n
"
);
kfree
(
ppst
);
return
-
EIO
;
}
return
cpufreq_register_driver
(
&
cpufreq_amd64_driver
);
}
/* driver entry point for term */
static
void
__exit
drv_exit
(
void
)
{
dprintk
(
KERN_INFO
PFX
"drv_exit
\n
"
);
cpufreq_unregister_driver
(
&
cpufreq_amd64_driver
);
kfree
(
ppst
);
}
MODULE_AUTHOR
(
"Paul Devriendt <paul.devriendt@amd.com>"
);
MODULE_DESCRIPTION
(
"AMD Athlon 64 and Opteron processor frequency driver."
);
MODULE_LICENSE
(
"GPL"
);
module_init
(
drv_init
);
module_exit
(
drv_exit
);
arch/i386/kernel/cpu/cpufreq/powernow-k8.h
0 → 100644
View file @
f07b8ab2
/*
* (c) 2003 Advanced Micro Devices, Inc.
* Your use of this code is subject to the terms and conditions of the
* GNU general public license version 2. See "../../../COPYING" or
* http://www.gnu.org/licenses/gpl.html
*/
/* processor's cpuid instruction support */
#define CPUID_PROCESSOR_SIGNATURE 1
/* function 1 */
#define CPUID_F1_FAM 0x00000f00
/* family mask */
#define CPUID_F1_XFAM 0x0ff00000
/* extended family mask */
#define CPUID_F1_MOD 0x000000f0
/* model mask */
#define CPUID_F1_STEP 0x0000000f
/* stepping level mask */
#define CPUID_XFAM_MOD 0x0ff00ff0
/* xtended fam, fam + model */
#define ATHLON64_XFAM_MOD 0x00000f40
/* xtended fam, fam + model */
#define OPTERON_XFAM_MOD 0x00000f50
/* xtended fam, fam + model */
#define ATHLON64_REV_C0 8
#define CPUID_GET_MAX_CAPABILITIES 0x80000000
#define CPUID_FREQ_VOLT_CAPABILITIES 0x80000007
#define P_STATE_TRANSITION_CAPABLE 6
/* Model Specific Registers for p-state transitions. MSRs are 64-bit. For */
/* writes (wrmsr - opcode 0f 30), the register number is placed in ecx, and */
/* the value to write is placed in edx:eax. For reads (rdmsr - opcode 0f 32), */
/* the register number is placed in ecx, and the data is returned in edx:eax. */
#define MSR_FIDVID_CTL 0xc0010041
#define MSR_FIDVID_STATUS 0xc0010042
/* Field definitions within the FID VID Low Control MSR : */
#define MSR_C_LO_INIT_FID_VID 0x00010000
#define MSR_C_LO_NEW_VID 0x00001f00
#define MSR_C_LO_NEW_FID 0x0000002f
#define MSR_C_LO_VID_SHIFT 8
/* Field definitions within the FID VID High Control MSR : */
#define MSR_C_HI_STP_GNT_TO 0x000fffff
/* Field definitions within the FID VID Low Status MSR : */
#define MSR_S_LO_CHANGE_PENDING 0x80000000
/* cleared when completed */
#define MSR_S_LO_MAX_RAMP_VID 0x1f000000
#define MSR_S_LO_MAX_FID 0x003f0000
#define MSR_S_LO_START_FID 0x00003f00
#define MSR_S_LO_CURRENT_FID 0x0000003f
/* Field definitions within the FID VID High Status MSR : */
#define MSR_S_HI_MAX_WORKING_VID 0x001f0000
#define MSR_S_HI_START_VID 0x00001f00
#define MSR_S_HI_CURRENT_VID 0x0000001f
/* fids (frequency identifiers) are arranged in 2 tables - lo and hi */
#define LO_FID_TABLE_TOP 6
#define HI_FID_TABLE_BOTTOM 8
#define LO_VCOFREQ_TABLE_TOP 1400
/* corresponding vco frequency values */
#define HI_VCOFREQ_TABLE_BOTTOM 1600
#define MIN_FREQ_RESOLUTION 200
/* fids jump by 2 matching freq jumps by 200 */
#define MAX_FID 0x2a
/* Spec only gives FID values as far as 5 GHz */
#define LEAST_VID 0x1e
/* Lowest (numerically highest) useful vid value */
#define MIN_FREQ 800
/* Min and max freqs, per spec */
#define MAX_FREQ 5000
#define INVALID_FID_MASK 0xffffffc1
/* not a valid fid if these bits are set */
#define INVALID_VID_MASK 0xffffffe0
/* not a valid vid if these bits are set */
#define STOP_GRANT_5NS 1
/* min poss memory access latency for voltage change */
#define PLL_LOCK_CONVERSION (1000/5)
/* ms to ns, then divide by clock period */
#define MAXIMUM_VID_STEPS 1
/* Current cpus only allow a single step of 25mV */
#define VST_UNITS_20US 20
/* Voltage Stabalization Time is in units of 20us */
/*
Version 1.4 of the PSB table. This table is constructed by BIOS and is
to tell the OS's power management driver which VIDs and FIDs are
supported by this particular processor. This information is obtained from
the data sheets for each processor model by the system vendor and
incorporated into the BIOS.
If the data in the PSB / PST is wrong, then this driver will program the
wrong values into hardware, which is very likely to lead to a crash.
*/
#define PSB_ID_STRING "AMDK7PNOW!"
#define PSB_ID_STRING_LEN 10
#define PSB_VERSION_1_4 0x14
struct
psb_s
{
u8
signature
[
10
];
u8
tableversion
;
u8
flags1
;
u16
voltagestabilizationtime
;
u8
flags2
;
u8
numpst
;
u32
cpuid
;
u8
plllocktime
;
u8
maxfid
;
u8
maxvid
;
u8
numpstates
;
};
/* Pairs of fid/vid values are appended to the version 1.4 PSB table. */
struct
pst_s
{
u8
fid
;
u8
vid
;
};
#ifdef DEBUG
#define dprintk(msg...) printk(msg)
#else
#define dprintk(msg...) do { } while(0)
#endif
static
inline
int
core_voltage_pre_transition
(
u32
reqvid
);
static
inline
int
core_voltage_post_transition
(
u32
reqvid
);
static
inline
int
core_frequency_transition
(
u32
reqfid
);
static
int
drv_verify
(
struct
cpufreq_policy
*
pol
);
static
int
drv_target
(
struct
cpufreq_policy
*
pol
,
unsigned
targfreq
,
unsigned
relation
);
static
int
__init
drv_cpu_init
(
struct
cpufreq_policy
*
pol
);
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