#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "mt-plat/mtk_thermal_monitor.h" #include "mtk_thermal_typedefs.h" #include "mach/mt_thermal.h" #include #include #include /* ************************************ */ /* Weak functions */ /* ************************************ */ int __attribute__ ((weak)) read_tbat_value(void) { pr_err("E_WF: %s doesn't exist\n", __func__); return 30; } /* ************************************ */ static kuid_t uid = KUIDT_INIT(0); static kgid_t gid = KGIDT_INIT(1000); static unsigned int interval; /* seconds, 0 : no auto polling */ static int trip_temp[10] = { 120000, 110000, 100000, 90000, 80000, 70000, 65000, 60000, 55000, 50000 }; /* static unsigned int cl_dev_dis_charge_state = 0; */ static unsigned int cl_dev_sysrst_state; static struct thermal_zone_device *thz_dev; /* static struct thermal_cooling_device *cl_dev_dis_charge; */ static struct thermal_cooling_device *cl_dev_sysrst; static int mtktsbattery_debug_log; static int kernelmode; static int g_THERMAL_TRIP[10] = { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }; static int num_trip; static char g_bind0[20] = { 0 }; static char g_bind1[20] = { 0 }; static char g_bind2[20] = { 0 }; static char g_bind3[20] = { 0 }; static char g_bind4[20] = { 0 }; static char g_bind5[20] = { 0 }; static char g_bind6[20] = { 0 }; static char g_bind7[20] = { 0 }; static char g_bind8[20] = { 0 }; static char g_bind9[20] = { 0 }; /** * If curr_temp >= polling_trip_temp1, use interval * else if cur_temp >= polling_trip_temp2 && curr_temp < polling_trip_temp1, use interval*polling_factor1 * else, use interval*polling_factor2 */ static int polling_trip_temp1 = 40000; static int polling_trip_temp2 = 20000; static int polling_factor1 = 5000; static int polling_factor2 = 10000; /* static int battery_write_flag=0; */ #define mtktsbattery_TEMP_CRIT 60000 /* 60.000 degree Celsius */ #define mtktsbattery_dprintk(fmt, args...) \ do { \ if (mtktsbattery_debug_log) { \ pr_debug("Power/Battery_Thermal" fmt, ##args); \ } \ } while (0) /* * kernel fopen/fclose */ /* static mm_segment_t oldfs; static void my_close(int fd) { set_fs(oldfs); sys_close(fd); } static int my_open(char *fname, int flag) { oldfs = get_fs(); set_fs(KERNEL_DS); return sys_open(fname, flag, 0); } */ static int get_hw_battery_temp(void) { /* int fd; char buf[64]; char *pmtdbufp = NULL; ssize_t pmtdsize; char *pvalue = NULL; int got_value=0; //open file and read current value fd = my_open("/sys/class/power_supply/battery/batt_temp", O_RDONLY); if (fd < 0) { mtktsbattery_dprintk("[get_hw_battery_temp]: open file fail"); return 0; } mtktsbattery_dprintk("[get_hw_battery_temp]: open file ok"); buf[sizeof(buf) - 1] = '\0'; pmtdsize = sys_read(fd, buf, sizeof(buf) - 1); pmtdbufp = buf; got_value = simple_strtol(pmtdbufp,&pvalue,10); // close file my_close(fd); // debug mtktsbattery_dprintk("[get_hw_battery_temp]: got_value=%d\n", got_value); return got_value; */ int ret = 0; #if defined(CONFIG_POWER_EXT) /* EVB */ ret = -1270; #else /* Phone */ ret = read_tbat_value(); ret = ret * 10; #endif return ret; } static DEFINE_MUTEX(Battery_lock); int ts_battery_at_boot_time = 0; static int mtktsbattery_get_hw_temp(void) { int t_ret = 0; static int battery[60] = { 0 }; static int counter = 0, first_time; if (ts_battery_at_boot_time == 0) { ts_battery_at_boot_time = 1; mtktsbattery_dprintk ("[mtktsbattery_get_hw_temp] at boot time, return 25000 as default\n"); battery[counter] = 25000; counter++; return 25000; } mutex_lock(&Battery_lock); /* get HW battery temp (TSBATTERY) */ /* cat /sys/class/power_supply/battery/batt_temp */ t_ret = get_hw_battery_temp(); t_ret = t_ret * 100; mutex_unlock(&Battery_lock); if (t_ret) mtktsbattery_dprintk("[mtktsbattery_get_hw_temp] counter=%d, first_time =%d\n", counter, first_time); mtktsbattery_dprintk("[mtktsbattery_get_hw_temp] T_Battery, %d\n", t_ret); return t_ret; } static int mtktsbattery_get_temp(struct thermal_zone_device *thermal, unsigned long *t) { *t = mtktsbattery_get_hw_temp(); if ((int)*t >= polling_trip_temp1) thermal->polling_delay = interval * 1000; else if ((int)*t < polling_trip_temp2) thermal->polling_delay = interval * polling_factor2; else thermal->polling_delay = interval * polling_factor1; return 0; } static int mtktsbattery_bind(struct thermal_zone_device *thermal, struct thermal_cooling_device *cdev) { int table_val = 0; if (!strcmp(cdev->type, g_bind0)) { table_val = 0; mtktsbattery_dprintk("[mtktsbattery_bind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind1)) { table_val = 1; mtktsbattery_dprintk("[mtktsbattery_bind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind2)) { table_val = 2; mtktsbattery_dprintk("[mtktsbattery_bind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind3)) { table_val = 3; mtktsbattery_dprintk("[mtktsbattery_bind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind4)) { table_val = 4; mtktsbattery_dprintk("[mtktsbattery_bind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind5)) { table_val = 5; mtktsbattery_dprintk("[mtktsbattery_bind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind6)) { table_val = 6; mtktsbattery_dprintk("[mtktsbattery_bind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind7)) { table_val = 7; mtktsbattery_dprintk("[mtktsbattery_bind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind8)) { table_val = 8; mtktsbattery_dprintk("[mtktsbattery_bind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind9)) { table_val = 9; mtktsbattery_dprintk("[mtktsbattery_bind] %s\n", cdev->type); } else { return 0; } if (mtk_thermal_zone_bind_cooling_device(thermal, table_val, cdev)) { mtktsbattery_dprintk("[mtktsbattery_bind] error binding cooling dev\n"); return -EINVAL; } mtktsbattery_dprintk("[mtktsbattery_bind] binding OK, %d\n", table_val); return 0; } static int mtktsbattery_unbind(struct thermal_zone_device *thermal, struct thermal_cooling_device *cdev) { int table_val = 0; if (!strcmp(cdev->type, g_bind0)) { table_val = 0; mtktsbattery_dprintk("[mtktsbattery_unbind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind1)) { table_val = 1; mtktsbattery_dprintk("[mtktsbattery_unbind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind2)) { table_val = 2; mtktsbattery_dprintk("[mtktsbattery_unbind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind3)) { table_val = 3; mtktsbattery_dprintk("[mtktsbattery_unbind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind4)) { table_val = 4; mtktsbattery_dprintk("[mtktsbattery_unbind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind5)) { table_val = 5; mtktsbattery_dprintk("[mtktsbattery_unbind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind6)) { table_val = 6; mtktsbattery_dprintk("[mtktsbattery_unbind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind7)) { table_val = 7; mtktsbattery_dprintk("[mtktsbattery_unbind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind8)) { table_val = 8; mtktsbattery_dprintk("[mtktsbattery_unbind] %s\n", cdev->type); } else if (!strcmp(cdev->type, g_bind9)) { table_val = 9; mtktsbattery_dprintk("[mtktsbattery_unbind] %s\n", cdev->type); } else return 0; if (thermal_zone_unbind_cooling_device(thermal, table_val, cdev)) { mtktsbattery_dprintk("[mtktsbattery_unbind] error unbinding cooling dev\n"); return -EINVAL; } mtktsbattery_dprintk("[mtktsbattery_unbind] unbinding OK\n"); return 0; } static int mtktsbattery_get_mode(struct thermal_zone_device *thermal, enum thermal_device_mode *mode) { *mode = (kernelmode) ? THERMAL_DEVICE_ENABLED : THERMAL_DEVICE_DISABLED; return 0; } static int mtktsbattery_set_mode(struct thermal_zone_device *thermal, enum thermal_device_mode mode) { kernelmode = mode; return 0; } static int mtktsbattery_get_trip_type(struct thermal_zone_device *thermal, int trip, enum thermal_trip_type *type) { *type = g_THERMAL_TRIP[trip]; return 0; } static int mtktsbattery_get_trip_temp(struct thermal_zone_device *thermal, int trip, unsigned long *temp) { *temp = trip_temp[trip]; return 0; } static int mtktsbattery_get_crit_temp(struct thermal_zone_device *thermal, unsigned long *temperature) { *temperature = mtktsbattery_TEMP_CRIT; return 0; } /* bind callback functions to thermalzone */ static struct thermal_zone_device_ops mtktsbattery_dev_ops = { .bind = mtktsbattery_bind, .unbind = mtktsbattery_unbind, .get_temp = mtktsbattery_get_temp, .get_mode = mtktsbattery_get_mode, .set_mode = mtktsbattery_set_mode, .get_trip_type = mtktsbattery_get_trip_type, .get_trip_temp = mtktsbattery_get_trip_temp, .get_crit_temp = mtktsbattery_get_crit_temp, }; /* static int dis_charge_get_max_state(struct thermal_cooling_device *cdev, unsigned long *state) { *state = 1; return 0; } static int dis_charge_get_cur_state(struct thermal_cooling_device *cdev, unsigned long *state) { *state = cl_dev_dis_charge_state; return 0; } static int dis_charge_set_cur_state(struct thermal_cooling_device *cdev, unsigned long state) { cl_dev_dis_charge_state = state; if(cl_dev_dis_charge_state == 1) { mtktsbattery_dprintk("[dis_charge_set_cur_state] disable charging\n"); } return 0; } */ static int tsbat_sysrst_get_max_state(struct thermal_cooling_device *cdev, unsigned long *state) { *state = 1; return 0; } static int tsbat_sysrst_get_cur_state(struct thermal_cooling_device *cdev, unsigned long *state) { *state = cl_dev_sysrst_state; return 0; } static int tsbat_sysrst_set_cur_state(struct thermal_cooling_device *cdev, unsigned long state) { cl_dev_sysrst_state = state; if (cl_dev_sysrst_state == 1) { pr_debug("Power/battery_Thermal: reset, reset, reset!!!"); pr_debug("@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@"); pr_debug("*****************************************"); pr_debug("@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@@"); /* BUG(); */ /* arch_reset(0,NULL); */ *(unsigned int *)0x0 = 0xdead; /* To trigger data abort to reset the system for thermal protection. */ } return 0; } /* static struct thermal_cooling_device_ops mtktsbattery_cooling_dis_charge_ops = { .get_max_state = dis_charge_get_max_state, .get_cur_state = dis_charge_get_cur_state, .set_cur_state = dis_charge_set_cur_state, };*/ static struct thermal_cooling_device_ops mtktsbattery_cooling_sysrst_ops = { .get_max_state = tsbat_sysrst_get_max_state, .get_cur_state = tsbat_sysrst_get_cur_state, .set_cur_state = tsbat_sysrst_set_cur_state, }; static int mtktsbattery_read(struct seq_file *m, void *v) /* static int mtktsbattery_read(char *buf, char **start, off_t off, int count, int *eof, void *data) */ { seq_printf(m, "[mtktsbattery_read] trip_0_temp=%d,trip_1_temp=%d,trip_2_temp=%d,trip_3_temp=%d,\n", trip_temp[0], trip_temp[1], trip_temp[2], trip_temp[3]); seq_printf(m, "trip_4_temp=%d,trip_5_temp=%d,trip_6_temp=%d,trip_7_temp=%d,trip_8_temp=%d,trip_9_temp=%d,\n", trip_temp[4], trip_temp[5], trip_temp[6], trip_temp[7], trip_temp[8], trip_temp[9]); seq_printf(m, "g_THERMAL_TRIP_0=%d,g_THERMAL_TRIP_1=%d,g_THERMAL_TRIP_2=%d,g_THERMAL_TRIP_3=%d,", g_THERMAL_TRIP[0], g_THERMAL_TRIP[1], g_THERMAL_TRIP[2], g_THERMAL_TRIP[3]); seq_printf(m, "g_THERMAL_TRIP_4=%d,g_THERMAL_TRIP_5=%d,g_THERMAL_TRIP_6=%d,g_THERMAL_TRIP_7=%d,", g_THERMAL_TRIP[4], g_THERMAL_TRIP[5], g_THERMAL_TRIP[6], g_THERMAL_TRIP[7]); seq_printf(m, "g_THERMAL_TRIP_8=%d,g_THERMAL_TRIP_9=%d,\n", g_THERMAL_TRIP[8], g_THERMAL_TRIP[9]); seq_printf(m, "cooldev0=%s,cooldev1=%s,cooldev2=%s,cooldev3=%s,cooldev4=%s,\n", g_bind0, g_bind1, g_bind2, g_bind3, g_bind4); seq_printf(m, "cooldev5=%s,cooldev6=%s,cooldev7=%s,cooldev8=%s,cooldev9=%s,time_ms=%d\n", g_bind5, g_bind6, g_bind7, g_bind8, g_bind9, interval * 1000); return 0; } static int mtktsbattery_register_thermal(void); static void mtktsbattery_unregister_thermal(void); static ssize_t mtktsbattery_write(struct file *file, const char __user *buffer, size_t count, loff_t *data) /* static ssize_t mtktsbattery_write(struct file *file, const char *buffer, unsigned long count, void *data) */ { int len = 0, i; struct mtktsbattery_data { int trip[10]; int t_type[10]; char bind0[20], bind1[20], bind2[20], bind3[20], bind4[20]; char bind5[20], bind6[20], bind7[20], bind8[20], bind9[20]; int time_msec; char desc[512]; }; struct mtktsbattery_data *ptr_mtktsbattery_data = kmalloc(sizeof(*ptr_mtktsbattery_data), GFP_KERNEL); if (ptr_mtktsbattery_data == NULL) return -ENOMEM; len = (count < (sizeof(ptr_mtktsbattery_data->desc) - 1)) ? count : (sizeof(ptr_mtktsbattery_data->desc) - 1); if (copy_from_user(ptr_mtktsbattery_data->desc, buffer, len)) { kfree(ptr_mtktsbattery_data); return 0; } ptr_mtktsbattery_data->desc[len] = '\0'; if (sscanf (ptr_mtktsbattery_data->desc, "%d %d %d %s %d %d %s %d %d %s %d %d %s %d %d %s %d %d %s %d %d %s %d %d %s %d %d %s %d %d %s %d", &num_trip, &ptr_mtktsbattery_data->trip[0], &ptr_mtktsbattery_data->t_type[0], ptr_mtktsbattery_data->bind0, &ptr_mtktsbattery_data->trip[1], &ptr_mtktsbattery_data->t_type[1], ptr_mtktsbattery_data->bind1, &ptr_mtktsbattery_data->trip[2], &ptr_mtktsbattery_data->t_type[2], ptr_mtktsbattery_data->bind2, &ptr_mtktsbattery_data->trip[3], &ptr_mtktsbattery_data->t_type[3], ptr_mtktsbattery_data->bind3, &ptr_mtktsbattery_data->trip[4], &ptr_mtktsbattery_data->t_type[4], ptr_mtktsbattery_data->bind4, &ptr_mtktsbattery_data->trip[5], &ptr_mtktsbattery_data->t_type[5], ptr_mtktsbattery_data->bind5, &ptr_mtktsbattery_data->trip[6], &ptr_mtktsbattery_data->t_type[6], ptr_mtktsbattery_data->bind6, &ptr_mtktsbattery_data->trip[7], &ptr_mtktsbattery_data->t_type[7], ptr_mtktsbattery_data->bind7, &ptr_mtktsbattery_data->trip[8], &ptr_mtktsbattery_data->t_type[8], ptr_mtktsbattery_data->bind8, &ptr_mtktsbattery_data->trip[9], &ptr_mtktsbattery_data->t_type[9], ptr_mtktsbattery_data->bind9, &ptr_mtktsbattery_data->time_msec) == 32) { mtktsbattery_dprintk("[mtktsbattery_write] mtktsbattery_unregister_thermal\n"); mtktsbattery_unregister_thermal(); if (num_trip < 0 || num_trip > 10) { aee_kernel_warning_api(__FILE__, __LINE__, DB_OPT_DEFAULT, "mtktsbattery_write", "Bad argument"); mtktsbattery_dprintk("[mtktsbattery_write] bad argument\n"); kfree(ptr_mtktsbattery_data); return -EINVAL; } for (i = 0; i < num_trip; i++) g_THERMAL_TRIP[i] = ptr_mtktsbattery_data->t_type[i]; g_bind0[0] = g_bind1[0] = g_bind2[0] = g_bind3[0] = g_bind4[0] = g_bind5[0] = g_bind6[0] = g_bind7[0] = g_bind8[0] = g_bind9[0] = '\0'; for (i = 0; i < 20; i++) { g_bind0[i] = ptr_mtktsbattery_data->bind0[i]; g_bind1[i] = ptr_mtktsbattery_data->bind1[i]; g_bind2[i] = ptr_mtktsbattery_data->bind2[i]; g_bind3[i] = ptr_mtktsbattery_data->bind3[i]; g_bind4[i] = ptr_mtktsbattery_data->bind4[i]; g_bind5[i] = ptr_mtktsbattery_data->bind5[i]; g_bind6[i] = ptr_mtktsbattery_data->bind6[i]; g_bind7[i] = ptr_mtktsbattery_data->bind7[i]; g_bind8[i] = ptr_mtktsbattery_data->bind8[i]; g_bind9[i] = ptr_mtktsbattery_data->bind9[i]; } mtktsbattery_dprintk("[mtktsbattery_write] g_THERMAL_TRIP_0=%d,g_THERMAL_TRIP_1=%d,", g_THERMAL_TRIP[0], g_THERMAL_TRIP[1]); mtktsbattery_dprintk("g_THERMAL_TRIP_2=%d,g_THERMAL_TRIP_3=%d,g_THERMAL_TRIP_4=%d,", g_THERMAL_TRIP[2], g_THERMAL_TRIP[3], g_THERMAL_TRIP[4]); mtktsbattery_dprintk("g_THERMAL_TRIP_5=%d,g_THERMAL_TRIP_6=%d,g_THERMAL_TRIP_7=%d,", g_THERMAL_TRIP[5], g_THERMAL_TRIP[6], g_THERMAL_TRIP[7]); mtktsbattery_dprintk("g_THERMAL_TRIP_8=%d,g_THERMAL_TRIP_9=%d,\n", g_THERMAL_TRIP[8], g_THERMAL_TRIP[9]); mtktsbattery_dprintk("[mtktsbattery_write] cooldev0=%s,cooldev1=%s,cooldev2=%s,cooldev3=%s,", g_bind0, g_bind1, g_bind2, g_bind3); mtktsbattery_dprintk("cooldev4=%s,cooldev5=%s,cooldev6=%s,cooldev7=%s,cooldev8=%s,cooldev9=%s\n", g_bind4, g_bind5, g_bind6, g_bind7, g_bind8, g_bind9); for (i = 0; i < num_trip; i++) trip_temp[i] = ptr_mtktsbattery_data->trip[i]; interval = ptr_mtktsbattery_data->time_msec / 1000; mtktsbattery_dprintk("[mtktsbattery_write] trip_0_temp=%d,trip_1_temp=%d,trip_2_temp=%d,", trip_temp[0], trip_temp[1], trip_temp[2]); mtktsbattery_dprintk("trip_3_temp=%d,trip_4_temp=%d,trip_5_temp=%d,trip_6_temp=%d,trip_7_temp=%d,", trip_temp[3], trip_temp[4], trip_temp[5], trip_temp[6], trip_temp[7]); mtktsbattery_dprintk("trip_8_temp=%d,trip_9_temp=%d,time_ms=%d\n", trip_temp[8], trip_temp[9], interval * 1000); mtktsbattery_dprintk("[mtktsbattery_write] mtktsbattery_register_thermal\n"); mtktsbattery_register_thermal(); kfree(ptr_mtktsbattery_data); /* battery_write_flag=1; */ return count; } mtktsbattery_dprintk("[mtktsbattery_write] bad argument\n"); aee_kernel_warning_api(__FILE__, __LINE__, DB_OPT_DEFAULT, "mtktsbattery_write", "Bad argument"); kfree(ptr_mtktsbattery_data); return -EINVAL; } void mtkts_battery_cancel_thermal_timer(void) { /* cancel timer */ /*pr_debug("mtkts_battery_cancel_thermal_timer\n"); */ /* stop thermal framework polling when entering deep idle */ /* For charging current throttling during deep idle, this delayed work cannot be canceled. if (thz_dev) cancel_delayed_work(&(thz_dev->poll_queue)); */ return; } void mtkts_battery_start_thermal_timer(void) { /*pr_debug("mtkts_battery_start_thermal_timer\n"); */ /* resume thermal framework polling when leaving deep idle */ /* For charging current throttling during deep idle, this delayed work cannot be canceled. if (thz_dev != NULL && interval != 0) mod_delayed_work(system_freezable_wq, &(thz_dev->poll_queue), round_jiffies(msecs_to_jiffies(3000))); */ return; } int mtktsbattery_register_cooler(void) { /* cooling devices */ cl_dev_sysrst = mtk_thermal_cooling_device_register("mtktsbattery-sysrst", NULL, &mtktsbattery_cooling_sysrst_ops); return 0; } static int mtktsbattery_register_thermal(void) { mtktsbattery_dprintk("[mtktsbattery_register_thermal]\n"); /* trips : trip 0~1 */ thz_dev = mtk_thermal_zone_device_register("mtktsbattery", num_trip, NULL, &mtktsbattery_dev_ops, 0, 0, 0, interval * 1000); return 0; } void mtktsbattery_unregister_cooler(void) { if (cl_dev_sysrst) { mtk_thermal_cooling_device_unregister(cl_dev_sysrst); cl_dev_sysrst = NULL; } } static void mtktsbattery_unregister_thermal(void) { mtktsbattery_dprintk("[mtktsbattery_unregister_thermal]\n"); if (thz_dev) { mtk_thermal_zone_device_unregister(thz_dev); thz_dev = NULL; } } static int mtkts_battery_open(struct inode *inode, struct file *file) { return single_open(file, mtktsbattery_read, NULL); } static const struct file_operations mtkts_battery_fops = { .owner = THIS_MODULE, .open = mtkts_battery_open, .read = seq_read, .llseek = seq_lseek, .write = mtktsbattery_write, .release = single_release, }; static int __init mtktsbattery_init(void) { int err = 0; struct proc_dir_entry *entry = NULL; struct proc_dir_entry *mtktsbattery_dir = NULL; mtktsbattery_dprintk("[mtktsbattery_init]\n"); err = mtktsbattery_register_cooler(); if (err) return err; err = mtktsbattery_register_thermal(); if (err) goto err_unreg; mtktsbattery_dir = mtk_thermal_get_proc_drv_therm_dir_entry(); if (!mtktsbattery_dir) { mtktsbattery_dprintk("%s mkdir /proc/driver/thermal failed\n", __func__); } else { entry = proc_create("tzbattery", S_IRUGO | S_IWUSR | S_IWGRP, mtktsbattery_dir, &mtkts_battery_fops); if (entry) proc_set_user(entry, uid, gid); } return 0; err_unreg: mtktsbattery_unregister_cooler(); return err; } static void __exit mtktsbattery_exit(void) { mtktsbattery_dprintk("[mtktsbattery_exit]\n"); mtktsbattery_unregister_thermal(); mtktsbattery_unregister_cooler(); } module_init(mtktsbattery_init); module_exit(mtktsbattery_exit);