/* * Copyright 2020-2024 NXP * * SPDX-License-Identifier: BSD-3-Clause */ #include #include #include #include #include "upower_api.h" #include "upower_defs.h" #define UPOWER_AP_MU1_ADDR U(0x29280000) struct MU_t *muptr = (struct MU_t *)UPOWER_AP_MU1_ADDR; void upower_apd_inst_isr(upwr_isr_callb txrx_isr, upwr_isr_callb excp_isr) { /* Do nothing */ } int upower_status(int status) { int ret = -1; switch (status) { case 0: VERBOSE("finished successfully!\n"); ret = 0; break; case -1: VERBOSE("memory allocation or resource failed!\n"); break; case -2: VERBOSE("invalid argument!\n"); break; case -3: VERBOSE("called in an invalid API state!\n"); break; default: VERBOSE("invalid return status\n"); break; } return ret; } void upower_wait_resp(void) { while (muptr->RSR.B.RF0 == 0) { udelay(100); } upwr_txrx_isr(); } static void user_upwr_rdy_callb(uint32_t soc, uint32_t vmajor, uint32_t vminor) { NOTICE("%s: soc=%x\n", __func__, soc); NOTICE("%s: RAM version:%d.%d\n", __func__, vmajor, vminor); } int upower_init(void) { int status; status = upwr_init(APD_DOMAIN, muptr, NULL, NULL, upower_apd_inst_isr, NULL); if (upower_status(status)) { ERROR("%s: upower init failure\n", __func__); return -EINVAL; } NOTICE("%s: start uPower RAM service\n", __func__); status = upwr_start(1, user_upwr_rdy_callb); upower_wait_resp(); /* poll status */ if (upower_status(status)) { NOTICE("%s: upower init failure\n", __func__); return status; } return 0; } int upower_pwm(int domain_id, bool pwr_on) { int ret, ret_val; uint32_t swt; if (domain_id == 9U || domain_id == 11U || domain_id == 12U) { swt = BIT_32(12) | BIT_32(11) | BIT_32(10) | BIT_32(9); } else { swt = BIT_32(domain_id); } if (pwr_on) { ret = upwr_pwm_power_on(&swt, NULL, NULL); } else { ret = upwr_pwm_power_off(&swt, NULL, NULL); } if (ret) { NOTICE("%s failed: ret: %d, pwr_on: %d\n", __func__, ret, pwr_on); return ret; } upower_wait_resp(); ret = upwr_poll_req_status(UPWR_SG_PWRMGMT, NULL, NULL, &ret_val, 1000); if (ret != UPWR_REQ_OK) { NOTICE("Failure %d, %s\n", ret, __func__); if (ret == UPWR_REQ_BUSY) { return -EBUSY; } else { return -EINVAL; } } return 0; } int upower_read_temperature(uint32_t sensor_id, int32_t *temperature) { int ret, ret_val; upwr_resp_t err_code; int64_t t; ret = upwr_tpm_get_temperature(sensor_id, NULL); if (ret) { return ret; } upower_wait_resp(); ret = upwr_poll_req_status(UPWR_SG_TEMPM, NULL, &err_code, &ret_val, 1000); if (ret > UPWR_REQ_OK) { return ret; } t = ret_val & 0xff; *temperature = (2673049 * t * t * t / 10000000 + 3734262 * t * t / 100000 + 4487042 * t / 100 - 4698694) / 100000; return 0; } int upower_pmic_i2c_write(uint32_t reg_addr, uint32_t reg_val) { int ret, ret_val; upwr_resp_t err_code; ret = upwr_xcp_i2c_access(0x32, 1, 1, reg_addr, reg_val, NULL); if (ret) { WARN("pmic i2c read failed ret %d\n", ret); return ret; } upower_wait_resp(); ret = upwr_poll_req_status(UPWR_SG_EXCEPT, NULL, &err_code, &ret_val, 1000); if (ret != UPWR_REQ_OK) { WARN("i2c poll Failure %d, err_code %d, ret_val 0x%x\n", ret, err_code, ret_val); return ret; } VERBOSE("PMIC write reg[0x%x], val[0x%x]\n", reg_addr, reg_val); return 0; } int upower_pmic_i2c_read(uint32_t reg_addr, uint32_t *reg_val) { int ret, ret_val; upwr_resp_t err_code; if (reg_val == NULL) { return -1; } ret = upwr_xcp_i2c_access(0x32, -1, 1, reg_addr, 0, NULL); if (ret) { WARN("pmic i2c read failed ret %d\n", ret); return ret; } upower_wait_resp(); ret = upwr_poll_req_status(UPWR_SG_EXCEPT, NULL, &err_code, &ret_val, 1000); if (ret != UPWR_REQ_OK) { WARN("i2c poll Failure %d, err_code %d, ret_val 0x%x\n", ret, err_code, ret_val); return ret; } *reg_val = ret_val; VERBOSE("PMIC read reg[0x%x], val[0x%x]\n", reg_addr, *reg_val); return 0; }