1 files changed, 670 insertions, 0 deletions
diff --git a/firmware/drivers/axp-pmu.c b/firmware/drivers/axp-pmu.c
new file mode 100644
index 0000000000..fd1126dbbf
--- /dev/null
+++ b/firmware/drivers/axp-pmu.c
@@ -0,0 +1,670 @@
+/***************************************************************************
+ *             __________               __   ___.
+ *   Open      \______   \ ____   ____ |  | _\_ |__   _______  ___
+ *   Source     |       _//  _ \_/ ___\|  |/ /| __ \ /  _ \  \/  /
+ *   Jukebox    |    |   (  <_> )  \___|    < | \_\ (  <_> > <  <
+ *   Firmware   |____|_  /\____/ \___  >__|_ \|___  /\____/__/\_ \
+ *                     \/            \/     \/    \/            \/
+ * $Id$
+ *
+ * Copyright (C) 2021 Aidan MacDonald
+ *
+ * This program is free software; you can redistribute it and/or
+ * modify it under the terms of the GNU General Public License
+ * as published by the Free Software Foundation; either version 2
+ * of the License, or (at your option) any later version.
+ *
+ * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
+ * KIND, either express or implied.
+ *
+ ****************************************************************************/
+#include "axp-pmu.h"
+#include "power.h"
+#include "system.h"
+#include "i2c-async.h"
+#include <string.h>
+/* Headers for the debug menu */
+#ifndef BOOTLOADER
+# include "action.h"
+# include "list.h"
+# include <stdio.h>
+#endif
+struct axp_adc_info {
+    uint8_t reg;
+    uint8_t en_reg;
+    uint8_t en_bit;
+};
+struct axp_supply_info {
+    uint8_t volt_reg;
+    uint8_t volt_reg_mask;
+    uint8_t en_reg;
+    uint8_t en_bit;
+    int min_mV;
+    int max_mV;
+    int step_mV;
+};
+static const struct axp_adc_info axp_adc_info[NUM_ADC_CHANNELS] = {
+    {0x56, AXP_REG_ADCENABLE1, 5}, /* ACIN_VOLTAGE */
+    {0x58, AXP_REG_ADCENABLE1, 4}, /* ACIN_CURRENT */
+    {0x5a, AXP_REG_ADCENABLE1, 3}, /* VBUS_VOLTAGE */
+    {0x5c, AXP_REG_ADCENABLE1, 2}, /* VBUS_CURRENT */
+    {0x5e, AXP_REG_ADCENABLE2, 7}, /* INTERNAL_TEMP */
+    {0x62, AXP_REG_ADCENABLE1, 1}, /* TS_INPUT */
+    {0x78, AXP_REG_ADCENABLE1, 7}, /* BATTERY_VOLTAGE */
+    {0x7a, AXP_REG_ADCENABLE1, 6}, /* CHARGE_CURRENT */
+    {0x7c, AXP_REG_ADCENABLE1, 6}, /* DISCHARGE_CURRENT */
+    {0x7e, AXP_REG_ADCENABLE1, 1}, /* APS_VOLTAGE */
+    {0x70, 0xff, 0},               /* BATTERY_POWER */
+};
+static const struct axp_supply_info axp_supply_info[AXP_NUM_SUPPLIES] = {
+#if HAVE_AXP_PMU == 192
+    [AXP_SUPPLY_DCDC1] = {
+        .volt_reg = 0x26,
+        .volt_reg_mask = 0x7f,
+        .en_reg = 0x12,
+        .en_bit = 0,
+        .min_mV = 700,
+        .max_mV = 3500,
+        .step_mV = 25,
+    },
+    [AXP_SUPPLY_DCDC2] = {
+        .volt_reg = 0x23,
+        .volt_reg_mask = 0x3f,
+        .en_reg = 0x10,
+        .en_bit = 0,
+        .min_mV = 700,
+        .max_mV = 2275,
+        .step_mV = 25,
+    },
+    [AXP_SUPPLY_DCDC3] = {
+        .volt_reg = 0x27,
+        .volt_reg_mask = 0x7f,
+        .en_reg = 0x12,
+        .en_bit = 1,
+        .min_mV = 700,
+        .max_mV = 3500,
+        .step_mV = 25,
+    },
+    /*
+     * NOTE: LDO1 is always on, and we can't query it or change voltages
+     */
+    [AXP_SUPPLY_LDO2] = {
+        .volt_reg = 0x28,
+        .volt_reg_mask = 0xf0,
+        .en_reg = 0x12,
+        .en_bit = 2,
+        .min_mV = 1800,
+        .max_mV = 3300,
+        .step_mV = 100,
+    },
+    [AXP_SUPPLY_LDO3] = {
+        .volt_reg = 0x28,
+        .volt_reg_mask = 0x0f,
+        .en_reg = 0x12,
+        .en_bit = 3,
+        .min_mV = 1800,
+        .max_mV = 3300,
+        .step_mV = 100,
+    },
+    [AXP_SUPPLY_LDO_IO0] = {
+        .volt_reg = 0x91,
+        .volt_reg_mask = 0xf0,
+        .en_reg = 0x90,
+        .en_bit = 0xff, /* this one requires special handling */
+        .min_mV = 1800,
+        .max_mV = 3300,
+        .step_mV = 100,
+    },
+#else
+# error "Untested AXP chip"
+#endif
+};
+static struct axp_driver {
+    int adc_enable;
+    int chargecurrent_setting;
+    int chip_id;
+} axp;
+static void axp_init_enabled_adcs(void)
+{
+    axp.adc_enable = 0;
+    /* Read chip ID, so we can display it on the debug screen.
+     * This is undocumented but there's Linux driver code floating around
+     * which suggests this should work for many AXP chips. */
+    axp.chip_id = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_CHIP_ID);
+    /* Read enabled ADCs from the hardware */
+    uint8_t regs[2];
+    int rc = i2c_reg_read(AXP_PMU_BUS, AXP_PMU_ADDR,
+                          AXP_REG_ADCENABLE1, 2, &regs[0]);
+    if(rc != I2C_STATUS_OK)
+        return;
+    /* Parse registers to set ADC enable bits */
+    const struct axp_adc_info* info = axp_adc_info;
+    for(int i = 0; i < NUM_ADC_CHANNELS; ++i) {
+        if(info[i].en_reg == 0xff)
+            continue;
+        if(regs[info[i].en_reg - AXP_REG_ADCENABLE1] & info[i].en_bit)
+            axp.adc_enable |= 1 << i;
+    }
+    /* Handle battery power ADC */
+    if((axp.adc_enable & (1 << ADC_BATTERY_VOLTAGE)) &&
+       (axp.adc_enable & (1 << ADC_DISCHARGE_CURRENT))) {
+        axp.adc_enable |= (1 << ADC_BATTERY_POWER);
+    }
+}
+void axp_init(void)
+{
+    axp_init_enabled_adcs();
+    /* We need discharge current ADC to reliably poll for a full battery */
+    int bits = axp.adc_enable;
+    bits |= (1 << ADC_DISCHARGE_CURRENT);
+    axp_adc_set_enabled(bits);
+    /* Read the maximum charging current */
+    int value = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_CHARGECONTROL1);
+    axp.chargecurrent_setting = (value < 0) ? -1 : (value & 0xf);
+}
+void axp_supply_set_voltage(int supply, int voltage)
+{
+    const struct axp_supply_info* info = &axp_supply_info[supply];
+    if(info->volt_reg == 0 || info->volt_reg_mask == 0)
+        return;
+    if(voltage > 0 && info->step_mV != 0) {
+        if(voltage < info->min_mV || voltage > info->max_mV)
+            return;
+        int regval = (voltage - info->min_mV) / info->step_mV;
+        i2c_reg_modify1(AXP_PMU_BUS, AXP_PMU_ADDR, info->volt_reg,
+                        info->volt_reg_mask, regval, NULL);
+    }
+    if(info->en_bit != 0xff) {
+        i2c_reg_setbit1(AXP_PMU_BUS, AXP_PMU_ADDR,
+                        info->en_reg, info->en_bit,
+                        voltage > 0 ? 1 : 0, NULL);
+    }
+}
+int axp_supply_get_voltage(int supply)
+{
+    const struct axp_supply_info* info = &axp_supply_info[supply];
+    if(info->volt_reg == 0)
+        return AXP_SUPPLY_NOT_PRESENT;
+    if(info->en_reg != 0) {
+        int r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, info->en_reg);
+        if(r < 0)
+            return AXP_SUPPLY_DISABLED;
+#if HAVE_AXP_PMU == 192
+        if(supply == AXP_SUPPLY_LDO_IO0) {
+            if((r & 7) != 2)
+                return AXP_SUPPLY_DISABLED;
+        } else
+#endif
+        {
+            if(r & (1 << info->en_bit) == 0)
+                return AXP_SUPPLY_DISABLED;
+        }
+    }
+    /* Hack, avoid undefined shift below. Can be useful too... */
+    if(info->volt_reg_mask == 0)
+        return info->min_mV;
+    int r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, info->volt_reg);
+    if(r < 0)
+        return 0;
+    int bit = find_first_set_bit(info->volt_reg_mask);
+    int val = (r & info->volt_reg_mask) >> bit;
+    return info->min_mV + (val * info->step_mV);
+}
+/* TODO: this can STILL indicate some false positives! */
+int axp_battery_status(void)
+{
+    int r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_POWERSTATUS);
+    if(r >= 0) {
+        /* Charging bit indicates we're currently charging */
+        if((r & 0x04) != 0)
+            return AXP_BATT_CHARGING;
+        /* Not plugged in means we're discharging */
+        if((r & 0xf0) == 0)
+            return AXP_BATT_DISCHARGING;
+    } else {
+        /* Report discharging if we can't find out power status */
+        return AXP_BATT_DISCHARGING;
+    }
+    /* If the battery is full and not in use, the charging bit will be 0,
+     * there will be an external power source, AND the discharge current
+     * will be zero. Seems to rule out all false positives. */
+    int d = axp_adc_read_raw(ADC_DISCHARGE_CURRENT);
+    if(d == 0)
+        return AXP_BATT_FULL;
+    return AXP_BATT_DISCHARGING;
+}
+int axp_input_status(void)
+{
+#ifdef HAVE_BATTERY_SWITCH
+    int input_status = 0;
+#else
+    int input_status = AXP_INPUT_BATTERY;
+#endif
+    int r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_POWERSTATUS);
+    if(r < 0)
+        return input_status;
+    /* Check for AC input */
+    if(r & 0x80)
+        input_status |= AXP_INPUT_AC;
+    /* Only report USB if ACIN and VBUS are not shorted */
+    if((r & 0x20) != 0 && (r & 0x02) == 0)
+        input_status |= AXP_INPUT_USB;
+#ifdef HAVE_BATTERY_SWITCH
+    /* Check for battery presence if target defines it as removable */
+    r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_CHARGESTATUS);
+    if(r >= 0 && (r & 0x20) != 0)
+        input_status |= AXP_INPUT_BATTERY;
+#endif
+    return input_status;
+}
+int axp_adc_read(int adc)
+{
+    int value = axp_adc_read_raw(adc);
+    if(value == INT_MIN)
+        return INT_MIN;
+    return axp_adc_conv_raw(adc, value);
+}
+int axp_adc_read_raw(int adc)
+{
+    /* Don't give a reading if the ADC is not enabled */
+    if((axp.adc_enable & (1 << adc)) == 0)
+        return INT_MIN;
+    /* Read the ADC */
+    uint8_t buf[3];
+    int count = (adc == ADC_BATTERY_POWER) ? 3 : 2;
+    uint8_t reg = axp_adc_info[adc].reg;
+    int rc = i2c_reg_read(AXP_PMU_BUS, AXP_PMU_ADDR, reg, count, &buf[0]);
+    if(rc != I2C_STATUS_OK)
+        return INT_MIN;
+    /* Parse the value */
+    if(adc == ADC_BATTERY_POWER)
+        return (buf[0] << 16) | (buf[1] << 8) | buf[2];
+    else if(adc == ADC_CHARGE_CURRENT || adc == ADC_DISCHARGE_CURRENT)
+        return (buf[0] << 5) | (buf[1] & 0x1f);
+    else
+        return (buf[0] << 4) | (buf[1] & 0xf);
+}
+int axp_adc_conv_raw(int adc, int value)
+{
+    switch(adc) {
+    case ADC_ACIN_VOLTAGE:
+    case ADC_VBUS_VOLTAGE:
+        /* 0 mV ... 6.9615 mV, step 1.7 mV */
+        return value * 17 / 10;
+    case ADC_ACIN_CURRENT:
+        /* 0 mA ... 2.5594 A, step 0.625 mA */
+        return value * 5 / 8;
+    case ADC_VBUS_CURRENT:
+        /* 0 mA ... 1.5356 A, step 0.375 mA */
+        return value * 3 / 8;
+    case ADC_INTERNAL_TEMP:
+        /* -144.7 C ... 264.8 C, step 0.1 C */
+        return value - 1447;
+    case ADC_TS_INPUT:
+        /* 0 mV ... 3.276 V, step 0.8 mV */
+        return value * 4 / 5;
+    case ADC_BATTERY_VOLTAGE:
+        /* 0 mV ... 4.5045 V, step 1.1 mV */
+        return value * 11 / 10;
+    case ADC_CHARGE_CURRENT:
+    case ADC_DISCHARGE_CURRENT:
+        /* 0 mA to 4.095 A, step 0.5 mA */
+        return value / 2;
+    case ADC_APS_VOLTAGE:
+        /* 0 mV to 5.733 V, step 1.4 mV */
+        return value * 7 / 5;
+    case ADC_BATTERY_POWER:
+        /* 0 uW to 23.6404 W, step 0.55 uW */
+        return value * 11 / 20;
+    default:
+        /* Shouldn't happen */
+        return INT_MIN;
+    }
+}
+int axp_adc_get_enabled(void)
+{
+    return axp.adc_enable;
+}
+void axp_adc_set_enabled(int adc_bits)
+{
+    /* Ignore no-op */
+    if(adc_bits == axp.adc_enable)
+        return;
+    /* Compute the new register values */
+    const struct axp_adc_info* info = axp_adc_info;
+    uint8_t regs[2] = {0, 0};
+    for(int i = 0; i < NUM_ADC_CHANNELS; ++i) {
+        if(info[i].en_reg == 0xff)
+            continue;
+        if(adc_bits & (1 << i))
+            regs[info[i].en_reg - 0x82] |= 1 << info[i].en_bit;
+    }
+    /* These ADCs share an enable bit */
+    if(adc_bits & ((1 << ADC_CHARGE_CURRENT)|(1 << ADC_DISCHARGE_CURRENT))) {
+        adc_bits |= (1 << ADC_CHARGE_CURRENT);
+        adc_bits |= (1 << ADC_DISCHARGE_CURRENT);
+    }
+    /* Enable required bits for battery power ADC */
+    if(adc_bits & (1 << ADC_BATTERY_POWER)) {
+        regs[0] |= 1 << info[ADC_DISCHARGE_CURRENT].en_bit;
+        regs[0] |= 1 << info[ADC_BATTERY_VOLTAGE].en_bit;
+    }
+    /* Update the configuration */
+    i2c_reg_write(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_ADCENABLE1, 2, &regs[0]);
+    axp.adc_enable = adc_bits;
+}
+int axp_adc_get_rate(void)
+{
+    int r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_ADCSAMPLERATE);
+    if(r < 0)
+        return AXP_ADC_RATE_100HZ; /* an arbitrary value */
+    return (r >> 6) & 3;
+}
+void axp_adc_set_rate(int rate)
+{
+    i2c_reg_modify1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_ADCSAMPLERATE,
+                    0xc0, (rate & 3) << 6, NULL);
+}
+static uint32_t axp_cc_parse(const uint8_t* buf)
+{
+    return ((uint32_t)buf[0] << 24) | (buf[1] << 16) | (buf[2] << 8) | buf[3];
+}
+void axp_cc_read(uint32_t* charge, uint32_t* discharge)
+{
+    uint8_t buf[8];
+    int rc = i2c_reg_read(AXP_PMU_BUS, AXP_PMU_ADDR,
+                          AXP_REG_COULOMBCOUNTERBASE, 8, &buf[0]);
+    if(rc != I2C_STATUS_OK) {
+        if(charge)
+            *charge = 0;
+        if(discharge)
+            *discharge = 0;
+        return;
+    }
+    if(charge)
+        *charge = axp_cc_parse(&buf[0]);
+    if(discharge)
+        *discharge = axp_cc_parse(&buf[4]);
+}
+void axp_cc_clear(void)
+{
+    i2c_reg_setbit1(AXP_PMU_BUS, AXP_PMU_ADDR,
+                    AXP_REG_COULOMBCOUNTERCTRL, 5, 1, NULL);
+}
+void axp_cc_enable(bool en)
+{
+    i2c_reg_setbit1(AXP_PMU_BUS, AXP_PMU_ADDR,
+                    AXP_REG_COULOMBCOUNTERCTRL, 7, en ? 1 : 0, NULL);
+}
+bool axp_cc_is_enabled(void)
+{
+    int reg = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR,
+                            AXP_REG_COULOMBCOUNTERCTRL);
+    return reg >= 0 && (reg & 0x40) != 0;
+}
+static const int chargecurrent_tbl[] = {
+    100,  190,  280,  360,
+    450,  550,  630,  700,
+    780,  880,  960,  1000,
+    1080, 1160, 1240, 1320,
+};
+static const int chargecurrent_tblsz = sizeof(chargecurrent_tbl)/sizeof(int);
+void axp_set_charge_current(int maxcurrent)
+{
+    /* Find the charge current just higher than maxcurrent */
+    int value = 0;
+    while(value < chargecurrent_tblsz &&
+          chargecurrent_tbl[value] <= maxcurrent)
+        ++value;
+    /* Select the next lower current, the greatest current <= maxcurrent */
+    if(value >= chargecurrent_tblsz)
+        value = chargecurrent_tblsz - 1;
+    else if(value > 0)
+        --value;
+    /* Don't issue i2c write if desired setting is already in use */
+    if(value == axp.chargecurrent_setting)
+        return;
+    /* Update register */
+    i2c_reg_modify1(AXP_PMU_BUS, AXP_PMU_ADDR,
+                    AXP_REG_CHARGECONTROL1, 0x0f, value, NULL);
+    axp.chargecurrent_setting = value;
+}
+int axp_get_charge_current(void)
+{
+    if(axp.chargecurrent_setting < 0)
+        return chargecurrent_tbl[0];
+    else
+        return chargecurrent_tbl[axp.chargecurrent_setting];
+}
+void axp_power_off(void)
+{
+    /* Set the shutdown bit */
+    i2c_reg_setbit1(AXP_PMU_BUS, AXP_PMU_ADDR,
+                    AXP_REG_SHUTDOWNLEDCTRL, 7, 1, NULL);
+}
+#ifndef BOOTLOADER
+enum {
+    AXP_DEBUG_CHIP_ID,
+    AXP_DEBUG_BATTERY_STATUS,
+    AXP_DEBUG_INPUT_STATUS,
+    AXP_DEBUG_CHARGE_CURRENT,
+    AXP_DEBUG_COULOMB_COUNTERS,
+    AXP_DEBUG_ADC_RATE,
+    AXP_DEBUG_FIRST_ADC,
+    AXP_DEBUG_FIRST_SUPPLY = AXP_DEBUG_FIRST_ADC + NUM_ADC_CHANNELS,
+    AXP_DEBUG_NUM_ENTRIES = AXP_DEBUG_FIRST_SUPPLY + AXP_NUM_SUPPLIES,
+};
+static int axp_debug_menu_cb(int action, struct gui_synclist* lists)
+{
+    (void)lists;
+    if(action == ACTION_NONE)
+        action = ACTION_REDRAW;
+    return action;
+}
+static const char* axp_debug_menu_get_name(int item, void* data,
+                                           char* buf, size_t buflen)
+{
+    (void)data;
+    static const char* const adc_names[] = {
+        "V_acin", "I_acin", "V_vbus", "I_vbus", "T_int",
+        "V_ts", "V_batt", "I_chrg", "I_dchg", "V_aps", "P_batt"
+    };
+    static const char* const adc_units[] = {
+        "mV", "mA", "mV", "mA", "C", "mV", "mV", "mA", "mA", "mV", "uW",
+    };
+    static const char* const supply_names[] = {
+        "DCDC1", "DCDC2", "DCDC3",
+        "LDO1", "LDO2", "LDO3", "LDO_IO0",
+    };
+    int adc = item - AXP_DEBUG_FIRST_ADC;
+    if(item >= AXP_DEBUG_FIRST_ADC && adc < NUM_ADC_CHANNELS) {
+        int raw_value = axp_adc_read_raw(adc);
+        if(raw_value == INT_MIN) {
+            snprintf(buf, buflen, "%s: [Disabled]", adc_names[adc]);
+            return buf;
+        }
+        int value = axp_adc_conv_raw(adc, raw_value);
+        if(adc == ADC_INTERNAL_TEMP) {
+            snprintf(buf, buflen, "%s: %d.%d %s", adc_names[adc],
+                     value/10, value%10, adc_units[adc]);
+        } else {
+            snprintf(buf, buflen, "%s: %d %s", adc_names[adc],
+                     value, adc_units[adc]);
+        }
+        return buf;
+    }
+    int supply = item - AXP_DEBUG_FIRST_SUPPLY;
+    if(item >= AXP_DEBUG_FIRST_SUPPLY && supply < AXP_NUM_SUPPLIES) {
+        int voltage = axp_supply_get_voltage(supply);
+        if(voltage == AXP_SUPPLY_NOT_PRESENT)
+            snprintf(buf, buflen, "%s: [Not Present]", supply_names[supply]);
+        else if(voltage == AXP_SUPPLY_DISABLED)
+            snprintf(buf, buflen, "%s: [Disabled]", supply_names[supply]);
+        else
+            snprintf(buf, buflen, "%s: %d mV", supply_names[supply], voltage);
+        return buf;
+    }
+    switch(item) {
+    case AXP_DEBUG_CHIP_ID: {
+        snprintf(buf, buflen, "Chip ID: %d (%02x) [Driver: AXP%d]",
+                 axp.chip_id, axp.chip_id, HAVE_AXP_PMU);
+        return buf;
+    } break;
+    case AXP_DEBUG_BATTERY_STATUS: {
+        switch(axp_battery_status()) {
+        case AXP_BATT_FULL:
+            return "Battery: Full";
+        case AXP_BATT_CHARGING:
+            return "Battery: Charging";
+        case AXP_BATT_DISCHARGING:
+            return "Battery: Discharging";
+        default:
+            return "Battery: Unknown";
+        }
+    } break;
+    case AXP_DEBUG_INPUT_STATUS: {
+        int s = axp_input_status();
+        const char* ac = (s & AXP_INPUT_AC) ? " AC" : "";
+        const char* usb = (s & AXP_INPUT_USB) ? " USB" : "";
+        const char* batt = (s & AXP_INPUT_BATTERY) ? " Battery" : "";
+        snprintf(buf, buflen, "Inputs:%s%s%s", ac, usb, batt);
+        return buf;
+    } break;
+    case AXP_DEBUG_CHARGE_CURRENT: {
+        int current = axp_get_charge_current();
+        snprintf(buf, buflen, "Max charge current: %d mA", current);
+        return buf;
+    } break;
+    case AXP_DEBUG_COULOMB_COUNTERS: {
+        uint32_t charge, discharge;
+        axp_cc_read(&charge, &discharge);
+        snprintf(buf, buflen, "Coulomb counters: +%lu / -%lu",
+                 (unsigned long)charge, (unsigned long)discharge);
+        return buf;
+    } break;
+    case AXP_DEBUG_ADC_RATE: {
+        int rate = 25 << axp_adc_get_rate();
+        snprintf(buf, buflen, "ADC sample rate: %d Hz", rate);
+        return buf;
+    } break;
+    default:
+        return "---";
+    }
+}
+bool axp_debug_menu(void)
+{
+    struct simplelist_info info;
+    simplelist_info_init(&info, "AXP debug", AXP_DEBUG_NUM_ENTRIES, NULL);
+    info.action_callback = axp_debug_menu_cb;
+    info.get_name = axp_debug_menu_get_name;
+    return simplelist_show_list(&info);
+}
+#endif /* !BOOTLOADER */
+/* This is basically the only valid implementation, so define it here */
+unsigned int power_input_status(void)
+{
+    unsigned int state = 0;
+    int input_status = axp_input_status();
+    if(input_status & AXP_INPUT_AC)
+        state |= POWER_INPUT_MAIN_CHARGER;
+    if(input_status & AXP_INPUT_USB)
+        state |= POWER_INPUT_USB_CHARGER;
+#ifdef HAVE_BATTERY_SWITCH
+    if(input_status & AXP_INPUT_BATTERY)
+        state |= POWER_INPUT_BATTERY;
+#endif
+    return state;
+}

diff --git a/firmware/drivers/axp-pmu.c b/firmware/drivers/axp-pmu.c new file mode 100644 index 0000000000..fd1126dbbf --- /dev/null +++ b/firmware/drivers/axp-pmu.c
@@ -0,0 +1,670 @@
	1	/***************************************************************************
	2	* __________ __ ___.
	3	* Open \______ \ ____ ____ \| \| _\_ \|__ _______ ___
	4	* Source \| _// _ \_/ ___\\| \|/ /\| __ \ / _ \ \/ /
	5	* Jukebox \| \| ( <_> ) \___\| < \| \_\ ( <_> > < <
	6	* Firmware \|____\|_ /\____/ \___ >__\|_ \\|___ /\____/__/\_ \
	7	* \/ \/ \/ \/ \/
	8	* $Id$
	9	*
	10	* Copyright (C) 2021 Aidan MacDonald
	11	*
	12	* This program is free software; you can redistribute it and/or
	13	* modify it under the terms of the GNU General Public License
	14	* as published by the Free Software Foundation; either version 2
	15	* of the License, or (at your option) any later version.
	16	*
	17	* This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY
	18	* KIND, either express or implied.
	19	*
	20	****************************************************************************/
	21
	22	#include "axp-pmu.h"
	23	#include "power.h"
	24	#include "system.h"
	25	#include "i2c-async.h"
	26	#include <string.h>
	27
	28	/* Headers for the debug menu */
	29	#ifndef BOOTLOADER
	30	# include "action.h"
	31	# include "list.h"
	32	# include <stdio.h>
	33	#endif
	34
	35	struct axp_adc_info {
	36	uint8_t reg;
	37	uint8_t en_reg;
	38	uint8_t en_bit;
	39	};
	40
	41	struct axp_supply_info {
	42	uint8_t volt_reg;
	43	uint8_t volt_reg_mask;
	44	uint8_t en_reg;
	45	uint8_t en_bit;
	46	int min_mV;
	47	int max_mV;
	48	int step_mV;
	49	};
	50
	51	static const struct axp_adc_info axp_adc_info[NUM_ADC_CHANNELS] = {
	52	{0x56, AXP_REG_ADCENABLE1, 5}, /* ACIN_VOLTAGE */
	53	{0x58, AXP_REG_ADCENABLE1, 4}, /* ACIN_CURRENT */
	54	{0x5a, AXP_REG_ADCENABLE1, 3}, /* VBUS_VOLTAGE */
	55	{0x5c, AXP_REG_ADCENABLE1, 2}, /* VBUS_CURRENT */
	56	{0x5e, AXP_REG_ADCENABLE2, 7}, /* INTERNAL_TEMP */
	57	{0x62, AXP_REG_ADCENABLE1, 1}, /* TS_INPUT */
	58	{0x78, AXP_REG_ADCENABLE1, 7}, /* BATTERY_VOLTAGE */
	59	{0x7a, AXP_REG_ADCENABLE1, 6}, /* CHARGE_CURRENT */
	60	{0x7c, AXP_REG_ADCENABLE1, 6}, /* DISCHARGE_CURRENT */
	61	{0x7e, AXP_REG_ADCENABLE1, 1}, /* APS_VOLTAGE */
	62	{0x70, 0xff, 0}, /* BATTERY_POWER */
	63	};
	64
	65	static const struct axp_supply_info axp_supply_info[AXP_NUM_SUPPLIES] = {
	66	#if HAVE_AXP_PMU == 192
	67	[AXP_SUPPLY_DCDC1] = {
	68	.volt_reg = 0x26,
	69	.volt_reg_mask = 0x7f,
	70	.en_reg = 0x12,
	71	.en_bit = 0,
	72	.min_mV = 700,
	73	.max_mV = 3500,
	74	.step_mV = 25,
	75	},
	76	[AXP_SUPPLY_DCDC2] = {
	77	.volt_reg = 0x23,
	78	.volt_reg_mask = 0x3f,
	79	.en_reg = 0x10,
	80	.en_bit = 0,
	81	.min_mV = 700,
	82	.max_mV = 2275,
	83	.step_mV = 25,
	84	},
	85	[AXP_SUPPLY_DCDC3] = {
	86	.volt_reg = 0x27,
	87	.volt_reg_mask = 0x7f,
	88	.en_reg = 0x12,
	89	.en_bit = 1,
	90	.min_mV = 700,
	91	.max_mV = 3500,
	92	.step_mV = 25,
	93	},
	94	/*
	95	* NOTE: LDO1 is always on, and we can't query it or change voltages
	96	*/
	97	[AXP_SUPPLY_LDO2] = {
	98	.volt_reg = 0x28,
	99	.volt_reg_mask = 0xf0,
	100	.en_reg = 0x12,
	101	.en_bit = 2,
	102	.min_mV = 1800,
	103	.max_mV = 3300,
	104	.step_mV = 100,
	105	},
	106	[AXP_SUPPLY_LDO3] = {
	107	.volt_reg = 0x28,
	108	.volt_reg_mask = 0x0f,
	109	.en_reg = 0x12,
	110	.en_bit = 3,
	111	.min_mV = 1800,
	112	.max_mV = 3300,
	113	.step_mV = 100,
	114	},
	115	[AXP_SUPPLY_LDO_IO0] = {
	116	.volt_reg = 0x91,
	117	.volt_reg_mask = 0xf0,
	118	.en_reg = 0x90,
	119	.en_bit = 0xff, /* this one requires special handling */
	120	.min_mV = 1800,
	121	.max_mV = 3300,
	122	.step_mV = 100,
	123	},
	124	#else
	125	# error "Untested AXP chip"
	126	#endif
	127	};
	128
	129	static struct axp_driver {
	130	int adc_enable;
	131	int chargecurrent_setting;
	132	int chip_id;
	133	} axp;
	134
	135	static void axp_init_enabled_adcs(void)
	136	{
	137	axp.adc_enable = 0;
	138
	139	/* Read chip ID, so we can display it on the debug screen.
	140	* This is undocumented but there's Linux driver code floating around
	141	* which suggests this should work for many AXP chips. */
	142	axp.chip_id = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_CHIP_ID);
	143
	144	/* Read enabled ADCs from the hardware */
	145	uint8_t regs[2];
	146	int rc = i2c_reg_read(AXP_PMU_BUS, AXP_PMU_ADDR,
	147	AXP_REG_ADCENABLE1, 2, &regs[0]);
	148	if(rc != I2C_STATUS_OK)
	149	return;
	150
	151	/* Parse registers to set ADC enable bits */
	152	const struct axp_adc_info* info = axp_adc_info;
	153	for(int i = 0; i < NUM_ADC_CHANNELS; ++i) {
	154	if(info[i].en_reg == 0xff)
	155	continue;
	156
	157	if(regs[info[i].en_reg - AXP_REG_ADCENABLE1] & info[i].en_bit)
	158	axp.adc_enable \|= 1 << i;
	159	}
	160
	161	/* Handle battery power ADC */
	162	if((axp.adc_enable & (1 << ADC_BATTERY_VOLTAGE)) &&
	163	(axp.adc_enable & (1 << ADC_DISCHARGE_CURRENT))) {
	164	axp.adc_enable \|= (1 << ADC_BATTERY_POWER);
	165	}
	166	}
	167
	168	void axp_init(void)
	169	{
	170	axp_init_enabled_adcs();
	171
	172	/* We need discharge current ADC to reliably poll for a full battery */
	173	int bits = axp.adc_enable;
	174	bits \|= (1 << ADC_DISCHARGE_CURRENT);
	175	axp_adc_set_enabled(bits);
	176
	177	/* Read the maximum charging current */
	178	int value = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_CHARGECONTROL1);
	179	axp.chargecurrent_setting = (value < 0) ? -1 : (value & 0xf);
	180	}
	181
	182	void axp_supply_set_voltage(int supply, int voltage)
	183	{
	184	const struct axp_supply_info* info = &axp_supply_info[supply];
	185	if(info->volt_reg == 0 \|\| info->volt_reg_mask == 0)
	186	return;
	187
	188	if(voltage > 0 && info->step_mV != 0) {
	189	if(voltage < info->min_mV \|\| voltage > info->max_mV)
	190	return;
	191
	192	int regval = (voltage - info->min_mV) / info->step_mV;
	193	i2c_reg_modify1(AXP_PMU_BUS, AXP_PMU_ADDR, info->volt_reg,
	194	info->volt_reg_mask, regval, NULL);
	195	}
	196
	197	if(info->en_bit != 0xff) {
	198	i2c_reg_setbit1(AXP_PMU_BUS, AXP_PMU_ADDR,
	199	info->en_reg, info->en_bit,
	200	voltage > 0 ? 1 : 0, NULL);
	201	}
	202	}
	203
	204	int axp_supply_get_voltage(int supply)
	205	{
	206	const struct axp_supply_info* info = &axp_supply_info[supply];
	207	if(info->volt_reg == 0)
	208	return AXP_SUPPLY_NOT_PRESENT;
	209
	210	if(info->en_reg != 0) {
	211	int r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, info->en_reg);
	212	if(r < 0)
	213	return AXP_SUPPLY_DISABLED;
	214
	215	#if HAVE_AXP_PMU == 192
	216	if(supply == AXP_SUPPLY_LDO_IO0) {
	217	if((r & 7) != 2)
	218	return AXP_SUPPLY_DISABLED;
	219	} else
	220	#endif
	221	{
	222	if(r & (1 << info->en_bit) == 0)
	223	return AXP_SUPPLY_DISABLED;
	224	}
	225	}
	226
	227	/* Hack, avoid undefined shift below. Can be useful too... */
	228	if(info->volt_reg_mask == 0)
	229	return info->min_mV;
	230
	231	int r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, info->volt_reg);
	232	if(r < 0)
	233	return 0;
	234
	235	int bit = find_first_set_bit(info->volt_reg_mask);
	236	int val = (r & info->volt_reg_mask) >> bit;
	237	return info->min_mV + (val * info->step_mV);
	238	}
	239
	240	/* TODO: this can STILL indicate some false positives! */
	241	int axp_battery_status(void)
	242	{
	243	int r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_POWERSTATUS);
	244	if(r >= 0) {
	245	/* Charging bit indicates we're currently charging */
	246	if((r & 0x04) != 0)
	247	return AXP_BATT_CHARGING;
	248
	249	/* Not plugged in means we're discharging */
	250	if((r & 0xf0) == 0)
	251	return AXP_BATT_DISCHARGING;
	252	} else {
	253	/* Report discharging if we can't find out power status */
	254	return AXP_BATT_DISCHARGING;
	255	}
	256
	257	/* If the battery is full and not in use, the charging bit will be 0,
	258	* there will be an external power source, AND the discharge current
	259	* will be zero. Seems to rule out all false positives. */
	260	int d = axp_adc_read_raw(ADC_DISCHARGE_CURRENT);
	261	if(d == 0)
	262	return AXP_BATT_FULL;
	263
	264	return AXP_BATT_DISCHARGING;
	265	}
	266
	267	int axp_input_status(void)
	268	{
	269	#ifdef HAVE_BATTERY_SWITCH
	270	int input_status = 0;
	271	#else
	272	int input_status = AXP_INPUT_BATTERY;
	273	#endif
	274
	275	int r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_POWERSTATUS);
	276	if(r < 0)
	277	return input_status;
	278
	279	/* Check for AC input */
	280	if(r & 0x80)
	281	input_status \|= AXP_INPUT_AC;
	282
	283	/* Only report USB if ACIN and VBUS are not shorted */
	284	if((r & 0x20) != 0 && (r & 0x02) == 0)
	285	input_status \|= AXP_INPUT_USB;
	286
	287	#ifdef HAVE_BATTERY_SWITCH
	288	/* Check for battery presence if target defines it as removable */
	289	r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_CHARGESTATUS);
	290	if(r >= 0 && (r & 0x20) != 0)
	291	input_status \|= AXP_INPUT_BATTERY;
	292	#endif
	293
	294	return input_status;
	295	}
	296
	297	int axp_adc_read(int adc)
	298	{
	299	int value = axp_adc_read_raw(adc);
	300	if(value == INT_MIN)
	301	return INT_MIN;
	302
	303	return axp_adc_conv_raw(adc, value);
	304	}
	305
	306	int axp_adc_read_raw(int adc)
	307	{
	308	/* Don't give a reading if the ADC is not enabled */
	309	if((axp.adc_enable & (1 << adc)) == 0)
	310	return INT_MIN;
	311
	312	/* Read the ADC */
	313	uint8_t buf[3];
	314	int count = (adc == ADC_BATTERY_POWER) ? 3 : 2;
	315	uint8_t reg = axp_adc_info[adc].reg;
	316	int rc = i2c_reg_read(AXP_PMU_BUS, AXP_PMU_ADDR, reg, count, &buf[0]);
	317	if(rc != I2C_STATUS_OK)
	318	return INT_MIN;
	319
	320	/* Parse the value */
	321	if(adc == ADC_BATTERY_POWER)
	322	return (buf[0] << 16) \| (buf[1] << 8) \| buf[2];
	323	else if(adc == ADC_CHARGE_CURRENT \|\| adc == ADC_DISCHARGE_CURRENT)
	324	return (buf[0] << 5) \| (buf[1] & 0x1f);
	325	else
	326	return (buf[0] << 4) \| (buf[1] & 0xf);
	327	}
	328
	329	int axp_adc_conv_raw(int adc, int value)
	330	{
	331	switch(adc) {
	332	case ADC_ACIN_VOLTAGE:
	333	case ADC_VBUS_VOLTAGE:
	334	/* 0 mV ... 6.9615 mV, step 1.7 mV */
	335	return value * 17 / 10;
	336	case ADC_ACIN_CURRENT:
	337	/* 0 mA ... 2.5594 A, step 0.625 mA */
	338	return value * 5 / 8;
	339	case ADC_VBUS_CURRENT:
	340	/* 0 mA ... 1.5356 A, step 0.375 mA */
	341	return value * 3 / 8;
	342	case ADC_INTERNAL_TEMP:
	343	/* -144.7 C ... 264.8 C, step 0.1 C */
	344	return value - 1447;
	345	case ADC_TS_INPUT:
	346	/* 0 mV ... 3.276 V, step 0.8 mV */
	347	return value * 4 / 5;
	348	case ADC_BATTERY_VOLTAGE:
	349	/* 0 mV ... 4.5045 V, step 1.1 mV */
	350	return value * 11 / 10;
	351	case ADC_CHARGE_CURRENT:
	352	case ADC_DISCHARGE_CURRENT:
	353	/* 0 mA to 4.095 A, step 0.5 mA */
	354	return value / 2;
	355	case ADC_APS_VOLTAGE:
	356	/* 0 mV to 5.733 V, step 1.4 mV */
	357	return value * 7 / 5;
	358	case ADC_BATTERY_POWER:
	359	/* 0 uW to 23.6404 W, step 0.55 uW */
	360	return value * 11 / 20;
	361	default:
	362	/* Shouldn't happen */
	363	return INT_MIN;
	364	}
	365	}
	366
	367	int axp_adc_get_enabled(void)
	368	{
	369	return axp.adc_enable;
	370	}
	371
	372	void axp_adc_set_enabled(int adc_bits)
	373	{
	374	/* Ignore no-op */
	375	if(adc_bits == axp.adc_enable)
	376	return;
	377
	378	/* Compute the new register values */
	379	const struct axp_adc_info* info = axp_adc_info;
	380	uint8_t regs[2] = {0, 0};
	381	for(int i = 0; i < NUM_ADC_CHANNELS; ++i) {
	382	if(info[i].en_reg == 0xff)
	383	continue;
	384
	385	if(adc_bits & (1 << i))
	386	regs[info[i].en_reg - 0x82] \|= 1 << info[i].en_bit;
	387	}
	388
	389	/* These ADCs share an enable bit */
	390	if(adc_bits & ((1 << ADC_CHARGE_CURRENT)\|(1 << ADC_DISCHARGE_CURRENT))) {
	391	adc_bits \|= (1 << ADC_CHARGE_CURRENT);
	392	adc_bits \|= (1 << ADC_DISCHARGE_CURRENT);
	393	}
	394
	395	/* Enable required bits for battery power ADC */
	396	if(adc_bits & (1 << ADC_BATTERY_POWER)) {
	397	regs[0] \|= 1 << info[ADC_DISCHARGE_CURRENT].en_bit;
	398	regs[0] \|= 1 << info[ADC_BATTERY_VOLTAGE].en_bit;
	399	}
	400
	401	/* Update the configuration */
	402	i2c_reg_write(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_ADCENABLE1, 2, &regs[0]);
	403	axp.adc_enable = adc_bits;
	404	}
	405
	406	int axp_adc_get_rate(void)
	407	{
	408	int r = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_ADCSAMPLERATE);
	409	if(r < 0)
	410	return AXP_ADC_RATE_100HZ; /* an arbitrary value */
	411
	412	return (r >> 6) & 3;
	413	}
	414
	415	void axp_adc_set_rate(int rate)
	416	{
	417	i2c_reg_modify1(AXP_PMU_BUS, AXP_PMU_ADDR, AXP_REG_ADCSAMPLERATE,
	418	0xc0, (rate & 3) << 6, NULL);
	419	}
	420
	421	static uint32_t axp_cc_parse(const uint8_t* buf)
	422	{
	423	return ((uint32_t)buf[0] << 24) \| (buf[1] << 16) \| (buf[2] << 8) \| buf[3];
	424	}
	425
	426	void axp_cc_read(uint32_t* charge, uint32_t* discharge)
	427	{
	428	uint8_t buf[8];
	429	int rc = i2c_reg_read(AXP_PMU_BUS, AXP_PMU_ADDR,
	430	AXP_REG_COULOMBCOUNTERBASE, 8, &buf[0]);
	431	if(rc != I2C_STATUS_OK) {
	432	if(charge)
	433	*charge = 0;
	434	if(discharge)
	435	*discharge = 0;
	436	return;
	437	}
	438
	439	if(charge)
	440	*charge = axp_cc_parse(&buf[0]);
	441	if(discharge)
	442	*discharge = axp_cc_parse(&buf[4]);
	443	}
	444
	445	void axp_cc_clear(void)
	446	{
	447	i2c_reg_setbit1(AXP_PMU_BUS, AXP_PMU_ADDR,
	448	AXP_REG_COULOMBCOUNTERCTRL, 5, 1, NULL);
	449	}
	450
	451	void axp_cc_enable(bool en)
	452	{
	453	i2c_reg_setbit1(AXP_PMU_BUS, AXP_PMU_ADDR,
	454	AXP_REG_COULOMBCOUNTERCTRL, 7, en ? 1 : 0, NULL);
	455	}
	456
	457	bool axp_cc_is_enabled(void)
	458	{
	459	int reg = i2c_reg_read1(AXP_PMU_BUS, AXP_PMU_ADDR,
	460	AXP_REG_COULOMBCOUNTERCTRL);
	461	return reg >= 0 && (reg & 0x40) != 0;
	462	}
	463
	464	static const int chargecurrent_tbl[] = {
	465	100, 190, 280, 360,
	466	450, 550, 630, 700,
	467	780, 880, 960, 1000,
	468	1080, 1160, 1240, 1320,
	469	};
	470
	471	static const int chargecurrent_tblsz = sizeof(chargecurrent_tbl)/sizeof(int);
	472
	473	void axp_set_charge_current(int maxcurrent)
	474	{
	475	/* Find the charge current just higher than maxcurrent */
	476	int value = 0;
	477	while(value < chargecurrent_tblsz &&
	478	chargecurrent_tbl[value] <= maxcurrent)
	479	++value;
	480
	481	/* Select the next lower current, the greatest current <= maxcurrent */
	482	if(value >= chargecurrent_tblsz)
	483	value = chargecurrent_tblsz - 1;
	484	else if(value > 0)
	485	--value;
	486
	487	/* Don't issue i2c write if desired setting is already in use */
	488	if(value == axp.chargecurrent_setting)
	489	return;
	490
	491	/* Update register */
	492	i2c_reg_modify1(AXP_PMU_BUS, AXP_PMU_ADDR,
	493	AXP_REG_CHARGECONTROL1, 0x0f, value, NULL);
	494	axp.chargecurrent_setting = value;
	495	}
	496
	497	int axp_get_charge_current(void)
	498	{
	499	if(axp.chargecurrent_setting < 0)
	500	return chargecurrent_tbl[0];
	501	else
	502	return chargecurrent_tbl[axp.chargecurrent_setting];
	503	}
	504
	505	void axp_power_off(void)
	506	{
	507	/* Set the shutdown bit */
	508	i2c_reg_setbit1(AXP_PMU_BUS, AXP_PMU_ADDR,
	509	AXP_REG_SHUTDOWNLEDCTRL, 7, 1, NULL);
	510	}
	511
	512	#ifndef BOOTLOADER
	513	enum {
	514	AXP_DEBUG_CHIP_ID,
	515	AXP_DEBUG_BATTERY_STATUS,
	516	AXP_DEBUG_INPUT_STATUS,
	517	AXP_DEBUG_CHARGE_CURRENT,
	518	AXP_DEBUG_COULOMB_COUNTERS,
	519	AXP_DEBUG_ADC_RATE,
	520	AXP_DEBUG_FIRST_ADC,
	521	AXP_DEBUG_FIRST_SUPPLY = AXP_DEBUG_FIRST_ADC + NUM_ADC_CHANNELS,
	522	AXP_DEBUG_NUM_ENTRIES = AXP_DEBUG_FIRST_SUPPLY + AXP_NUM_SUPPLIES,
	523	};
	524
	525	static int axp_debug_menu_cb(int action, struct gui_synclist* lists)
	526	{
	527	(void)lists;
	528
	529	if(action == ACTION_NONE)
	530	action = ACTION_REDRAW;
	531
	532	return action;
	533	}
	534
	535	static const char* axp_debug_menu_get_name(int item, void* data,
	536	char* buf, size_t buflen)
	537	{
	538	(void)data;
	539
	540	static const char* const adc_names[] = {
	541	"V_acin", "I_acin", "V_vbus", "I_vbus", "T_int",
	542	"V_ts", "V_batt", "I_chrg", "I_dchg", "V_aps", "P_batt"
	543	};
	544
	545	static const char* const adc_units[] = {
	546	"mV", "mA", "mV", "mA", "C", "mV", "mV", "mA", "mA", "mV", "uW",
	547	};
	548
	549	static const char* const supply_names[] = {
	550	"DCDC1", "DCDC2", "DCDC3",
	551	"LDO1", "LDO2", "LDO3", "LDO_IO0",
	552	};
	553
	554	int adc = item - AXP_DEBUG_FIRST_ADC;
	555	if(item >= AXP_DEBUG_FIRST_ADC && adc < NUM_ADC_CHANNELS) {
	556	int raw_value = axp_adc_read_raw(adc);
	557	if(raw_value == INT_MIN) {
	558	snprintf(buf, buflen, "%s: [Disabled]", adc_names[adc]);
	559	return buf;
	560	}
	561
	562	int value = axp_adc_conv_raw(adc, raw_value);
	563	if(adc == ADC_INTERNAL_TEMP) {
	564	snprintf(buf, buflen, "%s: %d.%d %s", adc_names[adc],
	565	value/10, value%10, adc_units[adc]);
	566	} else {
	567	snprintf(buf, buflen, "%s: %d %s", adc_names[adc],
	568	value, adc_units[adc]);
	569	}
	570
	571	return buf;
	572	}
	573
	574	int supply = item - AXP_DEBUG_FIRST_SUPPLY;
	575	if(item >= AXP_DEBUG_FIRST_SUPPLY && supply < AXP_NUM_SUPPLIES) {
	576	int voltage = axp_supply_get_voltage(supply);
	577	if(voltage == AXP_SUPPLY_NOT_PRESENT)
	578	snprintf(buf, buflen, "%s: [Not Present]", supply_names[supply]);
	579	else if(voltage == AXP_SUPPLY_DISABLED)
	580	snprintf(buf, buflen, "%s: [Disabled]", supply_names[supply]);
	581	else
	582	snprintf(buf, buflen, "%s: %d mV", supply_names[supply], voltage);
	583
	584	return buf;
	585	}
	586
	587	switch(item) {
	588	case AXP_DEBUG_CHIP_ID: {
	589	snprintf(buf, buflen, "Chip ID: %d (%02x) [Driver: AXP%d]",
	590	axp.chip_id, axp.chip_id, HAVE_AXP_PMU);
	591	return buf;
	592	} break;
	593
	594	case AXP_DEBUG_BATTERY_STATUS: {
	595	switch(axp_battery_status()) {
	596	case AXP_BATT_FULL:
	597	return "Battery: Full";
	598	case AXP_BATT_CHARGING:
	599	return "Battery: Charging";
	600	case AXP_BATT_DISCHARGING:
	601	return "Battery: Discharging";
	602	default:
	603	return "Battery: Unknown";
	604	}
	605	} break;
	606
	607	case AXP_DEBUG_INPUT_STATUS: {
	608	int s = axp_input_status();
	609	const char* ac = (s & AXP_INPUT_AC) ? " AC" : "";
	610	const char* usb = (s & AXP_INPUT_USB) ? " USB" : "";
	611	const char* batt = (s & AXP_INPUT_BATTERY) ? " Battery" : "";
	612	snprintf(buf, buflen, "Inputs:%s%s%s", ac, usb, batt);
	613	return buf;
	614	} break;
	615
	616	case AXP_DEBUG_CHARGE_CURRENT: {
	617	int current = axp_get_charge_current();
	618	snprintf(buf, buflen, "Max charge current: %d mA", current);
	619	return buf;
	620	} break;
	621
	622	case AXP_DEBUG_COULOMB_COUNTERS: {
	623	uint32_t charge, discharge;
	624	axp_cc_read(&charge, &discharge);
	625
	626	snprintf(buf, buflen, "Coulomb counters: +%lu / -%lu",
	627	(unsigned long)charge, (unsigned long)discharge);
	628	return buf;
	629	} break;
	630
	631	case AXP_DEBUG_ADC_RATE: {
	632	int rate = 25 << axp_adc_get_rate();
	633	snprintf(buf, buflen, "ADC sample rate: %d Hz", rate);
	634	return buf;
	635	} break;
	636
	637	default:
	638	return "---";
	639	}
	640	}
	641
	642	bool axp_debug_menu(void)
	643	{
	644	struct simplelist_info info;
	645	simplelist_info_init(&info, "AXP debug", AXP_DEBUG_NUM_ENTRIES, NULL);
	646	info.action_callback = axp_debug_menu_cb;
	647	info.get_name = axp_debug_menu_get_name;
	648	return simplelist_show_list(&info);
	649	}
	650	#endif /* !BOOTLOADER */
	651
	652	/* This is basically the only valid implementation, so define it here */
	653	unsigned int power_input_status(void)
	654	{
	655	unsigned int state = 0;
	656	int input_status = axp_input_status();
	657
	658	if(input_status & AXP_INPUT_AC)
	659	state \|= POWER_INPUT_MAIN_CHARGER;
	660
	661	if(input_status & AXP_INPUT_USB)
	662	state \|= POWER_INPUT_USB_CHARGER;
	663
	664	#ifdef HAVE_BATTERY_SWITCH
	665	if(input_status & AXP_INPUT_BATTERY)
	666	state \|= POWER_INPUT_BATTERY;
	667	#endif
	668
	669	return state;
	670	}