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alistair23-linux/drivers/ssb/driver_chipcommon_pmu.c
Rafał Miłecki 138173d4e8 MIPS: BCM47xx: Move NVRAM header to the include/linux/. 
There are two reasons for having this header in the common place:
1) Simplifying drivers that read NVRAM entries. We will be able to
   safely call bcm47xx_nvram_* functions without #ifdef-s.
2) Getting NVRAM driver out of MIPS arch code. This is needed to support
   BCM5301X arch which also requires this NVRAM driver. Patch for that
   will follow once we get is reviewed.

Signed-off-by: Rafał Miłecki <zajec5@gmail.com>
Acked-by: Hauke Mehrtens <hauke@hauke-m.de>
Cc: linux-mips@linux-mips.org
Cc: Arnd Bergmann <arnd@arndb.de>
Cc: Paul Walmsley <paul@pwsan.com>
Cc: linux-soc@vger.kernel.org
Patchwork: https://patchwork.linux-mips.org/patch/8619/
Signed-off-by: Ralf Baechle <ralf@linux-mips.org>
2015-04-01 17:22:00 +02:00

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/*
* Sonics Silicon Backplane
* Broadcom ChipCommon Power Management Unit driver
*
* Copyright 2009, Michael Buesch <m@bues.ch>
* Copyright 2007, Broadcom Corporation
*
* Licensed under the GNU/GPL. See COPYING for details.
*/
#include <linux/ssb/ssb.h>
#include <linux/ssb/ssb_regs.h>
#include <linux/ssb/ssb_driver_chipcommon.h>
#include <linux/delay.h>
#include <linux/export.h>
#ifdef CONFIG_BCM47XX
#include <linux/bcm47xx_nvram.h>
#endif
#include "ssb_private.h"
static u32 ssb_chipco_pll_read(struct ssb_chipcommon *cc, u32 offset)
{
chipco_write32(cc, SSB_CHIPCO_PLLCTL_ADDR, offset);
return chipco_read32(cc, SSB_CHIPCO_PLLCTL_DATA);
}
static void ssb_chipco_pll_write(struct ssb_chipcommon *cc,
u32 offset, u32 value)
{
chipco_write32(cc, SSB_CHIPCO_PLLCTL_ADDR, offset);
chipco_write32(cc, SSB_CHIPCO_PLLCTL_DATA, value);
}
static void ssb_chipco_regctl_maskset(struct ssb_chipcommon *cc,
u32 offset, u32 mask, u32 set)
{
u32 value;
chipco_read32(cc, SSB_CHIPCO_REGCTL_ADDR);
chipco_write32(cc, SSB_CHIPCO_REGCTL_ADDR, offset);
chipco_read32(cc, SSB_CHIPCO_REGCTL_ADDR);
value = chipco_read32(cc, SSB_CHIPCO_REGCTL_DATA);
value &= mask;
value |= set;
chipco_write32(cc, SSB_CHIPCO_REGCTL_DATA, value);
chipco_read32(cc, SSB_CHIPCO_REGCTL_DATA);
}
struct pmu0_plltab_entry {
u16 freq; /* Crystal frequency in kHz.*/
u8 xf; /* Crystal frequency value for PMU control */
u8 wb_int;
u32 wb_frac;
};
static const struct pmu0_plltab_entry pmu0_plltab[] = {
{ .freq = 12000, .xf = 1, .wb_int = 73, .wb_frac = 349525, },
{ .freq = 13000, .xf = 2, .wb_int = 67, .wb_frac = 725937, },
{ .freq = 14400, .xf = 3, .wb_int = 61, .wb_frac = 116508, },
{ .freq = 15360, .xf = 4, .wb_int = 57, .wb_frac = 305834, },
{ .freq = 16200, .xf = 5, .wb_int = 54, .wb_frac = 336579, },
{ .freq = 16800, .xf = 6, .wb_int = 52, .wb_frac = 399457, },
{ .freq = 19200, .xf = 7, .wb_int = 45, .wb_frac = 873813, },
{ .freq = 19800, .xf = 8, .wb_int = 44, .wb_frac = 466033, },
{ .freq = 20000, .xf = 9, .wb_int = 44, .wb_frac = 0, },
{ .freq = 25000, .xf = 10, .wb_int = 70, .wb_frac = 419430, },
{ .freq = 26000, .xf = 11, .wb_int = 67, .wb_frac = 725937, },
{ .freq = 30000, .xf = 12, .wb_int = 58, .wb_frac = 699050, },
{ .freq = 38400, .xf = 13, .wb_int = 45, .wb_frac = 873813, },
{ .freq = 40000, .xf = 14, .wb_int = 45, .wb_frac = 0, },
};
#define SSB_PMU0_DEFAULT_XTALFREQ 20000
static const struct pmu0_plltab_entry * pmu0_plltab_find_entry(u32 crystalfreq)
{
const struct pmu0_plltab_entry *e;
unsigned int i;
for (i = 0; i < ARRAY_SIZE(pmu0_plltab); i++) {
e = &pmu0_plltab[i];
if (e->freq == crystalfreq)
return e;
}
return NULL;
}
/* Tune the PLL to the crystal speed. crystalfreq is in kHz. */
static void ssb_pmu0_pllinit_r0(struct ssb_chipcommon *cc,
u32 crystalfreq)
{
struct ssb_bus *bus = cc->dev->bus;
const struct pmu0_plltab_entry *e = NULL;
u32 pmuctl, tmp, pllctl;
unsigned int i;
if (crystalfreq)
e = pmu0_plltab_find_entry(crystalfreq);
if (!e)
e = pmu0_plltab_find_entry(SSB_PMU0_DEFAULT_XTALFREQ);
BUG_ON(!e);
crystalfreq = e->freq;
cc->pmu.crystalfreq = e->freq;
/* Check if the PLL already is programmed to this frequency. */
pmuctl = chipco_read32(cc, SSB_CHIPCO_PMU_CTL);
if (((pmuctl & SSB_CHIPCO_PMU_CTL_XTALFREQ) >> SSB_CHIPCO_PMU_CTL_XTALFREQ_SHIFT) == e->xf) {
/* We're already there... */
return;
}
ssb_info("Programming PLL to %u.%03u MHz\n",
crystalfreq / 1000, crystalfreq % 1000);
/* First turn the PLL off. */
switch (bus->chip_id) {
case 0x4328:
chipco_mask32(cc, SSB_CHIPCO_PMU_MINRES_MSK,
~(1 << SSB_PMURES_4328_BB_PLL_PU));
chipco_mask32(cc, SSB_CHIPCO_PMU_MAXRES_MSK,
~(1 << SSB_PMURES_4328_BB_PLL_PU));
break;
case 0x5354:
chipco_mask32(cc, SSB_CHIPCO_PMU_MINRES_MSK,
~(1 << SSB_PMURES_5354_BB_PLL_PU));
chipco_mask32(cc, SSB_CHIPCO_PMU_MAXRES_MSK,
~(1 << SSB_PMURES_5354_BB_PLL_PU));
break;
default:
SSB_WARN_ON(1);
}
for (i = 1500; i; i--) {
tmp = chipco_read32(cc, SSB_CHIPCO_CLKCTLST);
if (!(tmp & SSB_CHIPCO_CLKCTLST_HAVEHT))
break;
udelay(10);
}
tmp = chipco_read32(cc, SSB_CHIPCO_CLKCTLST);
if (tmp & SSB_CHIPCO_CLKCTLST_HAVEHT)
ssb_emerg("Failed to turn the PLL off!\n");
/* Set PDIV in PLL control 0. */
pllctl = ssb_chipco_pll_read(cc, SSB_PMU0_PLLCTL0);
if (crystalfreq >= SSB_PMU0_PLLCTL0_PDIV_FREQ)
pllctl |= SSB_PMU0_PLLCTL0_PDIV_MSK;
else
pllctl &= ~SSB_PMU0_PLLCTL0_PDIV_MSK;
ssb_chipco_pll_write(cc, SSB_PMU0_PLLCTL0, pllctl);
/* Set WILD in PLL control 1. */
pllctl = ssb_chipco_pll_read(cc, SSB_PMU0_PLLCTL1);
pllctl &= ~SSB_PMU0_PLLCTL1_STOPMOD;
pllctl &= ~(SSB_PMU0_PLLCTL1_WILD_IMSK | SSB_PMU0_PLLCTL1_WILD_FMSK);
pllctl |= ((u32)e->wb_int << SSB_PMU0_PLLCTL1_WILD_IMSK_SHIFT) & SSB_PMU0_PLLCTL1_WILD_IMSK;
pllctl |= ((u32)e->wb_frac << SSB_PMU0_PLLCTL1_WILD_FMSK_SHIFT) & SSB_PMU0_PLLCTL1_WILD_FMSK;
if (e->wb_frac == 0)
pllctl |= SSB_PMU0_PLLCTL1_STOPMOD;
ssb_chipco_pll_write(cc, SSB_PMU0_PLLCTL1, pllctl);
/* Set WILD in PLL control 2. */
pllctl = ssb_chipco_pll_read(cc, SSB_PMU0_PLLCTL2);
pllctl &= ~SSB_PMU0_PLLCTL2_WILD_IMSKHI;
pllctl |= (((u32)e->wb_int >> 4) << SSB_PMU0_PLLCTL2_WILD_IMSKHI_SHIFT) & SSB_PMU0_PLLCTL2_WILD_IMSKHI;
ssb_chipco_pll_write(cc, SSB_PMU0_PLLCTL2, pllctl);
/* Set the crystalfrequency and the divisor. */
pmuctl = chipco_read32(cc, SSB_CHIPCO_PMU_CTL);
pmuctl &= ~SSB_CHIPCO_PMU_CTL_ILP_DIV;
pmuctl |= (((crystalfreq + 127) / 128 - 1) << SSB_CHIPCO_PMU_CTL_ILP_DIV_SHIFT)
& SSB_CHIPCO_PMU_CTL_ILP_DIV;
pmuctl &= ~SSB_CHIPCO_PMU_CTL_XTALFREQ;
pmuctl |= ((u32)e->xf << SSB_CHIPCO_PMU_CTL_XTALFREQ_SHIFT) & SSB_CHIPCO_PMU_CTL_XTALFREQ;
chipco_write32(cc, SSB_CHIPCO_PMU_CTL, pmuctl);
}
struct pmu1_plltab_entry {
u16 freq; /* Crystal frequency in kHz.*/
u8 xf; /* Crystal frequency value for PMU control */
u8 ndiv_int;
u32 ndiv_frac;
u8 p1div;
u8 p2div;
};
static const struct pmu1_plltab_entry pmu1_plltab[] = {
{ .freq = 12000, .xf = 1, .p1div = 3, .p2div = 22, .ndiv_int = 0x9, .ndiv_frac = 0xFFFFEF, },
{ .freq = 13000, .xf = 2, .p1div = 1, .p2div = 6, .ndiv_int = 0xb, .ndiv_frac = 0x483483, },
{ .freq = 14400, .xf = 3, .p1div = 1, .p2div = 10, .ndiv_int = 0xa, .ndiv_frac = 0x1C71C7, },
{ .freq = 15360, .xf = 4, .p1div = 1, .p2div = 5, .ndiv_int = 0xb, .ndiv_frac = 0x755555, },
{ .freq = 16200, .xf = 5, .p1div = 1, .p2div = 10, .ndiv_int = 0x5, .ndiv_frac = 0x6E9E06, },
{ .freq = 16800, .xf = 6, .p1div = 1, .p2div = 10, .ndiv_int = 0x5, .ndiv_frac = 0x3CF3CF, },
{ .freq = 19200, .xf = 7, .p1div = 1, .p2div = 9, .ndiv_int = 0x5, .ndiv_frac = 0x17B425, },
{ .freq = 19800, .xf = 8, .p1div = 1, .p2div = 11, .ndiv_int = 0x4, .ndiv_frac = 0xA57EB, },
{ .freq = 20000, .xf = 9, .p1div = 1, .p2div = 11, .ndiv_int = 0x4, .ndiv_frac = 0, },
{ .freq = 24000, .xf = 10, .p1div = 3, .p2div = 11, .ndiv_int = 0xa, .ndiv_frac = 0, },
{ .freq = 25000, .xf = 11, .p1div = 5, .p2div = 16, .ndiv_int = 0xb, .ndiv_frac = 0, },
{ .freq = 26000, .xf = 12, .p1div = 1, .p2div = 2, .ndiv_int = 0x10, .ndiv_frac = 0xEC4EC4, },
{ .freq = 30000, .xf = 13, .p1div = 3, .p2div = 8, .ndiv_int = 0xb, .ndiv_frac = 0, },
{ .freq = 38400, .xf = 14, .p1div = 1, .p2div = 5, .ndiv_int = 0x4, .ndiv_frac = 0x955555, },
{ .freq = 40000, .xf = 15, .p1div = 1, .p2div = 2, .ndiv_int = 0xb, .ndiv_frac = 0, },
};
#define SSB_PMU1_DEFAULT_XTALFREQ 15360
static const struct pmu1_plltab_entry * pmu1_plltab_find_entry(u32 crystalfreq)
{
const struct pmu1_plltab_entry *e;
unsigned int i;
for (i = 0; i < ARRAY_SIZE(pmu1_plltab); i++) {
e = &pmu1_plltab[i];
if (e->freq == crystalfreq)
return e;
}
return NULL;
}
/* Tune the PLL to the crystal speed. crystalfreq is in kHz. */
static void ssb_pmu1_pllinit_r0(struct ssb_chipcommon *cc,
u32 crystalfreq)
{
struct ssb_bus *bus = cc->dev->bus;
const struct pmu1_plltab_entry *e = NULL;
u32 buffer_strength = 0;
u32 tmp, pllctl, pmuctl;
unsigned int i;
if (bus->chip_id == 0x4312) {
/* We do not touch the BCM4312 PLL and assume
* the default crystal settings work out-of-the-box. */
cc->pmu.crystalfreq = 20000;
return;
}
if (crystalfreq)
e = pmu1_plltab_find_entry(crystalfreq);
if (!e)
e = pmu1_plltab_find_entry(SSB_PMU1_DEFAULT_XTALFREQ);
BUG_ON(!e);
crystalfreq = e->freq;
cc->pmu.crystalfreq = e->freq;
/* Check if the PLL already is programmed to this frequency. */
pmuctl = chipco_read32(cc, SSB_CHIPCO_PMU_CTL);
if (((pmuctl & SSB_CHIPCO_PMU_CTL_XTALFREQ) >> SSB_CHIPCO_PMU_CTL_XTALFREQ_SHIFT) == e->xf) {
/* We're already there... */
return;
}
ssb_info("Programming PLL to %u.%03u MHz\n",
crystalfreq / 1000, crystalfreq % 1000);
/* First turn the PLL off. */
switch (bus->chip_id) {
case 0x4325:
chipco_mask32(cc, SSB_CHIPCO_PMU_MINRES_MSK,
~((1 << SSB_PMURES_4325_BBPLL_PWRSW_PU) |
(1 << SSB_PMURES_4325_HT_AVAIL)));
chipco_mask32(cc, SSB_CHIPCO_PMU_MAXRES_MSK,
~((1 << SSB_PMURES_4325_BBPLL_PWRSW_PU) |
(1 << SSB_PMURES_4325_HT_AVAIL)));
/* Adjust the BBPLL to 2 on all channels later. */
buffer_strength = 0x222222;
break;
default:
SSB_WARN_ON(1);
}
for (i = 1500; i; i--) {
tmp = chipco_read32(cc, SSB_CHIPCO_CLKCTLST);
if (!(tmp & SSB_CHIPCO_CLKCTLST_HAVEHT))
break;
udelay(10);
}
tmp = chipco_read32(cc, SSB_CHIPCO_CLKCTLST);
if (tmp & SSB_CHIPCO_CLKCTLST_HAVEHT)
ssb_emerg("Failed to turn the PLL off!\n");
/* Set p1div and p2div. */
pllctl = ssb_chipco_pll_read(cc, SSB_PMU1_PLLCTL0);
pllctl &= ~(SSB_PMU1_PLLCTL0_P1DIV | SSB_PMU1_PLLCTL0_P2DIV);
pllctl |= ((u32)e->p1div << SSB_PMU1_PLLCTL0_P1DIV_SHIFT) & SSB_PMU1_PLLCTL0_P1DIV;
pllctl |= ((u32)e->p2div << SSB_PMU1_PLLCTL0_P2DIV_SHIFT) & SSB_PMU1_PLLCTL0_P2DIV;
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL0, pllctl);
/* Set ndiv int and ndiv mode */
pllctl = ssb_chipco_pll_read(cc, SSB_PMU1_PLLCTL2);
pllctl &= ~(SSB_PMU1_PLLCTL2_NDIVINT | SSB_PMU1_PLLCTL2_NDIVMODE);
pllctl |= ((u32)e->ndiv_int << SSB_PMU1_PLLCTL2_NDIVINT_SHIFT) & SSB_PMU1_PLLCTL2_NDIVINT;
pllctl |= (1 << SSB_PMU1_PLLCTL2_NDIVMODE_SHIFT) & SSB_PMU1_PLLCTL2_NDIVMODE;
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL2, pllctl);
/* Set ndiv frac */
pllctl = ssb_chipco_pll_read(cc, SSB_PMU1_PLLCTL3);
pllctl &= ~SSB_PMU1_PLLCTL3_NDIVFRAC;
pllctl |= ((u32)e->ndiv_frac << SSB_PMU1_PLLCTL3_NDIVFRAC_SHIFT) & SSB_PMU1_PLLCTL3_NDIVFRAC;
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL3, pllctl);
/* Change the drive strength, if required. */
if (buffer_strength) {
pllctl = ssb_chipco_pll_read(cc, SSB_PMU1_PLLCTL5);
pllctl &= ~SSB_PMU1_PLLCTL5_CLKDRV;
pllctl |= (buffer_strength << SSB_PMU1_PLLCTL5_CLKDRV_SHIFT) & SSB_PMU1_PLLCTL5_CLKDRV;
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL5, pllctl);
}
/* Tune the crystalfreq and the divisor. */
pmuctl = chipco_read32(cc, SSB_CHIPCO_PMU_CTL);
pmuctl &= ~(SSB_CHIPCO_PMU_CTL_ILP_DIV | SSB_CHIPCO_PMU_CTL_XTALFREQ);
pmuctl |= ((((u32)e->freq + 127) / 128 - 1) << SSB_CHIPCO_PMU_CTL_ILP_DIV_SHIFT)
& SSB_CHIPCO_PMU_CTL_ILP_DIV;
pmuctl |= ((u32)e->xf << SSB_CHIPCO_PMU_CTL_XTALFREQ_SHIFT) & SSB_CHIPCO_PMU_CTL_XTALFREQ;
chipco_write32(cc, SSB_CHIPCO_PMU_CTL, pmuctl);
}
static void ssb_pmu_pll_init(struct ssb_chipcommon *cc)
{
struct ssb_bus *bus = cc->dev->bus;
u32 crystalfreq = 0; /* in kHz. 0 = keep default freq. */
if (bus->bustype == SSB_BUSTYPE_SSB) {
#ifdef CONFIG_BCM47XX
char buf[20];
if (bcm47xx_nvram_getenv("xtalfreq", buf, sizeof(buf)) >= 0)
crystalfreq = simple_strtoul(buf, NULL, 0);
#endif
}
switch (bus->chip_id) {
case 0x4312:
case 0x4325:
ssb_pmu1_pllinit_r0(cc, crystalfreq);
break;
case 0x4328:
ssb_pmu0_pllinit_r0(cc, crystalfreq);
break;
case 0x5354:
if (crystalfreq == 0)
crystalfreq = 25000;
ssb_pmu0_pllinit_r0(cc, crystalfreq);
break;
case 0x4322:
if (cc->pmu.rev == 2) {
chipco_write32(cc, SSB_CHIPCO_PLLCTL_ADDR, 0x0000000A);
chipco_write32(cc, SSB_CHIPCO_PLLCTL_DATA, 0x380005C0);
}
break;
case 43222:
break;
default:
ssb_err("ERROR: PLL init unknown for device %04X\n",
bus->chip_id);
}
}
struct pmu_res_updown_tab_entry {
u8 resource; /* The resource number */
u16 updown; /* The updown value */
};
enum pmu_res_depend_tab_task {
PMU_RES_DEP_SET = 1,
PMU_RES_DEP_ADD,
PMU_RES_DEP_REMOVE,
};
struct pmu_res_depend_tab_entry {
u8 resource; /* The resource number */
u8 task; /* SET | ADD | REMOVE */
u32 depend; /* The depend mask */
};
static const struct pmu_res_updown_tab_entry pmu_res_updown_tab_4328a0[] = {
{ .resource = SSB_PMURES_4328_EXT_SWITCHER_PWM, .updown = 0x0101, },
{ .resource = SSB_PMURES_4328_BB_SWITCHER_PWM, .updown = 0x1F01, },
{ .resource = SSB_PMURES_4328_BB_SWITCHER_BURST, .updown = 0x010F, },
{ .resource = SSB_PMURES_4328_BB_EXT_SWITCHER_BURST, .updown = 0x0101, },
{ .resource = SSB_PMURES_4328_ILP_REQUEST, .updown = 0x0202, },
{ .resource = SSB_PMURES_4328_RADIO_SWITCHER_PWM, .updown = 0x0F01, },
{ .resource = SSB_PMURES_4328_RADIO_SWITCHER_BURST, .updown = 0x0F01, },
{ .resource = SSB_PMURES_4328_ROM_SWITCH, .updown = 0x0101, },
{ .resource = SSB_PMURES_4328_PA_REF_LDO, .updown = 0x0F01, },
{ .resource = SSB_PMURES_4328_RADIO_LDO, .updown = 0x0F01, },
{ .resource = SSB_PMURES_4328_AFE_LDO, .updown = 0x0F01, },
{ .resource = SSB_PMURES_4328_PLL_LDO, .updown = 0x0F01, },
{ .resource = SSB_PMURES_4328_BG_FILTBYP, .updown = 0x0101, },
{ .resource = SSB_PMURES_4328_TX_FILTBYP, .updown = 0x0101, },
{ .resource = SSB_PMURES_4328_RX_FILTBYP, .updown = 0x0101, },
{ .resource = SSB_PMURES_4328_XTAL_PU, .updown = 0x0101, },
{ .resource = SSB_PMURES_4328_XTAL_EN, .updown = 0xA001, },
{ .resource = SSB_PMURES_4328_BB_PLL_FILTBYP, .updown = 0x0101, },
{ .resource = SSB_PMURES_4328_RF_PLL_FILTBYP, .updown = 0x0101, },
{ .resource = SSB_PMURES_4328_BB_PLL_PU, .updown = 0x0701, },
};
static const struct pmu_res_depend_tab_entry pmu_res_depend_tab_4328a0[] = {
{
/* Adjust ILP Request to avoid forcing EXT/BB into burst mode. */
.resource = SSB_PMURES_4328_ILP_REQUEST,
.task = PMU_RES_DEP_SET,
.depend = ((1 << SSB_PMURES_4328_EXT_SWITCHER_PWM) |
(1 << SSB_PMURES_4328_BB_SWITCHER_PWM)),
},
};
static const struct pmu_res_updown_tab_entry pmu_res_updown_tab_4325a0[] = {
{ .resource = SSB_PMURES_4325_XTAL_PU, .updown = 0x1501, },
};
static const struct pmu_res_depend_tab_entry pmu_res_depend_tab_4325a0[] = {
{
/* Adjust HT-Available dependencies. */
.resource = SSB_PMURES_4325_HT_AVAIL,
.task = PMU_RES_DEP_ADD,
.depend = ((1 << SSB_PMURES_4325_RX_PWRSW_PU) |
(1 << SSB_PMURES_4325_TX_PWRSW_PU) |
(1 << SSB_PMURES_4325_LOGEN_PWRSW_PU) |
(1 << SSB_PMURES_4325_AFE_PWRSW_PU)),
},
};
static void ssb_pmu_resources_init(struct ssb_chipcommon *cc)
{
struct ssb_bus *bus = cc->dev->bus;
u32 min_msk = 0, max_msk = 0;
unsigned int i;
const struct pmu_res_updown_tab_entry *updown_tab = NULL;
unsigned int updown_tab_size = 0;
const struct pmu_res_depend_tab_entry *depend_tab = NULL;
unsigned int depend_tab_size = 0;
switch (bus->chip_id) {
case 0x4312:
min_msk = 0xCBB;
break;
case 0x4322:
case 43222:
/* We keep the default settings:
* min_msk = 0xCBB
* max_msk = 0x7FFFF
*/
break;
case 0x4325:
/* Power OTP down later. */
min_msk = (1 << SSB_PMURES_4325_CBUCK_BURST) |
(1 << SSB_PMURES_4325_LNLDO2_PU);
if (chipco_read32(cc, SSB_CHIPCO_CHIPSTAT) &
SSB_CHIPCO_CHST_4325_PMUTOP_2B)
min_msk |= (1 << SSB_PMURES_4325_CLDO_CBUCK_BURST);
/* The PLL may turn on, if it decides so. */
max_msk = 0xFFFFF;
updown_tab = pmu_res_updown_tab_4325a0;
updown_tab_size = ARRAY_SIZE(pmu_res_updown_tab_4325a0);
depend_tab = pmu_res_depend_tab_4325a0;
depend_tab_size = ARRAY_SIZE(pmu_res_depend_tab_4325a0);
break;
case 0x4328:
min_msk = (1 << SSB_PMURES_4328_EXT_SWITCHER_PWM) |
(1 << SSB_PMURES_4328_BB_SWITCHER_PWM) |
(1 << SSB_PMURES_4328_XTAL_EN);
/* The PLL may turn on, if it decides so. */
max_msk = 0xFFFFF;
updown_tab = pmu_res_updown_tab_4328a0;
updown_tab_size = ARRAY_SIZE(pmu_res_updown_tab_4328a0);
depend_tab = pmu_res_depend_tab_4328a0;
depend_tab_size = ARRAY_SIZE(pmu_res_depend_tab_4328a0);
break;
case 0x5354:
/* The PLL may turn on, if it decides so. */
max_msk = 0xFFFFF;
break;
default:
ssb_err("ERROR: PMU resource config unknown for device %04X\n",
bus->chip_id);
}
if (updown_tab) {
for (i = 0; i < updown_tab_size; i++) {
chipco_write32(cc, SSB_CHIPCO_PMU_RES_TABSEL,
updown_tab[i].resource);
chipco_write32(cc, SSB_CHIPCO_PMU_RES_UPDNTM,
updown_tab[i].updown);
}
}
if (depend_tab) {
for (i = 0; i < depend_tab_size; i++) {
chipco_write32(cc, SSB_CHIPCO_PMU_RES_TABSEL,
depend_tab[i].resource);
switch (depend_tab[i].task) {
case PMU_RES_DEP_SET:
chipco_write32(cc, SSB_CHIPCO_PMU_RES_DEPMSK,
depend_tab[i].depend);
break;
case PMU_RES_DEP_ADD:
chipco_set32(cc, SSB_CHIPCO_PMU_RES_DEPMSK,
depend_tab[i].depend);
break;
case PMU_RES_DEP_REMOVE:
chipco_mask32(cc, SSB_CHIPCO_PMU_RES_DEPMSK,
~(depend_tab[i].depend));
break;
default:
SSB_WARN_ON(1);
}
}
}
/* Set the resource masks. */
if (min_msk)
chipco_write32(cc, SSB_CHIPCO_PMU_MINRES_MSK, min_msk);
if (max_msk)
chipco_write32(cc, SSB_CHIPCO_PMU_MAXRES_MSK, max_msk);
}
/* http://bcm-v4.sipsolutions.net/802.11/SSB/PmuInit */
void ssb_pmu_init(struct ssb_chipcommon *cc)
{
u32 pmucap;
if (!(cc->capabilities & SSB_CHIPCO_CAP_PMU))
return;
pmucap = chipco_read32(cc, SSB_CHIPCO_PMU_CAP);
cc->pmu.rev = (pmucap & SSB_CHIPCO_PMU_CAP_REVISION);
ssb_dbg("Found rev %u PMU (capabilities 0x%08X)\n",
cc->pmu.rev, pmucap);
if (cc->pmu.rev == 1)
chipco_mask32(cc, SSB_CHIPCO_PMU_CTL,
~SSB_CHIPCO_PMU_CTL_NOILPONW);
else
chipco_set32(cc, SSB_CHIPCO_PMU_CTL,
SSB_CHIPCO_PMU_CTL_NOILPONW);
ssb_pmu_pll_init(cc);
ssb_pmu_resources_init(cc);
}
void ssb_pmu_set_ldo_voltage(struct ssb_chipcommon *cc,
enum ssb_pmu_ldo_volt_id id, u32 voltage)
{
struct ssb_bus *bus = cc->dev->bus;
u32 addr, shift, mask;
switch (bus->chip_id) {
case 0x4328:
case 0x5354:
switch (id) {
case LDO_VOLT1:
addr = 2;
shift = 25;
mask = 0xF;
break;
case LDO_VOLT2:
addr = 3;
shift = 1;
mask = 0xF;
break;
case LDO_VOLT3:
addr = 3;
shift = 9;
mask = 0xF;
break;
case LDO_PAREF:
addr = 3;
shift = 17;
mask = 0x3F;
break;
default:
SSB_WARN_ON(1);
return;
}
break;
case 0x4312:
if (SSB_WARN_ON(id != LDO_PAREF))
return;
addr = 0;
shift = 21;
mask = 0x3F;
break;
default:
return;
}
ssb_chipco_regctl_maskset(cc, addr, ~(mask << shift),
(voltage & mask) << shift);
}
void ssb_pmu_set_ldo_paref(struct ssb_chipcommon *cc, bool on)
{
struct ssb_bus *bus = cc->dev->bus;
int ldo;
switch (bus->chip_id) {
case 0x4312:
ldo = SSB_PMURES_4312_PA_REF_LDO;
break;
case 0x4328:
ldo = SSB_PMURES_4328_PA_REF_LDO;
break;
case 0x5354:
ldo = SSB_PMURES_5354_PA_REF_LDO;
break;
default:
return;
}
if (on)
chipco_set32(cc, SSB_CHIPCO_PMU_MINRES_MSK, 1 << ldo);
else
chipco_mask32(cc, SSB_CHIPCO_PMU_MINRES_MSK, ~(1 << ldo));
chipco_read32(cc, SSB_CHIPCO_PMU_MINRES_MSK); //SPEC FIXME found via mmiotrace - dummy read?
}
EXPORT_SYMBOL(ssb_pmu_set_ldo_voltage);
EXPORT_SYMBOL(ssb_pmu_set_ldo_paref);
static u32 ssb_pmu_get_alp_clock_clk0(struct ssb_chipcommon *cc)
{
u32 crystalfreq;
const struct pmu0_plltab_entry *e = NULL;
crystalfreq = chipco_read32(cc, SSB_CHIPCO_PMU_CTL) &
SSB_CHIPCO_PMU_CTL_XTALFREQ >> SSB_CHIPCO_PMU_CTL_XTALFREQ_SHIFT;
e = pmu0_plltab_find_entry(crystalfreq);
BUG_ON(!e);
return e->freq * 1000;
}
u32 ssb_pmu_get_alp_clock(struct ssb_chipcommon *cc)
{
struct ssb_bus *bus = cc->dev->bus;
switch (bus->chip_id) {
case 0x5354:
ssb_pmu_get_alp_clock_clk0(cc);
default:
ssb_err("ERROR: PMU alp clock unknown for device %04X\n",
bus->chip_id);
return 0;
}
}
u32 ssb_pmu_get_cpu_clock(struct ssb_chipcommon *cc)
{
struct ssb_bus *bus = cc->dev->bus;
switch (bus->chip_id) {
case 0x5354:
/* 5354 chip uses a non programmable PLL of frequency 240MHz */
return 240000000;
default:
ssb_err("ERROR: PMU cpu clock unknown for device %04X\n",
bus->chip_id);
return 0;
}
}
u32 ssb_pmu_get_controlclock(struct ssb_chipcommon *cc)
{
struct ssb_bus *bus = cc->dev->bus;
switch (bus->chip_id) {
case 0x5354:
return 120000000;
default:
ssb_err("ERROR: PMU controlclock unknown for device %04X\n",
bus->chip_id);
return 0;
}
}
void ssb_pmu_spuravoid_pllupdate(struct ssb_chipcommon *cc, int spuravoid)
{
u32 pmu_ctl = 0;
switch (cc->dev->bus->chip_id) {
case 0x4322:
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL0, 0x11100070);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL1, 0x1014140a);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL5, 0x88888854);
if (spuravoid == 1)
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL2, 0x05201828);
else
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL2, 0x05001828);
pmu_ctl = SSB_CHIPCO_PMU_CTL_PLL_UPD;
break;
case 43222:
if (spuravoid == 1) {
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL0, 0x11500008);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL1, 0x0C000C06);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL2, 0x0F600a08);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL3, 0x00000000);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL4, 0x2001E920);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL5, 0x88888815);
} else {
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL0, 0x11100008);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL1, 0x0c000c06);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL2, 0x03000a08);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL3, 0x00000000);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL4, 0x200005c0);
ssb_chipco_pll_write(cc, SSB_PMU1_PLLCTL5, 0x88888855);
}
pmu_ctl = SSB_CHIPCO_PMU_CTL_PLL_UPD;
break;
default:
ssb_printk(KERN_ERR PFX
"Unknown spuravoidance settings for chip 0x%04X, not changing PLL\n",
cc->dev->bus->chip_id);
return;
}
chipco_set32(cc, SSB_CHIPCO_PMU_CTL, pmu_ctl);
}
EXPORT_SYMBOL_GPL(ssb_pmu_spuravoid_pllupdate);
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