Author | Tokens | Token Proportion | Commits | Commit Proportion |
---|---|---|---|---|
Mike Leach | 4064 | 95.76% | 13 | 48.15% |
Pratik Patel | 76 | 1.79% | 2 | 7.41% |
Mathieu J. Poirier | 40 | 0.94% | 5 | 18.52% |
Suzuki K. Poulose | 23 | 0.54% | 3 | 11.11% |
Russell King | 21 | 0.49% | 1 | 3.70% |
Mian Yousaf Kaukab | 16 | 0.38% | 1 | 3.70% |
Jian Cai | 3 | 0.07% | 1 | 3.70% |
Miaoqian Lin | 1 | 0.02% | 1 | 3.70% |
Total | 4244 | 27 |
// SPDX-License-Identifier: GPL-2.0 /* * Copyright (c) 2020 Linaro Limited, All rights reserved. * Author: Mike Leach <mike.leach@linaro.org> */ #include <linux/platform_device.h> #include <linux/slab.h> #include "coresight-config.h" #include "coresight-etm-perf.h" #include "coresight-syscfg.h" #include "coresight-syscfg-configfs.h" /* * cscfg_ API manages configurations and features for the entire coresight * infrastructure. * * It allows the loading of configurations and features, and loads these into * coresight devices as appropriate. */ /* protect the cscsg_data and device */ static DEFINE_MUTEX(cscfg_mutex); /* only one of these */ static struct cscfg_manager *cscfg_mgr; /* load features and configuations into the lists */ /* get name feature instance from a coresight device list of features */ static struct cscfg_feature_csdev * cscfg_get_feat_csdev(struct coresight_device *csdev, const char *name) { struct cscfg_feature_csdev *feat_csdev = NULL; list_for_each_entry(feat_csdev, &csdev->feature_csdev_list, node) { if (strcmp(feat_csdev->feat_desc->name, name) == 0) return feat_csdev; } return NULL; } /* allocate the device config instance - with max number of used features */ static struct cscfg_config_csdev * cscfg_alloc_csdev_cfg(struct coresight_device *csdev, int nr_feats) { struct cscfg_config_csdev *config_csdev = NULL; struct device *dev = csdev->dev.parent; /* this is being allocated using the devm for the coresight device */ config_csdev = devm_kzalloc(dev, offsetof(struct cscfg_config_csdev, feats_csdev[nr_feats]), GFP_KERNEL); if (!config_csdev) return NULL; config_csdev->csdev = csdev; return config_csdev; } /* Load a config into a device if there are any feature matches between config and device */ static int cscfg_add_csdev_cfg(struct coresight_device *csdev, struct cscfg_config_desc *config_desc) { struct cscfg_config_csdev *config_csdev = NULL; struct cscfg_feature_csdev *feat_csdev; unsigned long flags; int i; /* look at each required feature and see if it matches any feature on the device */ for (i = 0; i < config_desc->nr_feat_refs; i++) { /* look for a matching name */ feat_csdev = cscfg_get_feat_csdev(csdev, config_desc->feat_ref_names[i]); if (feat_csdev) { /* * At least one feature on this device matches the config * add a config instance to the device and a reference to the feature. */ if (!config_csdev) { config_csdev = cscfg_alloc_csdev_cfg(csdev, config_desc->nr_feat_refs); if (!config_csdev) return -ENOMEM; config_csdev->config_desc = config_desc; } config_csdev->feats_csdev[config_csdev->nr_feat++] = feat_csdev; } } /* if matched features, add config to device.*/ if (config_csdev) { spin_lock_irqsave(&csdev->cscfg_csdev_lock, flags); list_add(&config_csdev->node, &csdev->config_csdev_list); spin_unlock_irqrestore(&csdev->cscfg_csdev_lock, flags); } return 0; } /* * Add the config to the set of registered devices - call with mutex locked. * Iterates through devices - any device that matches one or more of the * configuration features will load it, the others will ignore it. */ static int cscfg_add_cfg_to_csdevs(struct cscfg_config_desc *config_desc) { struct cscfg_registered_csdev *csdev_item; int err; list_for_each_entry(csdev_item, &cscfg_mgr->csdev_desc_list, item) { err = cscfg_add_csdev_cfg(csdev_item->csdev, config_desc); if (err) return err; } return 0; } /* * Allocate a feature object for load into a csdev. * memory allocated using the csdev->dev object using devm managed allocator. */ static struct cscfg_feature_csdev * cscfg_alloc_csdev_feat(struct coresight_device *csdev, struct cscfg_feature_desc *feat_desc) { struct cscfg_feature_csdev *feat_csdev = NULL; struct device *dev = csdev->dev.parent; int i; feat_csdev = devm_kzalloc(dev, sizeof(struct cscfg_feature_csdev), GFP_KERNEL); if (!feat_csdev) return NULL; /* parameters are optional - could be 0 */ feat_csdev->nr_params = feat_desc->nr_params; /* * if we need parameters, zero alloc the space here, the load routine in * the csdev device driver will fill out some information according to * feature descriptor. */ if (feat_csdev->nr_params) { feat_csdev->params_csdev = devm_kcalloc(dev, feat_csdev->nr_params, sizeof(struct cscfg_parameter_csdev), GFP_KERNEL); if (!feat_csdev->params_csdev) return NULL; /* * fill in the feature reference in the param - other fields * handled by loader in csdev. */ for (i = 0; i < feat_csdev->nr_params; i++) feat_csdev->params_csdev[i].feat_csdev = feat_csdev; } /* * Always have registers to program - again the load routine in csdev device * will fill out according to feature descriptor and device requirements. */ feat_csdev->nr_regs = feat_desc->nr_regs; feat_csdev->regs_csdev = devm_kcalloc(dev, feat_csdev->nr_regs, sizeof(struct cscfg_regval_csdev), GFP_KERNEL); if (!feat_csdev->regs_csdev) return NULL; /* load the feature default values */ feat_csdev->feat_desc = feat_desc; feat_csdev->csdev = csdev; return feat_csdev; } /* load one feature into one coresight device */ static int cscfg_load_feat_csdev(struct coresight_device *csdev, struct cscfg_feature_desc *feat_desc, struct cscfg_csdev_feat_ops *ops) { struct cscfg_feature_csdev *feat_csdev; unsigned long flags; int err; if (!ops->load_feat) return -EINVAL; feat_csdev = cscfg_alloc_csdev_feat(csdev, feat_desc); if (!feat_csdev) return -ENOMEM; /* load the feature into the device */ err = ops->load_feat(csdev, feat_csdev); if (err) return err; /* add to internal csdev feature list & initialise using reset call */ cscfg_reset_feat(feat_csdev); spin_lock_irqsave(&csdev->cscfg_csdev_lock, flags); list_add(&feat_csdev->node, &csdev->feature_csdev_list); spin_unlock_irqrestore(&csdev->cscfg_csdev_lock, flags); return 0; } /* * Add feature to any matching devices - call with mutex locked. * Iterates through devices - any device that matches the feature will be * called to load it. */ static int cscfg_add_feat_to_csdevs(struct cscfg_feature_desc *feat_desc) { struct cscfg_registered_csdev *csdev_item; int err; list_for_each_entry(csdev_item, &cscfg_mgr->csdev_desc_list, item) { if (csdev_item->match_flags & feat_desc->match_flags) { err = cscfg_load_feat_csdev(csdev_item->csdev, feat_desc, &csdev_item->ops); if (err) return err; } } return 0; } /* check feature list for a named feature - call with mutex locked. */ static bool cscfg_match_list_feat(const char *name) { struct cscfg_feature_desc *feat_desc; list_for_each_entry(feat_desc, &cscfg_mgr->feat_desc_list, item) { if (strcmp(feat_desc->name, name) == 0) return true; } return false; } /* check all feat needed for cfg are in the list - call with mutex locked. */ static int cscfg_check_feat_for_cfg(struct cscfg_config_desc *config_desc) { int i; for (i = 0; i < config_desc->nr_feat_refs; i++) if (!cscfg_match_list_feat(config_desc->feat_ref_names[i])) return -EINVAL; return 0; } /* * load feature - add to feature list. */ static int cscfg_load_feat(struct cscfg_feature_desc *feat_desc) { int err; struct cscfg_feature_desc *feat_desc_exist; /* new feature must have unique name */ list_for_each_entry(feat_desc_exist, &cscfg_mgr->feat_desc_list, item) { if (!strcmp(feat_desc_exist->name, feat_desc->name)) return -EEXIST; } /* add feature to any matching registered devices */ err = cscfg_add_feat_to_csdevs(feat_desc); if (err) return err; list_add(&feat_desc->item, &cscfg_mgr->feat_desc_list); return 0; } /* * load config into the system - validate used features exist then add to * config list. */ static int cscfg_load_config(struct cscfg_config_desc *config_desc) { int err; struct cscfg_config_desc *config_desc_exist; /* new configuration must have a unique name */ list_for_each_entry(config_desc_exist, &cscfg_mgr->config_desc_list, item) { if (!strcmp(config_desc_exist->name, config_desc->name)) return -EEXIST; } /* validate features are present */ err = cscfg_check_feat_for_cfg(config_desc); if (err) return err; /* add config to any matching registered device */ err = cscfg_add_cfg_to_csdevs(config_desc); if (err) return err; /* add config to perf fs to allow selection */ err = etm_perf_add_symlink_cscfg(cscfg_device(), config_desc); if (err) return err; list_add(&config_desc->item, &cscfg_mgr->config_desc_list); atomic_set(&config_desc->active_cnt, 0); return 0; } /* get a feature descriptor by name */ const struct cscfg_feature_desc *cscfg_get_named_feat_desc(const char *name) { const struct cscfg_feature_desc *feat_desc = NULL, *feat_desc_item; mutex_lock(&cscfg_mutex); list_for_each_entry(feat_desc_item, &cscfg_mgr->feat_desc_list, item) { if (strcmp(feat_desc_item->name, name) == 0) { feat_desc = feat_desc_item; break; } } mutex_unlock(&cscfg_mutex); return feat_desc; } /* called with cscfg_mutex held */ static struct cscfg_feature_csdev * cscfg_csdev_get_feat_from_desc(struct coresight_device *csdev, struct cscfg_feature_desc *feat_desc) { struct cscfg_feature_csdev *feat_csdev; list_for_each_entry(feat_csdev, &csdev->feature_csdev_list, node) { if (feat_csdev->feat_desc == feat_desc) return feat_csdev; } return NULL; } int cscfg_update_feat_param_val(struct cscfg_feature_desc *feat_desc, int param_idx, u64 value) { int err = 0; struct cscfg_feature_csdev *feat_csdev; struct cscfg_registered_csdev *csdev_item; mutex_lock(&cscfg_mutex); /* check if any config active & return busy */ if (atomic_read(&cscfg_mgr->sys_active_cnt)) { err = -EBUSY; goto unlock_exit; } /* set the value */ if ((param_idx < 0) || (param_idx >= feat_desc->nr_params)) { err = -EINVAL; goto unlock_exit; } feat_desc->params_desc[param_idx].value = value; /* update loaded instances.*/ list_for_each_entry(csdev_item, &cscfg_mgr->csdev_desc_list, item) { feat_csdev = cscfg_csdev_get_feat_from_desc(csdev_item->csdev, feat_desc); if (feat_csdev) feat_csdev->params_csdev[param_idx].current_value = value; } unlock_exit: mutex_unlock(&cscfg_mutex); return err; } /* * Conditionally up reference count on owner to prevent unload. * * module loaded configs need to be locked in to prevent premature unload. */ static int cscfg_owner_get(struct cscfg_load_owner_info *owner_info) { if ((owner_info->type == CSCFG_OWNER_MODULE) && (!try_module_get(owner_info->owner_handle))) return -EINVAL; return 0; } /* conditionally lower ref count on an owner */ static void cscfg_owner_put(struct cscfg_load_owner_info *owner_info) { if (owner_info->type == CSCFG_OWNER_MODULE) module_put(owner_info->owner_handle); } static void cscfg_remove_owned_csdev_configs(struct coresight_device *csdev, void *load_owner) { struct cscfg_config_csdev *config_csdev, *tmp; if (list_empty(&csdev->config_csdev_list)) return; list_for_each_entry_safe(config_csdev, tmp, &csdev->config_csdev_list, node) { if (config_csdev->config_desc->load_owner == load_owner) list_del(&config_csdev->node); } } static void cscfg_remove_owned_csdev_features(struct coresight_device *csdev, void *load_owner) { struct cscfg_feature_csdev *feat_csdev, *tmp; if (list_empty(&csdev->feature_csdev_list)) return; list_for_each_entry_safe(feat_csdev, tmp, &csdev->feature_csdev_list, node) { if (feat_csdev->feat_desc->load_owner == load_owner) list_del(&feat_csdev->node); } } /* * Unregister all configuration and features from configfs owned by load_owner. * Although this is called without the list mutex being held, it is in the * context of an unload operation which are strictly serialised, * so the lists cannot change during this call. */ static void cscfg_fs_unregister_cfgs_feats(void *load_owner) { struct cscfg_config_desc *config_desc; struct cscfg_feature_desc *feat_desc; list_for_each_entry(config_desc, &cscfg_mgr->config_desc_list, item) { if (config_desc->load_owner == load_owner) cscfg_configfs_del_config(config_desc); } list_for_each_entry(feat_desc, &cscfg_mgr->feat_desc_list, item) { if (feat_desc->load_owner == load_owner) cscfg_configfs_del_feature(feat_desc); } } /* * removal is relatively easy - just remove from all lists, anything that * matches the owner. Memory for the descriptors will be managed by the owner, * memory for the csdev items is devm_ allocated with the individual csdev * devices. */ static void cscfg_unload_owned_cfgs_feats(void *load_owner) { struct cscfg_config_desc *config_desc, *cfg_tmp; struct cscfg_feature_desc *feat_desc, *feat_tmp; struct cscfg_registered_csdev *csdev_item; lockdep_assert_held(&cscfg_mutex); /* remove from each csdev instance feature and config lists */ list_for_each_entry(csdev_item, &cscfg_mgr->csdev_desc_list, item) { /* * for each csdev, check the loaded lists and remove if * referenced descriptor is owned */ cscfg_remove_owned_csdev_configs(csdev_item->csdev, load_owner); cscfg_remove_owned_csdev_features(csdev_item->csdev, load_owner); } /* remove from the config descriptor lists */ list_for_each_entry_safe(config_desc, cfg_tmp, &cscfg_mgr->config_desc_list, item) { if (config_desc->load_owner == load_owner) { etm_perf_del_symlink_cscfg(config_desc); list_del(&config_desc->item); } } /* remove from the feature descriptor lists */ list_for_each_entry_safe(feat_desc, feat_tmp, &cscfg_mgr->feat_desc_list, item) { if (feat_desc->load_owner == load_owner) { list_del(&feat_desc->item); } } } /* * load the features and configs to the lists - called with list mutex held */ static int cscfg_load_owned_cfgs_feats(struct cscfg_config_desc **config_descs, struct cscfg_feature_desc **feat_descs, struct cscfg_load_owner_info *owner_info) { int i, err; lockdep_assert_held(&cscfg_mutex); /* load features first */ if (feat_descs) { for (i = 0; feat_descs[i]; i++) { err = cscfg_load_feat(feat_descs[i]); if (err) { pr_err("coresight-syscfg: Failed to load feature %s\n", feat_descs[i]->name); return err; } feat_descs[i]->load_owner = owner_info; } } /* next any configurations to check feature dependencies */ if (config_descs) { for (i = 0; config_descs[i]; i++) { err = cscfg_load_config(config_descs[i]); if (err) { pr_err("coresight-syscfg: Failed to load configuration %s\n", config_descs[i]->name); return err; } config_descs[i]->load_owner = owner_info; config_descs[i]->available = false; } } return 0; } /* set configurations as available to activate at the end of the load process */ static void cscfg_set_configs_available(struct cscfg_config_desc **config_descs) { int i; lockdep_assert_held(&cscfg_mutex); if (config_descs) { for (i = 0; config_descs[i]; i++) config_descs[i]->available = true; } } /* * Create and register each of the configurations and features with configfs. * Called without mutex being held. */ static int cscfg_fs_register_cfgs_feats(struct cscfg_config_desc **config_descs, struct cscfg_feature_desc **feat_descs) { int i, err; if (feat_descs) { for (i = 0; feat_descs[i]; i++) { err = cscfg_configfs_add_feature(feat_descs[i]); if (err) return err; } } if (config_descs) { for (i = 0; config_descs[i]; i++) { err = cscfg_configfs_add_config(config_descs[i]); if (err) return err; } } return 0; } /** * cscfg_load_config_sets - API function to load feature and config sets. * * Take a 0 terminated array of feature descriptors and/or configuration * descriptors and load into the system. * Features are loaded first to ensure configuration dependencies can be met. * * To facilitate dynamic loading and unloading, features and configurations * have a "load_owner", to allow later unload by the same owner. An owner may * be a loadable module or configuration dynamically created via configfs. * As later loaded configurations can use earlier loaded features, creating load * dependencies, a load order list is maintained. Unload is strictly in the * reverse order to load. * * @config_descs: 0 terminated array of configuration descriptors. * @feat_descs: 0 terminated array of feature descriptors. * @owner_info: Information on the owner of this set. */ int cscfg_load_config_sets(struct cscfg_config_desc **config_descs, struct cscfg_feature_desc **feat_descs, struct cscfg_load_owner_info *owner_info) { int err = 0; mutex_lock(&cscfg_mutex); if (cscfg_mgr->load_state != CSCFG_NONE) { mutex_unlock(&cscfg_mutex); return -EBUSY; } cscfg_mgr->load_state = CSCFG_LOAD; /* first load and add to the lists */ err = cscfg_load_owned_cfgs_feats(config_descs, feat_descs, owner_info); if (err) goto err_clean_load; /* add the load owner to the load order list */ list_add_tail(&owner_info->item, &cscfg_mgr->load_order_list); if (!list_is_singular(&cscfg_mgr->load_order_list)) { /* lock previous item in load order list */ err = cscfg_owner_get(list_prev_entry(owner_info, item)); if (err) goto err_clean_owner_list; } /* * make visible to configfs - configfs manipulation must occur outside * the list mutex lock to avoid circular lockdep issues with configfs * built in mutexes and semaphores. This is safe as it is not possible * to start a new load/unload operation till the current one is done. */ mutex_unlock(&cscfg_mutex); /* create the configfs elements */ err = cscfg_fs_register_cfgs_feats(config_descs, feat_descs); mutex_lock(&cscfg_mutex); if (err) goto err_clean_cfs; /* mark any new configs as available for activation */ cscfg_set_configs_available(config_descs); goto exit_unlock; err_clean_cfs: /* cleanup after error registering with configfs */ cscfg_fs_unregister_cfgs_feats(owner_info); if (!list_is_singular(&cscfg_mgr->load_order_list)) cscfg_owner_put(list_prev_entry(owner_info, item)); err_clean_owner_list: list_del(&owner_info->item); err_clean_load: cscfg_unload_owned_cfgs_feats(owner_info); exit_unlock: cscfg_mgr->load_state = CSCFG_NONE; mutex_unlock(&cscfg_mutex); return err; } EXPORT_SYMBOL_GPL(cscfg_load_config_sets); /** * cscfg_unload_config_sets - unload a set of configurations by owner. * * Dynamic unload of configuration and feature sets is done on the basis of * the load owner of that set. Later loaded configurations can depend on * features loaded earlier. * * Therefore, unload is only possible if:- * 1) no configurations are active. * 2) the set being unloaded was the last to be loaded to maintain dependencies. * * Once the unload operation commences, we disallow any configuration being * made active until it is complete. * * @owner_info: Information on owner for set being unloaded. */ int cscfg_unload_config_sets(struct cscfg_load_owner_info *owner_info) { int err = 0; struct cscfg_load_owner_info *load_list_item = NULL; mutex_lock(&cscfg_mutex); if (cscfg_mgr->load_state != CSCFG_NONE) { mutex_unlock(&cscfg_mutex); return -EBUSY; } /* unload op in progress also prevents activation of any config */ cscfg_mgr->load_state = CSCFG_UNLOAD; /* cannot unload if anything is active */ if (atomic_read(&cscfg_mgr->sys_active_cnt)) { err = -EBUSY; goto exit_unlock; } /* cannot unload if not last loaded in load order */ if (!list_empty(&cscfg_mgr->load_order_list)) { load_list_item = list_last_entry(&cscfg_mgr->load_order_list, struct cscfg_load_owner_info, item); if (load_list_item != owner_info) load_list_item = NULL; } if (!load_list_item) { err = -EINVAL; goto exit_unlock; } /* remove from configfs - again outside the scope of the list mutex */ mutex_unlock(&cscfg_mutex); cscfg_fs_unregister_cfgs_feats(owner_info); mutex_lock(&cscfg_mutex); /* unload everything from lists belonging to load_owner */ cscfg_unload_owned_cfgs_feats(owner_info); /* remove from load order list */ if (!list_is_singular(&cscfg_mgr->load_order_list)) { /* unlock previous item in load order list */ cscfg_owner_put(list_prev_entry(owner_info, item)); } list_del(&owner_info->item); exit_unlock: cscfg_mgr->load_state = CSCFG_NONE; mutex_unlock(&cscfg_mutex); return err; } EXPORT_SYMBOL_GPL(cscfg_unload_config_sets); /* Handle coresight device registration and add configs and features to devices */ /* iterate through config lists and load matching configs to device */ static int cscfg_add_cfgs_csdev(struct coresight_device *csdev) { struct cscfg_config_desc *config_desc; int err = 0; list_for_each_entry(config_desc, &cscfg_mgr->config_desc_list, item) { err = cscfg_add_csdev_cfg(csdev, config_desc); if (err) break; } return err; } /* iterate through feature lists and load matching features to device */ static int cscfg_add_feats_csdev(struct coresight_device *csdev, u32 match_flags, struct cscfg_csdev_feat_ops *ops) { struct cscfg_feature_desc *feat_desc; int err = 0; if (!ops->load_feat) return -EINVAL; list_for_each_entry(feat_desc, &cscfg_mgr->feat_desc_list, item) { if (feat_desc->match_flags & match_flags) { err = cscfg_load_feat_csdev(csdev, feat_desc, ops); if (err) break; } } return err; } /* Add coresight device to list and copy its matching info */ static int cscfg_list_add_csdev(struct coresight_device *csdev, u32 match_flags, struct cscfg_csdev_feat_ops *ops) { struct cscfg_registered_csdev *csdev_item; /* allocate the list entry structure */ csdev_item = kzalloc(sizeof(struct cscfg_registered_csdev), GFP_KERNEL); if (!csdev_item) return -ENOMEM; csdev_item->csdev = csdev; csdev_item->match_flags = match_flags; csdev_item->ops.load_feat = ops->load_feat; list_add(&csdev_item->item, &cscfg_mgr->csdev_desc_list); INIT_LIST_HEAD(&csdev->feature_csdev_list); INIT_LIST_HEAD(&csdev->config_csdev_list); spin_lock_init(&csdev->cscfg_csdev_lock); return 0; } /* remove a coresight device from the list and free data */ static void cscfg_list_remove_csdev(struct coresight_device *csdev) { struct cscfg_registered_csdev *csdev_item, *tmp; list_for_each_entry_safe(csdev_item, tmp, &cscfg_mgr->csdev_desc_list, item) { if (csdev_item->csdev == csdev) { list_del(&csdev_item->item); kfree(csdev_item); break; } } } /** * cscfg_register_csdev - register a coresight device with the syscfg manager. * * Registers the coresight device with the system. @match_flags used to check * if the device is a match for registered features. Any currently registered * configurations and features that match the device will be loaded onto it. * * @csdev: The coresight device to register. * @match_flags: Matching information to load features. * @ops: Standard operations supported by the device. */ int cscfg_register_csdev(struct coresight_device *csdev, u32 match_flags, struct cscfg_csdev_feat_ops *ops) { int ret = 0; mutex_lock(&cscfg_mutex); /* add device to list of registered devices */ ret = cscfg_list_add_csdev(csdev, match_flags, ops); if (ret) goto reg_csdev_unlock; /* now load any registered features and configs matching the device. */ ret = cscfg_add_feats_csdev(csdev, match_flags, ops); if (ret) { cscfg_list_remove_csdev(csdev); goto reg_csdev_unlock; } ret = cscfg_add_cfgs_csdev(csdev); if (ret) { cscfg_list_remove_csdev(csdev); goto reg_csdev_unlock; } pr_info("CSCFG registered %s", dev_name(&csdev->dev)); reg_csdev_unlock: mutex_unlock(&cscfg_mutex); return ret; } EXPORT_SYMBOL_GPL(cscfg_register_csdev); /** * cscfg_unregister_csdev - remove coresight device from syscfg manager. * * @csdev: Device to remove. */ void cscfg_unregister_csdev(struct coresight_device *csdev) { mutex_lock(&cscfg_mutex); cscfg_list_remove_csdev(csdev); mutex_unlock(&cscfg_mutex); } EXPORT_SYMBOL_GPL(cscfg_unregister_csdev); /** * cscfg_csdev_reset_feats - reset features for a CoreSight device. * * Resets all parameters and register values for any features loaded * into @csdev to their default values. * * @csdev: The CoreSight device. */ void cscfg_csdev_reset_feats(struct coresight_device *csdev) { struct cscfg_feature_csdev *feat_csdev; unsigned long flags; spin_lock_irqsave(&csdev->cscfg_csdev_lock, flags); if (list_empty(&csdev->feature_csdev_list)) goto unlock_exit; list_for_each_entry(feat_csdev, &csdev->feature_csdev_list, node) cscfg_reset_feat(feat_csdev); unlock_exit: spin_unlock_irqrestore(&csdev->cscfg_csdev_lock, flags); } EXPORT_SYMBOL_GPL(cscfg_csdev_reset_feats); /* * This activate configuration for either perf or sysfs. Perf can have multiple * active configs, selected per event, sysfs is limited to one. * * Increments the configuration descriptor active count and the global active * count. * * @cfg_hash: Hash value of the selected configuration name. */ static int _cscfg_activate_config(unsigned long cfg_hash) { struct cscfg_config_desc *config_desc; int err = -EINVAL; if (cscfg_mgr->load_state == CSCFG_UNLOAD) return -EBUSY; list_for_each_entry(config_desc, &cscfg_mgr->config_desc_list, item) { if ((unsigned long)config_desc->event_ea->var == cfg_hash) { /* if we happen upon a partly loaded config, can't use it */ if (config_desc->available == false) return -EBUSY; /* must ensure that config cannot be unloaded in use */ err = cscfg_owner_get(config_desc->load_owner); if (err) break; /* * increment the global active count - control changes to * active configurations */ atomic_inc(&cscfg_mgr->sys_active_cnt); /* * mark the descriptor as active so enable config on a * device instance will use it */ atomic_inc(&config_desc->active_cnt); err = 0; dev_dbg(cscfg_device(), "Activate config %s.\n", config_desc->name); break; } } return err; } static void _cscfg_deactivate_config(unsigned long cfg_hash) { struct cscfg_config_desc *config_desc; list_for_each_entry(config_desc, &cscfg_mgr->config_desc_list, item) { if ((unsigned long)config_desc->event_ea->var == cfg_hash) { atomic_dec(&config_desc->active_cnt); atomic_dec(&cscfg_mgr->sys_active_cnt); cscfg_owner_put(config_desc->load_owner); dev_dbg(cscfg_device(), "Deactivate config %s.\n", config_desc->name); break; } } } /* * called from configfs to set/clear the active configuration for use when * using sysfs to control trace. */ int cscfg_config_sysfs_activate(struct cscfg_config_desc *config_desc, bool activate) { unsigned long cfg_hash; int err = 0; mutex_lock(&cscfg_mutex); cfg_hash = (unsigned long)config_desc->event_ea->var; if (activate) { /* cannot be a current active value to activate this */ if (cscfg_mgr->sysfs_active_config) { err = -EBUSY; goto exit_unlock; } err = _cscfg_activate_config(cfg_hash); if (!err) cscfg_mgr->sysfs_active_config = cfg_hash; } else { /* disable if matching current value */ if (cscfg_mgr->sysfs_active_config == cfg_hash) { _cscfg_deactivate_config(cfg_hash); cscfg_mgr->sysfs_active_config = 0; } else err = -EINVAL; } exit_unlock: mutex_unlock(&cscfg_mutex); return err; } /* set the sysfs preset value */ void cscfg_config_sysfs_set_preset(int preset) { mutex_lock(&cscfg_mutex); cscfg_mgr->sysfs_active_preset = preset; mutex_unlock(&cscfg_mutex); } /* * Used by a device to get the config and preset selected as active in configfs, * when using sysfs to control trace. */ void cscfg_config_sysfs_get_active_cfg(unsigned long *cfg_hash, int *preset) { mutex_lock(&cscfg_mutex); *preset = cscfg_mgr->sysfs_active_preset; *cfg_hash = cscfg_mgr->sysfs_active_config; mutex_unlock(&cscfg_mutex); } EXPORT_SYMBOL_GPL(cscfg_config_sysfs_get_active_cfg); /** * cscfg_activate_config - Mark a configuration descriptor as active. * * This will be seen when csdev devices are enabled in the system. * Only activated configurations can be enabled on individual devices. * Activation protects the configuration from alteration or removal while * active. * * Selection by hash value - generated from the configuration name when it * was loaded and added to the cs_etm/configurations file system for selection * by perf. * * @cfg_hash: Hash value of the selected configuration name. */ int cscfg_activate_config(unsigned long cfg_hash) { int err = 0; mutex_lock(&cscfg_mutex); err = _cscfg_activate_config(cfg_hash); mutex_unlock(&cscfg_mutex); return err; } EXPORT_SYMBOL_GPL(cscfg_activate_config); /** * cscfg_deactivate_config - Mark a config descriptor as inactive. * * Decrement the configuration and global active counts. * * @cfg_hash: Hash value of the selected configuration name. */ void cscfg_deactivate_config(unsigned long cfg_hash) { mutex_lock(&cscfg_mutex); _cscfg_deactivate_config(cfg_hash); mutex_unlock(&cscfg_mutex); } EXPORT_SYMBOL_GPL(cscfg_deactivate_config); /** * cscfg_csdev_enable_active_config - Enable matching active configuration for device. * * Enables the configuration selected by @cfg_hash if the configuration is supported * on the device and has been activated. * * If active and supported the CoreSight device @csdev will be programmed with the * configuration, using @preset parameters. * * Should be called before driver hardware enable for the requested device, prior to * programming and enabling the physical hardware. * * @csdev: CoreSight device to program. * @cfg_hash: Selector for the configuration. * @preset: Preset parameter values to use, 0 for current / default values. */ int cscfg_csdev_enable_active_config(struct coresight_device *csdev, unsigned long cfg_hash, int preset) { struct cscfg_config_csdev *config_csdev_active = NULL, *config_csdev_item; const struct cscfg_config_desc *config_desc; unsigned long flags; int err = 0; /* quickly check global count */ if (!atomic_read(&cscfg_mgr->sys_active_cnt)) return 0; /* * Look for matching configuration - set the active configuration * context if found. */ spin_lock_irqsave(&csdev->cscfg_csdev_lock, flags); list_for_each_entry(config_csdev_item, &csdev->config_csdev_list, node) { config_desc = config_csdev_item->config_desc; if ((atomic_read(&config_desc->active_cnt)) && ((unsigned long)config_desc->event_ea->var == cfg_hash)) { config_csdev_active = config_csdev_item; csdev->active_cscfg_ctxt = (void *)config_csdev_active; break; } } spin_unlock_irqrestore(&csdev->cscfg_csdev_lock, flags); /* * If found, attempt to enable */ if (config_csdev_active) { /* * Call the generic routine that will program up the internal * driver structures prior to programming up the hardware. * This routine takes the driver spinlock saved in the configs. */ err = cscfg_csdev_enable_config(config_csdev_active, preset); if (!err) { /* * Successful programming. Check the active_cscfg_ctxt * pointer to ensure no pre-emption disabled it via * cscfg_csdev_disable_active_config() before * we could start. * * Set enabled if OK, err if not. */ spin_lock_irqsave(&csdev->cscfg_csdev_lock, flags); if (csdev->active_cscfg_ctxt) config_csdev_active->enabled = true; else err = -EBUSY; spin_unlock_irqrestore(&csdev->cscfg_csdev_lock, flags); } } return err; } EXPORT_SYMBOL_GPL(cscfg_csdev_enable_active_config); /** * cscfg_csdev_disable_active_config - disable an active config on the device. * * Disables the active configuration on the CoreSight device @csdev. * Disable will save the values of any registers marked in the configurations * as save on disable. * * Should be called after driver hardware disable for the requested device, * after disabling the physical hardware and reading back registers. * * @csdev: The CoreSight device. */ void cscfg_csdev_disable_active_config(struct coresight_device *csdev) { struct cscfg_config_csdev *config_csdev; unsigned long flags; /* * Check if we have an active config, and that it was successfully enabled. * If it was not enabled, we have no work to do, otherwise mark as disabled. * Clear the active config pointer. */ spin_lock_irqsave(&csdev->cscfg_csdev_lock, flags); config_csdev = (struct cscfg_config_csdev *)csdev->active_cscfg_ctxt; if (config_csdev) { if (!config_csdev->enabled) config_csdev = NULL; else config_csdev->enabled = false; } csdev->active_cscfg_ctxt = NULL; spin_unlock_irqrestore(&csdev->cscfg_csdev_lock, flags); /* true if there was an enabled active config */ if (config_csdev) cscfg_csdev_disable_config(config_csdev); } EXPORT_SYMBOL_GPL(cscfg_csdev_disable_active_config); /* Initialise system configuration management device. */ struct device *cscfg_device(void) { return cscfg_mgr ? &cscfg_mgr->dev : NULL; } /* Must have a release function or the kernel will complain on module unload */ static void cscfg_dev_release(struct device *dev) { mutex_lock(&cscfg_mutex); kfree(cscfg_mgr); cscfg_mgr = NULL; mutex_unlock(&cscfg_mutex); } /* a device is needed to "own" some kernel elements such as sysfs entries. */ static int cscfg_create_device(void) { struct device *dev; int err = -ENOMEM; mutex_lock(&cscfg_mutex); if (cscfg_mgr) { err = -EINVAL; goto create_dev_exit_unlock; } cscfg_mgr = kzalloc(sizeof(struct cscfg_manager), GFP_KERNEL); if (!cscfg_mgr) goto create_dev_exit_unlock; /* initialise the cscfg_mgr structure */ INIT_LIST_HEAD(&cscfg_mgr->csdev_desc_list); INIT_LIST_HEAD(&cscfg_mgr->feat_desc_list); INIT_LIST_HEAD(&cscfg_mgr->config_desc_list); INIT_LIST_HEAD(&cscfg_mgr->load_order_list); atomic_set(&cscfg_mgr->sys_active_cnt, 0); cscfg_mgr->load_state = CSCFG_NONE; /* setup the device */ dev = cscfg_device(); dev->release = cscfg_dev_release; dev->init_name = "cs_system_cfg"; err = device_register(dev); if (err) put_device(dev); create_dev_exit_unlock: mutex_unlock(&cscfg_mutex); return err; } /* * Loading and unloading is generally on user discretion. * If exiting due to coresight module unload, we need to unload any configurations that remain, * before we unregister the configfs intrastructure. * * Do this by walking the load_owner list and taking appropriate action, depending on the load * owner type. */ static void cscfg_unload_cfgs_on_exit(void) { struct cscfg_load_owner_info *owner_info = NULL; /* * grab the mutex - even though we are exiting, some configfs files * may still be live till we dump them, so ensure list data is * protected from a race condition. */ mutex_lock(&cscfg_mutex); while (!list_empty(&cscfg_mgr->load_order_list)) { /* remove in reverse order of loading */ owner_info = list_last_entry(&cscfg_mgr->load_order_list, struct cscfg_load_owner_info, item); /* action according to type */ switch (owner_info->type) { case CSCFG_OWNER_PRELOAD: /* * preloaded descriptors are statically allocated in * this module - just need to unload dynamic items from * csdev lists, and remove from configfs directories. */ pr_info("cscfg: unloading preloaded configurations\n"); break; case CSCFG_OWNER_MODULE: /* * this is an error - the loadable module must have been unloaded prior * to the coresight module unload. Therefore that module has not * correctly unloaded configs in its own exit code. * Nothing to do other than emit an error string as the static descriptor * references we need to unload will have disappeared with the module. */ pr_err("cscfg: ERROR: prior module failed to unload configuration\n"); goto list_remove; } /* remove from configfs - outside the scope of the list mutex */ mutex_unlock(&cscfg_mutex); cscfg_fs_unregister_cfgs_feats(owner_info); mutex_lock(&cscfg_mutex); /* Next unload from csdev lists. */ cscfg_unload_owned_cfgs_feats(owner_info); list_remove: /* remove from load order list */ list_del(&owner_info->item); } mutex_unlock(&cscfg_mutex); } static void cscfg_clear_device(void) { cscfg_unload_cfgs_on_exit(); cscfg_configfs_release(cscfg_mgr); device_unregister(cscfg_device()); } /* Initialise system config management API device */ int __init cscfg_init(void) { int err = 0; /* create the device and init cscfg_mgr */ err = cscfg_create_device(); if (err) return err; /* initialise configfs subsystem */ err = cscfg_configfs_init(cscfg_mgr); if (err) goto exit_err; /* preload built-in configurations */ err = cscfg_preload(THIS_MODULE); if (err) goto exit_err; dev_info(cscfg_device(), "CoreSight Configuration manager initialised"); return 0; exit_err: cscfg_clear_device(); return err; } void cscfg_exit(void) { cscfg_clear_device(); }
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