static void
brcmf_sdio_ai_coredisable(struct brcmf_sdio_dev *sdiodev,
struct chip_info *ci, u16 coreid)
{
u8 idx;
u32 regdata;
idx = brcmf_sdio_chip_getinfidx(ci, coreid);
/* if core is already in reset, just return */
regdata = brcmf_sdio_regrl(sdiodev,
ci->c_inf[idx].wrapbase+BCMA_RESET_CTL,
NULL);
if ((regdata & BCMA_RESET_CTL_RESET) != 0)
return;
brcmf_sdio_regwl(sdiodev, ci->c_inf[idx].wrapbase+BCMA_IOCTL, 0, NULL);
regdata = brcmf_sdio_regrl(sdiodev, ci->c_inf[idx].wrapbase+BCMA_IOCTL,
NULL);
udelay(10);
brcmf_sdio_regwl(sdiodev, ci->c_inf[idx].wrapbase+BCMA_RESET_CTL,
BCMA_RESET_CTL_RESET, NULL);
udelay(1);
}
static void
brcmf_sdio_chip_buscoresetup(struct brcmf_sdio_dev *sdiodev,
struct chip_info *ci)
{
u32 base = ci->c_inf[0].base;
/* get chipcommon rev */
ci->c_inf[0].rev = ci->corerev(sdiodev, ci, ci->c_inf[0].id);
/* get chipcommon capabilites */
ci->c_inf[0].caps = brcmf_sdio_regrl(sdiodev,
CORE_CC_REG(base, capabilities),
NULL);
/* get pmu caps & rev */
if (ci->c_inf[0].caps & CC_CAP_PMU) {
ci->pmucaps =
brcmf_sdio_regrl(sdiodev,
CORE_CC_REG(base, pmucapabilities),
NULL);
ci->pmurev = ci->pmucaps & PCAP_REV_MASK;
}
ci->c_inf[1].rev = ci->corerev(sdiodev, ci, ci->c_inf[1].id);
brcmf_dbg(INFO, "ccrev=%d, pmurev=%d, buscore rev/type=%d/0x%x\n",
ci->c_inf[0].rev, ci->pmurev,
ci->c_inf[1].rev, ci->c_inf[1].id);
/*
* Make sure any on-chip ARM is off (in case strapping is wrong),
* or downloaded code was already running.
*/
ci->coredisable(sdiodev, ci, BCMA_CORE_ARM_CM3);
}
static void
brcmf_sdio_ai_resetcore(struct brcmf_sdio_dev *sdiodev,
struct chip_info *ci, u16 coreid)
{
u8 idx;
u32 regdata;
idx = brcmf_sdio_chip_getinfidx(ci, coreid);
/* must disable first to work for arbitrary current core state */
brcmf_sdio_ai_coredisable(sdiodev, ci, coreid);
/* now do initialization sequence */
brcmf_sdio_regwl(sdiodev, ci->c_inf[idx].wrapbase+BCMA_IOCTL,
BCMA_IOCTL_FGC | BCMA_IOCTL_CLK, NULL);
regdata = brcmf_sdio_regrl(sdiodev, ci->c_inf[idx].wrapbase+BCMA_IOCTL,
NULL);
brcmf_sdio_regwl(sdiodev, ci->c_inf[idx].wrapbase+BCMA_RESET_CTL,
0, NULL);
udelay(1);
brcmf_sdio_regwl(sdiodev, ci->c_inf[idx].wrapbase+BCMA_IOCTL,
BCMA_IOCTL_CLK, NULL);
regdata = brcmf_sdio_regrl(sdiodev, ci->c_inf[idx].wrapbase+BCMA_IOCTL,
NULL);
udelay(1);
}
void
brcmf_sdio_chip_drivestrengthinit(struct brcmf_sdio_dev *sdiodev,
struct chip_info *ci, u32 drivestrength)
{
struct sdiod_drive_str *str_tab = NULL;
u32 str_mask = 0;
u32 str_shift = 0;
char chn[8];
u32 base = ci->c_inf[0].base;
if (!(ci->c_inf[0].caps & CC_CAP_PMU))
return;
switch (SDIOD_DRVSTR_KEY(ci->chip, ci->pmurev)) {
case SDIOD_DRVSTR_KEY(BCM4330_CHIP_ID, 12):
str_tab = (struct sdiod_drive_str *)&sdiod_drvstr_tab1_1v8;
str_mask = 0x00003800;
str_shift = 11;
break;
default:
brcmf_dbg(ERROR, "No SDIO Drive strength init done for chip %s rev %d pmurev %d\n",
brcmf_sdio_chip_name(ci->chip, chn, 8),
ci->chiprev, ci->pmurev);
break;
}
if (str_tab != NULL) {
u32 drivestrength_sel = 0;
u32 cc_data_temp;
int i;
for (i = 0; str_tab[i].strength != 0; i++) {
if (drivestrength >= str_tab[i].strength) {
drivestrength_sel = str_tab[i].sel;
break;
}
}
brcmf_sdio_regwl(sdiodev, CORE_CC_REG(base, chipcontrol_addr),
1, NULL);
cc_data_temp =
brcmf_sdio_regrl(sdiodev,
CORE_CC_REG(base, chipcontrol_addr),
NULL);
cc_data_temp &= ~str_mask;
drivestrength_sel <<= str_shift;
cc_data_temp |= drivestrength_sel;
brcmf_sdio_regwl(sdiodev, CORE_CC_REG(base, chipcontrol_addr),
cc_data_temp, NULL);
brcmf_dbg(INFO, "SDIO: %dmA drive strength selected, set to 0x%08x\n",
drivestrength, cc_data_temp);
}
}
static bool
brcmf_sdio_ai_iscoreup(struct brcmf_sdio_dev *sdiodev,
struct chip_info *ci, u16 coreid)
{
u32 regdata;
u8 idx;
bool ret;
idx = brcmf_sdio_chip_getinfidx(ci, coreid);
regdata = brcmf_sdio_regrl(sdiodev, ci->c_inf[idx].wrapbase+BCMA_IOCTL,
NULL);
ret = (regdata & (BCMA_IOCTL_FGC | BCMA_IOCTL_CLK)) == BCMA_IOCTL_CLK;
regdata = brcmf_sdio_regrl(sdiodev,
ci->c_inf[idx].wrapbase+BCMA_RESET_CTL,
NULL);
ret = ret && ((regdata & BCMA_RESET_CTL_RESET) == 0);
return ret;
}
static u32
brcmf_sdio_sb_corerev(struct brcmf_sdio_dev *sdiodev,
struct chip_info *ci, u16 coreid)
{
u32 regdata;
u8 idx;
idx = brcmf_sdio_chip_getinfidx(ci, coreid);
regdata = brcmf_sdio_regrl(sdiodev,
CORE_SB(ci->c_inf[idx].base, sbidhigh),
NULL);
return SBCOREREV(regdata);
}
static bool
brcmf_sdio_sb_iscoreup(struct brcmf_sdio_dev *sdiodev,
struct chip_info *ci, u16 coreid)
{
u32 regdata;
u8 idx;
idx = brcmf_sdio_chip_getinfidx(ci, coreid);
regdata = brcmf_sdio_regrl(sdiodev,
CORE_SB(ci->c_inf[idx].base, sbtmstatelow),
NULL);
regdata &= (SSB_TMSLOW_RESET | SSB_TMSLOW_REJECT |
SSB_IMSTATE_REJECT | SSB_TMSLOW_CLOCK);
return (SSB_TMSLOW_CLOCK == regdata);
}
static int brcmf_sdioh_get_cisaddr(struct brcmf_sdio_dev *sdiodev, u32 regaddr)
{
/* read 24 bits and return valid 17 bit addr */
int i, ret;
u32 scratch, regdata;
__le32 scratch_le;
u8 *ptr = (u8 *)&scratch_le;
for (i = 0; i < 3; i++) {
regdata = brcmf_sdio_regrl(sdiodev, regaddr, &ret);
if (ret != 0)
brcmf_err("Can't read!\n");
*ptr++ = (u8) regdata;
regaddr++;
}
/* Only the lower 17-bits are valid */
scratch = le32_to_cpu(scratch_le);
scratch &= 0x0001FFFF;
return scratch;
}
static int brcmf_sdio_chip_recognition(struct brcmf_sdio_dev *sdiodev,
struct chip_info *ci, u32 regs)
{
u32 regdata;
/*
* Get CC core rev
* Chipid is assume to be at offset 0 from regs arg
* For different chiptypes or old sdio hosts w/o chipcommon,
* other ways of recognition should be added here.
*/
ci->c_inf[0].id = BCMA_CORE_CHIPCOMMON;
ci->c_inf[0].base = regs;
regdata = brcmf_sdio_regrl(sdiodev,
CORE_CC_REG(ci->c_inf[0].base, chipid),
NULL);
ci->chip = regdata & CID_ID_MASK;
ci->chiprev = (regdata & CID_REV_MASK) >> CID_REV_SHIFT;
ci->socitype = (regdata & CID_TYPE_MASK) >> CID_TYPE_SHIFT;
brcmf_dbg(INFO, "chipid=0x%x chiprev=%d\n", ci->chip, ci->chiprev);
/* Address of cores for new chips should be added here */
switch (ci->chip) {
case BCM4329_CHIP_ID:
ci->c_inf[1].id = BCMA_CORE_SDIO_DEV;
ci->c_inf[1].base = BCM4329_CORE_BUS_BASE;
ci->c_inf[2].id = BCMA_CORE_INTERNAL_MEM;
ci->c_inf[2].base = BCM4329_CORE_SOCRAM_BASE;
ci->c_inf[3].id = BCMA_CORE_ARM_CM3;
ci->c_inf[3].base = BCM4329_CORE_ARM_BASE;
ci->ramsize = BCM4329_RAMSIZE;
break;
case BCM4330_CHIP_ID:
ci->c_inf[0].wrapbase = 0x18100000;
ci->c_inf[0].cib = 0x27004211;
ci->c_inf[1].id = BCMA_CORE_SDIO_DEV;
ci->c_inf[1].base = 0x18002000;
ci->c_inf[1].wrapbase = 0x18102000;
ci->c_inf[1].cib = 0x07004211;
ci->c_inf[2].id = BCMA_CORE_INTERNAL_MEM;
ci->c_inf[2].base = 0x18004000;
ci->c_inf[2].wrapbase = 0x18104000;
ci->c_inf[2].cib = 0x0d080401;
ci->c_inf[3].id = BCMA_CORE_ARM_CM3;
ci->c_inf[3].base = 0x18003000;
ci->c_inf[3].wrapbase = 0x18103000;
ci->c_inf[3].cib = 0x03004211;
ci->ramsize = 0x48000;
break;
case BCM4334_CHIP_ID:
ci->c_inf[0].wrapbase = 0x18100000;
ci->c_inf[0].cib = 0x29004211;
ci->c_inf[1].id = BCMA_CORE_SDIO_DEV;
ci->c_inf[1].base = 0x18002000;
ci->c_inf[1].wrapbase = 0x18102000;
ci->c_inf[1].cib = 0x0d004211;
ci->c_inf[2].id = BCMA_CORE_INTERNAL_MEM;
ci->c_inf[2].base = 0x18004000;
ci->c_inf[2].wrapbase = 0x18104000;
ci->c_inf[2].cib = 0x13080401;
ci->c_inf[3].id = BCMA_CORE_ARM_CM3;
ci->c_inf[3].base = 0x18003000;
ci->c_inf[3].wrapbase = 0x18103000;
ci->c_inf[3].cib = 0x07004211;
ci->ramsize = 0x80000;
break;
default:
brcmf_dbg(ERROR, "chipid 0x%x is not supported\n", ci->chip);
return -ENODEV;
}
switch (ci->socitype) {
case SOCI_SB:
ci->iscoreup = brcmf_sdio_sb_iscoreup;
ci->corerev = brcmf_sdio_sb_corerev;
ci->coredisable = brcmf_sdio_sb_coredisable;
ci->resetcore = brcmf_sdio_sb_resetcore;
break;
case SOCI_AI:
ci->iscoreup = brcmf_sdio_ai_iscoreup;
ci->corerev = brcmf_sdio_ai_corerev;
ci->coredisable = brcmf_sdio_ai_coredisable;
ci->resetcore = brcmf_sdio_ai_resetcore;
break;
default:
brcmf_dbg(ERROR, "socitype %u not supported\n", ci->socitype);
return -ENODEV;
}
return 0;
}
static void
brcmf_sdio_sb_resetcore(struct brcmf_sdio_dev *sdiodev,
struct chip_info *ci, u16 coreid)
{
u32 regdata;
u8 idx;
idx = brcmf_sdio_chip_getinfidx(ci, coreid);
/*
* Must do the disable sequence first to work for
* arbitrary current core state.
*/
brcmf_sdio_sb_coredisable(sdiodev, ci, coreid);
/*
* Now do the initialization sequence.
* set reset while enabling the clock and
* forcing them on throughout the core
*/
brcmf_sdio_regwl(sdiodev,
CORE_SB(ci->c_inf[idx].base, sbtmstatelow),
SSB_TMSLOW_FGC | SSB_TMSLOW_CLOCK | SSB_TMSLOW_RESET,
NULL);
regdata = brcmf_sdio_regrl(sdiodev,
CORE_SB(ci->c_inf[idx].base, sbtmstatelow),
NULL);
udelay(1);
/* clear any serror */
regdata = brcmf_sdio_regrl(sdiodev,
CORE_SB(ci->c_inf[idx].base, sbtmstatehigh),
NULL);
if (regdata & SSB_TMSHIGH_SERR)
brcmf_sdio_regwl(sdiodev,
CORE_SB(ci->c_inf[idx].base, sbtmstatehigh),
0, NULL);
regdata = brcmf_sdio_regrl(sdiodev,
CORE_SB(ci->c_inf[idx].base, sbimstate),
NULL);
if (regdata & (SSB_IMSTATE_IBE | SSB_IMSTATE_TO))
brcmf_sdio_regwl(sdiodev,
CORE_SB(ci->c_inf[idx].base, sbimstate),
regdata & ~(SSB_IMSTATE_IBE | SSB_IMSTATE_TO),
NULL);
/* clear reset and allow it to propagate throughout the core */
brcmf_sdio_regwl(sdiodev, CORE_SB(ci->c_inf[idx].base, sbtmstatelow),
SSB_TMSLOW_FGC | SSB_TMSLOW_CLOCK, NULL);
regdata = brcmf_sdio_regrl(sdiodev,
CORE_SB(ci->c_inf[idx].base, sbtmstatelow),
NULL);
udelay(1);
/* leave clock enabled */
brcmf_sdio_regwl(sdiodev, CORE_SB(ci->c_inf[idx].base, sbtmstatelow),
SSB_TMSLOW_CLOCK, NULL);
regdata = brcmf_sdio_regrl(sdiodev,
CORE_SB(ci->c_inf[idx].base, sbtmstatelow),
NULL);
udelay(1);
}
static void
brcmf_sdio_sb_coredisable(struct brcmf_sdio_dev *sdiodev,
struct chip_info *ci, u16 coreid)
{
u32 regdata, base;
u8 idx;
idx = brcmf_sdio_chip_getinfidx(ci, coreid);
base = ci->c_inf[idx].base;
regdata = brcmf_sdio_regrl(sdiodev, CORE_SB(base, sbtmstatelow), NULL);
if (regdata & SSB_TMSLOW_RESET)
return;
regdata = brcmf_sdio_regrl(sdiodev, CORE_SB(base, sbtmstatelow), NULL);
if ((regdata & SSB_TMSLOW_CLOCK) != 0) {
/*
* set target reject and spin until busy is clear
* (preserve core-specific bits)
*/
regdata = brcmf_sdio_regrl(sdiodev, CORE_SB(base, sbtmstatelow),
NULL);
brcmf_sdio_regwl(sdiodev, CORE_SB(base, sbtmstatelow),
regdata | SSB_TMSLOW_REJECT, NULL);
regdata = brcmf_sdio_regrl(sdiodev, CORE_SB(base, sbtmstatelow),
NULL);
udelay(1);
SPINWAIT((brcmf_sdio_regrl(sdiodev,
CORE_SB(base, sbtmstatehigh),
NULL) &
SSB_TMSHIGH_BUSY), 100000);
regdata = brcmf_sdio_regrl(sdiodev,
CORE_SB(base, sbtmstatehigh),
NULL);
if (regdata & SSB_TMSHIGH_BUSY)
brcmf_dbg(ERROR, "core state still busy\n");
regdata = brcmf_sdio_regrl(sdiodev, CORE_SB(base, sbidlow),
NULL);
if (regdata & SSB_IDLOW_INITIATOR) {
regdata = brcmf_sdio_regrl(sdiodev,
CORE_SB(base, sbimstate),
NULL);
regdata |= SSB_IMSTATE_REJECT;
brcmf_sdio_regwl(sdiodev, CORE_SB(base, sbimstate),
regdata, NULL);
regdata = brcmf_sdio_regrl(sdiodev,
CORE_SB(base, sbimstate),
NULL);
udelay(1);
SPINWAIT((brcmf_sdio_regrl(sdiodev,
CORE_SB(base, sbimstate),
NULL) &
SSB_IMSTATE_BUSY), 100000);
}
/* set reset and reject while enabling the clocks */
regdata = SSB_TMSLOW_FGC | SSB_TMSLOW_CLOCK |
SSB_TMSLOW_REJECT | SSB_TMSLOW_RESET;
brcmf_sdio_regwl(sdiodev, CORE_SB(base, sbtmstatelow),
regdata, NULL);
regdata = brcmf_sdio_regrl(sdiodev, CORE_SB(base, sbtmstatelow),
NULL);
udelay(10);
/* clear the initiator reject bit */
regdata = brcmf_sdio_regrl(sdiodev, CORE_SB(base, sbidlow),
NULL);
if (regdata & SSB_IDLOW_INITIATOR) {
regdata = brcmf_sdio_regrl(sdiodev,
CORE_SB(base, sbimstate),
NULL);
regdata &= ~SSB_IMSTATE_REJECT;
brcmf_sdio_regwl(sdiodev, CORE_SB(base, sbimstate),
regdata, NULL);
}
}
/* leave reset and reject asserted */
brcmf_sdio_regwl(sdiodev, CORE_SB(base, sbtmstatelow),
(SSB_TMSLOW_REJECT | SSB_TMSLOW_RESET), NULL);
udelay(1);
}
