#define LTC3676_MSKPG_LDO3 (1 << 6)
#define LTC3676_MSKPG_LDO4 (1 << 7)
-#define VDD_IO_VAL mV_to_regval(vout_to_vref(3300 * 10, 5))
-#define VDD_IO_VAL_LP mV_to_regval(vout_to_vref(3100 * 10, 5))
-#define VDD_IO_VAL_2 mV_to_regval(vout_to_vref(3300 * 10, 5_2))
-#define VDD_IO_VAL_2_LP mV_to_regval(vout_to_vref(3100 * 10, 5_2))
-#define VDD_SOC_VAL mV_to_regval(vout_to_vref(1425 * 10, 6))
-#define VDD_SOC_VAL_LP mV_to_regval(vout_to_vref(900 * 10, 6))
-#define VDD_DDR_VAL mV_to_regval(vout_to_vref(1500 * 10, 7))
-#define VDD_DDR_VAL_LP mV_to_regval(vout_to_vref(1500 * 10, 7))
-#define VDD_CORE_VAL mV_to_regval(vout_to_vref(1425 * 10, 8))
-#define VDD_CORE_VAL_LP mV_to_regval(vout_to_vref(900 * 10, 8))
+#define VDD_IO_VAL mV_to_regval(vout_to_vref(3300, 5))
+#define VDD_IO_VAL_LP mV_to_regval(vout_to_vref(3100, 5))
+#define VDD_IO_VAL_2 mV_to_regval(vout_to_vref(3300, 5_2))
+#define VDD_IO_VAL_2_LP mV_to_regval(vout_to_vref(3100, 5_2))
+#define VDD_SOC_VAL mV_to_regval(vout_to_vref(1425, 6))
+#define VDD_SOC_VAL_LP mV_to_regval(vout_to_vref(900, 6))
+#define VDD_DDR_VAL mV_to_regval(vout_to_vref(1500, 7))
+#define VDD_DDR_VAL_LP mV_to_regval(vout_to_vref(1500, 7))
+#define VDD_CORE_VAL mV_to_regval(vout_to_vref(1425, 8))
+#define VDD_CORE_VAL_LP mV_to_regval(vout_to_vref(900, 8))
/* LDO1 */
#define R1_1 470
#define R1(idx) R1_##idx
#define R2(idx) R2_##idx
+#define v2r(v,n,m) DIV_ROUND(((((v) < (n)) ? (n) : (v)) - (n)), (m))
+#define r2v(r,n,m) (((r) * (m) + (n)) / 10)
+
#define vout_to_vref(vout, idx) ((vout) * R2(idx) / (R1(idx) + R2(idx)))
#define vref_to_vout(vref, idx) DIV_ROUND_UP((vref) * (R1(idx) + R2(idx)), R2(idx))
-#define mV_to_regval(mV) DIV_ROUND(((((mV) < 4125) ? 4125 : (mV)) - 4125), 125)
-#define regval_to_mV(v) (((v) * 125 + 4125))
+#define mV_to_regval(mV) v2r((mV) * 10, 4125, 125)
+#define regval_to_mV(r) r2v(r, 4125, 125)
static struct ltc3676_regs {
u8 addr;
if (ret)
return ret;
- printf("VDDCORE set to %umV\n",
- DIV_ROUND(vref_to_vout(regval_to_mV(VDD_CORE_VAL), 8), 10));
- printf("VDDSOC set to %umV\n",
- DIV_ROUND(vref_to_vout(regval_to_mV(VDD_SOC_VAL), 6), 10));
+ ret = i2c_read(slave_addr, LTC3676_DVB4A, 1, &value, 1);
+ if (ret == 0) {
+ printf("VDDCORE set to %umV\n",
+ vref_to_vout(regval_to_mV(value), 8));
+ } else {
+ printf("Failed to read VDDCORE register setting\n");
+ }
+
+ ret = i2c_read(slave_addr, LTC3676_DVB2A, 1, &value, 1);
+ if (ret == 0) {
+ printf("VDDSOC set to %umV\n",
+ vref_to_vout(regval_to_mV(value), 6));
+ } else {
+ printf("Failed to read VDDSOC register setting\n");
+ }
if (tx6_rev_2()) {
ret = ltc3676_setup_regs(slave_addr, ltc3676_regs_2,
ARRAY_SIZE(ltc3676_regs_2));
- printf("VDDIO set to %umV\n",
- DIV_ROUND(vref_to_vout(
- regval_to_mV(VDD_IO_VAL_2), 5_2), 10));
+
+ ret = i2c_read(slave_addr, LTC3676_DVB1A, 1, &value, 1);
+ if (ret == 0) {
+ printf("VDDIO set to %umV\n",
+ vref_to_vout(regval_to_mV(value), 5_2));
+ } else {
+ printf("Failed to read VDDIO register setting\n");
+ }
} else {
ret = ltc3676_setup_regs(slave_addr, ltc3676_regs_1,
ARRAY_SIZE(ltc3676_regs_1));
#define NOETIMSET_DIS_OFF_NOE_TIM (1 << 3)
-#define VDD_RTC_VAL mV_to_regval_rtc(3000 * 10)
-#define VDD_HIGH_VAL mV_to_regval3(3000 * 10)
-#define VDD_HIGH_VAL_LP mV_to_regval3(3000 * 10)
-#define VDD_CORE_VAL mV_to_regval(1425 * 10)
-#define VDD_CORE_VAL_LP mV_to_regval(900 * 10)
-#define VDD_SOC_VAL mV_to_regval(1425 * 10)
-#define VDD_SOC_VAL_LP mV_to_regval(900 * 10)
-#define VDD_DDR_VAL mV_to_regval(1500 * 10)
-#define VDD_DDR_VAL_LP mV_to_regval(1500 * 10)
+#define VDD_RTC_VAL mV_to_regval_rtc(3000)
+#define VDD_HIGH_VAL mV_to_regval3(3000)
+#define VDD_HIGH_VAL_LP mV_to_regval3(3000)
+#define VDD_CORE_VAL mV_to_regval(1425) /* DCDC1 */
+#define VDD_CORE_VAL_LP mV_to_regval(900)
+#define VDD_SOC_VAL mV_to_regval(1425) /* DCDC2 */
+#define VDD_SOC_VAL_LP mV_to_regval(900)
+#define VDD_DDR_VAL mV_to_regval(1350) /* DCDC3 */
+#define VDD_DDR_VAL_LP mV_to_regval(1350)
/* calculate voltages in 10mV */
+#define v2r(v,n,m) DIV_ROUND(((((v) < (n)) ? (n) : (v)) - (n)), (m))
+#define r2v(r,n,m) (((r) * (m) + (n)) / 10)
+
/* DCDC1-3 */
-#define mV_to_regval(mV) DIV_ROUND(((((mV) < 6000) ? 6000 : (mV)) - 6000), 125)
-#define regval_to_mV(v) (((v) * 125 + 6000))
+#define mV_to_regval(mV) v2r((mV) * 10, 6000, 125)
+#define regval_to_mV(r) r2v(r, 6000, 125)
/* LDO1-2 */
-#define mV_to_regval2(mV) DIV_ROUND(((((mV) < 9000) ? 9000 : (mV)) - 9000), 250)
-#define regval2_to_mV(v) (((v) * 250 + 9000))
+#define mV_to_regval2(mV) v2r((mV) * 10, 9000, 250)
+#define regval2_to_mV(r) r2v(r, 9000, 250)
/* LDO3 */
-#define mV_to_regval3(mV) DIV_ROUND(((((mV) < 6000) ? 6000 : (mV)) - 6000), 250)
-#define regval3_to_mV(v) (((v) * 250 + 6000))
+#define mV_to_regval3(mV) v2r((mV) * 10, 6000, 250)
+#define regval3_to_mV(r) r2v(r, 6000, 250)
/* LDORTC */
-#define mV_to_regval_rtc(mV) DIV_ROUND(((((mV) < 17000) ? 17000 : (mV)) - 17000), 250)
-#define regval_rtc_to_mV(v) (((v) * 250 + 17000))
+#define mV_to_regval_rtc(mV) v2r((mV) * 10, 17000, 250)
+#define regval_rtc_to_mV(r) r2v(r, 17000, 250)
static struct rn5t567_regs {
u8 addr;
u8 mask;
} rn5t567_regs[] = {
{ RN5T567_NOETIMSET, NOETIMSET_DIS_OFF_NOE_TIM | 0x5, },
-#if 0
{ RN5T567_DC1DAC, VDD_CORE_VAL, },
{ RN5T567_DC2DAC, VDD_SOC_VAL, },
{ RN5T567_DC3DAC, VDD_DDR_VAL, },
{ RN5T567_LDOEN2, 0x10, ~0x30, },
{ RN5T567_LDODIS, 0x00, },
{ RN5T567_LDO3DAC, VDD_HIGH_VAL, },
- { RN5T567_LDORTCDAC, VDD_RTC_VAL, },
+ { RN5T567_LDORTC1DAC, VDD_RTC_VAL, },
{ RN5T567_LDORTC1_SLOT, 0x0f, ~0x3f, },
-#endif
-};
-
-static struct rn5t567_regs debug_regs[] __maybe_unused = {
- { 0x00, 4, },
- { 0x09, 4, },
- { 0x10, 16, },
- { 0x25, 26, },
- { 0x44, 3, },
- { 0x4c, 5, },
- { 0x56, 1, },
- { 0x58, 5, },
- { 0x97, 2, },
- { 0xb0, 1, },
- { 0xbc, 1, },
};
static int rn5t567_setup_regs(uchar slave_addr, struct rn5t567_regs *r,
return ret;
}
#endif
-// value = (value & ~r->mask) | r->val;
ret = i2c_write(slave_addr, r->addr, 1, &r->val, 1);
if (ret) {
printf("%s: failed to write PMIC register %02x: %d\n",
__func__, r->addr, ret);
return ret;
}
-#ifdef DEBUG
- ret = i2c_read(slave_addr, r->addr, 1, &value, 1);
- printf("PMIC reg %02x is %02x\n", r->addr, value);
-#endif
}
-#if 0
- for (i = 0; i < ARRAY_SIZE(debug_regs); i++) {
- int j;
-
- r = &debug_regs[i];
- for (j = r->addr; j < r->addr + r->val; j++) {
- unsigned char value;
-
- ret = i2c_read(slave_addr, j, 1, &value, 1);
- printf("PMIC reg %02x = %02x\n",
- j, value);
- }
- }
-#endif
- debug("%s() complete\n", __func__);
return 0;
}
if (ret)
return ret;
- printf("VDDCORE set to %umV\n",
- DIV_ROUND(regval_to_mV(VDD_CORE_VAL), 10));
- printf("VDDSOC set to %umV\n",
- DIV_ROUND(regval_to_mV(VDD_SOC_VAL), 10));
+ ret = i2c_read(slave_addr, RN5T567_DC1DAC, 1, &value, 1);
+ if (ret == 0) {
+ printf("VDDCORE set to %umV\n", regval_to_mV(value));
+ } else {
+ printf("Failed to read VDDCORE register setting\n");
+ }
+
+ ret = i2c_read(slave_addr, RN5T567_DC2DAC, 1, &value, 1);
+ if (ret == 0) {
+ printf("VDDSOC set to %umV\n", regval_to_mV(value));
+ } else {
+ printf("Failed to read VDDSOC register setting\n");
+ }
return ret;
}
#define RN5T618_LDO3DAC 0x4e /* IO */
#define RN5T618_LDORTCDAC 0x56 /* VBACKUP */
-#define VDD_RTC_VAL mV_to_regval_rtc(3000 * 10)
-#define VDD_HIGH_VAL mV_to_regval3(3000 * 10)
-#define VDD_HIGH_VAL_LP mV_to_regval3(3000 * 10)
-#define VDD_CORE_VAL mV_to_regval(1425 * 10)
-#define VDD_CORE_VAL_LP mV_to_regval(900 * 10)
-#define VDD_SOC_VAL mV_to_regval(1425 * 10)
-#define VDD_SOC_VAL_LP mV_to_regval(900 * 10)
-#define VDD_DDR_VAL mV_to_regval(1500 * 10)
-#define VDD_DDR_VAL_LP mV_to_regval(1500 * 10)
+#define VDD_RTC_VAL mV_to_regval_rtc(3000)
+#define VDD_HIGH_VAL mV_to_regval3(3000)
+#define VDD_HIGH_VAL_LP mV_to_regval3(3000)
+#define VDD_CORE_VAL mV_to_regval(1425) /* DCDC1 */
+#define VDD_CORE_VAL_LP mV_to_regval(900)
+#define VDD_SOC_VAL mV_to_regval(1425) /* DCDC2 */
+#define VDD_SOC_VAL_LP mV_to_regval(900)
+#define VDD_DDR_VAL mV_to_regval(1500) /* DCDC3 */
+#define VDD_DDR_VAL_LP mV_to_regval(1500)
/* calculate voltages in 10mV */
+#define v2r(v,n,m) DIV_ROUND(((((v) < (n)) ? (n) : (v)) - (n)), (m))
+#define r2v(r,n,m) (((r) * (m) + (n)) / 10)
+
/* DCDC1-3 */
-#define mV_to_regval(mV) DIV_ROUND(((((mV) < 6000) ? 6000 : (mV)) - 6000), 125)
-#define regval_to_mV(v) (((v) * 125 + 6000))
+#define mV_to_regval(mV) v2r((mV) * 10, 6000, 125)
+#define regval_to_mV(r) r2v(r, 6000, 125)
/* LDO1-2 */
-#define mV_to_regval2(mV) DIV_ROUND(((((mV) < 9000) ? 9000 : (mV)) - 9000), 250)
-#define regval2_to_mV(v) (((v) * 250 + 9000))
+#define mV_to_regval2(mV) v2r((mV) * 10, 9000, 250)
+#define regval2_to_mV(r) r2v(r, 9000, 250)
/* LDO3 */
-#define mV_to_regval3(mV) DIV_ROUND(((((mV) < 6000) ? 6000 : (mV)) - 6000), 250)
-#define regval3_to_mV(v) (((v) * 250 + 6000))
+#define mV_to_regval3(mV) v2r((mV) * 10, 6000, 250)
+#define regval3_to_mV(r) r2v(r, 6000, 250)
/* LDORTC */
-#define mV_to_regval_rtc(mV) DIV_ROUND(((((mV) < 17000) ? 17000 : (mV)) - 17000), 250)
-#define regval_rtc_to_mV(v) (((v) * 250 + 17000))
+#define mV_to_regval_rtc(mV) v2r((mV) * 10, 17000, 250)
+#define regval_rtc_to_mV(r) r2v(r, 17000, 250)
static struct rn5t618_regs {
u8 addr;
int ret;
int i;
- for (i = 0; i < count; i++, r++) {
- unsigned char value;
-
- ret = i2c_read(slave_addr, r->addr, 1, &value, 1);
- debug("PMIC reg %02x = %02x\n", r->addr, value);
- }
for (i = 0; i < count; i++, r++) {
#ifdef DEBUG
unsigned char value;
__func__, r->addr, ret);
return ret;
}
-#ifdef DEBUG
- ret = i2c_read(slave_addr, r->addr, 1, &value, 1);
- printf("PMIC reg %02x is %02x\n", r->addr, value);
-#endif
}
return 0;
}
if (ret)
return ret;
- printf("VDDCORE set to %umV\n",
- DIV_ROUND(regval_to_mV(VDD_CORE_VAL), 10));
- printf("VDDSOC set to %umV\n",
- DIV_ROUND(regval_to_mV(VDD_SOC_VAL), 10));
+ ret = i2c_read(slave_addr, RN5T618_DC1DAC, 1, &value, 1);
+ if (ret == 0) {
+ printf("VDDCORE set to %umV\n", regval_to_mV(value));
+ } else {
+ printf("Failed to read VDDCORE register setting\n");
+ }
+
+ ret = i2c_read(slave_addr, RN5T618_DC2DAC, 1, &value, 1);
+ if (ret == 0) {
+ printf("VDDSOC set to %umV\n", regval_to_mV(value));
+ } else {
+ printf("Failed to read VDDSOC register setting\n");
+ }
return ret;
}