static void mxs_mem_setup_cpu_and_hbus(void)
{
struct mxs_clkctrl_regs *clkctrl_regs =
(struct mxs_clkctrl_regs *)MXS_CLKCTRL_BASE;
/* Set fractional divider for ref_cpu to 480 * 18 / 19 = 454MHz
* and ungate CPU clock */
writeb(19 & CLKCTRL_FRAC_FRAC_MASK,
(uint8_t *)&clkctrl_regs->hw_clkctrl_frac0[CLKCTRL_FRAC0_CPU]);
/* Set CPU bypass */
writel(CLKCTRL_CLKSEQ_BYPASS_CPU,
&clkctrl_regs->hw_clkctrl_clkseq_set);
/* HBUS = 151MHz */
writel(CLKCTRL_HBUS_DIV_MASK, &clkctrl_regs->hw_clkctrl_hbus_set);
writel(((~3) << CLKCTRL_HBUS_DIV_OFFSET) & CLKCTRL_HBUS_DIV_MASK,
&clkctrl_regs->hw_clkctrl_hbus_clr);
early_delay(10000);
/* CPU clock divider = 1 */
clrsetbits_le32(&clkctrl_regs->hw_clkctrl_cpu,
CLKCTRL_CPU_DIV_CPU_MASK, 1);
/* Disable CPU bypass */
writel(CLKCTRL_CLKSEQ_BYPASS_CPU,
&clkctrl_regs->hw_clkctrl_clkseq_clr);
early_delay(15000);
}
static void mx23_mem_init(void)
{
/*
* Reset/ungate the EMI block. This is essential, otherwise the system
* suffers from memory instability. This thing is mx23 specific and is
* no longer present on mx28.
*/
mxs_reset_block((struct mxs_register_32 *)MXS_EMI_BASE);
mx23_mem_setup_vddmem();
/*
* Configure the DRAM registers
*/
/* Clear START and SREFRESH bit from DRAM_CTL8 */
clrbits_le32(MXS_DRAM_BASE + 0x20, (1 << 16) | (1 << 8));
initialize_dram_values();
/* Set START bit in DRAM_CTL8 */
setbits_le32(MXS_DRAM_BASE + 0x20, 1 << 16);
clrbits_le32(MXS_DRAM_BASE + 0x40, 1 << 17);
early_delay(20000);
/* Adjust EMI port priority. */
clrsetbits_le32(0x80020000, 0x1f << 16, 0x2);
early_delay(20000);
setbits_le32(MXS_DRAM_BASE + 0x40, 1 << 19);
setbits_le32(MXS_DRAM_BASE + 0x40, 1 << 11);
}
void mx28_mem_init_clock(void)
{
struct mx28_clkctrl_regs *clkctrl_regs =
(struct mx28_clkctrl_regs *)MXS_CLKCTRL_BASE;
/* Gate EMI clock */
writeb(CLKCTRL_FRAC_CLKGATE,
&clkctrl_regs->hw_clkctrl_frac0_set[CLKCTRL_FRAC0_EMI]);
/* Set fractional divider for ref_emi to 480 * 18 / 21 = 411MHz */
writeb(CLKCTRL_FRAC_CLKGATE | (21 & CLKCTRL_FRAC_FRAC_MASK),
&clkctrl_regs->hw_clkctrl_frac0[CLKCTRL_FRAC0_EMI]);
/* Ungate EMI clock */
writeb(CLKCTRL_FRAC_CLKGATE,
&clkctrl_regs->hw_clkctrl_frac0_clr[CLKCTRL_FRAC0_EMI]);
early_delay(11000);
/* Set EMI clock divider for EMI clock to 411 / 2 = 205MHz */
writel((2 << CLKCTRL_EMI_DIV_EMI_OFFSET) |
(1 << CLKCTRL_EMI_DIV_XTAL_OFFSET),
&clkctrl_regs->hw_clkctrl_emi);
/* Unbypass EMI */
writel(CLKCTRL_CLKSEQ_BYPASS_EMI,
&clkctrl_regs->hw_clkctrl_clkseq_clr);
early_delay(10000);
}
static void mxs_power_enable_4p2(void)
{
struct mxs_power_regs *power_regs =
(struct mxs_power_regs *)MXS_POWER_BASE;
uint32_t vdddctrl, vddactrl, vddioctrl;
uint32_t tmp;
vdddctrl = readl(&power_regs->hw_power_vdddctrl);
vddactrl = readl(&power_regs->hw_power_vddactrl);
vddioctrl = readl(&power_regs->hw_power_vddioctrl);
setbits_le32(&power_regs->hw_power_vdddctrl,
POWER_VDDDCTRL_DISABLE_FET | POWER_VDDDCTRL_ENABLE_LINREG |
POWER_VDDDCTRL_PWDN_BRNOUT);
setbits_le32(&power_regs->hw_power_vddactrl,
POWER_VDDACTRL_DISABLE_FET | POWER_VDDACTRL_ENABLE_LINREG |
POWER_VDDACTRL_PWDN_BRNOUT);
setbits_le32(&power_regs->hw_power_vddioctrl,
POWER_VDDIOCTRL_DISABLE_FET | POWER_VDDIOCTRL_PWDN_BRNOUT);
mxs_power_init_4p2_params();
mxs_power_init_4p2_regulator();
/* Shutdown battery (none present) */
if (!mxs_is_batt_ready()) {
clrbits_le32(&power_regs->hw_power_dcdc4p2,
POWER_DCDC4P2_BO_MASK);
writel(POWER_CTRL_DCDC4P2_BO_IRQ,
&power_regs->hw_power_ctrl_clr);
writel(POWER_CTRL_ENIRQ_DCDC4P2_BO,
&power_regs->hw_power_ctrl_clr);
}
mxs_power_init_dcdc_4p2_source();
writel(vdddctrl, &power_regs->hw_power_vdddctrl);
early_delay(20);
writel(vddactrl, &power_regs->hw_power_vddactrl);
early_delay(20);
writel(vddioctrl, &power_regs->hw_power_vddioctrl);
/*
* Check if FET is enabled on either powerout and if so,
* disable load.
*/
tmp = 0;
tmp |= !(readl(&power_regs->hw_power_vdddctrl) &
POWER_VDDDCTRL_DISABLE_FET);
tmp |= !(readl(&power_regs->hw_power_vddactrl) &
POWER_VDDACTRL_DISABLE_FET);
tmp |= !(readl(&power_regs->hw_power_vddioctrl) &
POWER_VDDIOCTRL_DISABLE_FET);
if (tmp)
writel(POWER_CHARGE_ENABLE_LOAD,
&power_regs->hw_power_charge_clr);
}
static void mx23_mem_setup_vddmem(void)
{
struct mxs_power_regs *power_regs =
(struct mxs_power_regs *)MXS_POWER_BASE;
/* We must wait before and after disabling the current limiter! */
early_delay(10000);
clrbits_le32(&power_regs->hw_power_vddmemctrl,
POWER_VDDMEMCTRL_ENABLE_ILIMIT);
early_delay(10000);
}
void mx28_mem_init(void)
{
struct mx28_clkctrl_regs *clkctrl_regs =
(struct mx28_clkctrl_regs *)MXS_CLKCTRL_BASE;
struct mx28_pinctrl_regs *pinctrl_regs =
(struct mx28_pinctrl_regs *)MXS_PINCTRL_BASE;
/* Set DDR2 mode */
writel(PINCTRL_EMI_DS_CTRL_DDR_MODE_DDR2,
&pinctrl_regs->hw_pinctrl_emi_ds_ctrl_set);
/* Power up PLL0 */
writel(CLKCTRL_PLL0CTRL0_POWER,
&clkctrl_regs->hw_clkctrl_pll0ctrl0_set);
early_delay(11000);
mx28_mem_init_clock();
mx28_mem_setup_vdda();
/*
* Configure the DRAM registers
*/
/* Clear START bit from DRAM_CTL16 */
clrbits_le32(MXS_DRAM_BASE + 0x40, 1);
init_m28_200mhz_ddr2();
/* Clear SREFRESH bit from DRAM_CTL17 */
clrbits_le32(MXS_DRAM_BASE + 0x44, 1);
/* Set START bit in DRAM_CTL16 */
setbits_le32(MXS_DRAM_BASE + 0x40, 1);
/* Wait for bit 20 (DRAM init complete) in DRAM_CTL58 */
while (!(readl(MXS_DRAM_BASE + 0xe8) & (1 << 20)))
;
mx28_mem_setup_vddd();
early_delay(10000);
mx28_mem_setup_cpu_and_hbus();
mx28_mem_get_size();
}
/**
* mxs_src_power_init() - Preconfigure the power block
*
* This function configures reasonable values for the DC-DC control loop
* and battery monitor.
*/
static void mxs_src_power_init(void)
{
struct mxs_power_regs *power_regs =
(struct mxs_power_regs *)MXS_POWER_BASE;
debug("SPL: Pre-Configuring power block\n");
/* Improve efficieny and reduce transient ripple */
writel(POWER_LOOPCTRL_TOGGLE_DIF | POWER_LOOPCTRL_EN_CM_HYST |
POWER_LOOPCTRL_EN_DF_HYST, &power_regs->hw_power_loopctrl_set);
clrsetbits_le32(&power_regs->hw_power_dclimits,
POWER_DCLIMITS_POSLIMIT_BUCK_MASK,
0x30 << POWER_DCLIMITS_POSLIMIT_BUCK_OFFSET);
setbits_le32(&power_regs->hw_power_battmonitor,
POWER_BATTMONITOR_EN_BATADJ);
/* Increase the RCSCALE level for quick DCDC response to dynamic load */
clrsetbits_le32(&power_regs->hw_power_loopctrl,
POWER_LOOPCTRL_EN_RCSCALE_MASK,
POWER_LOOPCTRL_RCSCALE_THRESH |
POWER_LOOPCTRL_EN_RCSCALE_8X);
clrsetbits_le32(&power_regs->hw_power_minpwr,
POWER_MINPWR_HALFFETS, POWER_MINPWR_DOUBLE_FETS);
/* 5V to battery handoff ... FIXME */
setbits_le32(&power_regs->hw_power_5vctrl, POWER_5VCTRL_DCDC_XFER);
early_delay(30);
clrbits_le32(&power_regs->hw_power_5vctrl, POWER_5VCTRL_DCDC_XFER);
}
/**
* mxs_power_clock2pll() - Switch CPU core clock source to PLL
*
* This function switches the CPU core clock from 24MHz XTAL oscilator
* to PLL. This can only be called once the PLL has re-locked and once
* the PLL is stable after reconfiguration.
*/
static void mxs_power_clock2pll(void)
{
struct mxs_clkctrl_regs *clkctrl_regs =
(struct mxs_clkctrl_regs *)MXS_CLKCTRL_BASE;
debug("SPL: Switching CPU core clock source to PLL\n");
/*
* TODO: Are we really? It looks like we turn on PLL0, but we then
* set the CLKCTRL_CLKSEQ_BYPASS_CPU bit of the (which was already
* set by mxs_power_clock2xtal()). Clearing this bit here seems to
* introduce some instability (causing the CPU core to hang). Maybe
* we aren't giving PLL0 enough time to stabilise?
*/
setbits_le32(&clkctrl_regs->hw_clkctrl_pll0ctrl0,
CLKCTRL_PLL0CTRL0_POWER);
early_delay(100);
/*
* TODO: Should the PLL0 FORCE_LOCK bit be set here followed be a
* wait on the PLL0 LOCK bit?
*/
setbits_le32(&clkctrl_regs->hw_clkctrl_clkseq,
CLKCTRL_CLKSEQ_BYPASS_CPU);
}
/**
* mxs_5v_boot() - Configure the power block to boot from 5V input
*
* This function handles configuration of the power block when supplied by
* a 5V input.
*/
static void mxs_5v_boot(void)
{
struct mxs_power_regs *power_regs =
(struct mxs_power_regs *)MXS_POWER_BASE;
debug("SPL: Configuring power block to boot from 5V input\n");
/*
* NOTE: In original IMX-Bootlets, this also checks for VBUSVALID,
* but their implementation always returns 1 so we omit it here.
*/
if (readl(&power_regs->hw_power_sts) & POWER_STS_VDD5V_GT_VDDIO) {
debug("SPL: 5V VDD good\n");
mxs_boot_valid_5v();
return;
}
early_delay(1000);
if (readl(&power_regs->hw_power_sts) & POWER_STS_VDD5V_GT_VDDIO) {
debug("SPL: 5V VDD good (after delay)\n");
mxs_boot_valid_5v();
return;
}
debug("SPL: 5V VDD not good\n");
mxs_handle_5v_conflict();
}
void mx28_power_init(void)
{
struct mx28_power_regs *power_regs =
(struct mx28_power_regs *)MXS_POWER_BASE;
mx28_power_clock2xtal();
mx28_power_clear_auto_restart();
mx28_power_set_linreg();
mx28_power_setup_5v_detect();
mx28_power_configure_power_source();
mx28_enable_output_rail_protection();
mx28_power_set_vddio(3300, 3150);
mx28_power_set_vddd(1350, 1200);
writel(POWER_CTRL_VDDD_BO_IRQ | POWER_CTRL_VDDA_BO_IRQ |
POWER_CTRL_VDDIO_BO_IRQ | POWER_CTRL_VDD5V_DROOP_IRQ |
POWER_CTRL_VBUS_VALID_IRQ | POWER_CTRL_BATT_BO_IRQ |
POWER_CTRL_DCDC4P2_BO_IRQ, &power_regs->hw_power_ctrl_clr);
writel(POWER_5VCTRL_PWDN_5VBRNOUT, &power_regs->hw_power_5vctrl_set);
early_delay(1000);
}
void mxs_mem_init(void)
{
early_delay(11000);
mxs_mem_init_clock();
mxs_mem_setup_vdda();
#if defined(CONFIG_MX23)
mx23_mem_init();
#elif defined(CONFIG_MX28)
mx28_mem_init();
#endif
early_delay(10000);
mxs_mem_setup_cpu_and_hbus();
}
static void mxs_power_clock2pll(void)
{
struct mxs_clkctrl_regs *clkctrl_regs =
(struct mxs_clkctrl_regs *)MXS_CLKCTRL_BASE;
setbits_le32(&clkctrl_regs->hw_clkctrl_pll0ctrl0,
CLKCTRL_PLL0CTRL0_POWER);
early_delay(100);
setbits_le32(&clkctrl_regs->hw_clkctrl_clkseq,
CLKCTRL_CLKSEQ_BYPASS_CPU);
}
void mx28_power_clock2pll(void)
{
struct mx28_clkctrl_regs *clkctrl_regs =
(struct mx28_clkctrl_regs *)MXS_CLKCTRL_BASE;
writel(CLKCTRL_PLL0CTRL0_POWER,
&clkctrl_regs->hw_clkctrl_pll0ctrl0_set);
early_delay(100);
writel(CLKCTRL_CLKSEQ_BYPASS_CPU,
&clkctrl_regs->hw_clkctrl_clkseq_clr);
}
static void mxs_mem_init_clock(void)
{
struct mxs_clkctrl_regs *clkctrl_regs =
(struct mxs_clkctrl_regs *)MXS_CLKCTRL_BASE;
#if defined(CONFIG_MX23)
/* Fractional divider for ref_emi is 33 ; 480 * 18 / 33 = 266MHz */
const unsigned char divider = 33;
#elif defined(CONFIG_MX28)
/* Fractional divider for ref_emi is 21 ; 480 * 18 / 21 = 411MHz */
const unsigned char divider = 21;
#endif
debug("SPL: Initialising FRAC0\n");
/* Gate EMI clock */
writeb(CLKCTRL_FRAC_CLKGATE,
&clkctrl_regs->hw_clkctrl_frac0_set[CLKCTRL_FRAC0_EMI]);
/* Set fractional divider for ref_emi */
writeb(CLKCTRL_FRAC_CLKGATE | (divider & CLKCTRL_FRAC_FRAC_MASK),
&clkctrl_regs->hw_clkctrl_frac0[CLKCTRL_FRAC0_EMI]);
/* Ungate EMI clock */
writeb(CLKCTRL_FRAC_CLKGATE,
&clkctrl_regs->hw_clkctrl_frac0_clr[CLKCTRL_FRAC0_EMI]);
early_delay(11000);
/* Set EMI clock divider for EMI clock to 411 / 2 = 205MHz */
writel((2 << CLKCTRL_EMI_DIV_EMI_OFFSET) |
(1 << CLKCTRL_EMI_DIV_XTAL_OFFSET),
&clkctrl_regs->hw_clkctrl_emi);
/* Unbypass EMI */
writel(CLKCTRL_CLKSEQ_BYPASS_EMI,
&clkctrl_regs->hw_clkctrl_clkseq_clr);
early_delay(10000);
debug("SPL: FRAC0 Initialised\n");
}
/**
* mxs_batt_boot() - Configure the power block to boot from battery input
*
* This function configures the power block to boot from the battery voltage
* supply.
*/
static void mxs_batt_boot(void)
{
struct mxs_power_regs *power_regs =
(struct mxs_power_regs *)MXS_POWER_BASE;
debug("SPL: Configuring power block to boot from battery\n");
clrbits_le32(&power_regs->hw_power_5vctrl, POWER_5VCTRL_PWDN_5VBRNOUT);
clrbits_le32(&power_regs->hw_power_5vctrl, POWER_5VCTRL_ENABLE_DCDC);
clrbits_le32(&power_regs->hw_power_dcdc4p2,
POWER_DCDC4P2_ENABLE_DCDC | POWER_DCDC4P2_ENABLE_4P2);
writel(POWER_CHARGE_ENABLE_LOAD, &power_regs->hw_power_charge_clr);
/* 5V to battery handoff. */
setbits_le32(&power_regs->hw_power_5vctrl, POWER_5VCTRL_DCDC_XFER);
early_delay(30);
clrbits_le32(&power_regs->hw_power_5vctrl, POWER_5VCTRL_DCDC_XFER);
writel(POWER_CTRL_ENIRQ_DCDC4P2_BO, &power_regs->hw_power_ctrl_clr);
clrsetbits_le32(&power_regs->hw_power_minpwr,
POWER_MINPWR_HALFFETS, POWER_MINPWR_DOUBLE_FETS);
mxs_power_set_linreg();
clrbits_le32(&power_regs->hw_power_vdddctrl,
POWER_VDDDCTRL_DISABLE_FET | POWER_VDDDCTRL_ENABLE_LINREG);
clrbits_le32(&power_regs->hw_power_vddactrl,
POWER_VDDACTRL_DISABLE_FET | POWER_VDDACTRL_ENABLE_LINREG);
clrbits_le32(&power_regs->hw_power_vddioctrl,
POWER_VDDIOCTRL_DISABLE_FET);
setbits_le32(&power_regs->hw_power_5vctrl,
POWER_5VCTRL_PWD_CHARGE_4P2_MASK);
setbits_le32(&power_regs->hw_power_5vctrl,
POWER_5VCTRL_ENABLE_DCDC);
clrsetbits_le32(&power_regs->hw_power_5vctrl,
POWER_5VCTRL_CHARGE_4P2_ILIMIT_MASK,
0x8 << POWER_5VCTRL_CHARGE_4P2_ILIMIT_OFFSET);
mxs_power_enable_4p2();
}
int mx28_is_batt_good(void)
{
struct mx28_power_regs *power_regs =
(struct mx28_power_regs *)MXS_POWER_BASE;
uint32_t volt;
volt = readl(&power_regs->hw_power_battmonitor);
volt &= POWER_BATTMONITOR_BATT_VAL_MASK;
volt >>= POWER_BATTMONITOR_BATT_VAL_OFFSET;
volt *= 8;
if ((volt >= 2400) && (volt <= 4300))
return 1;
clrsetbits_le32(&power_regs->hw_power_5vctrl,
POWER_5VCTRL_CHARGE_4P2_ILIMIT_MASK,
0x3 << POWER_5VCTRL_CHARGE_4P2_ILIMIT_OFFSET);
writel(POWER_5VCTRL_PWD_CHARGE_4P2_MASK,
&power_regs->hw_power_5vctrl_clr);
clrsetbits_le32(&power_regs->hw_power_charge,
POWER_CHARGE_STOP_ILIMIT_MASK | POWER_CHARGE_BATTCHRG_I_MASK,
POWER_CHARGE_STOP_ILIMIT_10MA | 0x3);
writel(POWER_CHARGE_PWD_BATTCHRG, &power_regs->hw_power_charge_clr);
writel(POWER_5VCTRL_PWD_CHARGE_4P2_MASK,
&power_regs->hw_power_5vctrl_clr);
early_delay(500000);
volt = readl(&power_regs->hw_power_battmonitor);
volt &= POWER_BATTMONITOR_BATT_VAL_MASK;
volt >>= POWER_BATTMONITOR_BATT_VAL_OFFSET;
volt *= 8;
if (volt >= 3500)
return 0;
if (volt >= 2400)
return 1;
writel(POWER_CHARGE_STOP_ILIMIT_MASK | POWER_CHARGE_BATTCHRG_I_MASK,
&power_regs->hw_power_charge_clr);
writel(POWER_CHARGE_PWD_BATTCHRG, &power_regs->hw_power_charge_set);
return 0;
}
static void mx23_mem_setup_vddmem(void)
{
struct mxs_power_regs *power_regs =
(struct mxs_power_regs *)MXS_POWER_BASE;
writel((0x10 << POWER_VDDMEMCTRL_TRG_OFFSET) |
POWER_VDDMEMCTRL_ENABLE_ILIMIT |
POWER_VDDMEMCTRL_ENABLE_LINREG |
POWER_VDDMEMCTRL_PULLDOWN_ACTIVE,
&power_regs->hw_power_vddmemctrl);
early_delay(10000);
writel((0x10 << POWER_VDDMEMCTRL_TRG_OFFSET) |
POWER_VDDMEMCTRL_ENABLE_LINREG,
&power_regs->hw_power_vddmemctrl);
}
/**
* mxs_is_batt_good() - Test if battery is operational at all
*
* This function starts recharging the battery and tests if the input current
* provided by the 5V input recharging the battery is also sufficient to power
* the DC-DC converter.
*/
static int mxs_is_batt_good(void)
{
struct mxs_power_regs *power_regs =
(struct mxs_power_regs *)MXS_POWER_BASE;
uint32_t volt = mxs_get_batt_volt();
if ((volt >= 2400) && (volt <= 4300)) {
debug("SPL: Battery is good\n");
return 1;
}
clrsetbits_le32(&power_regs->hw_power_5vctrl,
POWER_5VCTRL_CHARGE_4P2_ILIMIT_MASK,
0x3 << POWER_5VCTRL_CHARGE_4P2_ILIMIT_OFFSET);
writel(POWER_5VCTRL_PWD_CHARGE_4P2_MASK,
&power_regs->hw_power_5vctrl_clr);
clrsetbits_le32(&power_regs->hw_power_charge,
POWER_CHARGE_STOP_ILIMIT_MASK | POWER_CHARGE_BATTCHRG_I_MASK,
POWER_CHARGE_STOP_ILIMIT_10MA | 0x3);
writel(POWER_CHARGE_PWD_BATTCHRG, &power_regs->hw_power_charge_clr);
writel(POWER_5VCTRL_PWD_CHARGE_4P2_MASK,
&power_regs->hw_power_5vctrl_clr);
early_delay(500000);
volt = mxs_get_batt_volt();
if (volt >= 3500) {
debug("SPL: Battery Voltage too high\n");
return 0;
}
if (volt >= 2400) {
debug("SPL: Battery is good\n");
return 1;
}
writel(POWER_CHARGE_STOP_ILIMIT_MASK | POWER_CHARGE_BATTCHRG_I_MASK,
&power_regs->hw_power_charge_clr);
writel(POWER_CHARGE_PWD_BATTCHRG, &power_regs->hw_power_charge_set);
debug("SPL: Battery Voltage too low\n");
return 0;
}
static void mxs_5v_boot(void)
{
struct mxs_power_regs *power_regs =
(struct mxs_power_regs *)MXS_POWER_BASE;
/*
* NOTE: In original IMX-Bootlets, this also checks for VBUSVALID,
* but their implementation always returns 1 so we omit it here.
*/
if (readl(&power_regs->hw_power_sts) & POWER_STS_VDD5V_GT_VDDIO) {
mxs_boot_valid_5v();
return;
}
early_delay(1000);
if (readl(&power_regs->hw_power_sts) & POWER_STS_VDD5V_GT_VDDIO) {
mxs_boot_valid_5v();
return;
}
mxs_handle_5v_conflict();
}
void mx28_power_set_vddd(uint32_t new_target, uint32_t new_brownout)
{
struct mx28_power_regs *power_regs =
(struct mx28_power_regs *)MXS_POWER_BASE;
uint32_t cur_target, diff, bo_int = 0;
uint32_t powered_by_linreg = 0;
new_brownout = new_target - new_brownout;
cur_target = readl(&power_regs->hw_power_vdddctrl);
cur_target &= POWER_VDDDCTRL_TRG_MASK;
cur_target *= 25; /* 25 mV step*/
cur_target += 800; /* 800 mV lowest */
powered_by_linreg = mx28_get_vddd_power_source_off();
if (new_target > cur_target) {
if (powered_by_linreg) {
bo_int = readl(&power_regs->hw_power_vdddctrl);
clrbits_le32(&power_regs->hw_power_vdddctrl,
POWER_CTRL_ENIRQ_VDDD_BO);
}
setbits_le32(&power_regs->hw_power_vdddctrl,
POWER_VDDDCTRL_BO_OFFSET_MASK);
do {
if (new_target - cur_target > 100)
diff = cur_target + 100;
else
diff = new_target;
diff -= 800;
diff /= 25;
clrsetbits_le32(&power_regs->hw_power_vdddctrl,
POWER_VDDDCTRL_TRG_MASK, diff);
if (powered_by_linreg ||
(readl(&power_regs->hw_power_sts) &
POWER_STS_VDD5V_GT_VDDIO))
early_delay(1500);
else {
while (!(readl(&power_regs->hw_power_sts) &
POWER_STS_DC_OK))
;
}
cur_target = readl(&power_regs->hw_power_vdddctrl);
cur_target &= POWER_VDDDCTRL_TRG_MASK;
cur_target *= 25; /* 25 mV step*/
cur_target += 800; /* 800 mV lowest */
} while (new_target > cur_target);
if (powered_by_linreg) {
writel(POWER_CTRL_VDDD_BO_IRQ,
&power_regs->hw_power_ctrl_clr);
if (bo_int & POWER_CTRL_ENIRQ_VDDD_BO)
setbits_le32(&power_regs->hw_power_vdddctrl,
POWER_CTRL_ENIRQ_VDDD_BO);
}
} else {
do {
if (cur_target - new_target > 100)
diff = cur_target - 100;
else
diff = new_target;
diff -= 800;
diff /= 25;
clrsetbits_le32(&power_regs->hw_power_vdddctrl,
POWER_VDDDCTRL_TRG_MASK, diff);
if (powered_by_linreg ||
(readl(&power_regs->hw_power_sts) &
POWER_STS_VDD5V_GT_VDDIO))
early_delay(1500);
else {
while (!(readl(&power_regs->hw_power_sts) &
POWER_STS_DC_OK))
;
}
cur_target = readl(&power_regs->hw_power_vdddctrl);
cur_target &= POWER_VDDDCTRL_TRG_MASK;
cur_target *= 25; /* 25 mV step*/
cur_target += 800; /* 800 mV lowest */
} while (new_target < cur_target);
}
clrsetbits_le32(&power_regs->hw_power_vdddctrl,
POWER_VDDDCTRL_BO_OFFSET_MASK,
new_brownout << POWER_VDDDCTRL_BO_OFFSET_OFFSET);
}
/**
* mxs_power_init_4p2_regulator() - Start the 4P2 regulator
*
* This function enables the 4P2 regulator and switches the DC-DC converter
* to use the 4P2 input.
*/
static void mxs_power_init_4p2_regulator(void)
{
struct mxs_power_regs *power_regs =
(struct mxs_power_regs *)MXS_POWER_BASE;
uint32_t tmp, tmp2;
debug("SPL: Enabling 4P2 regulator\n");
setbits_le32(&power_regs->hw_power_dcdc4p2, POWER_DCDC4P2_ENABLE_4P2);
writel(POWER_CHARGE_ENABLE_LOAD, &power_regs->hw_power_charge_set);
writel(POWER_5VCTRL_CHARGE_4P2_ILIMIT_MASK,
&power_regs->hw_power_5vctrl_clr);
clrbits_le32(&power_regs->hw_power_dcdc4p2, POWER_DCDC4P2_TRG_MASK);
/* Power up the 4p2 rail and logic/control */
writel(POWER_5VCTRL_PWD_CHARGE_4P2_MASK,
&power_regs->hw_power_5vctrl_clr);
/*
* Start charging up the 4p2 capacitor. We ramp of this charge
* gradually to avoid large inrush current from the 5V cable which can
* cause transients/problems
*/
debug("SPL: Charging 4P2 capacitor\n");
mxs_enable_4p2_dcdc_input(0);
if (readl(&power_regs->hw_power_ctrl) & POWER_CTRL_VBUS_VALID_IRQ) {
/*
* If we arrived here, we were unable to recover from mx23 chip
* errata 5837. 4P2 is disabled and sufficient battery power is
* not present. Exiting to not enable DCDC power during 5V
* connected state.
*/
clrbits_le32(&power_regs->hw_power_dcdc4p2,
POWER_DCDC4P2_ENABLE_DCDC);
writel(POWER_5VCTRL_PWD_CHARGE_4P2_MASK,
&power_regs->hw_power_5vctrl_set);
debug("SPL: Unable to recover from mx23 errata 5837\n");
hang();
}
/*
* Here we set the 4p2 brownout level to something very close to 4.2V.
* We then check the brownout status. If the brownout status is false,
* the voltage is already close to the target voltage of 4.2V so we
* can go ahead and set the 4P2 current limit to our max target limit.
* If the brownout status is true, we need to ramp us the current limit
* so that we don't cause large inrush current issues. We step up the
* current limit until the brownout status is false or until we've
* reached our maximum defined 4p2 current limit.
*/
debug("SPL: Setting 4P2 brownout level\n");
clrsetbits_le32(&power_regs->hw_power_dcdc4p2,
POWER_DCDC4P2_BO_MASK,
22 << POWER_DCDC4P2_BO_OFFSET); /* 4.15V */
if (!(readl(&power_regs->hw_power_sts) & POWER_STS_DCDC_4P2_BO)) {
setbits_le32(&power_regs->hw_power_5vctrl,
0x3f << POWER_5VCTRL_CHARGE_4P2_ILIMIT_OFFSET);
} else {
tmp = (readl(&power_regs->hw_power_5vctrl) &
POWER_5VCTRL_CHARGE_4P2_ILIMIT_MASK) >>
POWER_5VCTRL_CHARGE_4P2_ILIMIT_OFFSET;
while (tmp < 0x3f) {
if (!(readl(&power_regs->hw_power_sts) &
POWER_STS_DCDC_4P2_BO)) {
tmp = readl(&power_regs->hw_power_5vctrl);
tmp |= POWER_5VCTRL_CHARGE_4P2_ILIMIT_MASK;
early_delay(100);
writel(tmp, &power_regs->hw_power_5vctrl);
break;
} else {
tmp++;
tmp2 = readl(&power_regs->hw_power_5vctrl);
tmp2 &= ~POWER_5VCTRL_CHARGE_4P2_ILIMIT_MASK;
tmp2 |= tmp <<
POWER_5VCTRL_CHARGE_4P2_ILIMIT_OFFSET;
writel(tmp2, &power_regs->hw_power_5vctrl);
early_delay(100);
}
}
}
clrbits_le32(&power_regs->hw_power_dcdc4p2, POWER_DCDC4P2_BO_MASK);
writel(POWER_CTRL_DCDC4P2_BO_IRQ, &power_regs->hw_power_ctrl_clr);
}
/**
* mxs_enable_4p2_dcdc_input() - Enable or disable the DCDC input from 4P2
* @xfer: Select if the input shall be enabled or disabled
*
* This function enables or disables the 4P2 input into the DC-DC converter.
*/
static void mxs_enable_4p2_dcdc_input(int xfer)
{
struct mxs_power_regs *power_regs =
(struct mxs_power_regs *)MXS_POWER_BASE;
uint32_t tmp, vbus_thresh, vbus_5vdetect, pwd_bo;
uint32_t prev_5v_brnout, prev_5v_droop;
debug("SPL: %s 4P2 DC-DC Input\n", xfer ? "Enabling" : "Disabling");
if (xfer && (readl(&power_regs->hw_power_5vctrl) &
POWER_5VCTRL_ENABLE_DCDC)) {
return;
}
prev_5v_brnout = readl(&power_regs->hw_power_5vctrl) &
POWER_5VCTRL_PWDN_5VBRNOUT;
prev_5v_droop = readl(&power_regs->hw_power_ctrl) &
POWER_CTRL_ENIRQ_VDD5V_DROOP;
clrbits_le32(&power_regs->hw_power_5vctrl, POWER_5VCTRL_PWDN_5VBRNOUT);
writel(POWER_RESET_UNLOCK_KEY | POWER_RESET_PWD_OFF,
&power_regs->hw_power_reset);
clrbits_le32(&power_regs->hw_power_ctrl, POWER_CTRL_ENIRQ_VDD5V_DROOP);
/*
* Recording orignal values that will be modified temporarlily
* to handle a chip bug. See chip errata for CQ ENGR00115837
*/
tmp = readl(&power_regs->hw_power_5vctrl);
vbus_thresh = tmp & POWER_5VCTRL_VBUSVALID_TRSH_MASK;
vbus_5vdetect = tmp & POWER_5VCTRL_VBUSVALID_5VDETECT;
pwd_bo = readl(&power_regs->hw_power_minpwr) & POWER_MINPWR_PWD_BO;
/*
* Disable mechanisms that get erroneously tripped by when setting
* the DCDC4P2 EN_DCDC
*/
clrbits_le32(&power_regs->hw_power_5vctrl,
POWER_5VCTRL_VBUSVALID_5VDETECT |
POWER_5VCTRL_VBUSVALID_TRSH_MASK);
writel(POWER_MINPWR_PWD_BO, &power_regs->hw_power_minpwr_set);
if (xfer) {
setbits_le32(&power_regs->hw_power_5vctrl,
POWER_5VCTRL_DCDC_XFER);
early_delay(20);
clrbits_le32(&power_regs->hw_power_5vctrl,
POWER_5VCTRL_DCDC_XFER);
setbits_le32(&power_regs->hw_power_5vctrl,
POWER_5VCTRL_ENABLE_DCDC);
} else {
setbits_le32(&power_regs->hw_power_dcdc4p2,
POWER_DCDC4P2_ENABLE_DCDC);
}
early_delay(25);
clrsetbits_le32(&power_regs->hw_power_5vctrl,
POWER_5VCTRL_VBUSVALID_TRSH_MASK, vbus_thresh);
if (vbus_5vdetect)
writel(vbus_5vdetect, &power_regs->hw_power_5vctrl_set);
if (!pwd_bo)
clrbits_le32(&power_regs->hw_power_minpwr, POWER_MINPWR_PWD_BO);
while (readl(&power_regs->hw_power_ctrl) & POWER_CTRL_VBUS_VALID_IRQ)
writel(POWER_CTRL_VBUS_VALID_IRQ,
&power_regs->hw_power_ctrl_clr);
if (prev_5v_brnout) {
writel(POWER_5VCTRL_PWDN_5VBRNOUT,
&power_regs->hw_power_5vctrl_set);
writel(POWER_RESET_UNLOCK_KEY,
&power_regs->hw_power_reset);
} else {
writel(POWER_5VCTRL_PWDN_5VBRNOUT,
&power_regs->hw_power_5vctrl_clr);
writel(POWER_RESET_UNLOCK_KEY | POWER_RESET_PWD_OFF,
&power_regs->hw_power_reset);
}
while (readl(&power_regs->hw_power_ctrl) & POWER_CTRL_VDD5V_DROOP_IRQ)
writel(POWER_CTRL_VDD5V_DROOP_IRQ,
&power_regs->hw_power_ctrl_clr);
if (prev_5v_droop)
clrbits_le32(&power_regs->hw_power_ctrl,
POWER_CTRL_ENIRQ_VDD5V_DROOP);
else
setbits_le32(&power_regs->hw_power_ctrl,
POWER_CTRL_ENIRQ_VDD5V_DROOP);
}
