/* Copyright 2019 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ /* * IDT P9221-R7 Wireless Power Receiver driver. */ #include "p9221.h" #include "charge_manager.h" #include "chipset.h" #include "common.h" #include "console.h" #include "gpio.h" #include "hooks.h" #include "power.h" #include "tcpm/tcpm.h" #include "timer.h" #include "usb_charge.h" #include "usb_pd.h" #include "util.h" #include #include "printf.h" #define CPRINTS(format, args...) cprints(CC_USBPD, "WPC " format, ## args) #define P9221_TX_TIMEOUT_MS (20 * 1000*1000) #define P9221_DCIN_TIMEOUT_MS (2 * 1000*1000) #define P9221_VRECT_TIMEOUT_MS (2 * 1000*1000) #define P9221_NOTIFIER_DELAY_MS (80*1000) #define P9221R7_ILIM_MAX_UA (1600 * 1000) #define P9221R7_OVER_CHECK_NUM 3 #define OVC_LIMIT 1 #define OVC_THRESHOLD 1400000 #define OVC_BACKOFF_LIMIT 900000 #define OVC_BACKOFF_AMOUNT 100000 /* P9221 parameters */ static struct wpc_charger_info p9221_charger_info = { .online = false, .i2c_port = I2C_PORT_WPC, .pp_buf_valid = false, }; static struct wpc_charger_info *wpc = &p9221_charger_info; static void p9221_set_offline(void); static const uint32_t p9221_ov_set_lut[] = { 17000000, 20000000, 15000000, 13000000, 11000000, 11000000, 11000000, 11000000 }; static int p9221_reg_is_8_bit(uint16_t reg) { switch (reg) { case P9221_CHIP_REVISION_REG: case P9221R7_VOUT_SET_REG: case P9221R7_ILIM_SET_REG: case P9221R7_CHARGE_STAT_REG: case P9221R7_EPT_REG: case P9221R7_SYSTEM_MODE_REG: case P9221R7_COM_CHAN_RESET_REG: case P9221R7_COM_CHAN_SEND_SIZE_REG: case P9221R7_COM_CHAN_SEND_IDX_REG: case P9221R7_COM_CHAN_RECV_SIZE_REG: case P9221R7_COM_CHAN_RECV_IDX_REG: case P9221R7_DEBUG_REG: case P9221R7_EPP_Q_FACTOR_REG: case P9221R7_EPP_TX_GUARANTEED_POWER_REG: case P9221R7_EPP_TX_POTENTIAL_POWER_REG: case P9221R7_EPP_TX_CAPABILITY_FLAGS_REG: case P9221R7_EPP_RENEGOTIATION_REG: case P9221R7_EPP_CUR_RPP_HEADER_REG: case P9221R7_EPP_CUR_NEGOTIATED_POWER_REG: case P9221R7_EPP_CUR_MAXIMUM_POWER_REG: case P9221R7_EPP_CUR_FSK_MODULATION_REG: case P9221R7_EPP_REQ_RPP_HEADER_REG: case P9221R7_EPP_REQ_NEGOTIATED_POWER_REG: case P9221R7_EPP_REQ_MAXIMUM_POWER_REG: case P9221R7_EPP_REQ_FSK_MODULATION_REG: case P9221R7_VRECT_TARGET_REG: case P9221R7_VRECT_KNEE_REG: case P9221R7_FOD_SECTION_REG: case P9221R7_VRECT_ADJ_REG: case P9221R7_ALIGN_X_ADC_REG: case P9221R7_ALIGN_Y_ADC_REG: case P9221R7_ASK_MODULATION_DEPTH_REG: case P9221R7_OVSET_REG: case P9221R7_EPP_TX_SPEC_REV_REG: return true; default: return false; } } static int p9221_read8(uint16_t reg, int *val) { return i2c_read_offset16(wpc->i2c_port, P9221_R7_ADDR_FLAGS, reg, val, 1); } static int p9221_write8(uint16_t reg, int val) { return i2c_write_offset16(wpc->i2c_port, P9221_R7_ADDR_FLAGS, reg, val, 1); } static int p9221_read16(uint16_t reg, int *val) { return i2c_read_offset16(wpc->i2c_port, P9221_R7_ADDR_FLAGS, reg, val, 2); } static int p9221_write16(uint16_t reg, int val) { return i2c_write_offset16(wpc->i2c_port, P9221_R7_ADDR_FLAGS, reg, val, 2); } static int p9221_block_read(uint16_t reg, uint8_t *data, int len) { return i2c_read_offset16_block(wpc->i2c_port, P9221_R7_ADDR_FLAGS, reg, data, len); } static int p9221_block_write(uint16_t reg, uint8_t *data, int len) { return i2c_write_offset16_block(wpc->i2c_port, P9221_R7_ADDR_FLAGS, reg, data, len); } static int p9221_set_cmd_reg(uint8_t cmd) { int cur_cmd; int retry; int ret; for (retry = 0; retry < P9221_COM_CHAN_RETRIES; retry++) { ret = p9221_read8(P9221_COM_REG, &cur_cmd); if (ret == EC_SUCCESS && cur_cmd == 0) break; msleep(25); } if (retry >= P9221_COM_CHAN_RETRIES) { CPRINTS("Failed to wait for cmd free %02x", cur_cmd); return EC_ERROR_TIMEOUT; } ret = p9221_write8(P9221_COM_REG, cmd); if (ret) CPRINTS("Failed to set cmd reg %02x: %d", cmd, ret); return ret; } /* Convert a register value to uV, Hz, or uA */ static int p9221_convert_reg_r7(uint16_t reg, uint16_t raw_data, uint32_t *val) { switch (reg) { case P9221R7_ALIGN_X_ADC_REG: /* raw */ case P9221R7_ALIGN_Y_ADC_REG: /* raw */ *val = raw_data; break; case P9221R7_VOUT_ADC_REG: /* 12-bit ADC raw */ case P9221R7_IOUT_ADC_REG: /* 12-bit ADC raw */ case P9221R7_DIE_TEMP_ADC_REG: /* 12-bit ADC raw */ case P9221R7_EXT_TEMP_REG: *val = raw_data & 0xFFF; break; case P9221R7_VOUT_SET_REG: /* 0.1V -> uV */ *val = raw_data * 100 * 1000; break; case P9221R7_IOUT_REG: /* mA -> uA */ case P9221R7_VRECT_REG: /* mV -> uV */ case P9221R7_VOUT_REG: /* mV -> uV */ case P9221R7_OP_FREQ_REG: /* kHz -> Hz */ case P9221R7_TX_PINGFREQ_REG: /* kHz -> Hz */ *val = raw_data * 1000; break; case P9221R7_ILIM_SET_REG: /* 100mA -> uA, 200mA offset */ *val = ((raw_data * 100) + 200) * 1000; break; case P9221R7_OVSET_REG: /* uV */ raw_data &= P9221R7_OVSET_MASK; *val = p9221_ov_set_lut[raw_data]; break; default: return -2; } return 0; } static int p9221_reg_read_converted(uint16_t reg, uint32_t *val) { int ret; int data; if (p9221_reg_is_8_bit(reg)) ret = p9221_read8(reg, &data); else ret = p9221_read16(reg, &data); if (ret) return ret; return p9221_convert_reg_r7(reg, data, val); } static int p9221_is_online(void) { int chip_id; if (p9221_read16(P9221_CHIP_ID_REG, &chip_id) || chip_id != P9221_CHIP_ID) return false; else return true; } int wpc_chip_is_online(void) { return p9221_is_online(); } void p9221_interrupt(enum gpio_signal signal) { task_wake(TASK_ID_WPC); } static int p9221r7_clear_interrupts(uint16_t mask) { int ret; ret = p9221_write16(P9221R7_INT_CLEAR_REG, mask); if (ret) { CPRINTS("Failed to clear INT reg: %d", ret); return ret; } ret = p9221_set_cmd_reg(P9221_COM_CLEAR_INT_MASK); if (ret) CPRINTS("Failed to reset INT: %d", ret); return ret; } /* * Enable interrupts on the P9221 R7, note we don't really need to disable * interrupts since when the device goes out of field, the P9221 is reset. */ static int p9221_enable_interrupts_r7(void) { uint16_t mask = 0; int ret; CPRINTS("Enable interrupts"); mask = P9221R7_STAT_LIMIT_MASK | P9221R7_STAT_CC_MASK | P9221_STAT_VRECT; p9221r7_clear_interrupts(mask); ret = p9221_write8(P9221_INT_ENABLE_REG, mask); if (ret) CPRINTS("Failed to enable INTs: %d", ret); return ret; } static int p9221_send_csp(uint8_t status) { int ret; CPRINTS("Send CSP=%d", status); mutex_lock(&wpc->cmd_lock); ret = p9221_write8(P9221R7_CHARGE_STAT_REG, status); if (ret == EC_SUCCESS) ret = p9221_set_cmd_reg(P9221R7_COM_SENDCSP); mutex_unlock(&wpc->cmd_lock); return ret; } static int p9221_send_eop(uint8_t reason) { int rv; CPRINTS("Send EOP reason=%d", reason); mutex_lock(&wpc->cmd_lock); rv = p9221_write8(P9221R7_EPT_REG, reason); if (rv == EC_SUCCESS) rv = p9221_set_cmd_reg(P9221R7_COM_SENDEPT); mutex_unlock(&wpc->cmd_lock); return rv; } static void print_current_samples(uint32_t *iout_val, int count) { int i; char temp[P9221R7_OVER_CHECK_NUM * 9 + 1] = { 0 }; for (i = 0; i < count ; i++) snprintf(temp + i * 9, sizeof(temp) - i * 9, "%08x ", iout_val[i]); CPRINTS("OVER IOUT_SAMPLES: %s", temp); } /* * Number of times to poll the status to see if the current limit condition * was transient or not. */ static void p9221_limit_handler_r7(uint16_t orign_irq_src) { uint8_t reason; int i; int ret; int ovc_count = 0; uint32_t iout_val[P9221R7_OVER_CHECK_NUM] = { 0 }; int irq_src = (int)orign_irq_src; CPRINTS("OVER INT: %02x", irq_src); if (irq_src & P9221R7_STAT_OVV) { reason = P9221_EOP_OVER_VOLT; goto send_eop; } if (irq_src & P9221R7_STAT_OVT) { reason = P9221_EOP_OVER_TEMP; goto send_eop; } if ((irq_src & P9221R7_STAT_UV) && !(irq_src & P9221R7_STAT_OVC)) return; reason = P9221_EOP_OVER_CURRENT; for (i = 0; i < P9221R7_OVER_CHECK_NUM; i++) { ret = p9221r7_clear_interrupts( irq_src & P9221R7_STAT_LIMIT_MASK); msleep(50); if (ret) continue; ret = p9221_reg_read_converted(P9221R7_IOUT_REG, &iout_val[i]); if (ret) { CPRINTS("Failed to read IOUT[%d]: %d", i, ret); continue; } else if (iout_val[i] > OVC_THRESHOLD) { ovc_count++; } ret = p9221_read16(P9221_STATUS_REG, &irq_src); if (ret) { CPRINTS("Failed to read status: %d", ret); continue; } if ((irq_src & P9221R7_STAT_OVC) == 0) { print_current_samples(iout_val, i + 1); CPRINTS("OVER condition %04x cleared after %d tries", irq_src, i); return; } CPRINTS("OVER status is still %04x, retry", irq_src); } if (ovc_count < OVC_LIMIT) { print_current_samples(iout_val, P9221R7_OVER_CHECK_NUM); CPRINTS("ovc_threshold=%d, ovc_count=%d, ovc_limit=%d", OVC_THRESHOLD, ovc_count, OVC_LIMIT); return; } send_eop: CPRINTS("OVER is %04x, sending EOP %d", irq_src, reason); ret = p9221_send_eop(reason); if (ret) CPRINTS("Failed to send EOP %d: %d", reason, ret); } static void p9221_abort_transfers(void) { wpc->tx_busy = false; wpc->tx_done = true; wpc->rx_done = true; wpc->rx_len = 0; } /* Handler for r7 and R7 chips */ static void p9221r7_irq_handler(uint16_t irq_src) { int res; if (irq_src & P9221R7_STAT_LIMIT_MASK) p9221_limit_handler_r7(irq_src); /* Receive complete */ if (irq_src & P9221R7_STAT_CCDATARCVD) { int rxlen = 0; res = p9221_read8(P9221R7_COM_CHAN_RECV_SIZE_REG, &rxlen); if (res) CPRINTS("Failed to read len: %d", res); if (rxlen) { res = p9221_block_read(P9221R7_DATA_RECV_BUF_START, wpc->rx_buf, rxlen); if (res) { CPRINTS("Failed to read CC data: %d", res); rxlen = 0; } wpc->rx_len = rxlen; wpc->rx_done = true; } } /* Send complete */ if (irq_src & P9221R7_STAT_CCSENDBUSY) { wpc->tx_busy = false; wpc->tx_done = true; } /* Proprietary packet */ if (irq_src & P9221R7_STAT_PPRCVD) { res = p9221_block_read(P9221R7_DATA_RECV_BUF_START, wpc->pp_buf, sizeof(wpc->pp_buf)); if (res) { CPRINTS("Failed to read PP: %d", res); wpc->pp_buf_valid = false; return; } /* We only care about PP which come with 0x4F header */ wpc->pp_buf_valid = (wpc->pp_buf[0] == 0x4F); hexdump(wpc->pp_buf, sizeof(wpc->pp_buf)); } /* CC Reset complete */ if (irq_src & P9221R7_STAT_CCRESET) p9221_abort_transfers(); } static int p9221_is_epp(void) { int ret, reg; uint32_t vout_uv; if (p9221_read8(P9221R7_SYSTEM_MODE_REG, ®) == EC_SUCCESS) return reg & P9221R7_SYSTEM_MODE_EXTENDED_MASK; /* Check based on power supply voltage */ ret = p9221_reg_read_converted(P9221R7_VOUT_ADC_REG, &vout_uv); if (ret) { CPRINTS("Failed to read VOUT_ADC: %d", ret); return false; } CPRINTS("Voltage is %duV", vout_uv); if (vout_uv > P9221_EPP_THRESHOLD_UV) return true; return false; } static void p9221_config_fod(void) { int epp; uint8_t *fod; int fod_len; int ret; int retries = 3; CPRINTS("Config FOD"); epp = p9221_is_epp(); fod_len = epp ? board_get_epp_fod(&fod) : board_get_fod(&fod); if (!fod_len || !fod) { CPRINTS("FOD data not found"); return; } while (retries) { uint8_t fod_read[fod_len]; CPRINTS("Writing %s FOD (n=%d try=%d)", epp ? "EPP" : "BPP", fod_len, retries); ret = p9221_block_write(P9221R7_FOD_REG, fod, fod_len); if (ret) goto no_fod; /* Verify the FOD has been written properly */ ret = p9221_block_read(P9221R7_FOD_REG, fod_read, fod_len); if (ret) goto no_fod; if (memcmp(fod, fod_read, fod_len) == 0) return; hexdump(fod_read, fod_len); retries--; msleep(100); } no_fod: CPRINTS("Failed to set FOD. retries:%d ret:%d", retries, ret); } static void p9221_set_online(void) { int ret; CPRINTS("Set online"); wpc->online = true; wpc->tx_busy = false; wpc->tx_done = true; wpc->rx_done = false; wpc->charge_supplier = CHARGE_SUPPLIER_WPC_BPP; ret = p9221_enable_interrupts_r7(); if (ret) CPRINTS("Failed to enable INT: %d", ret); /* NOTE: depends on _is_epp() which is not valid until DC_IN */ p9221_config_fod(); } static void p9221_vbus_check_timeout(void) { CPRINTS("Timeout VBUS, online=%d", wpc->online); if (wpc->online) p9221_set_offline(); } DECLARE_DEFERRED(p9221_vbus_check_timeout); static void p9221_set_offline(void) { CPRINTS("Set offline"); wpc->online = false; /* Reset PP buf so we can get a new serial number next time around */ wpc->pp_buf_valid = false; p9221_abort_transfers(); hook_call_deferred(&p9221_vbus_check_timeout_data, -1); } /* P9221_NOTIFIER_DELAY_MS from VRECTON */ static int p9221_notifier_check_det(void) { if (wpc->online) goto done; /* send out a FOD but is_epp() is still invalid */ p9221_set_online(); /* Give the vbus 2 seconds to come up. */ CPRINTS("Waiting VBUS"); hook_call_deferred(&p9221_vbus_check_timeout_data, -1); hook_call_deferred(&p9221_vbus_check_timeout_data, P9221_DCIN_TIMEOUT_MS); done: wpc->p9221_check_det = false; return 0; } static int p9221_get_charge_supplier(void) { if (!wpc->online) return EC_ERROR_UNKNOWN; if (p9221_is_epp()) { uint32_t tx_id; int txmf_id; int ret; wpc->charge_supplier = CHARGE_SUPPLIER_WPC_EPP; ret = p9221_read16(P9221R7_EPP_TX_MFG_CODE_REG, &txmf_id); if (ret || txmf_id != P9221_GPP_TX_MF_ID) return ret; ret = p9221_block_read(P9221R7_PROP_TX_ID_REG, (uint8_t *) &tx_id, P9221R7_PROP_TX_ID_SIZE); if (ret) return ret; if (tx_id & P9221R7_PROP_TX_ID_GPP_MASK) wpc->charge_supplier = CHARGE_SUPPLIER_WPC_GPP; CPRINTS("txmf_id=0x%04x tx_id=0x%08x supplier=%d", txmf_id, tx_id, wpc->charge_supplier); } else { wpc->charge_supplier = CHARGE_SUPPLIER_WPC_BPP; CPRINTS("supplier=%d", wpc->charge_supplier); } return EC_SUCCESS; } static int p9221_get_icl(int charge_supplier) { switch (charge_supplier) { case CHARGE_SUPPLIER_WPC_EPP: case CHARGE_SUPPLIER_WPC_GPP: return P9221_DC_ICL_EPP_MA; case CHARGE_SUPPLIER_WPC_BPP: default: return P9221_DC_ICL_BPP_MA; } } static int p9221_get_ivl(int charge_supplier) { switch (charge_supplier) { case CHARGE_SUPPLIER_WPC_EPP: case CHARGE_SUPPLIER_WPC_GPP: return P9221_DC_IVL_EPP_MV; case CHARGE_SUPPLIER_WPC_BPP: default: return P9221_DC_IVL_BPP_MV; } } static void p9221_update_charger(int type, struct charge_port_info *chg) { if (!chg) charge_manager_update_dualrole(0, CAP_UNKNOWN); else charge_manager_update_dualrole(0, CAP_DEDICATED); charge_manager_update_charge(type, 0, chg); } static int p9221_reg_write_converted_r7(uint16_t reg, uint32_t val) { int ret = 0; uint16_t data; int i; /* Do the appropriate conversion */ switch (reg) { case P9221R7_ILIM_SET_REG: /* uA -> 0.1A, offset 0.2A */ if ((val < 200000) || (val > 1600000)) return -EC_ERROR_INVAL; data = (val / (100 * 1000)) - 2; break; case P9221R7_VOUT_SET_REG: /* uV -> 0.1V */ val /= 1000; if (val < 3500 || val > 9000) return -EC_ERROR_INVAL; data = val / 100; break; case P9221R7_OVSET_REG: /* uV */ for (i = 0; i < ARRAY_SIZE(p9221_ov_set_lut); i++) { if (val == p9221_ov_set_lut[i]) break; } if (i == ARRAY_SIZE(p9221_ov_set_lut)) return -EC_ERROR_INVAL; data = i; break; default: return -EC_ERROR_INVAL; } if (p9221_reg_is_8_bit(reg)) ret = p9221_write8(reg, data); else ret = p9221_write16(reg, data); return ret; } static int p9221_set_dc_icl(void) { /* Increase the IOUT limit */ if (p9221_reg_write_converted_r7(P9221R7_ILIM_SET_REG, P9221R7_ILIM_MAX_UA)) CPRINTS("%s set rx_iout limit fail.", __func__); return EC_SUCCESS; } static void p9221_notifier_check_vbus(void) { struct charge_port_info chg; wpc->p9221_check_vbus = false; CPRINTS("%s online:%d vbus:%d", __func__, wpc->online, wpc->vbus_status); /* * We now have confirmation from DC_IN, kill the timer, p9221_online * will be set by this function. */ hook_call_deferred(&p9221_vbus_check_timeout_data, -1); if (wpc->vbus_status) { /* WPC VBUS on ,Always write FOD, check dc_icl, send CSP */ p9221_set_dc_icl(); p9221_config_fod(); p9221_send_csp(1); /* when wpc vbus attached after 2s, set wpc online */ if (!wpc->online) p9221_set_online(); /* WPC VBUS on , update charge voltage and current */ p9221_get_charge_supplier(); chg.voltage = p9221_get_ivl(wpc->charge_supplier); chg.current = p9221_get_icl(wpc->charge_supplier); p9221_update_charger(wpc->charge_supplier, &chg); } else { /* * Vbus detached, set wpc offline and update wpc charge voltage * and current to zero. */ if (wpc->online) { p9221_set_offline(); p9221_update_charger(wpc->charge_supplier, NULL); } } CPRINTS("check_vbus changed on:%d vbus:%d", wpc->online, wpc->vbus_status); } static void p9221_detect_work(void) { CPRINTS("%s online:%d check_vbus:%d check_det:%d vbus:%d", __func__, wpc->online, wpc->p9221_check_vbus, wpc->p9221_check_det, wpc->vbus_status); /* Step 1 */ if (wpc->p9221_check_det) p9221_notifier_check_det(); /* Step 2 */ if (wpc->p9221_check_vbus) p9221_notifier_check_vbus(); } DECLARE_DEFERRED(p9221_detect_work); void p9221_notify_vbus_change(int vbus) { wpc->p9221_check_vbus = true; wpc->vbus_status = vbus; hook_call_deferred(&p9221_detect_work_data, P9221_NOTIFIER_DELAY_MS); } void wireless_power_charger_task(void *u) { while (1) { int ret, irq_src; task_wait_event(-1); ret = p9221_read16(P9221_INT_REG, &irq_src); if (ret) { CPRINTS("Failed to read INT REG"); continue; } CPRINTS("INT SRC 0x%04x", irq_src); if (p9221r7_clear_interrupts(irq_src)) continue; if (irq_src & P9221_STAT_VRECT) { CPRINTS("VRECTON, online=%d", wpc->online); if (!wpc->online) { wpc->p9221_check_det = true; hook_call_deferred(&p9221_detect_work_data, P9221_NOTIFIER_DELAY_MS); } } p9221r7_irq_handler(irq_src); } }