#include "step_counter.h" static struct step_c_context *step_c_context_obj; static struct step_c_init_info *step_counter_init_list[MAX_CHOOSE_STEP_C_NUM] = { 0 }; /* modified */ static void step_c_early_suspend(struct early_suspend *h); static void step_c_late_resume(struct early_suspend *h); static void step_c_work_func(struct work_struct *work) { struct step_c_context *cxt = NULL; int out_size; /* hwm_sensor_data sensor_data; */ int value, status, div; int64_t nt; struct timespec time; int err, idx; cxt = step_c_context_obj; if (NULL == cxt->step_c_data.get_data) STEP_C_LOG("step_c driver not register data path\n"); time.tv_sec = time.tv_nsec = 0; time = get_monotonic_coarse(); nt = time.tv_sec * 1000000000LL + time.tv_nsec; /* add wake lock to make sure data can be read before system suspend */ err = cxt->step_c_data.get_data(&value, &status); if (err) { STEP_C_ERR("get step_c data fails!!\n"); goto step_c_loop; } else { { cxt->drv_data.step_c_data.values[0] = value; cxt->drv_data.step_c_data.status = status; cxt->drv_data.step_c_data.time = nt; } } if (true == cxt->is_first_data_after_enable) { cxt->is_first_data_after_enable = false; /* filter -1 value */ if (STEP_C_INVALID_VALUE == cxt->drv_data.step_c_data.values[0]) { STEP_C_LOG(" read invalid data\n"); goto step_c_loop; } } /* report data to input device */ /* printk("new step_c work run....\n"); */ STEP_C_LOG("step_c data[%d]\n", cxt->drv_data.step_c_data.values[0]); step_c_data_report(cxt->idev, cxt->drv_data.step_c_data.values[0], cxt->drv_data.step_c_data.status); step_c_loop: if (true == cxt->is_polling_run) mod_timer(&cxt->timer, jiffies + atomic_read(&cxt->delay) / (1000 / HZ)); } static void step_c_poll(unsigned long data) { struct step_c_context *obj = (struct step_c_context *)data; if (obj != NULL) schedule_work(&obj->report); } static struct step_c_context *step_c_context_alloc_object(void) { struct step_c_context *obj = kzalloc(sizeof(*obj), GFP_KERNEL); STEP_C_LOG("step_c_context_alloc_object++++\n"); if (!obj) { STEP_C_ERR("Alloc step_c object error!\n"); return NULL; } atomic_set(&obj->delay, 200); /*5Hz set work queue delay time 200ms */ atomic_set(&obj->wake, 0); INIT_WORK(&obj->report, step_c_work_func); init_timer(&obj->timer); obj->timer.expires = jiffies + atomic_read(&obj->delay) / (1000 / HZ); obj->timer.function = step_c_poll; obj->timer.data = (unsigned long)obj; obj->is_first_data_after_enable = false; obj->is_polling_run = false; mutex_init(&obj->step_c_op_mutex); obj->is_batch_enable = false; /* for batch mode init */ STEP_C_LOG("step_c_context_alloc_object----\n"); return obj; } int step_notify(STEP_NOTIFY_TYPE type) { int err = 0; int value = 0; struct step_c_context *cxt = NULL; cxt = step_c_context_obj; STEP_C_LOG("step_notify++++\n"); if (type == TYPE_STEP_DETECTOR) { STEP_C_LOG("fwq TYPE_STEP_DETECTOR notify\n"); /* cxt->step_c_data.get_data_step_d(&value); */ /* step_c_data_report(cxt->idev,value,3); */ value = 1; input_report_rel(cxt->idev, EVENT_TYPE_STEP_DETECTOR_VALUE, value); input_sync(cxt->idev); } if (type == TYPE_SIGNIFICANT) { STEP_C_LOG("fwq TYPE_SIGNIFICANT notify\n"); /* cxt->step_c_data.get_data_significant(&value); */ value = 1; input_report_rel(cxt->idev, EVENT_TYPE_SIGNIFICANT_VALUE, value); input_sync(cxt->idev); } return err; } static int step_d_real_enable(int enable) { int err = 0; struct step_c_context *cxt = NULL; cxt = step_c_context_obj; if (1 == enable) { err = cxt->step_c_ctl.enable_step_detect(1); if (err) { err = cxt->step_c_ctl.enable_step_detect(1); if (err) { err = cxt->step_c_ctl.enable_step_detect(1); if (err) STEP_C_ERR("step_d enable(%d) err 3 timers = %d\n", enable, err); } } STEP_C_LOG("step_d real enable\n"); } if (0 == enable) { err = cxt->step_c_ctl.enable_step_detect(0); if (err) STEP_C_ERR("step_d enable(%d) err = %d\n", enable, err); STEP_C_LOG("step_d real disable\n"); } return err; } static int significant_real_enable(int enable) { int err = 0; struct step_c_context *cxt = NULL; cxt = step_c_context_obj; if (1 == enable) { err = cxt->step_c_ctl.enable_significant(1); if (err) { err = cxt->step_c_ctl.enable_significant(1); if (err) { err = cxt->step_c_ctl.enable_significant(1); if (err) STEP_C_ERR ("enable_significant enable(%d) err 3 timers = %d\n", enable, err); } } STEP_C_LOG("enable_significant real enable\n"); } if (0 == enable) { err = cxt->step_c_ctl.enable_significant(0); if (err) STEP_C_ERR("enable_significantenable(%d) err = %d\n", enable, err); STEP_C_LOG("enable_significant real disable\n"); } return err; } static int step_c_real_enable(int enable) { int err = 0; struct step_c_context *cxt = NULL; cxt = step_c_context_obj; if (1 == enable) { if (true == cxt->is_active_data || true == cxt->is_active_nodata) { err = cxt->step_c_ctl.enable_nodata(1); if (err) { err = cxt->step_c_ctl.enable_nodata(1); if (err) { err = cxt->step_c_ctl.enable_nodata(1); if (err) STEP_C_ERR("step_c enable(%d) err 3 timers = %d\n", enable, err); } } STEP_C_LOG("step_c real enable\n"); } } if (0 == enable) { if (false == cxt->is_active_data && false == cxt->is_active_nodata) { err = cxt->step_c_ctl.enable_nodata(0); if (err) STEP_C_ERR("step_c enable(%d) err = %d\n", enable, err); STEP_C_LOG("step_c real disable\n"); } } return err; } static int step_c_enable_data(int enable) { struct step_c_context *cxt = NULL; int err = 0; cxt = step_c_context_obj; if (NULL == cxt->step_c_ctl.open_report_data) { STEP_C_ERR("no step_c control path\n"); return -1; } if (1 == enable) { STEP_C_LOG("STEP_C enable data\n"); cxt->is_active_data = true; cxt->is_first_data_after_enable = true; cxt->step_c_ctl.open_report_data(1); if (false == cxt->is_polling_run && cxt->is_batch_enable == false) { if (false == cxt->step_c_ctl.is_report_input_direct) { mod_timer(&cxt->timer, jiffies + atomic_read(&cxt->delay) / (1000 / HZ)); cxt->is_polling_run = true; } } } if (0 == enable) { STEP_C_LOG("STEP_C disable\n"); cxt->is_active_data = false; cxt->step_c_ctl.open_report_data(0); if (true == cxt->is_polling_run) { if (false == cxt->step_c_ctl.is_report_input_direct) { cxt->is_polling_run = false; del_timer_sync(&cxt->timer); cancel_work_sync(&cxt->report); cxt->drv_data.step_c_data.values[0] = STEP_C_INVALID_VALUE; } } } step_c_real_enable(enable); return 0; } int step_c_enable_nodata(int enable) { struct step_c_context *cxt = NULL; int err = 0; cxt = step_c_context_obj; if (NULL == cxt->step_c_ctl.enable_nodata) { STEP_C_ERR("step_c_enable_nodata:step_c ctl path is NULL\n"); return -1; } if (1 == enable) cxt->is_active_nodata = true; if (0 == enable) cxt->is_active_nodata = false; step_c_real_enable(enable); return 0; } static ssize_t step_c_show_enable_nodata(struct device *dev, struct device_attribute *attr, char *buf) { int len = 0; STEP_C_LOG(" not support now\n"); return len; } static ssize_t step_c_store_enable_nodata(struct device *dev, struct device_attribute *attr, const char *buf, size_t count) { STEP_C_LOG("step_c_store_enable nodata buf=%s\n", buf); mutex_lock(&step_c_context_obj->step_c_op_mutex); struct step_c_context *cxt = NULL; int err = 0; cxt = step_c_context_obj; if (NULL == cxt->step_c_ctl.enable_nodata) { STEP_C_LOG("step_c_ctl enable nodata NULL\n"); mutex_unlock(&step_c_context_obj->step_c_op_mutex); return count; } if (!strncmp(buf, "1", 1)) step_c_enable_nodata(1); else if (!strncmp(buf, "0", 1)) step_c_enable_nodata(0); else STEP_C_ERR(" step_c_store enable nodata cmd error !!\n"); mutex_unlock(&step_c_context_obj->step_c_op_mutex); } static ssize_t step_c_store_active(struct device *dev, struct device_attribute *attr, const char *buf, size_t count) { STEP_C_LOG("step_c_store_active buf=%s\n", buf); struct step_c_context *cxt = NULL; int res = 0; int handle = 0; int en = 0; mutex_lock(&step_c_context_obj->step_c_op_mutex); cxt = step_c_context_obj; if (NULL == cxt->step_c_ctl.open_report_data) { STEP_C_LOG("step_c_ctl enable NULL\n"); mutex_unlock(&step_c_context_obj->step_c_op_mutex); return count; } res = sscanf(buf, "%d,%d", &handle, &en); if (res != 2) STEP_C_LOG(" step_store_active param error: res = %d\n", res); STEP_C_LOG(" step_store_active handle=%d ,en=%d\n", handle, en); switch (handle) { case ID_STEP_COUNTER: if (1 == en) step_c_enable_data(1); else if (0 == en) step_c_enable_data(0); else STEP_C_ERR(" step_c_store_active error !!\n"); break; case ID_STEP_DETECTOR: if (1 == en) step_d_real_enable(1); else if (0 == en) step_d_real_enable(0); else STEP_C_ERR(" step_d_real_enable error !!\n"); break; case ID_SIGNIFICANT_MOTION: if (1 == en) significant_real_enable(1); else if (0 == en) significant_real_enable(0); else STEP_C_ERR(" significant_real_enable error !!\n"); break; } mutex_unlock(&step_c_context_obj->step_c_op_mutex); STEP_C_LOG(" step_c_store_active done\n"); return count; } /*----------------------------------------------------------------------------*/ static ssize_t step_c_show_active(struct device *dev, struct device_attribute *attr, char *buf) { struct step_c_context *cxt = NULL; cxt = step_c_context_obj; int div = cxt->step_c_data.vender_div; STEP_C_LOG("step_c vender_div value: %d\n", div); return snprintf(buf, PAGE_SIZE, "%d\n", div); } static ssize_t step_c_store_delay(struct device *dev, struct device_attribute *attr, const char *buf, size_t count) { mutex_lock(&step_c_context_obj->step_c_op_mutex); struct step_c_context *devobj = (struct step_c_context *)dev_get_drvdata(dev); int delay; int mdelay = 0; struct step_c_context *cxt = NULL; int err = 0; cxt = step_c_context_obj; if (NULL == cxt->step_c_ctl.set_delay) { STEP_C_LOG("step_c_ctl set_delay NULL\n"); mutex_unlock(&step_c_context_obj->step_c_op_mutex); return count; } err = kstrtoint(buf, 10, &delay); if (err != 0) { STEP_C_ERR("invalid format!!\n"); mutex_unlock(&step_c_context_obj->step_c_op_mutex); return count; } if (false == cxt->step_c_ctl.is_report_input_direct) { mdelay = (int)delay / 1000 / 1000; atomic_set(&step_c_context_obj->delay, mdelay); } cxt->step_c_ctl.set_delay(delay); STEP_C_LOG(" step_c_delay %d ns\n", delay); mutex_unlock(&step_c_context_obj->step_c_op_mutex); return count; } static ssize_t step_c_show_delay(struct device *dev, struct device_attribute *attr, char *buf) { int len = 0; STEP_C_LOG(" not support now\n"); return len; } static ssize_t step_c_store_batch(struct device *dev, struct device_attribute *attr, const char *buf, size_t count) { STEP_C_LOG("step_c_store_batch buf=%s\n", buf); mutex_lock(&step_c_context_obj->step_c_op_mutex); struct step_c_context *cxt = NULL; int err = 0; cxt = step_c_context_obj; if (!strncmp(buf, "1", 1)) { cxt->is_batch_enable = true; if (true == cxt->is_polling_run) { cxt->is_polling_run = false; del_timer_sync(&cxt->timer); cancel_work_sync(&cxt->report); cxt->drv_data.step_c_data.values[0] = STEP_C_INVALID_VALUE; cxt->drv_data.step_c_data.values[1] = STEP_C_INVALID_VALUE; cxt->drv_data.step_c_data.values[2] = STEP_C_INVALID_VALUE; } } else if (!strncmp(buf, "0", 1)) { cxt->is_batch_enable = false; if (false == cxt->is_polling_run) { if (false == cxt->step_c_ctl.is_report_input_direct) { mod_timer(&cxt->timer, jiffies + atomic_read(&cxt->delay) / (1000 / HZ)); cxt->is_polling_run = true; } } } else { STEP_C_ERR(" step_c_store_batch error !!\n"); } mutex_unlock(&step_c_context_obj->step_c_op_mutex); STEP_C_LOG(" step_c_store_batch done: %d\n", cxt->is_batch_enable); return count; } static ssize_t step_c_show_batch(struct device *dev, struct device_attribute *attr, char *buf) { return snprintf(buf, PAGE_SIZE, "%d\n", 0); } static ssize_t step_c_store_flush(struct device *dev, struct device_attribute *attr, const char *buf, size_t count) { mutex_lock(&step_c_context_obj->step_c_op_mutex); struct step_c_context *devobj = (struct step_c_context *)dev_get_drvdata(dev); /* do read FIFO data function and report data immediately */ mutex_unlock(&step_c_context_obj->step_c_op_mutex); return count; } static ssize_t step_c_show_flush(struct device *dev, struct device_attribute *attr, char *buf) { return snprintf(buf, PAGE_SIZE, "%d\n", 0); } static ssize_t step_c_show_devnum(struct device *dev, struct device_attribute *attr, char *buf) { char *devname = NULL; devname = dev_name(&step_c_context_obj->idev->dev); return snprintf(buf, PAGE_SIZE, "%s\n", devname + 5); } static int step_counter_remove(struct platform_device *pdev) { STEP_C_LOG("step_counter_remove\n"); return 0; } static int step_counter_probe(struct platform_device *pdev) { STEP_C_LOG("step_counter_probe\n"); return 0; } #ifdef CONFIG_OF static const struct of_device_id step_counter_of_match[] = { {.compatible = "mediatek,step_counter",}, {}, }; #endif static struct platform_driver step_counter_driver = { .probe = step_counter_probe, .remove = step_counter_remove, .driver = { .name = "step_counter", #ifdef CONFIG_OF .of_match_table = step_counter_of_match, #endif } }; static int step_c_real_driver_init(void) { int i = 0; int err = 0; STEP_C_LOG(" step_c_real_driver_init +\n"); for (i = 0; i < MAX_CHOOSE_STEP_C_NUM; i++) { STEP_C_LOG(" i=%d\n", i); if (0 != step_counter_init_list[i]) { STEP_C_LOG(" step_c try to init driver %s\n", step_counter_init_list[i]->name); err = step_counter_init_list[i]->init(); if (0 == err) { STEP_C_LOG(" step_c real driver %s probe ok\n", step_counter_init_list[i]->name); break; } } } if (i == MAX_CHOOSE_STEP_C_NUM) { STEP_C_LOG(" step_c_real_driver_init fail\n"); err = -1; } return err; } int step_c_driver_add(struct step_c_init_info *obj) { int err = 0; int i = 0; STEP_C_FUN(); for (i = 0; i < MAX_CHOOSE_STEP_C_NUM; i++) { if (i == 0) { STEP_C_LOG("register step_counter driver for the first time\n"); if (platform_driver_register(&step_counter_driver)) STEP_C_ERR("failed to register gensor driver already exist\n"); } if (NULL == step_counter_init_list[i]) { obj->platform_diver_addr = &step_counter_driver; step_counter_init_list[i] = obj; break; } } if (NULL == step_counter_init_list[i]) { STEP_C_ERR("STEP_C driver add err\n"); err = -1; } return err; } EXPORT_SYMBOL_GPL(step_c_driver_add); static int step_c_misc_init(struct step_c_context *cxt) { int err = 0; /* kernel-3.10\include\linux\Miscdevice.h */ /* use MISC_DYNAMIC_MINOR exceed 64 */ cxt->mdev.minor = M_STEP_C_MISC_MINOR; cxt->mdev.name = STEP_C_MISC_DEV_NAME; err = misc_register(&cxt->mdev); if (err) STEP_C_ERR("unable to register step_c misc device!!\n"); return err; } static void step_c_input_destroy(struct step_c_context *cxt) { struct input_dev *dev = cxt->idev; input_unregister_device(dev); input_free_device(dev); } static int step_c_input_init(struct step_c_context *cxt) { struct input_dev *dev; int err = 0; dev = input_allocate_device(); if (NULL == dev) return -ENOMEM; dev->name = STEP_C_INPUTDEV_NAME; input_set_capability(dev, EV_REL, EVENT_TYPE_STEP_DETECTOR_VALUE); input_set_capability(dev, EV_REL, EVENT_TYPE_SIGNIFICANT_VALUE); input_set_capability(dev, EV_ABS, EVENT_TYPE_STEP_C_VALUE); input_set_capability(dev, EV_ABS, EVENT_TYPE_STEP_C_STATUS); input_set_abs_params(dev, EVENT_TYPE_STEP_C_VALUE, STEP_C_VALUE_MIN, STEP_C_VALUE_MAX, 0, 0); input_set_abs_params(dev, EVENT_TYPE_STEP_C_STATUS, STEP_C_STATUS_MIN, STEP_C_STATUS_MAX, 0, 0); input_set_drvdata(dev, cxt); set_bit(EV_REL, dev->evbit); err = input_register_device(dev); if (err < 0) { input_free_device(dev); return err; } cxt->idev = dev; return 0; } DEVICE_ATTR(step_cenablenodata, S_IWUSR | S_IRUGO, step_c_show_enable_nodata, step_c_store_enable_nodata); DEVICE_ATTR(step_cactive, S_IWUSR | S_IRUGO, step_c_show_active, step_c_store_active); DEVICE_ATTR(step_cdelay, S_IWUSR | S_IRUGO, step_c_show_delay, step_c_store_delay); DEVICE_ATTR(step_cbatch, S_IWUSR | S_IRUGO, step_c_show_batch, step_c_store_batch); DEVICE_ATTR(step_cflush, S_IWUSR | S_IRUGO, step_c_show_flush, step_c_store_flush); DEVICE_ATTR(step_cdevnum, S_IWUSR | S_IRUGO, step_c_show_devnum, NULL); static struct attribute *step_c_attributes[] = { &dev_attr_step_cenablenodata.attr, &dev_attr_step_cactive.attr, &dev_attr_step_cdelay.attr, &dev_attr_step_cbatch.attr, &dev_attr_step_cflush.attr, &dev_attr_step_cdevnum.attr, NULL }; static struct attribute_group step_c_attribute_group = { .attrs = step_c_attributes }; int step_c_register_data_path(struct step_c_data_path *data) { struct step_c_context *cxt = NULL; int err = 0; cxt = step_c_context_obj; cxt->step_c_data.get_data = data->get_data; cxt->step_c_data.vender_div = data->vender_div; cxt->step_c_data.get_data_significant = data->get_data_significant; cxt->step_c_data.get_data_step_d = data->get_data_step_d; STEP_C_LOG("step_c register data path vender_div: %d\n", cxt->step_c_data.vender_div); if (NULL == cxt->step_c_data.get_data || NULL == cxt->step_c_data.get_data_significant || NULL == cxt->step_c_data.get_data_step_d) { STEP_C_LOG("step_c register data path fail\n"); return -1; } return 0; } int step_c_register_control_path(struct step_c_control_path *ctl) { struct step_c_context *cxt = NULL; int err = 0; cxt = step_c_context_obj; cxt->step_c_ctl.set_delay = ctl->set_delay; cxt->step_c_ctl.open_report_data = ctl->open_report_data; cxt->step_c_ctl.enable_nodata = ctl->enable_nodata; cxt->step_c_ctl.is_support_batch = ctl->is_support_batch; cxt->step_c_ctl.is_report_input_direct = ctl->is_report_input_direct; cxt->step_c_ctl.is_support_batch = ctl->is_support_batch; cxt->step_c_ctl.enable_significant = ctl->enable_significant; cxt->step_c_ctl.enable_step_detect = ctl->enable_step_detect; if (NULL == cxt->step_c_ctl.set_delay || NULL == cxt->step_c_ctl.open_report_data || NULL == cxt->step_c_ctl.enable_nodata || NULL == cxt->step_c_ctl.enable_significant || NULL == cxt->step_c_ctl.enable_step_detect) { STEP_C_LOG("step_c register control path fail\n"); return -1; } /* add misc dev for sensor hal control cmd */ err = step_c_misc_init(step_c_context_obj); if (err) { STEP_C_ERR("unable to register step_c misc device!!\n"); return -2; } err = sysfs_create_group(&step_c_context_obj->mdev.this_device->kobj, &step_c_attribute_group); if (err < 0) { STEP_C_ERR("unable to create step_c attribute file\n"); return -3; } kobject_uevent(&step_c_context_obj->mdev.this_device->kobj, KOBJ_ADD); return 0; } int step_c_data_report(struct input_dev *dev, int value, int status) { /* STEP_C_LOG("+step_c_data_report! %d, %d, %d, %d\n",x,y,z,status); */ input_report_abs(dev, EVENT_TYPE_STEP_C_VALUE, value); input_report_abs(dev, EVENT_TYPE_STEP_C_STATUS, status); input_sync(dev); } static int step_c_probe(struct platform_device *pdev) { int err; STEP_C_LOG("+++++++++++++step_c_probe!!\n"); step_c_context_obj = step_c_context_alloc_object(); if (!step_c_context_obj) { err = -ENOMEM; STEP_C_ERR("unable to allocate devobj!\n"); goto exit_alloc_data_failed; } /* init real step_c driver */ err = step_c_real_driver_init(); if (err) { STEP_C_ERR("step_c real driver init fail\n"); goto real_driver_init_fail; } /* init input dev */ err = step_c_input_init(step_c_context_obj); if (err) { STEP_C_ERR("unable to register step_c input device!\n"); goto exit_alloc_input_dev_failed; } #if defined(CONFIG_HAS_EARLYSUSPEND) && defined(CONFIG_EARLYSUSPEND) atomic_set(&(step_c_context_obj->early_suspend), 0); step_c_context_obj->early_drv.level = EARLY_SUSPEND_LEVEL_STOP_DRAWING - 1, step_c_context_obj->early_drv.suspend = step_c_early_suspend, step_c_context_obj->early_drv.resume = step_c_late_resume, register_early_suspend(&step_c_context_obj->early_drv); #endif STEP_C_LOG("----step_c_probe OK !!\n"); return 0; exit_hwmsen_create_attr_failed: exit_misc_register_failed: exit_err_sysfs: if (err) { STEP_C_ERR("sysfs node creation error\n"); step_c_input_destroy(step_c_context_obj); } real_driver_init_fail: exit_alloc_input_dev_failed: kfree(step_c_context_obj); exit_alloc_data_failed: STEP_C_LOG("----step_c_probe fail !!!\n"); return err; } static int step_c_remove(struct platform_device *pdev) { int err = 0; STEP_C_FUN(f); input_unregister_device(step_c_context_obj->idev); sysfs_remove_group(&step_c_context_obj->idev->dev.kobj, &step_c_attribute_group); err = misc_deregister(&step_c_context_obj->mdev); if (err) STEP_C_ERR("misc_deregister fail: %d\n", err); kfree(step_c_context_obj); return 0; } #if defined(CONFIG_HAS_EARLYSUSPEND) && defined(CONFIG_EARLYSUSPEND) static void step_c_early_suspend(struct early_suspend *h) { atomic_set(&(step_c_context_obj->early_suspend), 1); STEP_C_LOG(" step_c_early_suspend ok------->hwm_obj->early_suspend=%d\n", atomic_read(&(step_c_context_obj->early_suspend))); } /*----------------------------------------------------------------------------*/ static void step_c_late_resume(struct early_suspend *h) { atomic_set(&(step_c_context_obj->early_suspend), 0); STEP_C_LOG(" step_c_late_resume ok------->hwm_obj->early_suspend=%d\n", atomic_read(&(step_c_context_obj->early_suspend))); } #endif static int step_c_suspend(struct platform_device *dev, pm_message_t state) { return 0; } /*----------------------------------------------------------------------------*/ static int step_c_resume(struct platform_device *dev) { return 0; } #ifdef CONFIG_OF static const struct of_device_id m_step_c_pl_of_match[] = { {.compatible = "mediatek,m_step_c_pl",}, {}, }; #endif static struct platform_driver step_c_driver = { .probe = step_c_probe, .remove = step_c_remove, .suspend = step_c_suspend, .resume = step_c_resume, .driver = { .name = STEP_C_PL_DEV_NAME, #ifdef CONFIG_OF .of_match_table = m_step_c_pl_of_match, #endif } }; static int __init step_c_init(void) { STEP_C_FUN(); if (platform_driver_register(&step_c_driver)) { STEP_C_ERR("failed to register step_c driver\n"); return -ENODEV; } return 0; } static void __exit step_c_exit(void) { platform_driver_unregister(&step_c_driver); platform_driver_unregister(&step_counter_driver); } late_initcall(step_c_init); /* module_init(step_c_init); */ /* module_exit(step_c_exit); */ MODULE_LICENSE("GPL"); MODULE_DESCRIPTION("STEP_CMETER device driver"); MODULE_AUTHOR("Mediatek");