/* $OpenBSD: powernow-k8.c,v 1.23 2007/05/31 17:49:16 gwk Exp $ */
/*
* Copyright (c) 2004 Martin Végiard.
* Copyright (c) 2004-2005 Bruno Ducrot
* Copyright (c) 2004 FUKUDA Nobuhiko <nfukuda@spa.is.uec.ac.jp>
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions
* are met:
* 1. Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
/* AMD POWERNOW K8 driver */
#include <sys/types.h>
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/malloc.h>
#include <sys/sysctl.h>
#include <dev/isa/isareg.h>
#include <i386/isa/isa_machdep.h>
#include <machine/cpu.h>
#include <machine/cpufunc.h>
#include <machine/bus.h>
#include "acpicpu.h"
#if NACPICPU > 0
#include <dev/acpi/acpidev.h>
#include <dev/acpi/acpivar.h>
#endif
#define BIOS_START 0xe0000
#define BIOS_LEN 0x20000
#define BIOS_STEP 16
/*
* MSRs and bits used by PowerNow! technology
*/
#define MSR_AMDK7_FIDVID_CTL 0xc0010041
#define MSR_AMDK7_FIDVID_STATUS 0xc0010042
#define AMD_PN_FID_VID 0x06
/* Bitfields used by K8 */
#define PN8_CTR_FID(x) ((x) & 0x3f)
#define PN8_CTR_VID(x) (((x) & 0x1f) << 8)
#define PN8_CTR_PENDING(x) (((x) & 1) << 32)
#define PN8_STA_CFID(x) ((x) & 0x3f)
#define PN8_STA_SFID(x) (((x) >> 8) & 0x3f)
#define PN8_STA_MFID(x) (((x) >> 16) & 0x3f)
#define PN8_STA_PENDING(x) (((x) >> 31) & 0x01)
#define PN8_STA_CVID(x) (((x) >> 32) & 0x1f)
#define PN8_STA_SVID(x) (((x) >> 40) & 0x1f)
#define PN8_STA_MVID(x) (((x) >> 48) & 0x1f)
/* Reserved1 to powernow k8 configuration */
#define PN8_PSB_VERSION 0x14
#define PN8_PSB_TO_RVO(x) ((x) & 0x03)
#define PN8_PSB_TO_IRT(x) (((x) >> 2) & 0x03)
#define PN8_PSB_TO_MVS(x) (((x) >> 4) & 0x03)
#define PN8_PSB_TO_BATT(x) (((x) >> 6) & 0x03)
/* ACPI ctr_val status register to powernow k8 configuration */
#define PN8_ACPI_CTRL_TO_FID(x) ((x) & 0x3f)
#define PN8_ACPI_CTRL_TO_VID(x) (((x) >> 6) & 0x1f)
#define PN8_ACPI_CTRL_TO_VST(x) (((x) >> 11) & 0x1f)
#define PN8_ACPI_CTRL_TO_MVS(x) (((x) >> 18) & 0x03)
#define PN8_ACPI_CTRL_TO_PLL(x) (((x) >> 20) & 0x7f)
#define PN8_ACPI_CTRL_TO_RVO(x) (((x) >> 28) & 0x03)
#define PN8_ACPI_CTRL_TO_IRT(x) (((x) >> 30) & 0x03)
#define PN8_PLL_LOCK(x) ((x) * 1000/5)
#define WRITE_FIDVID(fid, vid, ctrl) \
wrmsr(MSR_AMDK7_FIDVID_CTL, \
(((ctrl) << 32) | (1ULL << 16) | ((vid) << 8) | (fid)))
#define COUNT_OFF_IRT(irt) DELAY(10 * (1 << (irt)))
#define COUNT_OFF_VST(vst) DELAY(20 * (vst))
#define FID_TO_VCO_FID(fid) \
(((fid) < 8) ? (8 + ((fid) << 1)) : (fid))
#define POWERNOW_MAX_STATES 16
struct k8pnow_state {
int freq;
uint8_t fid;
uint8_t vid;
};
struct k8pnow_cpu_state {
struct k8pnow_state state_table[POWERNOW_MAX_STATES];
unsigned int n_states;
unsigned int sgtc;
unsigned int vst;
unsigned int mvs;
unsigned int pll;
unsigned int rvo;
unsigned int irt;
int low;
};
struct psb_s {
char signature[10]; /* AMDK7PNOW! */
uint8_t version;
uint8_t flags;
uint16_t ttime; /* Min Settling time */
uint8_t reserved;
uint8_t n_pst;
};
struct pst_s {
uint32_t cpuid;
uint8_t pll;
uint8_t fid;
uint8_t vid;
uint8_t n_states;
};
struct k8pnow_cpu_state *k8pnow_current_state = NULL;
extern int setperf_prio;
int k8pnow_read_pending_wait(uint64_t *);
int k8pnow_decode_pst(struct k8pnow_cpu_state *, uint8_t *);
int k8pnow_states(struct k8pnow_cpu_state *, uint32_t, unsigned int,
unsigned int);
#if NACPICPU > 0
int k8pnow_acpi_init(struct k8pnow_cpu_state *, uint64_t);
void k8pnow_acpi_pss_changed(struct acpicpu_pss *, int);
int k8pnow_acpi_states(struct k8pnow_cpu_state *, struct acpicpu_pss *, int,
uint64_t);
#endif
int
k8pnow_read_pending_wait(uint64_t *status)
{
unsigned int i = 100000;
while (i--) {
*status = rdmsr(MSR_AMDK7_FIDVID_STATUS);
if (!PN8_STA_PENDING(*status))
return 0;
}
printf("k8pnow_read_pending_wait: change pending stuck.\n");
return 1;
}
void
k8_powernow_setperf(int level)
{
unsigned int i;
uint64_t status;
int cfid, cvid, fid = 0, vid = 0, rvo;
u_int val;
struct k8pnow_cpu_state *cstate;
/*
* We dont do a k8pnow_read_pending_wait here, need to ensure that the
* change pending bit isn't stuck,
*/
status = rdmsr(MSR_AMDK7_FIDVID_STATUS);
if (PN8_STA_PENDING(status))
return;
cfid = PN8_STA_CFID(status);
cvid = PN8_STA_CVID(status);
cstate = k8pnow_current_state;
i = ((level * cstate->n_states) + 1) / 101;
if (i >= cstate->n_states)
i = cstate->n_states - 1;
fid = cstate->state_table[i].fid;
vid = cstate->state_table[i].vid;
if (fid == cfid && vid == cvid)
return;
/*
* Phase 1: Raise core voltage to requested VID if frequency is
* going up.
*/
while (cvid > vid) {
val = cvid - (1 << cstate->mvs);
WRITE_FIDVID(cfid, (val > 0) ? val : 0, 1ULL);
if (k8pnow_read_pending_wait(&status))
return;
cvid = PN8_STA_CVID(status);
COUNT_OFF_VST(cstate->vst);
}
/* ... then raise to voltage + RVO (if required) */
for (rvo = cstate->rvo; rvo > 0 && cvid > 0; --rvo) {
/* XXX It's not clear from spec if we have to do that
* in 0.25 step or in MVS. Therefore do it as it's done
* under Linux */
WRITE_FIDVID(cfid, cvid - 1, 1ULL);
if (k8pnow_read_pending_wait(&status))
return;
cvid = PN8_STA_CVID(status);
COUNT_OFF_VST(cstate->vst);
}
/* Phase 2: change to requested core frequency */
if (cfid != fid) {
u_int vco_fid, vco_cfid;
vco_fid = FID_TO_VCO_FID(fid);
vco_cfid = FID_TO_VCO_FID(cfid);
while (abs(vco_fid - vco_cfid) > 2) {
if (fid > cfid) {
if (cfid > 6)
val = cfid + 2;
else
val = FID_TO_VCO_FID(cfid) + 2;
} else
val = cfid - 2;
WRITE_FIDVID(val, cvid, (uint64_t)
PN8_PLL_LOCK(cstate->pll));
if (k8pnow_read_pending_wait(&status))
return;
cfid = PN8_STA_CFID(status);
COUNT_OFF_IRT(cstate->irt);
vco_cfid = FID_TO_VCO_FID(cfid);
}
WRITE_FIDVID(fid, cvid, (uint64_t) PN8_PLL_LOCK(cstate->pll));
if (k8pnow_read_pending_wait(&status))
return;
cfid = PN8_STA_CFID(status);
COUNT_OFF_IRT(cstate->irt);
}
/* Phase 3: change to requested voltage */
if (cvid != vid) {
WRITE_FIDVID(cfid, vid, 1ULL);
if (k8pnow_read_pending_wait(&status))
return;
cvid = PN8_STA_CVID(status);
COUNT_OFF_VST(cstate->vst);
}
if (cfid == fid || cvid == vid)
cpuspeed = cstate->state_table[i].freq;
}
/*
* Given a set of pair of fid/vid, and number of performance states,
* compute state_table via an insertion sort.
*/
int
k8pnow_decode_pst(struct k8pnow_cpu_state *cstate, uint8_t *p)
{
int i, j, n;
struct k8pnow_state state;
for (n = 0, i = 0; i < cstate->n_states; i++) {
state.fid = *p++;
state.vid = *p++;
/*
* The minimum supported frequency per the data sheet is 800MHz
* The maximum supported frequency is 5000MHz.
*/
state.freq = 800 + state.fid * 100;
j = n;
while (j > 0 && cstate->state_table[j - 1].freq > state.freq) {
memcpy(&cstate->state_table[j],
&cstate->state_table[j - 1],
sizeof(struct k8pnow_state));
--j;
}
memcpy(&cstate->state_table[j], &state,
sizeof(struct k8pnow_state));
n++;
}
return 1;
}
int
k8pnow_states(struct k8pnow_cpu_state *cstate, uint32_t cpusig,
unsigned int fid, unsigned int vid)
{
struct psb_s *psb;
struct pst_s *pst;
uint8_t *p;
int i;
for (p = (u_int8_t *)ISA_HOLE_VADDR(BIOS_START);
p < (u_int8_t *)ISA_HOLE_VADDR(BIOS_START + BIOS_LEN); p +=
BIOS_STEP) {
if (memcmp(p, "AMDK7PNOW!", 10) == 0) {
psb = (struct psb_s *)p;
if (psb->version != PN8_PSB_VERSION)
return 0;
cstate->vst = psb->ttime;
cstate->rvo = PN8_PSB_TO_RVO(psb->reserved);
cstate->irt = PN8_PSB_TO_IRT(psb->reserved);
cstate->mvs = PN8_PSB_TO_MVS(psb->reserved);
cstate->low = PN8_PSB_TO_BATT(psb->reserved);
p+= sizeof(struct psb_s);
for (i = 0; i < psb->n_pst; ++i) {
pst = (struct pst_s *) p;
cstate->pll = pst->pll;
cstate->n_states = pst->n_states;
if (cpusig == pst->cpuid &&
pst->fid == fid && pst->vid == vid) {
return (k8pnow_decode_pst(cstate,
p+= sizeof (struct pst_s)));
}
p += sizeof(struct pst_s) + 2
* cstate->n_states;
}
}
}
return 0;
}
#if NACPICPU > 0
int
k8pnow_acpi_states(struct k8pnow_cpu_state * cstate, struct acpicpu_pss * pss,
int nstates, uint64_t status)
{
struct k8pnow_state state;
int j, k, n;
uint32_t ctrl;
k = -1;
for (n = 0; n < cstate->n_states; n++) {
if (status == pss[n].pss_status)
k = n;
ctrl = pss[n].pss_ctrl;
state.fid = PN8_ACPI_CTRL_TO_FID(ctrl);
state.vid = PN8_ACPI_CTRL_TO_VID(ctrl);
state.freq = pss[n].pss_core_freq;
j = n;
while (j > 0 && cstate->state_table[j - 1].freq > state.freq) {
memcpy(&cstate->state_table[j],
&cstate->state_table[j - 1],
sizeof(struct k8pnow_state));
--j;
}
memcpy(&cstate->state_table[j], &state,
sizeof(struct k8pnow_state));
}
return k;
}
void
k8pnow_acpi_pss_changed(struct acpicpu_pss * pss, int npss)
{
int curs;
struct k8pnow_cpu_state * cstate;
uint32_t ctrl;
uint64_t status;
status = rdmsr(MSR_AMDK7_FIDVID_STATUS);
cstate = k8pnow_current_state;
curs = k8pnow_acpi_states(cstate, pss, npss, status);
ctrl = pss[curs].pss_ctrl;
cstate->vst = PN8_ACPI_CTRL_TO_VST(ctrl);
cstate->mvs = PN8_ACPI_CTRL_TO_MVS(ctrl);
cstate->pll = PN8_ACPI_CTRL_TO_PLL(ctrl);
cstate->irt = PN8_ACPI_CTRL_TO_IRT(ctrl);
cstate->low = 0;
cstate->n_states = npss;
}
int
k8pnow_acpi_init(struct k8pnow_cpu_state * cstate, uint64_t status)
{
int curs;
uint32_t ctrl;
struct acpicpu_pss *pss;
cstate->n_states = acpicpu_fetch_pss(&pss);
if (cstate->n_states == 0)
return 0;
acpicpu_set_notify(k8pnow_acpi_pss_changed);
curs = k8pnow_acpi_states(cstate, pss, cstate->n_states, status);
ctrl = pss[curs].pss_ctrl;
cstate->vst = PN8_ACPI_CTRL_TO_VST(ctrl);
cstate->mvs = PN8_ACPI_CTRL_TO_MVS(ctrl);
cstate->pll = PN8_ACPI_CTRL_TO_PLL(ctrl);
cstate->irt = PN8_ACPI_CTRL_TO_IRT(ctrl);
cstate->low = 0;
return 1;
}
#endif /* NACPICPU */
void
k8_powernow_init(void)
{
uint64_t status;
u_int maxfid, maxvid, i;
struct k8pnow_cpu_state *cstate;
struct k8pnow_state *state;
struct cpu_info * ci;
char * techname = NULL;
u_int32_t regs[4];
ci = curcpu();
if (setperf_prio > 1)
return;
if (k8pnow_current_state)
return;
cpuid(0x80000000, regs);
if (regs[0] < 0x80000007)
return;
cpuid(0x80000007, regs);
if (!(regs[3] & AMD_PN_FID_VID))
return;
/* Extended CPUID signature value */
cpuid(0x80000001, regs);
cstate = malloc(sizeof(struct k8pnow_cpu_state), M_DEVBUF, M_NOWAIT);
if (!cstate)
return;
cstate->n_states = 0;
status = rdmsr(MSR_AMDK7_FIDVID_STATUS);
maxfid = PN8_STA_MFID(status);
maxvid = PN8_STA_MVID(status);
/*
* If start FID is different to max FID, then it is a
* mobile processor. If not, it is a low powered desktop
* processor.
*/
if (PN8_STA_SFID(status) != PN8_STA_MFID(status))
techname = "PowerNow! K8";
else
techname = "Cool'n'Quiet K8";
#if NACPICPU > 0
/* If we have acpi check acpi first */
if (!k8pnow_acpi_init(cstate, status))
#endif
{
if (!k8pnow_states(cstate, ci->ci_signature, maxfid, maxvid))
k8pnow_states(cstate, regs[0], maxfid, maxvid);
}
if (cstate->n_states) {
printf("%s: %s %d MHz: speeds:",
ci->ci_dev.dv_xname, techname, cpuspeed);
for (i = cstate->n_states; i > 0; i--) {
state = &cstate->state_table[i-1];
printf(" %d", state->freq);
}
printf(" MHz\n");
k8pnow_current_state = cstate;
cpu_setperf = k8_powernow_setperf;
setperf_prio = 1;
return;
}
free(cstate, M_DEVBUF);
}
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