/* Copyright (c) 2012-2018, The Linux Foundation. All rights reserved. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License version 2 and * only version 2 as published by the Free Software Foundation. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * */ #include "tsens.h" #include "tsens-mtc.h" struct tsens_device *tsens_controller_is_present(void) { struct tsens_device *tmdev_chip = NULL; if (list_empty(&tsens_device_list)) { pr_err("%s: TSENS controller not available\n", __func__); return tmdev_chip; } list_for_each_entry(tmdev_chip, &tsens_device_list, list) return tmdev_chip; return tmdev_chip; } EXPORT_SYMBOL(tsens_controller_is_present); int tsens_mtc_reset_history_counter(unsigned int zone) { unsigned int reg_cntl, is_valid; void __iomem *sensor_addr; struct tsens_device *tmdev = NULL; if (zone > TSENS_NUM_MTC_ZONES_SUPPORT) return -EINVAL; tmdev = tsens_controller_is_present(); if (!tmdev) { pr_err("No TSENS controller present\n"); return -EPROBE_DEFER; } sensor_addr = TSENS_TM_MTC_ZONE0_SW_MASK_ADDR(tmdev->tsens_tm_addr); reg_cntl = readl_relaxed((sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); is_valid = (reg_cntl & TSENS_RESET_HISTORY_MASK) >> TSENS_RESET_HISTORY_SHIFT; if (!is_valid) { /*Enable the bit to reset counter*/ writel_relaxed(reg_cntl | (1 << TSENS_RESET_HISTORY_SHIFT), (sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); reg_cntl = readl_relaxed((sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); pr_debug("tsens : zone =%d reg=%x\n", zone, reg_cntl); } /*Disable the bit to start counter*/ writel_relaxed(reg_cntl & ~(1 << TSENS_RESET_HISTORY_SHIFT), (sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); reg_cntl = readl_relaxed((sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); pr_debug("tsens : zone =%d reg=%x\n", zone, reg_cntl); return 0; } EXPORT_SYMBOL(tsens_mtc_reset_history_counter); int tsens_set_mtc_zone_sw_mask(unsigned int zone, unsigned int th1_enable, unsigned int th2_enable) { unsigned int reg_cntl; void __iomem *sensor_addr; struct tsens_device *tmdev = NULL; u32 ver_major, ver_minor; if (zone > TSENS_NUM_MTC_ZONES_SUPPORT) return -EINVAL; tmdev = tsens_controller_is_present(); if (!tmdev) { pr_err("No TSENS controller present\n"); return -EPROBE_DEFER; } ver_major = tmdev->ctrl_data->ver_major; ver_minor = tmdev->ctrl_data->ver_minor; if (ver_major == 1 && ver_minor == 4) { sensor_addr = TSENS_TM_MTC_ZONE0_SW_MASK_ADDR_V14 (tmdev->tsens_tm_addr); } else { sensor_addr = TSENS_TM_MTC_ZONE0_SW_MASK_ADDR (tmdev->tsens_tm_addr); } if (th1_enable && th2_enable) writel_relaxed(TSENS_MTC_IN_EFFECT, (sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); if (!th1_enable && !th2_enable) writel_relaxed(TSENS_MTC_DISABLE, (sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); if (th1_enable && !th2_enable) writel_relaxed(TSENS_TH1_MTC_IN_EFFECT, (sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); if (!th1_enable && th2_enable) writel_relaxed(TSENS_TH2_MTC_IN_EFFECT, (sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); reg_cntl = readl_relaxed((sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); pr_debug("tsens : zone =%d th1=%d th2=%d reg=%x\n", zone, th1_enable, th2_enable, reg_cntl); return 0; } EXPORT_SYMBOL(tsens_set_mtc_zone_sw_mask); int tsens_get_mtc_zone_log(unsigned int zone, void *zone_log) { unsigned int i, reg_cntl, is_valid, log[TSENS_MTC_ZONE_LOG_SIZE]; int *zlog = (int *)zone_log; void __iomem *sensor_addr; struct tsens_device *tmdev = NULL; u32 ver_major, ver_minor; if (zone > TSENS_NUM_MTC_ZONES_SUPPORT) return -EINVAL; tmdev = tsens_controller_is_present(); if (!tmdev) { pr_err("No TSENS controller present\n"); return -EPROBE_DEFER; } ver_major = tmdev->ctrl_data->ver_major; ver_minor = tmdev->ctrl_data->ver_minor; if (ver_major == 1 && ver_minor == 4) sensor_addr = TSENS_TM_MTC_ZONE0_LOG_V14(tmdev->tsens_tm_addr); else sensor_addr = TSENS_TM_MTC_ZONE0_LOG(tmdev->tsens_tm_addr); reg_cntl = readl_relaxed((sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); is_valid = (reg_cntl & TSENS_LOGS_VALID_MASK) >> TSENS_LOGS_VALID_SHIFT; if (is_valid) { log[0] = (reg_cntl & TSENS_LOGS_LATEST_MASK); log[1] = (reg_cntl & TSENS_LOGS_LOG1_MASK) >> TSENS_LOGS_LOG1_SHIFT; log[2] = (reg_cntl & TSENS_LOGS_LOG2_MASK) >> TSENS_LOGS_LOG2_SHIFT; log[3] = (reg_cntl & TSENS_LOGS_LOG3_MASK) >> TSENS_LOGS_LOG3_SHIFT; log[4] = (reg_cntl & TSENS_LOGS_LOG4_MASK) >> TSENS_LOGS_LOG4_SHIFT; log[5] = (reg_cntl & TSENS_LOGS_LOG5_MASK) >> TSENS_LOGS_LOG5_SHIFT; for (i = 0; i < (TSENS_MTC_ZONE_LOG_SIZE); i++) { *(zlog+i) = log[i]; pr_debug("Log[%d]=%d\n", i, log[i]); } } else { pr_debug("tsens: Valid bit disabled\n"); return -EINVAL; } return 0; } EXPORT_SYMBOL(tsens_get_mtc_zone_log); int tsens_get_mtc_zone_history(unsigned int zone, void *zone_hist) { unsigned int i, reg_cntl, hist[TSENS_MTC_ZONE_HISTORY_SIZE]; int *zhist = (int *)zone_hist; void __iomem *sensor_addr; struct tsens_device *tmdev = NULL; if (zone > TSENS_NUM_MTC_ZONES_SUPPORT) return -EINVAL; tmdev = tsens_controller_is_present(); if (!tmdev) { pr_err("No TSENS controller present\n"); return -EPROBE_DEFER; } sensor_addr = TSENS_TM_MTC_ZONE0_HISTORY(tmdev->tsens_tm_addr); reg_cntl = readl_relaxed((sensor_addr + (zone * TSENS_SN_ADDR_OFFSET))); hist[0] = (reg_cntl & TSENS_PS_COOL_CMD_MASK); hist[1] = (reg_cntl & TSENS_PS_YELLOW_CMD_MASK) >> TSENS_PS_YELLOW_CMD_SHIFT; hist[2] = (reg_cntl & TSENS_PS_RED_CMD_MASK) >> TSENS_PS_RED_CMD_SHIFT; for (i = 0; i < (TSENS_MTC_ZONE_HISTORY_SIZE); i++) { *(zhist+i) = hist[i]; pr_debug("tsens : %d\n", hist[i]); } return 0; } EXPORT_SYMBOL(tsens_get_mtc_zone_history);